Azure Attestation client library for Python

The Microsoft Azure Attestation (MAA) service is a unified solution for remotely verifying the trustworthiness of a platform and integrity of the binaries running inside it. The service supports attestation of the platforms backed by Trusted Platform Modules (TPMs) alongside the ability to attest to the state of Trusted Execution Environments (TEEs) such as Intel(tm) Software Guard Extensions (SGX) enclaves and Virtualization-based Security (VBS) enclaves.

Attestation is a process for demonstrating that software binaries were properly instantiated on a trusted platform. Remote relying parties can then gain confidence that only such intended software is running on trusted hardware. Azure Attestation is a unified customer-facing service and framework for attestation.

Azure Attestation enables cutting-edge security paradigms such as Azure Confidential computing and Intelligent Edge protection. Customers have been requesting the ability to independently verify the location of a machine, the posture of a virtual machine (VM) on that machine, and the environment within which enclaves are running on that VM. Azure Attestation will empower these and many additional customer requests.

Azure Attestation receives evidence from compute entities, turns them into a set of claims, validates them against configurable policies, and produces cryptographic proofs for claims-based applications (for example, relying parties and auditing authorities).

This package has been tested with Python 2.7, 3.6 to 3.9.

For a more complete view of Azure libraries, see the azure sdk python release.

NOTE: This is a preview SDK for the Microsoft Azure Attestation service. It provides all the essential functionality to access the Azure Attestation service, it should be considered ‘as-is” and is subject to changes in the future which may break compatibility with previous versions.

Source code | Package (PyPI) | API reference documentation | Product documentation

Getting started

Prerequisites

  • An Azure subscription. To use Azure services, including the Microsoft Azure Attestation service, you’ll need a subscription. If you do not have an existing Azure account, you may sign up for a free trial or use your Visual Studio Subscription benefits when you create an account.

  • An existing Azure Attestation Instance, or you can use the “shared provider” available in each Azure region. If you need to create an Azure Attestation service instance, you can use the Azure Portal or Azure CLI.

Install the package

Install the Microsoft Azure Attestation client library for Python with PyPI:

pip install --pre azure-security-attestation

Authenticate the client

In order to interact with the Microsoft Azure Attestation service, you’ll need to create an instance of the Attestation Client or Attestation Administration Client class. You need a attestation instance url, which you may see as “DNS Name” in the portal,

and client secret credentials (client id, client secret, tenant id) to instantiate a client object.

Client secret credential authentication is being used in this getting started section but you can find more ways to authenticate with Azure identity. To use the DefaultAzureCredential provider shown below, or other credential providers provided with the Azure SDK, you should install the Azure.Identity package:

pip install azure-identity

Create/Get credentials

Use the Azure CLI snippet below to create/get client secret credentials.

  • Create a service principal and configure its access to Azure resources:

       az ad sp create-for-rbac -n <your-application-name> --skip-assignment
    
    Output:
    
    {
        "appId": "generated-app-ID",
        "displayName": "dummy-app-name",
        "name": "http://dummy-app-name",
        "password": "random-password",
        "tenant": "tenant-ID"
    }
    
  • Take note of the service principal objectId

       az ad sp show --id <appId> --query objectId
    
    Output:
    
    "<your-service-principal-object-id>"
    
  • Use the returned credentials above to set AZURE_CLIENT_ID (appId), AZURE_CLIENT_SECRET (password), and AZURE_TENANT_ID (tenant) environment variables. The following example shows a way to do this in Powershell:

$Env:AZURE_CLIENT_ID="generated-app-ID"
$Env:AZURE_CLIENT_SECRET="random-password"
$Env:AZURE_TENANT_ID="tenant-ID"

For more information about the Azure Identity APIs and how to use them, see Azure Identity client library

Key concepts

There are four major families of functionality provided in this preview SDK:

The Microsoft Azure Attestation service runs in two separate modes: “Isolated” and “AAD”. When the service is running in “Isolated” mode, the customer needs to provide additional information beyond their authentication credentials to verify that they are authorized to modify the state of an attestation instance.

Finally, each region in which the Microsoft Azure Attestation service is available supports a “shared” instance, which can be used to attest SGX enclaves which only need verification against the azure baseline (there are no policies applied to the shared instance). TPM attestation is not available in the shared instance. While the shared instance requires AAD authentication, it does not have any RBAC policies - any customer with a valid AAD bearer token can attest using the shared instance.

Attestation

SGX or TPM attestation is the process of validating evidence collected from a trusted execution environment to ensure that it meets both the Azure baseline for that environment and customer defined policies applied to that environment.

Attestation service token signing certificate discovery and validation

One of the core operational guarantees of the Azure Attestation Service is that the service operates “operationally out of the TCB”. In other words, there is no way that a Microsoft operator could tamper with the operation of the service, or corrupt data sent from the client. To ensure this guarantee, the core of the attestation service runs in an Intel(tm) SGX enclave.

