drivers/auth/crypto_mod.c - filogic/atf - Gitiles

 /*
  * Copyright (c) 2015-2023, Arm Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <assert.h>

 #include <common/debug.h>
 #include <drivers/auth/crypto_mod.h>

 /* Variable exported by the crypto library through REGISTER_CRYPTO_LIB() */

 /*
  * The crypto module is responsible for verifying digital signatures and hashes.
  * It relies on a crypto library to perform the cryptographic operations.
  *
  * The crypto module itself does not impose any specific format on signatures,
  * signature algorithm, keys or hashes, but most cryptographic libraries will
  * take the parameters as the following DER encoded ASN.1 structures:
  *
  *     AlgorithmIdentifier ::= SEQUENCE  {
  *         algorithm        OBJECT IDENTIFIER,
  *         parameters       ANY DEFINED BY algorithm OPTIONAL
  *     }
  *
  *     DigestInfo ::= SEQUENCE {
  *         digestAlgorithm  AlgorithmIdentifier,
  *         digest           OCTET STRING
  *     }
  *
  *     SubjectPublicKeyInfo ::= SEQUENCE  {
  *         algorithm        AlgorithmIdentifier,
  *         subjectPublicKey BIT STRING
  *     }
  *
  *     SignatureAlgorithm ::= AlgorithmIdentifier
  *
  *     SignatureValue ::= BIT STRING
  */

 /*
  * Perform some static checking and call the library initialization function
  */
 void crypto_mod_init(void)
 {
 	assert(crypto_lib_desc.name != NULL);
 	assert(crypto_lib_desc.init != NULL);
 #if CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_ONLY || \
 CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC
 	assert(crypto_lib_desc.verify_signature != NULL);
 	assert(crypto_lib_desc.verify_hash != NULL);
 #endif /* CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_ONLY || \
 	  CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC */

 #if CRYPTO_SUPPORT == CRYPTO_HASH_CALC_ONLY || \
 CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC
 	assert(crypto_lib_desc.calc_hash != NULL);
 #endif /* CRYPTO_SUPPORT == CRYPTO_HASH_CALC_ONLY || \
 	  CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC */

 	/* Initialize the cryptographic library */
 	crypto_lib_desc.init();
 	INFO("Using crypto library '%s'\n", crypto_lib_desc.name);
 }

 #if CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_ONLY || \
 CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC
 /*
  * Function to verify a digital signature
  *
  * Parameters:
  *
  *   data_ptr, data_len: signed data
  *   sig_ptr, sig_len: the digital signature
  *   sig_alg_ptr, sig_alg_len: the digital signature algorithm
  *   pk_ptr, pk_len: the public key
  */
 int crypto_mod_verify_signature(void *data_ptr, unsigned int data_len,
 				void *sig_ptr, unsigned int sig_len,
 				void *sig_alg_ptr, unsigned int sig_alg_len,
 				void *pk_ptr, unsigned int pk_len)
 {
 	assert(data_ptr != NULL);
 	assert(data_len != 0);
 	assert(sig_ptr != NULL);
 	assert(sig_len != 0);
 	assert(sig_alg_ptr != NULL);
 	assert(sig_alg_len != 0);
 	assert(pk_ptr != NULL);
 	assert(pk_len != 0);

 	return crypto_lib_desc.verify_signature(data_ptr, data_len,
 						sig_ptr, sig_len,
 						sig_alg_ptr, sig_alg_len,
 						pk_ptr, pk_len);
 }

 /*
  * Verify a hash by comparison
  *
  * Parameters:
  *
  *   data_ptr, data_len: data to be hashed
  *   digest_info_ptr, digest_info_len: hash to be compared
  */
 int crypto_mod_verify_hash(void *data_ptr, unsigned int data_len,
 			   void *digest_info_ptr, unsigned int digest_info_len)
 {
 	assert(data_ptr != NULL);
 	assert(data_len != 0);
 	assert(digest_info_ptr != NULL);
 	assert(digest_info_len != 0);

 	return crypto_lib_desc.verify_hash(data_ptr, data_len,
 					   digest_info_ptr, digest_info_len);
 }
 #endif /* CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_ONLY || \
 	  CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC */

