332 lines
13 KiB
Markdown
332 lines
13 KiB
Markdown
---
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stage: Secure
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group: Static Analysis
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info: To determine the technical writer assigned to the Stage/Group associated with this page, see https://about.gitlab.com/handbook/product/ux/technical-writing/#assignments
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type: reference
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---
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# Secure and Govern terminology **(FREE)**
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The glossary of terms aims to achieve the following:
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- Promote a ubiquitous language that can be used everywhere - with customers, on issues, in Slack, in code.
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- Improve the effectiveness of communication between team members.
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- Reduce the potential for miscommunication.
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- Bring new team members and community contributors up to speed faster, reducing the time to productivity.
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The definitions of the terms outlined in this document are in the context of the GitLab
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products. Therefore, a term may have a different meaning to users outside of GitLab.
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## Terms
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### Analyzer
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Software that performs a scan. The scan analyzes an attack surface for vulnerabilities and produces
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a report containing findings. Reports adhere to the [Secure report format](#secure-report-format).
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Analyzers integrate into GitLab using a CI job. The report produced by the analyzer is published as
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an artifact after the job is complete. GitLab ingests this report, allowing users to visualize and
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manage found vulnerabilities. For more information, see [Security Scanner Integration](../../../development/integrations/secure.md).
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Many GitLab analyzers follow a standard approach using Docker to run a wrapped scanner. For example,
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the image `semgrep` is an analyzer that wraps the scanner `Semgrep`.
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### Attack surface
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The different places in an application that are vulnerable to attack. Secure products discover and
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search the attack surface during scans. Each product defines the attack surface differently. For
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example, SAST uses files and line numbers, and DAST uses URLs.
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### Corpus
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The set of meaningful test cases that are generated while the fuzzer is running. Each meaningful
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test case produces new coverage in the tested program. It's advised to re-use the corpus and pass it
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to subsequent runs.
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### CNA
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[CVE](#cve) Numbering Authorities (CNAs) are organizations from around the world that are authorized by
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the [Mitre Corporation](https://cve.mitre.org/) to assign [CVE](#cve)s to vulnerabilities in products or
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services within their respective scope. [GitLab is a CNA](https://about.gitlab.com/security/cve/).
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### CVE
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Common Vulnerabilities and Exposures (CVE®) is a list of common identifiers for publicly known
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cybersecurity vulnerabilities. The list is managed by the [Mitre Corporation](https://cve.mitre.org/).
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### CVSS
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The Common Vulnerability Scoring System (CVSS) is a free and open industry standard for assessing
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the severity of computer system security vulnerabilities.
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### CWE
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Common Weakness Enumeration (CWE™) is a community-developed list of common software and hardware
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weakness types that have security ramifications. Weaknesses are flaws, faults, bugs,
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vulnerabilities, or other errors in software or hardware implementation, code, design, or
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architecture. If left unaddressed, weaknesses could result in systems, networks, or hardware being
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vulnerable to attack. The CWE List and associated classification taxonomy serve as a language that
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you can use to identify and describe these weaknesses in terms of CWEs.
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### Deduplication
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When a category's process deems findings to be the same, or if they are similar enough that a noise reduction is
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required, only one finding is kept and the others are eliminated. Read more about the [deduplication process](../vulnerability_report/pipeline.md#deduplication-process).
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### Duplicate finding
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A legitimate finding that is reported multiple times. This can occur when different scanners
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discover the same finding, or when a single scan inadvertently reports the same finding more than
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once.
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### False positive
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A finding that doesn't exist but is incorrectly reported as existing.
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### Finding
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An asset that has the potential to be vulnerable, identified in a project by an analyzer. Assets
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include but are not restricted to source code, binary packages, containers, dependencies, networks,
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applications, and infrastructure.
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Findings are all potential vulnerability items scanners identify in MRs/feature branches. Only after merging to default does a finding become a [vulnerability](#vulnerability).
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You can interact with vulnerability findings in two ways.
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1. You can open an issue or merge request for the vulnerability finding.
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1. You can dismiss the vulnerability finding. Dismissing the finding hides it from the default views.