To allow customers to verify that operations were actually performed inside the enclave, most responses from the Attestation Service are encoded in a JSON Web Token, which is signed by a key held within the attestation service’s enclave.

This token will be signed by a signing certificate issued by the MAA service for the specified instance.

If the MAA service instance is running in a region where the service runs in an SGX enclave, then the certificate issued by the server can be verified using the oe_verify_attestation_certificate API.

The ``AttestationResponse` <https://docs.microsoft.com/python/api/azure-security-attestation/azure.security.attestation.attestationresponse?view=azure-python-preview>`_ object contains two main attributes: token and value. The token attribute contains the complete token returned by the attestation service, the value attribute contains the body of the JSON Web Token response.

Policy Management

Each attestation service instance has a policy applied to it which defines additional criteria which the customer has defined.

For more information on attestation policies, see Attestation Policy

Policy Management certificate management

When an attestation instance is running in “Isolated” mode, the customer who created the instance will have provided a policy management certificate at the time the instance is created. All policy modification operations require that the customer sign the policy data with one of the existing policy management certificates. The Policy Management Certificate Management APIs enable clients to “roll” the policy management certificates.

Isolated Mode and AAD Mode

Each Microsoft Azure Attestation service instance operates in either “AAD” mode or “Isolated” mode. When an MAA instance is operating in AAD mode, it means that the customer which created the attestation instance allows Azure Active Directory and Azure Role Based Access control policies to verify access to the attestation instance.

AttestationType

The Microsoft Azure Attestation service supports attesting different types of evidence depending on the environment. Currently, MAA supports the following Trusted Execution environments:

Runtime Data and Inittime Data

RuntimeData refers to data which is presented to the Intel SGX Quote generation logic or the oe_get_report/oe_get_evidence APIs. If the caller to the attest API provided a runtime_data attribute, The Azure Attestation service will validate that the first 32 bytes of the report_data field in the SGX Quote/OE Report/OE Evidence matches the SHA256 hash of the runtime_data.

InitTime data refers to data which is used to configure the SGX enclave being attested.

Note that InitTime data is not supported on Azure DCsv2-Series virtual machines.

Additional concepts

Examples

Create client instance

Creates an instance of the Attestation Client at uri endpoint.

attest_client = AttestationClient(
    credential=DefaultAzureCredential(),
    instance_url=base_uri)

Get attestation policy

The set_policy method retrieves the attestation policy from the service. Attestation Policies are instanced on a per-attestation type basis, the AttestationType parameter defines the type to retrieve.

policy_response = attest_client.get_policy(AttestationType.SGX_ENCLAVE)
print('Instance SGX policy: ', policy_response.value)
print('Token: ', policy_response.token)

Set an attestation policy for a specified attestation type

If the attestation service instance is running in Isolated mode, the set_policy API needs to provide a signing certificate (and private key) which can be used to validate that the caller is authorized to modify policy on the attestation instance. If the service instance is running in AAD mode, then the signing certificate and key are optional.

Under the covers, the SetPolicy APIs create a JSON Web Token based on the policy document and signing information which is sent to the attestation service.

policy_set_response = attest_client.set_policy(AttestationType.SGX_ENCLAVE,
    attestation_policy,
    signing_key=AttestationSigningKey(key, signing_certificate))
policy_get_response = attest_client.get_policy(AttestationType.SGX_ENCLAVE)
assert policy_get_response.value == attestation_policy

If the service instance is running in AAD mode, the call to set_policy can be simplified:

policy_set_response = attest_client.set_policy(AttestationType.SGX_ENCLAVE,
    attestation_policy)
# Now retrieve the policy which was just set.
policy_get_response = attest_client.get_policy(AttestationType.SGX_ENCLAVE)
assert policy_get_response.value == attestation_policy

Clients need to be able to verify that the attestation policy document was not modified before the policy document was received by the attestation service’s enclave.

There are two properties provided in the PolicyResult that can be used to verify that the service received the policy document:

To verify the hash, clients can generate an attestation token and verify the hash generated from that token:

# The set_policy API will create an AttestationToken signed with the
# AttestationSigningKey  to transmit the policy. To verify that the policy
# specified by the caller was received by the service inside the enclave, we
# verify that the hash of the policy document returned from the Attestation
# Service matches the hash of an attestation token created locally.
expected_policy = AttestationToken(
    body=StoredAttestationPolicy(attestation_policy),
    signer=AttestationSigningKey(key, signing_certificate))
hasher = hashes.Hash(hashes.SHA256())
hasher.update(expected_policy.serialize().encode('utf-8'))
expected_hash = hasher.finalize()

assert expected_hash == policy_set_response.value.policy_token_hash

Attest SGX Enclave

Use the ``attest_sgx` <https://docs.microsoft.com/python/api/azure-security-attestation/azure.security.attestation.attestationclient?view=azure-python-preview#attest-sgx-enclave-quote–inittime-data-none–runtime-data-none–draft-policy-none—-kwargs->`_ method to attest an SGX enclave.

