cve-report-aggregator 0.14.0

Aggregate and deduplicate vulnerability scan reports from Grype and Trivy

CVE Report Aggregation and Deduplication Tool

A Python package for aggregating and deduplicating Grype and Trivy vulnerability scan reports, extracted from Zarf packages. Optionally enrich CVE data using OpenAI GPT models to provide actionable mitigation summaries in the context of UDS Core security controls.

[!IMPORTANT] Will implement customizable prompts and support for additional AI providers in future releases.

Quick Start

Using Docker (Recommended)

# Pull the latest signed image
docker pull ghcr.io/mkm29/cve-report-aggregator:latest

# Process reports with default settings
docker run --rm \
  -v $(pwd)/reports:/home/cve-aggregator/reports:ro \
  -v $(pwd)/output:/home/cve-aggregator/output \
  ghcr.io/mkm29/cve-report-aggregator:latest

# Output: $HOME/output/<package>-<version>.json

Using pipx (Local Installation)

# Install
pipx install cve-report-aggregator

# Process reports from ./reports/
cve-report-aggregator

# Output: $HOME/output/unified-YYYYMMDDhhmmss.json

Common Usage Patterns

# Use Trivy scanner instead of Grype
cve-report-aggregator --scanner trivy

# Enable AI-powered CVE enrichment
export OPENAI_API_KEY=sk-...
cve-report-aggregator --enrich-cves

# Process with custom input directory and verbose logging
cve-report-aggregator -i /path/to/reports --log-level DEBUG

# Use highest severity across multiple scans
cve-report-aggregator --mode highest-score

Features

• Self-Contained Docker Image: Includes all scanning tools (Grype, Syft, Trivy, UDS CLI) in a single hardened Alpine-based image
• Supply Chain Security: SLSA Level 3 compliant with signed images, SBOMs, and provenance attestations
• AI-Powered CVE Enrichment: Optional OpenAI integration for automated vulnerability mitigation analysis
• Production-Ready Package: Installable via pip/pipx with proper dependency management
• Rich Terminal Output: Beautiful, color-coded tables and progress indicators using the Rich library
• Multi-Scanner Support: Works with both Grype and Trivy scanners
• SBOM Auto-Scan: Automatically detects and scans Syft SBOM files with Grype
• Auto-Conversion: Automatically converts Grype reports to CycloneDX format for Trivy scanning
• CVE Deduplication: Combines identical vulnerabilities across multiple scans
• Automatic Null CVSS Filtering: Filters out invalid CVSS scores (null, N/A, or zero) from all vulnerability reports
• CVSS 3.x-Based Severity Selection: Optional mode to select highest severity based on actual CVSS 3.x base scores
• Scanner Source Tracking: Identifies which scanner (Grype or Trivy) provided the vulnerability data
• Occurrence Tracking: Counts how many times each CVE appears
• Flexible CLI: Click-based interface with rich-click styling and sensible defaults
• Security Hardened: Non-root user (UID 1001), minimal Alpine base, pinned dependencies, and vulnerability-scanned

Table of Contents

• Installation
• Configuration
• Pipeline Architecture
• Usage Examples
• CVE Enrichment
• Output Formats
• Performance
• Development
• Contributing

Installation

Using Docker (Recommended)

The easiest way to use CVE Report Aggregator is via the pre-built Docker image, which includes all necessary scanning tools (Grype, Syft, Trivy, UDS CLI):

# Pull the latest signed image from GitHub Container Registry
docker pull ghcr.io/mkm29/cve-report-aggregator:latest

# Or build locally
docker build -t cve-report-aggregator .

# Or use Docker Compose
docker compose run cve-aggregator --help

# Run with mounted volumes for reports and output
docker run --rm \
  -v $(pwd)/reports:/workspace/reports:ro \
  -v $(pwd)/output:/home/cve-aggregator/output \
  -v $(pwd)/packages:/home/cve-aggregator/packages \
  ghcr.io/mkm29/cve-report-aggregator:latest \
  --verbose

# Note: Output files are automatically saved to $HOME/output with package name and version:
# Format: <package_name>-<package_version>.json (e.g., core-logging-0.54.1-unicorn.json)

See Docker Security & Supply Chain for signature verification and SBOM attestations.

From PyPI

# Install globally
pip install cve-report-aggregator

# Or install with pipx (recommended)
pipx install cve-report-aggregator

From Source

# Clone the repository
git clone https://github.com/mkm29/cve-report-aggregator.git
cd cve-report-aggregator

# Install in development mode
pip install -e .

# Or install with dev dependencies
pip install -e ".[dev]"

Prerequisites

For Docker users: No prerequisites needed - all tools are included in the image.

