Tag: STIG Compliance

Trying to get your head around STIG (Security Technical Implementation Guides) compliance? Anchore is here to help. With the help of MITRE Security Automation Framework (SAF) we’ll walk you through the quickset path to STIG Compliance and ultimately the converted Authority to Operate (ATO).

The goal for any company that aims to provide software services to the Department of Defense (DoD) is an ATO. Without this stamp of approval your software will never get into the hands of the warfighters that need it most. STIG compliance is a necessary needle that must be thread on the path to ATO. Luckily, MITRE has developed and open-sourced SAF to smooth the often complex and time-consuming STIG compliance process.

We’ll get you up to speed on MITRE SAF and how it helps you achieve STIG compliance in this blog post but before we jump straight into the content be sure to bookmark our webinar with the Chief Architect of MITRE Security Automation Framework (SAF), Aaron Lippold. Josh Bressers, VP of Security at Anchore and Lippold provide a behind the scenes look at SAF and how it dramatically reduces the friction of the STIG compliance process.

What is the MITRE Security Automation Framework (SAF)?

The MITRE SAF is both a high-level cybersecurity framework and an umbrella that encompasses a set of security/compliance tools. It is designed to simplify STIG compliance by translating DISA (Defense Information Systems Agency) SRG (Security Requirements Guide) guidance into actionable steps. 

By following the Security Automation Framework, organizations can streamline and automate the hardened configuration of their DevSecOps pipeline to achieve an ATO (Authority to Operate).

The SAF offers four primary benefits:

1. Accelerate Path to ATO: By streamlining STIG compliance, SAF enables organizations to get their applications into the hands of DoD operators faster. This acceleration is crucial for meeting operational demands without compromising on security standards.
2. Establish Security Requirements: SAF translates SRGs and STIGs into actionable steps tailored to an organization’s specific DevSecOps pipeline. This eliminates ambiguity and ensures security controls are implemented correctly.
3. Build Security In: The framework provides tooling that can be directly embedded into the software development pipeline. By automating STIG configurations and policy checks, it ensures that security measures are consistently applied, leaving no room for false steps.
4. Assess and Monitor Vulnerabilities: SAF offers visualization and analysis tools that assist organizations in making informed decisions about their current vulnerability inventory. It helps chart a path toward achieving STIG compliance and ultimately an ATO.

The overarching vision of the MITRE SAF is to “implement evolving security requirements while deploying apps at speed.” In essence, it allows organizations to have their cake and eat it too—gaining the benefits of accelerated software delivery without letting cybersecurity risks grow unchecked.

How does MITRE SAF work?

MITRE SAF is segmented into 5 capabilities that map to specific stages of the DevSecOps pipeline or STIG compliance process:

1. Plan
2. Harden
3. Validate
4. Normalize
5. Visualize

Let’s break down each of these capabilities.

Plan

There are hundreds of existing STIGs for products ranging from Microsoft Windows to Cisco Routers to MySQL databases. On the off chance that a product your team wants to use doesn’t have a pre-existing STIG, SAF’s Vulcan tool is helps translate the application SRG into a tailored STIG that can then be used to achieve compliance.

Vulcan helps streamline the process of creating STIG-ready security guidance and the accompanying InSpec automated policy that confirms a specific instance of software is configured in a compliant manner.

Vulcan does this by modeling the STIG intent form and tailoring the applicable SRG controls into a finished STIG for an application. The finished STIG is then sent to DISA for peer review and formal publishing as a STIG. Vulcan allows the author to develop both human-readable instructions and machine-readable InSpec automated validation code at the same time.

Harden

The hardening capability focuses on automating STIG compliance through the use of pre-built infrastructure configuration scripts. SAF hardening content allows organizations to:

• Use their preferred configuration management tools: Chef Cookbooks, Ansible Playbooks, Terraform Modules, etc. are available as open source templates on MITRE’s GitHub page.
• Share and collaborate: All hardening content is open source, encouraging community involvement and shared learning.
• Coverage for the full development stack: Ensuring that every layer, from cloud infrastructure to applications, adheres to security standards.

Validate

The validation capability focuses on verifying the hardening meets the applicable STIG compliance standard. These validation checks are automated via the SAF CLI tool that incorporates the InSpec policies for a STIG. With SAF CLI, organizations can:

• Automatically validate STIG compliance: By integrating SAF CLI directly into your CI/CD pipeline and invoking InSpec policy checks at every build; shifting security left by surfacing policy violations early.
• Promote community collaboration: Like the hardening content, validation scripts are open source and accessible by the community for collaborative efforts.
• Span the entire development stack: Validation—similar to hardening—isn’t limited to a single layer; it encompasses cloud infrastructure, platforms, operating systems, databases, web servers, and applications.
• Incorporate manual attestation: To achieve comprehensive coverage of policy requirements that automated tools might not fully address.

