pw_crypto/docs.rst - pigweed/pigweed - Git at Google

 .. _module-pw_crypto:

 =========
 pw_crypto
 =========
 A set of safe (read: easy to use, hard to misuse) crypto APIs.

 The following crypto services are provided by this module.

 1. Hashing a message with `SHA256`_.
 2. Verifying a digital signature signed with `ECDSA`_ over the NIST P256 curve.
 3. Many more to come ...

 ------
 SHA256
 ------

 1. Obtaining a oneshot digest.

 .. code-block:: cpp

    #include "pw_crypto/sha256.h"

    std::byte digest[32];
    if (!pw::crypto::sha256::Hash(message, digest).ok()) {
      // Handle errors.
    }

    // The content can also come from a pw::stream::Reader.
    if (!pw::crypto::sha256::Hash(reader, digest).ok()) {
      // Handle errors.
    }

 2. Hashing a long, potentially non-contiguous message.

 .. code-block:: cpp

    #include "pw_crypto/sha256.h"

    std::byte digest[32];

    if (!pw::crypto::sha256::Sha256()
        .Update(chunk1).Update(chunk2).Update(chunk...)
        .Final().ok()) {
      // Handle errors.
    }

 -----
 ECDSA
 -----

 1. Verifying a digital signature signed with ECDSA over the NIST P256 curve.

 .. code-block:: cpp

    #include "pw_crypto/sha256.h"

    std::byte digest[32];
    if (!pw::crypto::sha256::Hash(message, digest).ok()) {
      // handle errors.
    }

    if (!pw::crypto::ecdsa::VerifyP256Signature(public_key, digest,
                                                signature).ok()) {
      // handle errors.
    }

 2. Verifying a digital signature signed with ECDSA over the NIST P256 curve,
    with a long and/or non-contiguous message.

 .. code-block:: cpp

    #include "pw_crypto/sha256.h"

    std::byte digest[32];

    if (!pw::crypto::sha256::Sha256()
        .Update(chunk1).Update(chunk2).Update(chunkN)
        .Final(digest).ok()) {
        // Handle errors.
    }

    if (!pw::crypto::ecdsa::VerifyP256Signature(public_key, digest,
                                                signature).ok()) {
        // Handle errors.
    }

 -------------
 Configuration
 -------------

 The crypto services offered by pw_crypto can be backed by different backend
 crypto libraries.

 Mbed TLS
 ========

 The `Mbed TLS project <https://www.trustedfirmware.org/projects/mbed-tls/>`_
 is a mature and full-featured crypto library that implements cryptographic
 primitives, X.509 certificate manipulation and the SSL/TLS and DTLS protocols.

 The project also has good support for interfacing to cryptographic accelerators.

 The small code footprint makes the project suitable and popular for embedded
 systems.

 To select the Mbed TLS backend, the MbedTLS library needs to be installed and
 configured. If using GN, do,

 .. code-block:: sh

    # Install and configure MbedTLS
    pw package install mbedtls
    gn gen out --args='
        dir_pw_third_party_mbedtls=getenv("PW_PACKAGE_ROOT")+"/mbedtls"
        pw_crypto_SHA256_BACKEND="//pw_crypto:sha256_mbedtls_v3"
        pw_crypto_ECDSA_BACKEND="//pw_crypto:ecdsa_mbedtls_v3"
    '

    ninja -C out

 If using Bazel, add the Mbed TLS repository to your WORKSPACE and select
 appropriate backends by adding them to your project's `platform
 <https://bazel.build/extending/platforms>`_:

 .. code-block:: python

    platform(
      name = "my_platform",
       constraint_values = [
         "@pigweed//pw_crypto:sha256_mbedtls_backend",
         "@pigweed//pw_crypto:ecdsa_mbedtls_backend",
         # ... other constraint_values
       ],
    )

 For optimal code size and/or performance, the Mbed TLS library can be configured
 per product. Mbed TLS configuration is achieved by turning on and off MBEDTLS_*
 options in a config.h file. See //third_party/mbedtls for how this is done.

 ``pw::crypto::sha256`` does not need any special configuration as it uses the
 mbedtls_sha256_* APIs directly. However you can optionally turn on
 ``MBEDTLS_SHA256_SMALLER`` to further reduce the code size to from 3KiB to
 ~1.8KiB at a ~30% slowdown cost (Cortex-M4).

 .. code-block:: c

    #define MBEDTLS_SHA256_SMALLER

 ``pw::crypto::ecdsa`` requires the following minimum configurations which yields
 a code size of ~12KiB.