For local installation: You will need uv and at least one scanner:

• grype - For Grype scanning (default scanner)
• trivy - For Trivy scanning
  • syft - For converting reports to CycloneDX format (Trivy workflow)

# Install Grype
brew install grype

# Install Syft (for Trivy workflow)
brew install syft

# Install Trivy
brew install aquasecurity/trivy/trivy

Configuration

CVE Report Aggregator supports flexible configuration through multiple sources with the following precedence (highest to lowest):

1. CLI Arguments - Command-line flags and options
2. YAML Configuration File - .cve-aggregator.yaml or .cve-aggregator.yml
3. Environment Variables - Prefixed with CVE_AGGREGATOR_
4. Default Values

CLI Options

Option	Short	Description	Default
--input-dir	-i	Input directory containing scan reports or SBOMs	./reports
--scanner	-s	Scanner type to process (grype or trivy)	grype
--log-level	-l	Logging level (DEBUG, INFO, WARNING, ERROR, CRITICAL)	INFO
--mode	-m	Aggregation mode: highest-score, first-occurrence, grype-only, trivy-only	highest-score
--enrich-cves		Enable CVE enrichment with OpenAI	false
--openai-api-key		OpenAI API key (defaults to OPENAI_API_KEY env var)	None
--openai-model		OpenAI model to use for enrichment	gpt-5-nano
--openai-reasoning-effort		Reasoning effort level (low, medium, high)	medium
--max-cves-to-enrich		Maximum number of CVEs to enrich	None (all)
--enrich-severity-filter		Severity levels to enrich (can be used multiple times)	Critical, High
--help	-h	Show help message and exit	N/A
--version		Show version and exit	N/A

YAML Configuration File

Create a .cve-aggregator.yaml or .cve-aggregator.yml file in your project directory:

# Scanner and processing settings
scanner: grype                          # Scanner type: grype or trivy
mode: highest-score                     # Aggregation mode
log_level: INFO                         # Logging level

input_dir: ./reports                    # Input directory for reports

# Parallel processing
maxWorkers: 14                          # Concurrent download workers (auto-detect if omitted)

# Remote package downloads
downloadRemotePackages: true            # Enable remote SBOM downloads
registry: registry.defenseunicorns.com
organization: sld-45
packages:
  - name: gitlab
    version: 18.4.2-uds.0-unicorn
    architecture: amd64
  - name: gitlab-runner
    version: 18.4.0-uds.0-unicorn
    architecture: amd64

# CVE Enrichment (OpenAI)
enrich:
  enabled: true
  provider: openai  # only openai is supported currently
  model: gpt-5  # OpenAI model (gpt-5-nano, gpt-4o, etc.)
  # apiKey: YOUR_OPENAI_API_KEY_HERE # or set via OPENAI_API_KEY environment variable
  reasoningEffort: medium  # Level of reasoning effort: minimal, low, medium, high
  severities:  # Severity levels to enrich
    - Critical
    - High
  verbosity: medium  # Verbosity level: low, medium, high
  seed: 42  # Optional: Seed for reproducibility
  metadata:  # Optional: Metadata tags for OpenAI requests
    project: cve-report-aggregator
    organization: defenseunicorns

See .cve-aggregator.example.yaml for a complete example.

Package Sources: Local vs Remote

CVE Report Aggregator supports two package sources with intelligent fallback behavior:

1. Local Packages (Priority)

If a ./packages/ directory exists with Zarf package archives (.tar.zst files), the application will automatically use them:

# Directory structure
./packages/
├── zarf-package-gitlab-amd64-18.4.2-uds.0-unicorn.tar.zst
├── zarf-package-gitlab-runner-amd64-18.4.0-uds.0-unicorn.tar.zst
└── zarf-package-headlamp-amd64-0.35.0-uds.0-registry1.tar.zst

# Run with local packages (no configuration needed)
cve-report-aggregator

Benefits:

• No configuration required - automatically detected
• Package metadata extracted from archives using zarf package inspect
• Faster than remote downloads (no network I/O)
• Works in air-gapped environments

Note: Zarf init packages (zarf-init-*.tar.zst) are automatically excluded as they contain infrastructure components.