Normalize

Normalization addresses the challenge of interoperability between different security tools and data formats. SAF CLI performs double-duty by taking on the normalization function as well as validation. It is able to:

• Translate data into OHDF: OASIS Heimdall Data Format (OHDF), is an open standard that structures countless proprietary security metadata formats into a single universal format.
• Leverage open source OHDF libraries: Organizations can use OHDF converters as libraries within their custom applications.
• Automate data conversion: By incorporating SAF CLI into the DevSecOps pipeline, data is automatically standardized with each run.
• Increased compliance efficiency: A single data format for all security data allows interoperability and facilitates efficient and automated STIG compliance.

Example: Below is an example of Burp Suite’s proprietary data format normalized to the OHDF JSON format:

Visualize

Visualization is critical for understanding security posture and making informed decisions. SAF provides an open source, self-hosted visualization tool named Heimdall. It ingests OHDF normalized security data and provides the data analysis tools to enable organizations to:

• Aggregate security and compliance results: Compiling data into comprehensive rollups, charts, and timelines for a holistic view of security and compliance status.
• Perform deep dives: Allowing teams to explore detailed vulnerability information to facilitate investigation and remediation, ultimately speeding up time to STIG compliance.
• Guide risk reduction efforts: Visualization of insights help with prioritization of security and compliance tasks reducing risk in the most efficient manner.

How is SAF related to a DoD Software Factory?

A DoD Software Factory is the common term for a DevSecOps pipeline that meets the definition laid out in DoD Enterprise DevSecOps Reference Design. All software that ultimately achieves an ATO has to be built on a fully implemented DoD Software Factory. You can either build your own or use a pre-existing DoD Software Factory like the US Air Force’s Platform One or the US Navy’s Black Pearl.

As we saw earlier, MITRE SAF is a framework meant to help you achieve STIG compliance and is a portion of your journey towards an ATO. STIG compliance applies to both the software that you write as well as the DevSecOps platform that your software is built on. Building your own DoD Software Factory means committing to going through the ATO process and STIG compliance for the DevSecOps platform first then a second time for the end-user application.

Wrap-Up

The MITRE SAF is a huge leg up for modern, cloud-native DevSecOps software vendors that are currently navigating the labyrinth towards ATO. By providing actionable guidance, automation tooling, and a community-driven approach, SAF dramatically reduces the time to ATO. It bridges the gap between the speed of DevOps software delivery and secure, compliant applications ready for critical DoD missions with national security implications. 

Embracing SAF means more than just meeting regulatory requirements; it’s about building a resilient, efficient, and secure development pipeline that can adapt to evolving security demands. In an era where cybersecurity threats are evolving just as rapidly as software, leveraging frameworks like MITRE SAF is not an efficient path to compliance—it’s essential for sustained success.

In the rapidly modernizing landscape of cybersecurity compliance, evolving to a continuous compliance posture is more critical than ever—particularly for organizations involved with the Department of Defense (DoD) and other government agencies. At the heart of the DoD’s modern approach to software development is the DoD Enterprise DevSecOps Reference Design, commonly implemented as a DoD Software Factory. 

A key component of this framework is adhering to the Security Technical Implementation Guides (STIGs) developed by the Defense Information Systems Agency (DISA). STIG compliance within the DevSecOps pipeline not only accelerates the delivery of secure software but also embeds robust security practices directly into the development process, safeguarding sensitive data and reinforcing national security.

This comprehensive guide will walk you through what STIGs are, who should care about them, the levels of STIG compliance, key categories of STIG requirements, how to prepare for the STIG compliance process, and the tools available to automate STIG implementation and maintenance.

What are STIGs and who should care?

Understanding DISA and STIGs

The Defense Information Systems Agency (DISA) is the DoD agency responsible for delivering information technology (IT) support to ensure the security of U.S. national defense systems. To help organizations meet the DoD’s rigorous security controls, DISA develops Security Technical Implementation Guides (STIGs).

STIGs are configuration standards that provide prescriptive guidance on how to secure operating systems, network devices, software, and other IT systems. They serve as a secure configuration standard to harden systems against cyber threats.