 .. code-block:: c

    #define MBEDTLS_BIGNUM_C
    #define MBEDTLS_ECP_C
    #define MBEDTLS_ECDSA_C
    // The ASN1 options are needed only because mbedtls considers and verifies
    // them (in check_config.h) as dependencies of MBEDTLS_ECDSA_C.
    #define MBEDTLS_ASN1_WRITE_C
    #define MBEDTLS_ASN1_PARSE_C
    #define MBEDTLS_ECP_NO_INTERNAL_RNG
    #define MBEDTLS_ECP_DP_SECP256R1_ENABLED

 Micro ECC
 =========

 To select Micro ECC, the library needs to be installed and configured.

 .. code-block:: sh

    # Install and configure Micro ECC
    pw package install micro-ecc
    gn gen out --args='
        dir_pw_third_party_micro_ecc=getenv("PW_PACKAGE_ROOT")+"/micro-ecc"
        pw_crypto_ECDSA_BACKEND="//pw_crypto:ecdsa_uecc"
    '

 The default micro-ecc backend uses big endian as is standard practice. It also
 has a little-endian configuration which can be used to slightly reduce call
 stack frame use and/or when non pw_crypto clients use the same micro-ecc
 with a little-endian configuration. The little-endian version of micro-ecc
 can be selected with ``pw_crypto_ECDSA_BACKEND="//pw_crypto:ecdsa_uecc_little_endian"``

 Note Micro-ECC does not implement any hashing functions, so you will need to use other backends for SHA256 functionality if needed.

 ------------
 Size Reports
 ------------

 Below are size reports for each crypto service. These vary across
 configurations.

 .. include:: size_report

 -------------
 API reference
 -------------
 .. doxygenfunction:: pw::crypto::ecdsa::VerifyP256Signature(ConstByteSpan public_key, ConstByteSpan digest, ConstByteSpan signature)
 .. doxygenfunction:: pw::crypto::sha256::Hash(ConstByteSpan message, ByteSpan out_digest)
 .. doxygenfunction:: pw::crypto::sha256::Hash(stream::Reader& reader, ByteSpan out_digest)
 .. doxygenvariable:: pw::crypto::sha256::kDigestSizeBytes
 .. doxygenfunction:: pw::crypto::sha256::Sha256::Final(ByteSpan out_digest)
 .. doxygenfunction:: pw::crypto::sha256::Sha256::Update(ConstByteSpan data)
 .. doxygenenum::     pw::crypto::sha256::Sha256State
	.. _module-pw_crypto:

	=========
	pw_crypto
	=========
	A set of safe (read: easy to use, hard to misuse) crypto APIs.

	The following crypto services are provided by this module.

	1. Hashing a message with `SHA256`_.
	2. Verifying a digital signature signed with `ECDSA`_ over the NIST P256 curve.
	3. Many more to come ...

	------
	SHA256
	------

	1. Obtaining a oneshot digest.

	.. code-block:: cpp

	#include "pw_crypto/sha256.h"

	std::byte digest[32];
	if (!pw::crypto::sha256::Hash(message, digest).ok()) {
	// Handle errors.
	}

	// The content can also come from a pw::stream::Reader.
	if (!pw::crypto::sha256::Hash(reader, digest).ok()) {
	// Handle errors.
	}

	2. Hashing a long, potentially non-contiguous message.

	.. code-block:: cpp

	#include "pw_crypto/sha256.h"

	std::byte digest[32];

	if (!pw::crypto::sha256::Sha256()
	.Update(chunk1).Update(chunk2).Update(chunk...)
	.Final().ok()) {
	// Handle errors.
	}

	-----
	ECDSA
	-----

	1. Verifying a digital signature signed with ECDSA over the NIST P256 curve.

	.. code-block:: cpp

	#include "pw_crypto/sha256.h"

	std::byte digest[32];
	if (!pw::crypto::sha256::Hash(message, digest).ok()) {
	// handle errors.
	}

	if (!pw::crypto::ecdsa::VerifyP256Signature(public_key, digest,
	signature).ok()) {
	// handle errors.
	}

	2. Verifying a digital signature signed with ECDSA over the NIST P256 curve,
	with a long and/or non-contiguous message.

	.. code-block:: cpp

	#include "pw_crypto/sha256.h"

	std::byte digest[32];

	if (!pw::crypto::sha256::Sha256()
	.Update(chunk1).Update(chunk2).Update(chunkN)
	.Final(digest).ok()) {
	// Handle errors.
	}

	if (!pw::crypto::ecdsa::VerifyP256Signature(public_key, digest,
	signature).ok()) {
	// Handle errors.
	}

	-------------
	Configuration
	-------------

	The crypto services offered by pw_crypto can be backed by different backend
	crypto libraries.