2. Remote Packages (Fallback)

Remote packages are downloaded only if no local packages are found in ./packages/:

# .cve-aggregator.yaml
downloadRemotePackages: true
registry: registry.defenseunicorns.com
organization: sld-45
packages:
  - name: gitlab
    version: 18.4.2-uds.0-unicorn
    architecture: amd64

Requirements:

• downloadRemotePackages: true in configuration
• Registry and organization configured
• UDS Zarf CLI installed and authenticated
• Package list with name, version, and architecture

3. Local-Only Mode

To disable remote downloads entirely (useful for air-gapped environments):

# .cve-aggregator.yaml
localOnly: true  # Skip remote downloads even if no local packages found

Behavior Summary

Scenario	Local Packages?	downloadRemotePackages	Behavior
Local packages exist	✅	Any value	Use local packages
No local packages + remote enabled	❌	true	Download remote packages
No local packages + remote disabled	❌	false	Process existing reports in ./reports/
Local-only mode enabled	Any	Any value	Use local packages only, skip remote

Priority Order:

1. Local packages in ./packages/ (if exist)
2. Remote package downloads (if downloadRemotePackages: true and no local packages)
3. Existing reports in ./reports/ (fallback)

Environment Variables

All configuration options can be set via environment variables with the CVE_AGGREGATOR_ prefix (with the exception of the OPENAI_API_KEY, which has no prefix). For example:

# Scanner settings
export CVE_AGGREGATOR_SCANNER=grype
export CVE_AGGREGATOR_MODE=highest-score
export CVE_AGGREGATOR_LOG_LEVEL=DEBUG

# Input/output
export CVE_AGGREGATOR_INPUT_DIR=/path/to/reports
export CVE_AGGREGATOR_OUTPUT_FILE=/path/to/output.json

# Parallel processing
export CVE_AGGREGATOR_MAX_WORKERS=14

# Remote packages
export CVE_AGGREGATOR_DOWNLOAD_REMOTE_PACKAGES=true
export CVE_AGGREGATOR_REGISTRY=registry.example.com
export CVE_AGGREGATOR_ORGANIZATION=my-org

# CVE Enrichment
export OPENAI_API_KEY=sk-...                            # OpenAI API key (no prefix)
export CVE_AGGREGATOR_ENRICH_CVES=true
export CVE_AGGREGATOR_OPENAI_MODEL=gpt-5-nano
export CVE_AGGREGATOR_OPENAI_REASONING_EFFORT=medium
export CVE_AGGREGATOR_MAX_CVES_TO_ENRICH=50

Configuration Examples

Basic Usage with Defaults

# Process reports from ./reports/ with default settings
cve-report-aggregator

# Output: $HOME/output/unified-YYYYMMDDhhmmss.json

Custom Scanner and Verbosity

# Use Trivy scanner with debug logging
cve-report-aggregator --scanner trivy --log-level DEBUG

CVE Enrichment

# Enable AI-powered enrichment for Critical and High CVEs
export OPENAI_API_KEY=sk-...
cve-report-aggregator --enrich-cves

# Customize enrichment settings
cve-report-aggregator \
  --enrich-cves \
  --openai-model gpt-4o \
  --openai-reasoning-effort high \
  --max-cves-to-enrich 10 \
  --enrich-severity-filter Critical

Remote Package Downloads

# .cve-aggregator.yaml
downloadRemotePackages: true
registry: registry.defenseunicorns.com
organization: sld-45
maxWorkers: 14
packages:
  - name: gitlab
    version: 18.4.2-uds.0-unicorn

# Run with config file
cve-report-aggregator --config .cve-aggregator.yaml

Prerequisites

This depends on how you plan to use CVE Report Aggregator. The recommended method is via the Docker image, which includes all necessary tooling. In which case, the only prerequisite is having Docker installed.

For running from source, you will need uv. Additionally, you will need at least one of the following scanners installed, depending on your workflow: You can expect the following performance improvements when utilizing parallel downloads (ThreadPoolExecutor):

• ~10-15 seconds for 14 packages
• A 10-14x speedup compared to sequential downloads (which can take ~150s for 14 packages)

Auto-Detection: If maxWorkers is not specified, the optimal worker count is automatically detected using the formula: min(<number_of_packages>, cpu_cores * 2 - 2). Set to 1 to disable parallelization.

Thread Safety: All parallel operations use thread-safe data structures (Lock()) to ensure data integrity across concurrent workers.

Pipeline Architecture

CVE Report Aggregator uses a package-first download architecture where Zarf packages are downloaded in parallel, each yielding multiple SBOM files (one per container image). These SBOMs are then processed with the selected scanner (Grype or Trivy), followed by aggregation, deduplication, and optional CVE enrichment.