For example, a STIG for the open source Apache web server would specify that encryption is enabled for all traffic (incoming or outgoing). This would require the generation of SSL/TLS certificates on the server in the correct location, updating the server’s configuration file to reference this certificate and re-configuration of the server to serve traffic from a secure port rather than the default insecure port.

Who should care about STIG compliance?

STIG compliance is mandatory for any organization that operates within the DoD network or handles DoD information. This includes:

• DoD Contractors and Vendors: Companies providing products or services to the DoD—a.k.a. the defense industrial base (DIB)—must ensure their systems comply with STIG requirements.
• Government Agencies: Federal agencies interfacing with the DoD need to adhere to applicable STIGs.
• DoD Information Technology Teams: IT professionals within the DoD responsible for system security must implement STIGs.

Connection to the RMF and NIST SP 800-53

The Risk Management Framework (RMF)—more formally NIST 800-37—is a framework that integrates security and risk management into IT systems as they are being developed. The STIG compliance process outlined below is directly integrated into the higher-level RMF process. As you follow the RMF, the individual steps of STIG compliance will be completed in turn.

STIGs are also closely connected to the NIST 800-53, colloquially known as the “Control Catalog”. NIST 800-53 outlines security and privacy controls for all federal information systems; the controls are not prescriptive about the implementation, only the best practices and outcomes that need to be achieved. 

As DISA developed the STIG compliance standard, they started with the NIST 800-53 controls then “tailored” them to meet the needs of the DoD; these customized security best practices are known as Security Requirements Guides (SRGs). In order to remove all ambiguity around how to meet these higher-level best practices STIGs were created with implementation specific instructions.

For example, an SRG will mandate that all systems utilize a cybersecurity best practice, such as, role-based access control (RBAC) to prevent users without the correct privileges from accessing certain systems. A STIG, on the other hand, will detail exactly how to configure an RBAC system to meet the highest security standards.

Levels of STIG Compliance

The DISA STIG compliance standard uses Severity Category Codes to classify vulnerabilities based on their potential impact on system security. These codes help organizations prioritize remediation efforts. The three Severity Category Codes are:

1. Category I (Cat I): These are the highest risk vulnerabilities, allowing an attacker immediate access to a system or network or allowing superuser access. Due to their high risk nature, these vulnerabilities be addressed immediately.
2. Category II (Cat II): These vulnerabilities provide information with a high potential of giving access to intruders. These findings are considered a medium risk and should be remediated promptly.
3. Category III (Cat III): These vulnerabilities constitute the lowest risk, providing information that could potentially lead to compromise. Although not as pressing as Cat II & III issues, it is still important to address these vulnerabilities to minimize risk and enhance overall security.

Understanding these categories is crucial in the STIG process, as they guide organizations in prioritizing remediation of vulnerabilities.

Key categories of STIG requirements

Given the extensive range of technologies used in DoD environments, there are hundreds of STIGs applicable to different systems, devices, applications, and more. While we won’t list all STIG requirements here, it’s important to understand the key categories and who they apply to.

1. Operating System STIGs

Applies to: System Administrators and IT Teams managing servers and workstations

Examples:

• Microsoft Windows STIGs: Provides guidelines for securing Windows operating systems.
• Linux STIGs: Offers secure configuration requirements for various Linux distributions.

2. Network Device STIGs

Applies to: Network Engineers and Administrators

Examples:

• Network Router STIGs: Outlines security configurations for routers to protect network traffic.
• Network Firewall STIGs: Details how to secure firewall settings to control access to networks.

3. Application STIGs

Applies to: Software Developers and Application Managers

Examples:

• Generic Application Security STIG: Outlines the necessary security best practices needed to be STIG compliant
• Web Server STIG: Provides security requirements for web servers.
• Database STIG: Specifies how to secure database management systems (DBMS).

4. Mobile Device STIGs

Applies to: Mobile Device Administrators and Security Teams

Examples:

• Apple iOS STIG: Guides securing of Apple mobile devices used within the DoD.
• Android OS STIG: Details security configurations for Android devices.

5. Cloud Computing STIGs

Applies to: Cloud Service Providers and Cloud Infrastructure Teams

Examples:

• Microsoft Azure SQL Database STIG: Offers security requirements for Azure SQL Database cloud service.
• Cloud Computing OS STIG: Details secure configurations for any operating system offered by a cloud provider that doesn’t have a specific STIG.

Each category addresses specific technologies and includes a STIG checklist to ensure all necessary configurations are applied. 

You can view an example of a STIG checklist for “Application Security and Development” by following this link.