	Mbed TLS
	========

	The `Mbed TLS project <https://www.trustedfirmware.org/projects/mbed-tls/>`_
	is a mature and full-featured crypto library that implements cryptographic
	primitives, X.509 certificate manipulation and the SSL/TLS and DTLS protocols.

	The project also has good support for interfacing to cryptographic accelerators.

	The small code footprint makes the project suitable and popular for embedded
	systems.

	To select the Mbed TLS backend, the MbedTLS library needs to be installed and
	configured. If using GN, do,

	.. code-block:: sh

	# Install and configure MbedTLS
	pw package install mbedtls
	gn gen out --args='
	dir_pw_third_party_mbedtls=getenv("PW_PACKAGE_ROOT")+"/mbedtls"
	pw_crypto_SHA256_BACKEND="//pw_crypto:sha256_mbedtls_v3"
	pw_crypto_ECDSA_BACKEND="//pw_crypto:ecdsa_mbedtls_v3"
	'

	ninja -C out

	If using Bazel, add the Mbed TLS repository to your WORKSPACE and select
	appropriate backends by adding them to your project's `platform
	<https://bazel.build/extending/platforms>`_:

	.. code-block:: python

	platform(
	name = "my_platform",
	constraint_values = [
	"@pigweed//pw_crypto:sha256_mbedtls_backend",
	"@pigweed//pw_crypto:ecdsa_mbedtls_backend",
	# ... other constraint_values
	],
	)

	For optimal code size and/or performance, the Mbed TLS library can be configured
	per product. Mbed TLS configuration is achieved by turning on and off MBEDTLS_*
	options in a config.h file. See //third_party/mbedtls for how this is done.

	``pw::crypto::sha256`` does not need any special configuration as it uses the
	mbedtls_sha256_* APIs directly. However you can optionally turn on
	``MBEDTLS_SHA256_SMALLER`` to further reduce the code size to from 3KiB to
	~1.8KiB at a ~30% slowdown cost (Cortex-M4).

	.. code-block:: c

	#define MBEDTLS_SHA256_SMALLER

	``pw::crypto::ecdsa`` requires the following minimum configurations which yields
	a code size of ~12KiB.

	.. code-block:: c

	#define MBEDTLS_BIGNUM_C
	#define MBEDTLS_ECP_C
	#define MBEDTLS_ECDSA_C
	// The ASN1 options are needed only because mbedtls considers and verifies
	// them (in check_config.h) as dependencies of MBEDTLS_ECDSA_C.
	#define MBEDTLS_ASN1_WRITE_C
	#define MBEDTLS_ASN1_PARSE_C
	#define MBEDTLS_ECP_NO_INTERNAL_RNG
	#define MBEDTLS_ECP_DP_SECP256R1_ENABLED

	Micro ECC
	=========

	To select Micro ECC, the library needs to be installed and configured.

	.. code-block:: sh

	# Install and configure Micro ECC
	pw package install micro-ecc
	gn gen out --args='
	dir_pw_third_party_micro_ecc=getenv("PW_PACKAGE_ROOT")+"/micro-ecc"
	pw_crypto_ECDSA_BACKEND="//pw_crypto:ecdsa_uecc"
	'

	The default micro-ecc backend uses big endian as is standard practice. It also
	has a little-endian configuration which can be used to slightly reduce call
	stack frame use and/or when non pw_crypto clients use the same micro-ecc
	with a little-endian configuration. The little-endian version of micro-ecc
	can be selected with ``pw_crypto_ECDSA_BACKEND="//pw_crypto:ecdsa_uecc_little_endian"``

	Note Micro-ECC does not implement any hashing functions, so you will need to use other backends for SHA256 functionality if needed.

	------------
	Size Reports
	------------

	Below are size reports for each crypto service. These vary across
	configurations.

	.. include:: size_report

	-------------
	API reference
	-------------
	.. doxygenfunction:: pw::crypto::ecdsa::VerifyP256Signature(ConstByteSpan public_key, ConstByteSpan digest, ConstByteSpan signature)
	.. doxygenfunction:: pw::crypto::sha256::Hash(ConstByteSpan message, ByteSpan out_digest)
	.. doxygenfunction:: pw::crypto::sha256::Hash(stream::Reader& reader, ByteSpan out_digest)
	.. doxygenvariable:: pw::crypto::sha256::kDigestSizeBytes
	.. doxygenfunction:: pw::crypto::sha256::Sha256::Final(ByteSpan out_digest)
	.. doxygenfunction:: pw::crypto::sha256::Sha256::Update(ConstByteSpan data)
	.. doxygenenum:: pw::crypto::sha256::Sha256State