Part 1: Download & Scanning Pipeline

The first stage handles parallel package downloads and vulnerability scanning in a 3-row hybrid layout:

flowchart TB
    %% Row 1: Package Downloads (Force Horizontal Layout with invisible connections)
    subgraph downloads[" "]
        direction LR
        pkg1[gitlab]
        pkg2[gitlab-runner]
        pkg3[headlamp]
        pkg4[metrics-server]

        pkg1 ~~~ pkg2 ~~~ pkg3 ~~~ pkg4
    end

    %% Invisible connector for spacing
    downloads --> collector

    %% Row 2: Two-Column Processing
    subgraph processing[" "]
        direction LR

        %% Left Column
        subgraph collector["SBOM Collection"]
            direction TB
            extract[Extract SBOMs]:::sbomStyle
            detect{Detect Format<br/>}:::decisionStyle
            select[Scanner Selection]:::decisionStyle
            extract --> detect --> select
        end

        %% Right Column
        subgraph scanners["Scanner Execution"]
            direction TB

            subgraph grype["Grype Path"]
                direction LR
                g1[Direct Scan<br/>grype sbom:file]:::grypeStyle
                g2[Grype<br/>Reports]:::grypeStyle
                g1 --> g2
            end

            subgraph trivy["Trivy Path"]
                direction LR
                t1[Convert<br/>syft convert]:::trivyStyle
                t2[Scan<br/>trivy sbom]:::trivyStyle
                t3[Trivy<br/>Reports]:::trivyStyle
                t1 --> t2 --> t3
            end
        end

        select -.Grype.-> grype
        select -.Trivy.-> trivy
    end

    %% Row 3: Output
    subgraph output_row["Output"]
        output[Scan Reports Ready<br/>for Aggregation]:::transitionStyle
    end

    %% Connect to output
    g2 --> output
    t3 --> output

    %% Style Definitions
    classDef downloadStyle fill:#1976d2,stroke:#0d47a1,color:#fff,stroke-width:2px
    classDef sbomStyle fill:#7b1fa2,stroke:#4a148c,color:#fff,stroke-width:2px
    classDef decisionStyle fill:#ffa000,stroke:#ff6f00,color:#000,stroke-width:2px
    classDef grypeStyle fill:#d32f2f,stroke:#b71c1c,color:#fff,stroke-width:2px
    classDef trivyStyle fill:#f57c00,stroke:#e65100,color:#fff,stroke-width:2px
    classDef transitionStyle fill:#546e7a,stroke:#37474f,color:#fff,stroke-width:2px

    class pkg1,pkg2,pkg3,pkg4 downloadStyle

Part 2: Aggregation & Output Pipeline

The second stage handles deduplication, enrichment, and report generation:

flowchart TB
    INPUT1[Scan Reports<br/>From Scanner]

    subgraph agg["5. Aggregation & Deduplication"]
        direction TB
        MERGE[Merge Reports<br/>GHSA → CVE Conversion]
        DEDUP[Deduplicate by CVE ID]
        SEVERITY{Severity Mode?}
        FIRST[First Occurrence<br/>Use First Report]
        HIGHEST[Highest Score<br/>Compare CVSS 3.x]
    end

    subgraph enrich["6. CVE Enrichment<br/>(Optional)"]
        direction TB
        FILTER[Filter by Severity<br/>Default: Critical + High]
        ENRICH_CHECK{enrich-cves<br/>enabled?}
        OPENAI[OpenAI Analysis<br/>UDS Security Context]
        MITIGATION[Add Mitigation<br/>Summaries]
    end

    subgraph output["7. Report Generation"]
        direction TB
        JSON1[gitlab-VERSION.json]
        CSV1[gitlab-VERSION.csv]
        JSON2[gitlab-runner-VERSION.json]
        CSV2[gitlab-runner-VERSION.csv]
        SUMMARY[executive-summary.json]
    end

    INPUT1 --> MERGE
    MERGE --> DEDUP
    DEDUP --> SEVERITY

    SEVERITY -->|first-occurrence| FIRST
    SEVERITY -->|highest-score| HIGHEST

    FIRST --> FILTER
    HIGHEST --> FILTER

    FILTER --> ENRICH_CHECK
    ENRICH_CHECK -->|Yes| OPENAI
    ENRICH_CHECK -->|No| JSON1

    OPENAI --> MITIGATION
    MITIGATION --> JSON1

    JSON1 --> CSV1
    JSON1 --> JSON2
    JSON2 --> CSV2
    JSON2 --> SUMMARY

    classDef transitionStyle fill:#546e7a,stroke:#37474f,color:#fff,stroke-width:2px
    classDef aggStyle fill:#388e3c,stroke:#1b5e20,color:#fff,stroke-width:2px
    classDef decisionStyle fill:#ffa000,stroke:#ff6f00,color:#000,stroke-width:2px
    classDef enrichStyle fill:#5e35b1,stroke:#311b92,color:#fff,stroke-width:2px
    classDef outputStyle fill:#00796b,stroke:#004d40,color:#fff,stroke-width:2px

    class INPUT1 transitionStyle
    class MERGE,DEDUP,FIRST,HIGHEST aggStyle
    class SEVERITY,ENRICH_CHECK decisionStyle
    class FILTER,OPENAI,MITIGATION enrichStyle
    class JSON1,CSV1,JSON2,CSV2,SUMMARY outputStyle

