mbedtls/docs/architecture/testing/driver-interface-test-strategy.md
2019-09-04 19:41:16 +02:00

7.7 KiB

Mbed Crypto driver interface test strategy

This document describes the test strategy for the driver interfaces in Mbed Crypto. Mbed Crypto has interfaces for secure element drivers, accelerator drivers and entropy drivers. This document is about testing Mbed Crypto itself; testing drivers is out of scope.

The driver interfaces are standardized through PSA Cryptography functional specifications.

Secure element driver interface

The secure element driver interface (SE interface for short) is defined by psa/crypto_se_driver.h. This is an interface between Mbed Crypto and one or more third-party drivers.

The SE interface consists of one function provided by Mbed Crypto (psa_register_se_driver) and many functions that drivers must implement. To make a driver usable by Mbed Crypto, the initialization code must call psa_register_se_driver with a structure that describes the driver. The structure mostly contains function pointers, pointing to the driver's methods. All calls to a driver function are triggered by a call to a PSA crypto API function.

SE driver interface unit tests

This section describes unit tests that must be implemented to validate the secure element driver interface. Note that a test case may cover multiple requirements; for example a “good case” test can validate that the proper function is called, that it receives the expected inputs and that it produces the expected outputs.

Many SE driver interface unit tests could be covered by running the existing API tests with a key in a secure element.

SE driver registration

  • Test psa_register_se_driver with valid and with invalid arguments.
  • Make at least one failing call to psa_register_se_driver followed by a successful call.
  • Make at least one test that successfully registers the maximum number of drivers and fails to register one more.

Dispatch to SE driver

For each API function that can lead to a driver call (more precisely, for each driver method call site, but this is practically equivalent):

  • Make at least one test with a key in a secure element that checks that the driver method is called. A few API functions involve multiple driver methods; these should validate that all the expected driver methods are called.
  • Make at least one test with a key that is not in a secure element that checks that the driver method is not called.
  • Make at least one test with a key in a secure element with a driver that does not have the requisite method (i.e. the method pointer is NULL) but has the substructure containing that method, and check that the return value is PSA_ERROR_NOT_SUPPORTED.
  • Make at least one test with a key in a secure element with a driver that does not have the substructure containing that method (i.e. the pointer to the substructure is NULL), and check that the return value is PSA_ERROR_NOT_SUPPORTED.
  • At least one test should register multiple drivers with a key in each driver and check that the expected driver is called. This does not need to be done for all operations (use a white-box approach to determine if operations may use different code paths to choose the driver).
  • At least one test should register the same driver structure with multiple lifetime values and check that the driver receives the expected lifetime value.

Some methods only make sense as a group (for example a driver that provides the MAC methods must provide all or none). In those cases, test with all of them null and none of them null.

SE driver inputs

For each API function that can lead to a driver call (more precisely, for each driver method call site, but this is practically equivalent):

  • Wherever the specification guarantees parameters that satisfy certain preconditions, check these preconditions whenever practical.
  • If the API function can take parameters that are invalid and must not reach the driver, call the API function with such parameters and verify that the driver method is not called.

SE driver outputs

For each API function that leads to a driver call, call it with parameters that cause a driver to be invoked and check how Mbed Crypto handles the outputs.

  • Correct outputs.
  • Incorrect outputs such as an invalid output length.
  • Expected errors (e.g. PSA_ERROR_INVALID_SIGNATURE from a signature verification method).
  • Unexpected errors. At least test that if the driver returns PSA_ERROR_GENERIC_ERROR, this is propagated correctly.

Key creation functions invoke multiple methods and need more complex error handling:

  • Check the consequence of errors detected at each stage (slot number allocation or validation, key creation method, storage accesses).
  • Check that the storage ends up in the expected state. At least make sure that no intermediate file remains after a failure.

Persistence of SE keys

The following tests must be performed at least one for each key creation method (import, generate, ...).

  • Test that keys in a secure element survive psa_close_key(); psa_open_key().
  • Test that keys in a secure element survive mbedtls_psa_crypto_free(); psa_crypto_init().
  • Test that the driver's persistent data survives mbedtls_psa_crypto_free(); psa_crypto_init().
  • Test that psa_destroy_key() does not leave any trace of the key.

Resilience for SE drivers

Creating or removing a key in a secure element involves multiple storage modifications (M1, ..., Mn). If the operation is interrupted by a reset at any point, it must be either rolled back or completed.

  • For each potential interruption point (before M1, between M1 and M2, ..., after Mn), call mbedtls_psa_crypto_free(); psa_crypto_init() at that point and check that this either rolls back or completes the operation that was started.
  • This must be done for each key creation method and for key destruction.
  • This must be done for each possible flow, including error cases (e.g. a key creation that fails midway due to OUT_OF_MEMORY).
  • The recovery during psa_crypto_init can itself be interrupted. Test those interruptions too.
  • Two things need to be tested: the key that is being created or destroyed, and the driver's persistent storage.
  • Check both that the storage has the expected content (this can be done by e.g. using a key that is supposed to be present) and does not have any unexpected content (for keys, this can be done by checking that psa_open_key fails with PSA_ERRROR_DOES_NOT_EXIST).

This requires instrumenting the storage implementation, either to force it to fail at each point or to record successive storage states and replay each of them. Each psa_its_xxx function call is assumed to be atomic.

SE driver system tests

Real-world use case

We must have at least one driver that is close to real-world conditions:

  • With its own source tree.
  • Running on actual hardware.
  • Run the full driver validation test suite (which does not yet exist).
  • Run at least one test application (e.g. the Mbed OS TLS example).

This requirement shall be fulfilled by the Microchip ATECC508A driver.

Complete driver

We should have at least one driver that covers the whole interface:

  • With its own source tree.
  • Implementing all the methods.
  • Run the full driver validation test suite (which does not yet exist).

A PKCS#11 driver would be a good candidate. It would be useful as part of our product offering.

Accelerator driver interface

The accelerator driver interface is defined by psa/crypto_accel_driver.h.

TODO

Entropy driver interface

The entropy driver interface is defined by psa/crypto_entropy_driver.h.

TODO