VulnCheck has some new, free API endpoints for the cybersecurity community.
Two extremely useful ones are for their extended version of CISA’s KEV, and an in-situ replacement for NVD’s sad excuse for an API and soon-to-be-removed JSON feeds.
There are two ways to work with these APIs. One is retrieve a “backup” of the entire dataset as a ZIP file, and the other is to use the API to retrieve individual CVEs from each “index”.
You’ll need a free API key from VulnCheck to use these APIs.
All code shown makes the assumption that you’ve stored your API key in an environment variable named VULNCHECK_API_KEY
.
After the curl
examples, there’s a section on a small Golang CLI I made to make it easier to get combined extended KEV and NVDv2 CVE information in one CLI call for a given CVE.
Retrieving the complete dataset is a multi-step process. First you make a call to the specific API endpoint for each index to backup. That returns some JSON with a temporary, AWS pre-signed URL (a method to grant temporary access to files stored in AWS S3) to download the ZIP file. Then you download the ZIP file, and finally you extract the contents of the ZIP file into a directory. The output is different for the NVDv2 and extended KEV indexes, but the core process is the same.
Here’s a curl
idiom for the NVDv2 index backup. The result is a directory of uncompressed JSON that’s in the same format as the NVDv2 JSON feeds.
# Grab the temporary AWS pre-signed URL for the NVDv2 index and then download the ZIP file.
curl \
--silent \
--output vcnvd2.zip --url "$(
curl \
--silent \
--cookie "token=${VULNCHECK_API_KEY}" \
--header 'Accept: application/json' \
--url "https://api.vulncheck.com/v3/backup/nist-nvd2" | jq -r '.data[].url'
)"
rm -rf ./nvd2
# unzip it
unzip -q -o -d ./nvd2 vcnvd2.zip
# uncompress the JSON files
ls ./nvd2/*gz | xargs gunzip
tree ./nvd2
./nvd2
├── nvdcve-2.0-000.json
├── nvdcve-2.0-001.json
├── nvdcve-2.0-002.json
├── nvdcve-2.0-003.json
├── nvdcve-2.0-004.json
├── nvdcve-2.0-005.json
├── nvdcve-2.0-006.json
├── nvdcve-2.0-007.json
├── nvdcve-2.0-008.json
├── nvdcve-2.0-009.json
├── nvdcve-2.0-010.json
├── nvdcve-2.0-011.json
├── nvdcve-2.0-012.json
├── nvdcve-2.0-013.json
├── nvdcve-2.0-014.json
├── nvdcve-2.0-015.json
├── nvdcve-2.0-016.json
├── nvdcve-2.0-017.json
├── nvdcve-2.0-018.json
├── nvdcve-2.0-019.json
├── nvdcve-2.0-020.json
├── nvdcve-2.0-021.json
├── nvdcve-2.0-022.json
├── nvdcve-2.0-023.json
├── nvdcve-2.0-024.json
├── nvdcve-2.0-025.json
├── nvdcve-2.0-026.json
├── nvdcve-2.0-027.json
├── nvdcve-2.0-028.json
├── nvdcve-2.0-029.json
├── nvdcve-2.0-030.json
├── nvdcve-2.0-031.json
├── nvdcve-2.0-032.json
├── nvdcve-2.0-033.json
├── nvdcve-2.0-034.json
├── nvdcve-2.0-035.json
├── nvdcve-2.0-036.json
├── nvdcve-2.0-037.json
├── nvdcve-2.0-038.json
├── nvdcve-2.0-039.json
├── nvdcve-2.0-040.json
├── nvdcve-2.0-041.json
├── nvdcve-2.0-042.json
├── nvdcve-2.0-043.json
├── nvdcve-2.0-044.json
├── nvdcve-2.0-045.json
├── nvdcve-2.0-046.json
├── nvdcve-2.0-047.json
├── nvdcve-2.0-048.json
├── nvdcve-2.0-049.json
├── nvdcve-2.0-050.json
├── nvdcve-2.0-051.json
├── nvdcve-2.0-052.json
├── nvdcve-2.0-053.json
├── nvdcve-2.0-054.json
├── nvdcve-2.0-055.json
├── nvdcve-2.0-056.json
├── nvdcve-2.0-057.json
├── nvdcve-2.0-058.json
├── nvdcve-2.0-059.json
├── nvdcve-2.0-060.json
├── nvdcve-2.0-061.json
├── nvdcve-2.0-062.json
├── nvdcve-2.0-063.json
├── nvdcve-2.0-064.json
├── nvdcve-2.0-065.json
├── nvdcve-2.0-066.json
├── nvdcve-2.0-067.json
├── nvdcve-2.0-068.json
├── nvdcve-2.0-069.json
├── nvdcve-2.0-070.json
├── nvdcve-2.0-071.json
├── nvdcve-2.0-072.json
├── nvdcve-2.0-073.json
├── nvdcve-2.0-074.json
├── nvdcve-2.0-075.json
├── nvdcve-2.0-076.json
├── nvdcve-2.0-077.json
├── nvdcve-2.0-078.json