Processing Pipeline Overview

The complete processing pipeline consists of seven stages:

1. Parallel Package Downloads (ThreadPoolExecutor):

   • Downloads Zarf packages concurrently using UDS CLI
   • Worker count: min(num_packages, cpu_count * 2 - 2)
   • Each package extracts multiple SBOM files (one per container image)

2. SBOM Collection:

   • Gathers all extracted SBOM files
   • Auto-detects SBOM format (checks for artifacts + descriptor fields)

3. Scanner Selection:

   • Grype (default): Direct SBOM scanning
   • Trivy: CycloneDX conversion then scanning

4. Scanner Processing:

   • Grype Path: grype sbom:<file> -o json → Grype reports
   • Trivy Path: syft convert <file> -o cyclonedx-json → trivy sbom <file> -f json → Trivy reports

5. Aggregation & Deduplication:

   • Merge all scan reports
   • Convert GHSA IDs to CVE IDs (preferred for standardization)
   • Deduplicate by CVE ID
   • Severity Mode Selection:
     • first-occurrence: Use severity from first report (default)
     • highest-score: Compare CVSS 3.x scores, select highest

6. CVE Enrichment (optional, requires --enrich-cves flag):

   • Filter by severity (default: Critical + High)
   • Analyze with OpenAI using UDS Core security context
   • Add single-sentence mitigation summaries

7. Report Generation:

   • Per-package JSON reports: <package>-<version>.json
   • Per-package CSV reports: <package>-<version>.csv
   • Executive summary: executive-summary-<timestamp>.json
   • All files saved to $HOME/output/

Prerequisites

Depending on scanner choice:

• grype - For Grype scanning (default scanner)
• trivy - For Trivy scanning
  • syft - For converting reports to CycloneDX format (Trivy workflow)

# Install Grype
brew install grype

# Install syft (for Trivy workflow)
brew install syft

# Install trivy
brew install aquasecurity/trivy/trivy

Installation

Using Docker (Recommended)

The easiest way to use CVE Report Aggregator is via the pre-built Docker image, which includes all necessary scanning tools (Grype, Syft, Trivy, UDS CLI):

# Pull the latest signed image from GitHub Container Registry
docker pull ghcr.io/mkm29/cve-report-aggregator:latest

# Or build locally
docker build -t cve-report-aggregator .

# Or use Docker Compose
docker compose run cve-aggregator --help

# Run with mounted volumes for reports and output
docker run --rm \
  -v $(pwd)/reports:/workspace/reports:ro \
  -v $(pwd)/output:/home/cve-aggregator/output \
  -v $(pwd)/packages:/home/cve-aggregator/packages \
  ghcr.io/mkm29/cve-report-aggregator:latest \
  --verbose

# Note: Output files are automatically saved to $HOME/output with package name and version:
# Format: <package_name>-<package_version>.json (e.g., core-logging-0.54.1-unicorn.json)

Image Security & Supply Chain

All container images are built securely using GitHub Actions and cosign, achieving SLSA Level 3 compliance with the following features:

• Signed with Cosign: Keyless signing using GitHub OIDC identity
• SBOM Included: CycloneDX and SPDX attestations attached to every image
• Provenance: SLSA Level 3 compliant build attestations
• Multi-Architecture: Supports both amd64 and arm64
• Vulnerability Scanned: Regularly scanned with Grype and Trivy

Verify Image Signature

# Install cosign
brew install cosign

# Verify the image signature
cosign verify ghcr.io/mkm29/cve-report-aggregator:latest \
  --certificate-identity-regexp='https://github.com/mkm29/cve-report-aggregator' \
  --certificate-oidc-issuer='https://token.actions.githubusercontent.com'

# Output shows verified signature with GitHub Actions identity

Download and Verify SBOM

# Download CycloneDX SBOM (JSON format)
cosign verify-attestation ghcr.io/mkm29/cve-report-aggregator:latest \
  --type cyclonedx \
  --certificate-identity-regexp='https://github.com/mkm29/cve-report-aggregator' \
  --certificate-oidc-issuer='https://token.actions.githubusercontent.com' | \
  jq -r '.payload' | base64 -d | jq . > sbom-cyclonedx.json

# Download SPDX SBOM (JSON format)
cosign verify-attestation ghcr.io/mkm29/cve-report-aggregator:latest \
  --type spdx \
  --certificate-identity-regexp='https://github.com/mkm29/cve-report-aggregator' \
  --certificate-oidc-issuer='https://token.actions.githubusercontent.com' | \
  jq -r '.payload' | base64 -d | jq . > sbom-spdx.json

