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Version: 1.2

Attestation in Contrast

This document describes the attestation architecture of Contrast, adhering to the definitions of Remote ATtestation procedureS (RATS) in RFC 9334. The following gives a detailed description of Contrast's attestation architecture. At the end of this document, we included an FAQ that answers the most common questions regarding attestation in hindsight of the security benefits.

Attestation architecture

Contrast integrates with the RATS architecture, leveraging their definition of roles and processes including Attesters, Verifiers, and Relying Parties.

Conceptual attestation architecture

Figure 1: Conceptual attestation architecture. Taken from RFC 9334.

  • Attester: Assigned to entities that are responsible for creating Evidence which is then sent to a Verifier.
  • Verifier: These entities utilize the Evidence, Reference Values, and Endorsements. They assess the trustworthiness of the Attester by applying an Appraisal Policy for Evidence. Following this assessment, Verifiers generate Attestation Results for use by Relying Parties. The Appraisal Policy for Evidence may be provided by the Verifier Owner, programmed into the Verifier, or acquired through other means.
  • Relying Party: Assigned to entities that utilize Attestation Results, applying their own appraisal policies to make specific decisions, such as authorization decisions. This process is referred to as the "appraisal of Attestation Results." The Appraisal Policy for Attestation Results might be sourced from the Relying Party Owner, configured by the owner, embedded in the Relying Party, or obtained through other protocols or mechanisms.

Components of Contrast's attestation

The key components involved in the attestation process of Contrast are detailed below:

Attester: Application Pods

This includes all Pods of the Contrast deployment that run inside Confidential Containers and generate cryptographic evidence reflecting their current configuration and state. Their evidence is rooted in the hardware measurements from the CPU and their confidential VM environment. The details of this evidence are given below in the section on evidence generation and appraisal.

Attestation flow of a confidential pod

Figure 2: Attestation flow of a confidential pod. Based on the layered attester graphic in RFC 9334.

Pods run in Contrast's runtime environment (B), effectively within a confidential VM. During launch, the CPU (A) measures the initial memory content of the confidential VM that contains Contrast's pod-VM image and generates the corresponding attestation evidence. The image is in IGVM format, encapsulating all information required to launch a virtual machine, including the kernel, the initramfs, and kernel cmdline. The kernel cmdline contains the root hash for dm-verity that ensures the integrity of the root filesystem. The root filesystem contains all components of the container's runtime environment including the guest agent (C).

In the userland, the guest agent takes care of enforcing the runtime policy of the pod. While the policy is passed in during the initialization procedure via the host, the evidence for the runtime policy is part of the CPU measurements. During the deployment the policy is annotated to the Kubernetes Pod resources. The hypervisor adds the hash of the policy to the attestation report via the HOSTDATA (on AMD SEV-SNP) or MRCONFIGID (Intel TDX) fields. When provided with the policy from the Kata host, the guest agent verifies that the policy's hash matches the one in the HOSTDATA/MRCONFIGID field.

In summary a Pod's evidence is the attestation report of the CPU that provides evidence for runtime environment and the runtime policy.

Verifier: Coordinator and CLI

The Coordinator acts as a verifier within the Contrast deployment, configured with a Manifest that defines the reference values and serves as an appraisal policy for all pods in the deployment. It also pulls endorsements from hardware vendors to verify the hardware claims. The Coordinator operates within the cluster as a confidential container and provides similar evidence as any other Pod when it acts as an attester. In RATS terminology, the Coordinator's dual role is defined as a lead attester in a composite device which spans the entire deployment: Coordinator and the workload pods. It collects evidence from other attesters and conveys it to a verifier, generating evidence about the layout of the whole composite device based on the Manifest as the appraisal policy.

Deployment attestation as a composite device

Figure 3: Contrast deployment as a composite device. Based on the composite device in RFC 9334.