├── nvdcve-2.0-079.json
├── nvdcve-2.0-080.json
├── nvdcve-2.0-081.json
├── nvdcve-2.0-082.json
├── nvdcve-2.0-083.json
├── nvdcve-2.0-084.json
├── nvdcve-2.0-085.json
├── nvdcve-2.0-086.json
├── nvdcve-2.0-087.json
├── nvdcve-2.0-088.json
├── nvdcve-2.0-089.json
├── nvdcve-2.0-090.json
├── nvdcve-2.0-091.json
├── nvdcve-2.0-092.json
├── nvdcve-2.0-093.json
├── nvdcve-2.0-094.json
├── nvdcve-2.0-095.json
├── nvdcve-2.0-096.json
├── nvdcve-2.0-097.json
├── nvdcve-2.0-098.json
├── nvdcve-2.0-099.json
├── nvdcve-2.0-100.json
├── nvdcve-2.0-101.json
├── nvdcve-2.0-102.json
├── nvdcve-2.0-103.json
├── nvdcve-2.0-104.json
├── nvdcve-2.0-105.json
├── nvdcve-2.0-106.json
├── nvdcve-2.0-107.json
├── nvdcve-2.0-108.json
├── nvdcve-2.0-109.json
├── nvdcve-2.0-110.json
├── nvdcve-2.0-111.json
├── nvdcve-2.0-112.json
├── nvdcve-2.0-113.json
├── nvdcve-2.0-114.json
├── nvdcve-2.0-115.json
├── nvdcve-2.0-116.json
├── nvdcve-2.0-117.json
├── nvdcve-2.0-118.json
├── nvdcve-2.0-119.json
├── nvdcve-2.0-120.json
└── nvdcve-2.0-121.json
1 directory, 122 files
Here’s a curl
idiom for the extended KEV index backup. The result is a directory with a single uncompressed JSON that’s in an extended format of what’s in the CISA KEV JSON.s
# Grab the temporary AWS pre-signed URL for the NVDv2 index and then download the ZIP file.
curl \
--silent \
--output vckev.zip --url "$(
curl \
--silent \
--cookie "token=${VULNCHECK_API_KEY}" \
--header 'Accept: application/json' \
--url "https://api.vulncheck.com/v3/backup/vulncheck-kev" | jq -r '.data[].url'
)"
rm -rf ./vckev
# unzip it
unzip -q -o -d ./vckev vckev.zip
tree ./vckev
./vckev
└── vulncheck_known_exploited_vulnerabilities.json
1 directory, 1 file
While there are other, searchable fields for each index, the primary use case for most of us is getting information on individual CVEs. The API calls are virtually identical, apart from the selected index.
NOTE: the examples pipe the output through jq
to make the API results easier to read.
curl \
--silent \
--cookie "token=${VULNCHECK_API_KEY}" \
--header 'Accept: application/json' \
--url "https://api.vulncheck.com/v3/index/nist-nvd2?cve=CVE-2024-23334" | jq
{
"_benchmark": 0.056277,
"_meta": {
"timestamp": "2024-03-23T08:47:17.940032202Z",
"index": "nist-nvd2",
"limit": 100,
"total_documents": 1,
"sort": "_id",
"parameters": [
{
"name": "cve",
"format": "CVE-YYYY-N{4-7}"
},
{
"name": "alias"
},
{
"name": "iava",
"format": "[0-9]{4}[A-Z-0-9]+"
},
{
"name": "threat_actor"
},
{
"name": "mitre_id"
},
{
"name": "misp_id"
},
{
"name": "ransomware"
},
{
"name": "botnet"
},
{
"name": "published"
},
{
"name": "lastModStartDate",
"format": "YYYY-MM-DD"
},
{
"name": "lastModEndDate",
"format": "YYYY-MM-DD"
}
],
"order": "desc",
"page": 1,
"total_pages": 1,
"max_pages": 6,
"first_item": 1,
"last_item": 1
},
"data": [
{
"id": "CVE-2024-23334",
"sourceIdentifier": "[email protected]",
"vulnStatus": "Modified",
"published": "2024-01-29T23:15:08.563",
"lastModified": "2024-02-09T03:15:09.603",
"descriptions": [
{
"lang": "en",
"value": "aiohttp is an asynchronous HTTP client/server framework for asyncio and Python. When using aiohttp as a web server and configuring static routes, it is necessary to specify the root path for static files. Additionally, the option 'follow_symlinks' can be used to determine whether to follow symbolic links outside the static root directory. When 'follow_symlinks' is set to True, there is no validation to check if reading a file is within the root directory. This can lead to directory traversal vulnerabilities, resulting in unauthorized access to arbitrary files on the system, even when symlinks are not present. Disabling follow_symlinks and using a reverse proxy are encouraged mitigations. Version 3.9.2 fixes this issue."