# View all attestations and signatures
cosign tree ghcr.io/mkm29/cve-report-aggregator:latest

Download Build Provenance

# Download SLSA provenance attestation
cosign verify-attestation ghcr.io/mkm29/cve-report-aggregator:latest \
  --type slsaprovenance \
  --certificate-identity-regexp='https://github.com/mkm29/cve-report-aggregator' \
  --certificate-oidc-issuer='https://token.actions.githubusercontent.com' | \
  jq -r '.payload' | base64 -d | jq . > provenance.json

Available Image Tags

Images are published to GitHub Container Registry with the following tags:

• latest - Latest stable release (recommended for production)
• v*.*.* - Specific version tags (e.g., v0.5.1, v0.5.2)
• rc - Release candidate builds (for testing pre-release versions)

# Pull specific version
docker pull ghcr.io/mkm29/cve-report-aggregator:v0.5.1

# Pull latest stable
docker pull ghcr.io/mkm29/cve-report-aggregator:latest

# Pull release candidate (if available)
docker pull ghcr.io/mkm29/cve-report-aggregator:rc

All tags are signed and include full attestations (signature, SBOM, provenance).

CVE Enrichment

CVE Report Aggregator supports optional AI-powered enrichment using OpenAI GPT models to automatically analyze vulnerabilities in the context of UDS Core security controls. This feature generates concise, actionable mitigation summaries that explain how defense-in-depth security measures help protect against specific CVEs.

Note: Batch API enrichment typically completes within minutes to hours (up to 24-hour maximum). The CLI will poll for completion automatically and display progress updates.

Quick Start

# Set API key
export OPENAI_API_KEY=sk-...

# Enable enrichment (enriches Critical and High severity CVEs by default)
cve-report-aggregator --enrich-cves

# Customize enrichment with higher reasoning effort
cve-report-aggregator \
  --enrich-cves \
  --openai-model gpt-4o \
  --openai-reasoning-effort high \
  --max-cves-to-enrich 10 \
  --enrich-severity-filter Critical

Reasoning Effort

The openai_reasoning_effort parameter controls how deeply the AI model analyzes each CVE:

• minimal: Basic analysis with minimal token usage
• low: Faster, more concise analysis with lower token usage
• medium (default): Balanced analysis with good quality and reasonable token usage
• high: Most thorough analysis with higher quality but increased token usage

When to adjust:

• Use minimal for quick overviews or large CVE sets
• Use low for large CVE sets where speed and cost are priorities
• Use medium (default) for most production use cases
• Use high for critical vulnerabilities requiring detailed analysis

Note: The reasoning_effort parameter is only supported by GPT-5 models (gpt-5-nano, gpt-5-mini). The temperature parameter is fixed at 1.0 for GPT-5 models as required by OpenAI.

# Example: High-quality analysis for critical CVEs only
cve-report-aggregator \
  --enrich-cves \
  --openai-reasoning-effort high \
  --enrich-severity-filter Critical

Output Format

Enrichments are added to the unified report under the enrichments key:

{
  "enrichments": {
    "CVE-2024-12345": {
      "cve_id": "CVE-2024-12345",
      "mitigation_summary": "UDS helps to mitigate CVE-2024-12345 by enforcing non-root container execution through Pepr admission policies and blocking unauthorized external network access via default-deny NetworkPolicies.",
      "analysis_model": "gpt-5-nano",
      "analysis_timestamp": "2025-01-20T12:34:56.789Z"
    }
  },
  "summary": {
    "enrichment": {
      "enabled": true,
      "total_cves": 150,
      "enriched_cves": 45,
      "model": "gpt-5-nano",
      "severity_filter": ["Critical", "High"]
    }
  }
}

Docker Credentials Management

The Docker container supports two methods for providing registry credentials:

1. Build-Time Secrets
2. Environment Variables

Method 1: Build-Time Secrets

[!IMPORTANT] Since this package (image) currently has public access, this method is not used. Changing the visibility to private would be required to safely use this method, however, since the credentials are baked in, shared credentials would need to be used for all users. This method makes it difficult to granularly control access per user. Consider using environment variables for more flexible credential management.

Create a credentials file in JSON format with username, password, and registry fields:

cat > docker/config.json <<EOF
{
  "username": "myuser",
  "password": "mypassword",
  "registry": "ghcr.io"
}
EOF
chmod 600 docker/config.json

Important: Always encrypt the credentials file with SOPS before committing:

# Encrypt the credentials file
sops -e docker/config.json.dec > docker/config.json.enc

# Or encrypt in place
sops -e docker/config.json.dec > docker/config.json.enc

Build the image with the secret:

# If using encrypted file, decrypt first
sops -d docker/config.json.enc > docker/config.json.dec

# Build with the decrypted credentials
docker buildx build \
  --secret id=credentials,src=./docker/config.json.dec \
  -f docker/Dockerfile \
  -t cve-report-aggregator:latest .