The CLI serves as the verifier for the Coordinator and the entire Contrast deployment, containing the reference values for the Coordinator and the endorsements from hardware vendors. These reference values are built into the CLI during our release process and can be reproduced offline via reproducible builds.

Relying Party: Data owner

A relying party in the Contrast scenario could be, for example, the data owner that interacts with the application. The relying party can use the CLI to obtain the attestation results and Contrast's CA certificates bound to these results. The CA certificates can then be used by the relying party to authenticate the application, for example through TLS connections.

Evidence generation and appraisal

Evidence types and formats

In Contrast, attestation evidence revolves around a hardware-generated attestation report, which contains several critical pieces of information:

  • The hardware attestation report: This report includes details such as the chip identifier, platform information, microcode versions, and comprehensive guest measurements. The entire report is signed by the CPU's private key, ensuring the authenticity and integrity of the data provided.
  • The launch measurements: Included within the hardware attestation report, this is a digest generated by the CPU that represents a hash of all initial guest memory pages. This includes essential components like the kernel, initramfs, and the kernel command line. Notably, it incorporates the root filesystem's dm-verity root hash, verifying the integrity of the root filesystem.
  • The runtime policy hash: Also part of the hardware attestation report, this field contains the hash of the Rego policy which dictates all expected API commands and their values from the host to the Kata guest agent. It encompasses crucial settings such as dm-verity hashes for the container image layers, environment variables, and mount points.

Appraisal policies for evidence

The appraisal of this evidence in Contrast is governed by two main components:

  • The Manifest: A JSON file used by the Coordinator to align with reference values. It sets the expectations for runtime policy hashes for each pod and includes what should be reported in the hardware attestation report for each component of the deployment.
  • The CLI's appraisal policy: This policy encompasses expected values of the Coordinator’s guest measurements and its runtime policy. It's embedded into the CLI during the build process and ensures that any discrepancy between the built-in values and those reported by the hardware attestation can be identified and addressed. The integrity of this policy is safeguardable through reproducible builds, allowing verification against the source code reference.

Frequently asked questions about attestation in Contrast

What's the purpose of remote attestation in Contrast?

Remote attestation in Contrast ensures that software runs within a secure, isolated confidential computing environment. This process certifies that the memory is encrypted and confirms the integrity and authenticity of the software running within the deployment. By validating the runtime environment and the policies enforced on it, Contrast ensures that the system operates in a trustworthy state and hasn't been tampered with.

How does Contrast ensure the security of the attestation process?

Contrast leverages hardware-rooted security features such as AMD SEV-SNP or Intel TDX to generate cryptographic evidence of a pod’s current state and configuration. This evidence is checked against pre-defined appraisal policies to guarantee that only verified and authorized pods are part of a Contrast deployment.

What security benefits does attestation provide?

Attestation confirms the integrity of the runtime environment and the identity of the workloads. It plays a critical role in preventing unauthorized changes and detecting potential modifications at runtime. The attestation provides integrity and authenticity guarantees, enabling relying parties—such as workload operators or data owners—to confirm the effective protection against potential threats, including malicious cloud insiders, co-tenants, or compromised workload operators. More details on the specific security benefits can be found here.

How can you verify the authenticity of attestation results?

Attestation results in Contrast are tied to cryptographic proofs generated and signed by the hardware itself. These proofs are then verified using public keys from trusted hardware vendors, ensuring that the results aren't only accurate but also resistant to tampering. For further authenticity verification, all of Contrast's code is reproducibly built, and the attestation evidence can be verified locally from the source code.

How are attestation results used by relying parties?

Relying parties use attestation results to make informed security decisions, such as allowing access to sensitive data or resources only if the attestation verifies the system's integrity. Thereafter, the use of Contrast's CA certificates in TLS connections provides a practical approach to communicate securely with the application.

Summary

In summary, Contrast's attestation strategy adheres to the RATS guidelines and consists of robust verification mechanisms that ensure each component of the deployment is secure and trustworthy. This comprehensive approach allows Contrast to provide a high level of security assurance to its users.