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### Grouping
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A flexible and non-destructive way to visually organize vulnerabilities in groups when there are multiple findings
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that are likely related but do not qualify for deduplication. For example, you can include findings that should be
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evaluated together, would be fixed by the same action, or come from the same source. Grouping behavior for vulnerabilities is
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under development and tracked in issue [267588](https://gitlab.com/gitlab-org/gitlab/-/issues/267588).
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### Insignificant finding
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A legitimate finding that a particular customer doesn't care about.
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### Location fingerprint
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A finding's location fingerprint is a text value that's unique for each location on the attack
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surface. Each security product defines this according to its type of attack surface. For example, SAST
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incorporates file path and line number.
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### Package managers and package types
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#### Package managers
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A package manager is a system that manages your project dependencies.
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The package manager provides a method to install new dependencies (also referred to as "packages"), manage where packages are stored on your file system, and offer capabilities for you to publish your own packages.
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#### Package types
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Each package manager, platform, type, or ecosystem has its own conventions and protocols to identify, locate, and provision software packages.
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The following table is a non-exhaustive list of some of the package managers and types referenced in GitLab documentation and software tools.
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<style>
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table.package-managers-and-types tr:nth-child(even) {
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background-color: transparent;
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}
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table.package-managers-and-types td {
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border-left: 1px solid #dbdbdb;
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border-right: 1px solid #dbdbdb;
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border-bottom: 1px solid #dbdbdb;
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}
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table.package-managers-and-types tr td:first-child {
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border-left: 0;
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}
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table.package-managers-and-types tr td:last-child {
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border-right: 0;
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}
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table.package-managers-and-types ul {
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font-size: 1em;
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list-style-type: none;
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padding-left: 0px;
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margin-bottom: 0px;
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}
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</style>
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<table class="package-managers-and-types">
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<thead>
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<tr>
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<th>Package Type</th>
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<th>Package Manager</th>
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</tr>
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</thead>
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<tbody>
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<tr>
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<td>gem</td>
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<td><a href="https://bundler.io/">Bundler</a></td>
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</tr>
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<tr>
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<td>Packagist</td>
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<td><a href="https://getcomposer.org/">Composer</a></td>
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</tr>
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<tr>
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<td>Conan</td>
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<td><a href="https://conan.io/">Conan</a></td>
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</tr>
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<tr>
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<td>go</td>
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<td><a href="https://go.dev/blog/using-go-modules">go</a></td>
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</tr>
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<tr>
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<td rowspan="3">maven</td>
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<td><a href="https://gradle.org/">Gradle</a></td>
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</tr>
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<tr>
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<td><a href="https://maven.apache.org/">Maven</a></td>
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</tr>
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<tr>
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<td><a href="https://www.scala-sbt.org">sbt</a></td>
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</tr>
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<tr>
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<td rowspan="2">npm</td>
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<td><a href="https://www.npmjs.com">npm</a></td>
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</tr>
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<tr>
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<td><a href="https://classic.yarnpkg.com/en">yarn</a></td>
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</tr>
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<tr>
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<td>NuGet</td>
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<td><a href="https://www.nuget.org/">NuGet</a></td>
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</tr>
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<tr>
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<td rowspan="4">PyPI</td>
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<td><a href="https://setuptools.pypa.io/en/latest/">Setuptools</a></td>
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</tr>
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<tr>
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<td><a href="https://pip.pypa.io/en/stable">pip</a></td>
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</tr>
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<tr>
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<td><a href="https://pipenv.pypa.io/en/latest">Pipenv</a></td>
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</tr>
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<tr>
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<td><a href="https://python-poetry.org/">Poetry</a></td>
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</tr>
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</tbody>
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</table>
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### Pipeline Security tab
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A page that displays findings discovered in the associated CI pipeline.
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### Post-filter
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Post-filters help reduce noise in the scanner results and automate manual tasks. You can specify criteria that updates
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or modifies vulnerability data based on scanner results. For example, you can flag findings as likely False Positives
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and automatically resolve vulnerabilities that are no longer detected. These are not permanent actions and can be changed.