# Remove decrypted file after build
rm docker/config.json.dec

Or build directly with unencrypted file (for local development):

docker buildx build \
  --secret id=credentials,src=./docker/config.json \
  -f docker/Dockerfile \
  -t local/cve-report-aggregator:latest .

The credentials will be stored in the image at $DOCKER_CONFIG/config.json (defaults to /home/cve-aggregator/.docker/config.json) in proper Docker authentication format with base64-encoded credentials.

Run the container (no runtime credentials needed - uses baked-in config.json):

docker run --rm cve-report-aggregator:latest --help

Important: This method bakes credentials into the image. Only use for private registries and never push images with credentials to public registries.

Method 2: Environment Variables

docker run -it --rm \
  -e REGISTRY_URL="$UDS_URL" \
  -e UDS_USERNAME="$UDS_USERNAME" \
  -e UDS_PASSWORD="$UDS_PASSWORD" \
  -e OPENAI_API_KEY="$OPENAI_API_KEY" \
  cve-report-aggregator:latest --help

How Credentials Are Handled

The entrypoint.sh script checks for Docker authentication on startup:

1. Docker config.json (Build-Time): Checks if $DOCKER_CONFIG/config.json exists

   • If found: Skips all credential checks and login - uses existing Docker auth
   • Location: /home/cve-aggregator/.docker/config.json

2. Environment Variables (if config.json not found): Requires all three variables:

   • REGISTRY_URL - Registry URL (e.g., registry.defenseunicorns.com)
   • UDS_USERNAME - Registry username
   • UDS_PASSWORD - Registry password

If config.json doesn't exist and environment variables are not provided, the container exits with an error.

From Source

# Clone the repository
git clone https://github.com/mkm29/cve-report-aggregator.git
cd cve-report-aggregator

# Install in development mode
pip install -e .

# Or install with dev dependencies
pip install -e ".[dev]"

From PyPi

# Install globally
pip install cve-report-aggregator

# Or install with pipx (recommended)
pipx install cve-report-aggregator

Usage

Basic Usage (Default Locations)

Process reports from ./reports/ and automatically save timestamped output to $HOME/output/:

cve-report-aggregator
# Output:
#   $HOME/output/<package>/<package>-<version>.json
#   $HOME/output/<package>/<package>-<version>.csv

Use Trivy Scanner

Automatically convert reports to CycloneDX and scan with Trivy:

cve-report-aggregator --scanner trivy

Process SBOM Files

The script automatically detects and scans Syft SBOM files:

cve-report-aggregator -i /path/to/sboms -v

Custom Input Directory

# Specify custom input directory (output still goes to $HOME/output)
cve-report-aggregator -i /path/to/reports

Verbose Mode

Enable detailed processing output:

cve-report-aggregator -v

Combined Options

cve-report-aggregator -i ./scans --scanner trivy -v
# Output:
#   $HOME/output/<package>/<package>-<version>.json
#   $HOME/output/<package>/<package>-<version>.csv

Use Highest Severity Across Scanners

When scanning with multiple scanners (or multiple runs of the same scanner), automatically select the highest severity rating:

# Scan the same image with both Grype and Trivy, use highest severity
grype myapp:latest -o json > reports/grype-app.json
trivy image myapp:latest -f json -o reports/trivy-app.json
cve-report-aggregator -i reports/ --mode highest-score
# Output:
#   $HOME/output/<package>/<package>-<version>.json
#   $HOME/output/<package>/<package>-<version>.csv

This is particularly useful when:

• Combining results from multiple scanners with different severity assessments
• Ensuring conservative (worst-case) severity ratings for compliance
• Aggregating multiple scans over time where severity data may have been updated

Note: All output files are automatically saved to $HOME/output/ in a <package> subdirectory with the package version in the format <package_name>-<package_version>.json.

For complete configuration options, see the Configuration section.

Output Formats

The tool generates reports in two formats for maximum flexibility:

1. JSON Format (Unified Report)

The unified report includes:

Metadata

• Generation timestamp
• Scanner type and version
• Source report count and filenames
• Package name and version

Summary

• Total vulnerability occurrences
• Unique vulnerability count
• Severity breakdown (Critical, High, Medium, Low, Negligible, Unknown)
• Per-image scan results

Vulnerabilities (Deduplicated)

For each unique CVE/GHSA:

• Vulnerability ID
• Occurrence count
• Selected scanner (which scanner provided the vulnerability data)
• Severity and CVSS scores
• Fix availability and versions
• All affected sources (images and artifacts)
• Detailed match information

2. CSV Format (Simplified Export)

A simplified CSV export is automatically generated alongside each unified JSON report for easy consumption in spreadsheet applications and reporting tools.