One of the core challenges customers have interacting with encrypted environments is how to ensure that you can securely communicate with the code running in the environment (“enclave code”).

One solution to this problem is what is known as “Secure Key Release”, which is a pattern that enables secure communication with enclave code.

To implement the “Secure Key Release” pattern, the enclave code generates an ephemeral asymmetric key. It then serializes the public portion of the key to some format (possibly a JSON Web Key, or PEM, or some other serialization format).

The enclave code then calculates the SHA256 value of the public key and passes it as an input to code which generates an SGX Quote (for OpenEnclave, that would be the oe_get_evidence or oe_get_report).

The client then sends the SGX quote and the serialized key to the attestation service. The attestation service will validate the quote and ensure that the hash of the key is present in the quote and will issue an “Attestation Token”.

The client can then send that Attestation Token (which contains the serialized key) to a 3rd party “relying party”. The relying party then validates that the attestation token was created by the attestation service, and thus the serialized key can be used to encrypt some data held by the “relying party” to send to the service.

This example shows one common pattern of calling into the attestation service to retrieve an attestation token associated with a request.

This example assumes that you have an existing AttestationClient object which is configured with the base URI for your endpoint. It also assumes that you have an SGX Quote (quote) generated from within the SGX enclave you are attesting, and “Runtime Data” (runtime_data) which is referenced in the SGX Quote.

# Collect quote and runtime data from an SGX enclave.
#
# For the "Secure Key Release" scenario, the runtime data is normally a serialized asymmetric key.
# When the 'quote' (attestation evidence) is created specify the SHA256 hash
# of the runtime data when creating the evidence.
#
# When the generated evidence is created, the hash of the runtime data is
#  included in the secured portion of the evidence.
#
# The Attestation service will validate that the Evidence is valid and that
# the SHA256 of the RuntimeData parameter is included in the evidence.
response = attest_client.attest_sgx_enclave(
        quote,
        runtime_data=AttestationData(runtime_data, is_json=False))
assert response.value.enclave_held_data == runtime_data
assert response.value.sgx_collateral is not None

# At this point, the EnclaveHeldData field in the attestationResult.Value
# property will hold the input binaryRuntimeData.

# The token is now passed to the "relying party". The relying party will
# validate that the token was issued by the Attestation Service. It then
# extracts the asymmetric key from the EnclaveHeldData field. The relying
#  party will then Encrypt it's "key" data using the asymmetric key and
# transmits it back to the enclave.
encryptedData = send_token_to_relying_party(attestationResult.Token)

# Now the encrypted data can be passed into the enclave which can decrypt that data.

Additional information on how to perform attestation token validation can be found in the MAA Service Attestation Sample.

Retrieve Token Certificates

Use get_signing_certificates to retrieve the certificates which can be used to validate the token returned from the attestation service.

signers = attest_client.get_signing_certificates()
for signer in signers:
    cert = cryptography.x509.load_der_x509_certificate(signer.certificates[0], backend=default_backend())
    print('Cert  iss:', cert.issuer, '; subject:', cert.subject)

Troubleshooting

Most Attestation service operations will raise exceptions defined in Azure Core. The attestation service APIs will throw a HttpResponseError on failure with helpful error codes. Many of these errors are recoverable.

try:
response = attest_client.attest_sgx_enclave(
        quote,
        runtime_data=AttestationData(runtime_data, is_json=False))
except HttpResponseError as ex:
    // Ignore invalid quote errors.
    if ex.error == "InvalidParameter":
        pass
}

Additional troubleshooting information for the MAA service can be found here

Next steps

For more information about the Microsoft Azure Attestation service, please see our documentation page.

Contributing

This project welcomes contributions and suggestions. Most contributions require you to agree to a Contributor License Agreement (CLA) declaring that you have the right to, and actually do, grant us the rights to use your contribution. For details, visit the Contributor License Agreement site.

When you submit a pull request, a CLA-bot will automatically determine whether you need to provide a CLA and decorate the PR appropriately (e.g., label, comment). Simply follow the instructions provided by the bot. You will only need to do this once across all repos using our CLA.

This project has adopted the Microsoft Open Source Code of Conduct. For more information see the Code of Conduct FAQ or contact opencode@microsoft.com with any additional questions or comments.

See CONTRIBUTING.md for details on building, testing, and contributing to these libraries.

Provide Feedback

If you encounter any bugs or have suggestions, please file an issue in the Issues section of the project.

Impressions

Indices and tables