},
{
"lang": "es",
"value": "aiohttp es un framework cliente/servidor HTTP asíncrono para asyncio y Python. Cuando se utiliza aiohttp como servidor web y se configuran rutas estáticas, es necesario especificar la ruta raíz para los archivos estáticos. Además, la opción 'follow_symlinks' se puede utilizar para determinar si se deben seguir enlaces simbólicos fuera del directorio raíz estático. Cuando 'follow_symlinks' se establece en Verdadero, no hay validación para verificar si la lectura de un archivo está dentro del directorio raíz. Esto puede generar vulnerabilidades de directory traversal, lo que resulta en acceso no autorizado a archivos arbitrarios en el sistema, incluso cuando no hay enlaces simbólicos presentes. Se recomiendan como mitigaciones deshabilitar follow_symlinks y usar un proxy inverso. La versión 3.9.2 soluciona este problema."
}
],
"references": [
{
"url": "https://github.com/aio-libs/aiohttp/commit/1c335944d6a8b1298baf179b7c0b3069f10c514b",
"source": "[email protected]",
"tags": [
"Patch"
]
},
{
"url": "https://github.com/aio-libs/aiohttp/pull/8079",
"source": "[email protected]",
"tags": [
"Patch"
]
},
{
"url": "https://github.com/aio-libs/aiohttp/security/advisories/GHSA-5h86-8mv2-jq9f",
"source": "[email protected]",
"tags": [
"Exploit",
"Mitigation",
"Vendor Advisory"
]
},
{
"url": "https://lists.fedoraproject.org/archives/list/[email protected]/message/ICUOCFGTB25WUT336BZ4UNYLSZOUVKBD/",
"source": "[email protected]"
},
{
"url": "https://lists.fedoraproject.org/archives/list/[email protected]/message/XXWVZIVAYWEBHNRIILZVB3R3SDQNNAA7/",
"source": "[email protected]",
"tags": [
"Mailing List"
]
}
],
"metrics": {
"cvssMetricV31": [
{
"source": "[email protected]",
"type": "Primary",
"cvssData": {
"version": "3.1",
"vectorString": "CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:H/I:N/A:N",
"attackVector": "NETWORK",
"attackComplexity": "LOW",
"privilegesRequired": "NONE",
"userInteraction": "NONE",
"scope": "UNCHANGED",
"confidentialityImpact": "HIGH",
"integrityImpact": "NONE",
"availabilityImpact": "NONE",
"baseScore": 7.5,
"baseSeverity": "HIGH"
},
"exploitabilityScore": 3.9,
"impactScore": 3.6
},
{
"source": "[email protected]",
"type": "Secondary",
"cvssData": {
"version": "3.1",
"vectorString": "CVSS:3.1/AV:N/AC:H/PR:N/UI:N/S:U/C:H/I:N/A:N",
"attackVector": "NETWORK",
"attackComplexity": "HIGH",
"privilegesRequired": "NONE",
"userInteraction": "NONE",
"scope": "UNCHANGED",
"confidentialityImpact": "HIGH",
"integrityImpact": "NONE",
"availabilityImpact": "NONE",
"baseScore": 5.9,
"baseSeverity": "MEDIUM"
},
"exploitabilityScore": 2.2,
"impactScore": 3.6
}
]
},
"weaknesses": [
{
"source": "[email protected]",
"type": "Primary",
"description": [
{
"lang": "en",
"value": "CWE-22"
}
]
}
],
"configurations": [
{
"nodes": [
{
"operator": "OR",
"cpeMatch": [
{
"vulnerable": true,
"criteria": "cpe:2.3:a:aiohttp:aiohttp:*:*:*:*:*:*:*:*",
"versionStartIncluding": "1.0.5",
"versionEndExcluding": "3.9.2",
"matchCriteriaId": "CC18B2A9-9D80-4A6E-94E7-8FC010D8FC70"
}
]
}
]
},
{
"nodes": [
{
"operator": "OR",
"cpeMatch": [
{
"vulnerable": true,
"criteria": "cpe:2.3:o:fedoraproject:fedora:39:*:*:*:*:*:*:*",
"matchCriteriaId": "B8EDB836-4E6A-4B71-B9B2-AA3E03E0F646"
}
]
}
]
}
],
"_timestamp": "2024-02-09T05:33:33.170054Z"
}
]
}
curl \
--silent \
--cookie "token=${VULNCHECK_API_KEY}" \