Filename Format: <package_name>-<timestamp>.csv

Columns:

• CVE ID: Vulnerability identifier
• Severity: Severity level (Critical, High, Medium, Low, etc.)
• Count: Number of occurrences across all scanned images
• CVSS: Highest CVSS 3.x score (or "N/A" if unavailable)
• Impact: Impact analysis from OpenAI enrichment (if enabled)
• Mitigation: Mitigation summary from OpenAI enrichment (if enabled)

Example:

"CVE-2023-4863","Critical","5","9.8","Without UDS Core controls, this critical vulnerability...","UDS helps to mitigate CVE-2023-4863 by..."
"CVE-2023-4973","High","3","7.5","This vulnerability could allow...","UDS helps to mitigate CVE-2023-4973 by..."

Features:

• Sorted by severity (Critical > High > Medium > Low) and CVSS score
• Includes enrichment data when CVE enrichment is enabled
• UTF-8 encoded with proper CSV escaping

Location: $HOME/output/<package_name>/<package_name>-<package_version>.csv

Development

Running Tests

# Run all tests
uv run pytest

# Run with coverage
uv run pytest --cov=cve_report_aggregator --cov-report=html

# Run specific test file
uv run pytest tests/test_severity.py

Code Quality

# Lint code
uv run ruff check src/ tests/

# Type checking
uv run mypy src/

# Or run both
uv run lint

Building the Package

# Build distribution packages
python -m build

# Install locally
pip install dist/cve_report_aggregator-0.1.0-py3-none-any.whl

Project Structure

cve-report-aggregator/
├── src/
│   └── cve_report_aggregator/
│       ├── __init__.py           # Package exports and metadata
│       ├── main.py               # CLI entry point
│       ├── models.py             # Type definitions
│       ├── utils.py              # Utility functions
│       ├── severity.py           # CVSS and severity logic
│       ├── scanner.py            # Scanner integrations
│       ├── aggregator.py         # Deduplication engine
│       └── report.py             # Report generation
├── tests/
│   ├── __init__.py
│   ├── conftest.py               # Pytest fixtures
│   ├── test_severity.py          # Severity tests
│   └── test_aggregator.py        # Aggregation tests
├── pyproject.toml                # Project configuration
├── README.md                     # This file
└── LICENSE                       # MIT License

Example Workflows

Grype Workflow (Default)

# Scan multiple container images with Grype
grype registry.io/app/service1:v1.0 -o json > reports/service1.json
grype registry.io/app/service2:v1.0 -o json > reports/service2.json
grype registry.io/app/service3:v1.0 -o json > reports/service3.json

# Aggregate all reports (output saved to $HOME/output with timestamp)
cve-report-aggregator --log-level DEBUG

# Query results with jq (use the timestamped file)
REPORT=$(ls -t $HOME/output/unified-*.json | head -1)
jq '.summary' "$REPORT"
jq '.vulnerabilities[] | select(.vulnerability.severity == "Critical")' "$REPORT"

SBOM Workflow

# Generate SBOMs with Syft (or use Zarf-generated SBOMs)
syft registry.io/app/service1:v1.0 -o json > sboms/service1.json
syft registry.io/app/service2:v1.0 -o json > sboms/service2.json

# Script automatically detects and scans SBOMs with Grype
cve-report-aggregator -i ./sboms --log-level DEBUG

# Results include all vulnerabilities found (use timestamped file)
REPORT=$(ls -t $HOME/output/unified-*.json | head -1)
jq '.summary.by_severity' "$REPORT"

Trivy Workflow

# Start with Grype reports (script will convert to CycloneDX)
grype registry.io/app/service1:v1.0 -o json > reports/service1.json
grype registry.io/app/service2:v1.0 -o json > reports/service2.json

# Aggregate and scan with Trivy (auto-converts to CycloneDX)
cve-report-aggregator --scanner trivy --log-level DEBUG

# Or scan SBOMs directly with Trivy
cve-report-aggregator -i ./sboms --scanner trivy --log-level DEBUG

# View most recent output
REPORT=$(ls -t $HOME/output/unified-*.json | head -1)
jq '.summary' "$REPORT"

License

MIT License - See LICENSE file for details

Contributing

Contributions are welcome! Please:

1. Fork the repository
2. Create a feature branch
3. Add tests for new functionality
4. Ensure all tests pass
5. Submit a pull request

Changelog

See CHANGELOG.md for version history and changes.