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crypto-condor is a Python library for compliance testing of implementations of cryptographic primitives

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crypto-condor

The logo of crypto-condor, depicting a condor holding a key.

crypto-condor is a tool for compliance testing of cryptographic primitives, in the form of a Python library and CLI. It is complemented by an extensive documentation, featuring guides on the primitives supported.

Q: What is a cryptographic primitive?

A: A low-level cryptographic algorithm, generally used to build a protocol. For example, AES is an encryption primitive that is used in the TLS protocol, which is the protocol your browser used to securely get this page.

Q: What is compliance testing?

A: Algorithms are described in specifications, such as FIPS publications or RFCs. When implementing these algorithms, we want to ensure that they comply with the specification, i.e. the implementation behaves as the algorithm described.

Q: How to test for compliance then?

A: We can use test vectors, which are sets of inputs and their corresponding outputs. For example, encrypting with AES is a deterministic operation: for a given key and message, AES will always return the same ciphertext. So we can choose some input values, run the algorithm, and record the value returned. All implementations of AES are then expected to return the same ciphertext for this given key and message. If it does not, then it is not compliant.

Q: And so, what does crypto-condor do?

A: crypto-condor provides both a nice Python API and a wrapper system to test implementations with sets of test vectors that come from sources such as the NIST CAVP.

The Python API exposes test functions that take an implementation as input, in the form of a Python function or class, passes the inputs defined by the test vectors to that implementation, and checks if the outputs are those defined by the vectors.

The wrappers are small programs that already define the function prototype. The user calls the implementation to test inside this function, and crypto-condor runs it with the test vectors as with the Python API.

And it comes with a documentation, wrapper examples, and guides on supported primitives.

Requirements

crypto-condor requires Python 3.11+. For information, it is developed using Python 3.12.2 on Fedora 39.

The implementations of AES, Kyber, Dilithium, and TestU01 are written in C and are compiled directly on the user's machine. As such, they require a C compiler and GNU Make. These primitives are only compiled when required, and not when installing the package:

  • AES: when testing the output of an implementation using classic modes of operation (not CCM or GCM).
  • Kyber: when testing the output of an implementation or when using test vectors on the encapsulate function.
  • Dilithium: when testing the output of an implementation.
  • TestU01: when used to test a file.

Installation

It is available on PyPI:

python -m pip install crypto-condor

An up-to-date list of the requirements can be found in the [tool.poetry.dependencies] section of the pyproject.toml file.

Usage

The documentation is available at https://quarkslab.github.io/crypto-condor/latest/index.html.

Once installed, the CLI is available as crypto-condor-cli. It is structured in commands, similar to Git. Run it without arguments or with --help to display the help message detailing the available subcommands. You can check the documentation for a quick rundown of all the commands.

As for the Python library, it is available as crypto_condor (note the underscore). Each primitive has its own module under primitives, e.g. crypto_condor.primitives.AES. It contains the functions used to test implementations.

Development

See CONTRIBUTING.

Changelog and versioning

A changelog is available. This projects adheres to CalVer. The format used is YYYY.MM.DD[.MICRO][-MODIFIER]:

  • YYYY: full year (2023).
  • 0M: zero-padded month (01, 02, ..., 12).
  • 0D: zero-padded day (01, 02, ..., 31).
  • MICRO: an increasing counter, used for patches published in the same day.
  • MODIFIER: usually rc<n> to indicate a release candidate.

Authors

  • Julio Loayza Meneses, Quarkslab.
  • Angèle Bossuat, Quarkslab.
  • Dahmun Goudarzi, Quarkslab.

Logo idea by Robin David, drawing by Irene Loayza.

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