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Support for automatically resolving findings is tracked in epic [7478](https://gitlab.com/groups/gitlab-org/-/epics/7478) and
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support for cheap scan is proposed in issue [349926](https://gitlab.com/gitlab-org/gitlab/-/issues/349926).
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### Pre-filter
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An irreversible action that is done to filter out targets before analysis occurs. This is usually provided to allow
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the user to reduce scope and noise as well as speed up the analysis. This should not be done if a record is needed as
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we currently do not store anything related to the skipped/excluded code or assets.
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Examples: `DS_EXCLUDED_PATHS` should `Exclude files and directories from the scan based on the paths provided.`
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### Primary identifier
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A finding's primary identifier is a value that is unique to each finding. The external type and external ID
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of the finding's [first identifier](https://gitlab.com/gitlab-org/security-products/security-report-schemas/-/blob/v2.4.0-rc1/dist/sast-report-format.json#L228)
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combine to create the value.
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Examples of primary identifiers include `PluginID` for OWASP Zed Attack Proxy (ZAP), or `CVE` for
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Trivy. The identifier must be stable. Subsequent scans must return the same value for the
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same finding, even if the location has slightly changed.
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### Report finding
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A [finding](#finding) that only exists in a report produced by an analyzer, and is yet to be
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persisted to the database. The report finding becomes a [vulnerability finding](#vulnerability-finding)
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once it's imported into the database.
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### Scan type (report type)
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Describes the type of scan. This must be one of the following:
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- `api_fuzzing`
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- `container_scanning`
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- `coverage_fuzzing`
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- `dast`
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- `dependency_scanning`
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- `sast`
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- `secret_detection`
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This list is subject to change as scanners are added.
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### Scanner
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Software that can scan for vulnerabilities. The resulting scan report is typically not in the
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[Secure report format](#secure-report-format). Examples include ESLint, Trivy, and ZAP.
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### Secure product
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A group of features related to a specific area of application security with first-class support by
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GitLab.
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Products include Container Scanning, Dependency Scanning, Dynamic Application Security
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Testing (DAST), Secret Detection, Static Application Security Testing (SAST), and Fuzz Testing.
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Each of these products typically include one or more analyzers.
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### Secure report format
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A standard report format that Secure products comply with when creating JSON reports. The format is described by a
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[JSON schema](https://gitlab.com/gitlab-org/security-products/security-report-schemas).
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### Security Dashboard
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Provides an overview of all the vulnerabilities for a project, group, or GitLab instance.
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Vulnerabilities are only created from findings discovered on the project's default branch.
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### Seed corpus
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The set of test cases given as initial input to the fuzz target. This usually speeds up the fuzz
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target substantially. This can be either manually created test cases or auto-generated with the fuzz
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target itself from previous runs.
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### Vendor
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The party maintaining an analyzer. As such, a vendor is responsible for integrating a scanner into
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GitLab and keeping it compatible as they evolve. A vendor isn't necessarily the author or maintainer
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of the scanner, as in the case of using an open core or OSS project as a base solution of an
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offering. For scanners included as part of a GitLab distribution or GitLab subscription, the vendor
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is listed as GitLab.
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### Vulnerability
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A flaw that has a negative impact on the security of its environment. Vulnerabilities describe the
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error or weakness, and don't describe where the error is located (see [finding](#finding)).
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Each vulnerability maps to a unique finding.
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Vulnerabilities exist in the default branch. Findings (see [finding](#finding)) are all potential vulnerability items scanners identify in MRs/feature branches. Only after merging to default does a finding become a vulnerability.
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### Vulnerability finding
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When a [report finding](#report-finding) is stored to the database, it becomes a vulnerability
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[finding](#finding).
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### Vulnerability tracking
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Deals with the responsibility of matching findings across scans so that a finding's life cycle can
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be understood. Engineers and security teams use this information to decide whether to merge code
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changes, and to see unresolved findings and when they were introduced.
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Vulnerabilities are tracked by comparing the location fingerprint, primary identifier, and report type.
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### Vulnerability occurrence
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Deprecated, see [finding](#finding).
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