How to Prepare for the STIG Compliance Process

Achieving DISA STIG compliance involves a structured approach. Here are the stages of the STIG process and tips to prepare:

Stage 1: Identifying Applicable STIGs

With hundreds of STIGs relevant to different organizations and technology stacks, this step should not be underestimated. First, conduct an inventory of all systems, devices, applications, and technologies in use. Then, review the complete list of STIGs to match each to your inventory to ensure that all critical areas requiring secure configuration are addressed. This step is essential to avoiding gaps in compliance.

Tip: Use automated tools to scan your environment then match assets to relevant STIGs.

Stage 2: Implementation

After you’ve mapped your technology to the corresponding STIGs, the process of implementing the security configurations outlined in the guides begins. This step may require collaboration between IT, security, and development teams to ensure that the configurations are compatible with the organization’s infrastructure while enforcing strict security standards. Be sure to keep detailed records of changes made.

Tip: Prioritize implementing fixes for Cat I vulnerabilities first, followed by Cat II and Cat III. Depending on the urgency and needs of the mission, ATO can still be achieved with partial STIG compliance. Prioritizing efforts increases the chances that partial compliance is permitted.

Stage 3: Auditing & Maintenance

After the STIGs have been implemented, regular auditing and maintenance are critical to ensure ongoing compliance, verifying that no deviations have occurred over time due to system updates, patches, or other changes. This stage includes periodic scans, manual reviews, and remediation of any identified gaps. Additionally, organizations should develop a plan to stay informed about new STIG releases and updates from DISA.

Tip: Establish a maintenance schedule and assign responsibilities to team members. Alternatively, adopting a policy-as-code approach to continuous compliance by embedding STIG compliance requirements “-as-code” directly into your DevSecOps pipeline, you can automate this process.

General Preparation Tips

• Training: Ensure your team is familiar with STIG requirements and the compliance process.
• Collaboration: Work cross-functionally with all relevant departments, including IT, security, and compliance teams.
• Resource Allocation: Dedicate sufficient resources, including time and personnel, to the compliance effort.
• Continuous Improvement: Treat STIG compliance as an ongoing process rather than a one-time project.

Tools to automate STIG implementation and maintenance

Automation can significantly streamline the STIG compliance process. Here are some tools that can help:

1. Anchore STIG (Static and Runtime)

• Purpose: Automates the process of checking container images against STIG requirements.
• Benefits:
  • Simplifies compliance for containerized applications.
  • Integrates into CI/CD pipelines for continuous compliance.
• Use Case: Ideal for DevSecOps teams utilizing containers in their deployments.

2. SCAP Compliance Checker

• Purpose: Provides automated compliance scanning using the Security Content Automation Protocol (SCAP).
• Benefits:
  • Validates system configurations against STIGs.
  • Generates detailed compliance reports.
• Use Case: Useful for system administrators needing to audit various operating systems.

3. DISA STIG Viewer

• Purpose: Helps in viewing and managing STIG checklists.
• Benefits:
  • Allows for easy navigation of STIG requirements.
  • Facilitates documentation and reporting.
• Use Case: Assists compliance officers in tracking compliance status.

4. DevOps Automation Tools

• Infrastructure Automation Examples: Red Hat Ansible, Perforce Puppet, Hashicorp Terraform
• Software Build Automation Examples: CloudBees CI, GitLab
• Purpose: Automate the deployment of secure configurations that meet STIG compliance across multiple systems.
• Benefits:
  • Ensures consistent application of secure configuration standards.
  • Reduces manual effort and the potential for errors.
• Use Case: Suitable for large-scale environments where manual configuration is impractical.

5. Vulnerability Management Tools

• Examples: Anchore Secure
• Purpose: Identify vulnerabilities and compliance issues within your network.
• Benefits:
  • Provides actionable insights to remediate security gaps.
  • Offers continuous monitoring capabilities.
• Use Case: Critical for security teams focused on proactive risk management.

Wrap-Up

Achieving DISA STIG compliance is mandatory for organizations working with the DoD. By understanding what STIGs are, who they apply to, and how to navigate the compliance process, your organization can meet the stringent compliance requirements set forth by DISA. As a bonus, you will enhance its security posture and reduce the potential for a security breach.

Remember, compliance is not a one-time event but an ongoing effort that requires regular updates, audits, and maintenance. Leveraging automation tools like Anchore STIG and Anchore Secure can significantly ease this burden, allowing your team to focus on strategic initiatives rather than manual compliance tasks.

Stay proactive, keep your team informed, and make use of the resources available to ensure that your IT systems remain secure and compliant.