--header 'Accept: application/json' \
--url "https://api.vulncheck.com/v3/index/vulncheck-kev?cve=CVE-2024-23334" | jq
{
"_benchmark": 0.328855,
"_meta": {
"timestamp": "2024-03-23T08:47:41.025967418Z",
"index": "vulncheck-kev",
"limit": 100,
"total_documents": 1,
"sort": "_id",
"parameters": [
{
"name": "cve",
"format": "CVE-YYYY-N{4-7}"
},
{
"name": "alias"
},
{
"name": "iava",
"format": "[0-9]{4}[A-Z-0-9]+"
},
{
"name": "threat_actor"
},
{
"name": "mitre_id"
},
{
"name": "misp_id"
},
{
"name": "ransomware"
},
{
"name": "botnet"
},
{
"name": "published"
},
{
"name": "lastModStartDate",
"format": "YYYY-MM-DD"
},
{
"name": "lastModEndDate",
"format": "YYYY-MM-DD"
},
{
"name": "pubStartDate",
"format": "YYYY-MM-DD"
},
{
"name": "pubEndDate",
"format": "YYYY-MM-DD"
}
],
"order": "desc",
"page": 1,
"total_pages": 1,
"max_pages": 6,
"first_item": 1,
"last_item": 1
},
"data": [
{
"vendorProject": "aiohttp",
"product": "aiohttp",
"shortDescription": "aiohttp is an asynchronous HTTP client/server framework for asyncio and Python. When using aiohttp as a web server and configuring static routes, it is necessary to specify the root path for static files. Additionally, the option 'follow_symlinks' can be used to determine whether to follow symbolic links outside the static root directory. When 'follow_symlinks' is set to True, there is no validation to check if reading a file is within the root directory. This can lead to directory traversal vulnerabilities, resulting in unauthorized access to arbitrary files on the system, even when symlinks are not present. Disabling follow_symlinks and using a reverse proxy are encouraged mitigations. Version 3.9.2 fixes this issue.",
"vulnerabilityName": "aiohttp aiohttp Improper Limitation of a Pathname to a Restricted Directory ('Path Traversal')",
"required_action": "Apply remediations or mitigations per vendor instructions or discontinue use of the product if remediation or mitigations are unavailable.",
"knownRansomwareCampaignUse": "Known",
"cve": [
"CVE-2024-23334"
],
"vulncheck_xdb": [
{
"xdb_id": "231b48941355",
"xdb_url": "https://vulncheck.com/xdb/231b48941355",
"date_added": "2024-02-28T22:30:21Z",
"exploit_type": "infoleak",
"clone_ssh_url": "[email protected]:ox1111/CVE-2024-23334.git"
},
{
"xdb_id": "f1d001911304",
"xdb_url": "https://vulncheck.com/xdb/f1d001911304",
"date_added": "2024-03-19T16:28:56Z",
"exploit_type": "infoleak",
"clone_ssh_url": "[email protected]:jhonnybonny/CVE-2024-23334.git"
}
],
"vulncheck_reported_exploitation": [
{
"url": "https://cyble.com/blog/cgsi-probes-shadowsyndicate-groups-possible-exploitation-of-aiohttp-vulnerability-cve-2024-23334/",
"date_added": "2024-03-15T00:00:00Z"
}
],
"date_added": "2024-03-15T00:00:00Z",
"_timestamp": "2024-03-23T08:27:47.861266Z"
}
]
}
There’s a project on Codeberg that has code and binaries for macOS, Linux, and Windows for a small CLI that gets you combined extended KEV and NVDv2 information all in one call.
The project README has examples and installation instructions.
The post VulnCheck’s Free Community KEV & CVE APIs (Code & Golang CLI Utility) appeared first on rud.is.
*** This is a Security Bloggers Network syndicated blog from rud.is authored by hrbrmstr. Read the original post at: https://rud.is/b/2024/03/23/vulnchecks-free-community-kev-cve-apis-code-golang-cli-utility/