 #if CRYPTO_SUPPORT == CRYPTO_HASH_CALC_ONLY || \
 CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC
 /*
  * Calculate a hash
  *
  * Parameters:
  *
  *   alg: message digest algorithm
  *   data_ptr, data_len: data to be hashed
  *   output: resulting hash
  */
 int crypto_mod_calc_hash(enum crypto_md_algo alg, void *data_ptr,
 			 unsigned int data_len,
 			 unsigned char output[CRYPTO_MD_MAX_SIZE])
 {
 	assert(data_ptr != NULL);
 	assert(data_len != 0);
 	assert(output != NULL);

 	return crypto_lib_desc.calc_hash(alg, data_ptr, data_len, output);
 }
 #endif /* CRYPTO_SUPPORT == CRYPTO_HASH_CALC_ONLY || \
 	  CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC */

 int crypto_mod_convert_pk(void *full_pk_ptr, unsigned int full_pk_len,
 			  void **hashed_pk_ptr, unsigned int *hashed_pk_len)
 {
 	if (crypto_lib_desc.convert_pk != NULL) {
 		return crypto_lib_desc.convert_pk(full_pk_ptr, full_pk_len,
 						  hashed_pk_ptr, hashed_pk_len);
 	}

 	*hashed_pk_ptr = full_pk_ptr;
 	*hashed_pk_len = full_pk_len;

 	return 0;
 }

 /*
  * Authenticated decryption of data
  *
  * Parameters:
  *
  *   dec_algo: authenticated decryption algorithm
  *   data_ptr, len: data to be decrypted (inout param)
  *   key, key_len, key_flags: symmetric decryption key
  *   iv, iv_len: initialization vector
  *   tag, tag_len: authentication tag
  */
 int crypto_mod_auth_decrypt(enum crypto_dec_algo dec_algo, void *data_ptr,
 			    size_t len, const void *key, unsigned int key_len,
 			    unsigned int key_flags, const void *iv,
 			    unsigned int iv_len, const void *tag,
 			    unsigned int tag_len)
 {
 	assert(crypto_lib_desc.auth_decrypt != NULL);
 	assert(data_ptr != NULL);
 	assert(len != 0U);
 	assert(key != NULL);
 	assert(key_len != 0U);
 	assert(iv != NULL);
 	assert((iv_len != 0U) && (iv_len <= CRYPTO_MAX_IV_SIZE));
 	assert(tag != NULL);
 	assert((tag_len != 0U) && (tag_len <= CRYPTO_MAX_TAG_SIZE));

 	return crypto_lib_desc.auth_decrypt(dec_algo, data_ptr, len, key,
 					    key_len, key_flags, iv, iv_len, tag,
 					    tag_len);
 }
	/*
	* Copyright (c) 2015-2023, Arm Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <assert.h>

	#include <common/debug.h>
	#include <drivers/auth/crypto_mod.h>

	/* Variable exported by the crypto library through REGISTER_CRYPTO_LIB() */

	/*
	* The crypto module is responsible for verifying digital signatures and hashes.
	* It relies on a crypto library to perform the cryptographic operations.
	*
	* The crypto module itself does not impose any specific format on signatures,
	* signature algorithm, keys or hashes, but most cryptographic libraries will
	* take the parameters as the following DER encoded ASN.1 structures:
	*
	* AlgorithmIdentifier ::= SEQUENCE {
	* algorithm OBJECT IDENTIFIER,
	* parameters ANY DEFINED BY algorithm OPTIONAL
	* }
	*
	* DigestInfo ::= SEQUENCE {
	* digestAlgorithm AlgorithmIdentifier,
	* digest OCTET STRING
	* }
	*
	* SubjectPublicKeyInfo ::= SEQUENCE {
	* algorithm AlgorithmIdentifier,
	* subjectPublicKey BIT STRING
	* }
	*
	* SignatureAlgorithm ::= AlgorithmIdentifier
	*
	* SignatureValue ::= BIT STRING
	*/

	/*
	* Perform some static checking and call the library initialization function
	*/
	void crypto_mod_init(void)
	{
	assert(crypto_lib_desc.name != NULL);
	assert(crypto_lib_desc.init != NULL);
	#if CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_ONLY \|\| \
	CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC
	assert(crypto_lib_desc.verify_signature != NULL);
	assert(crypto_lib_desc.verify_hash != NULL);
	#endif /* CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_ONLY \|\| \
	CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC */

	#if CRYPTO_SUPPORT == CRYPTO_HASH_CALC_ONLY \|\| \
	CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC
	assert(crypto_lib_desc.calc_hash != NULL);
	#endif /* CRYPTO_SUPPORT == CRYPTO_HASH_CALC_ONLY \|\| \
	CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC */

	/* Initialize the cryptographic library */
	crypto_lib_desc.init();
	INFO("Using crypto library '%s'\n", crypto_lib_desc.name);
	}

	#if CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_ONLY \|\| \
	CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC
	/*
	* Function to verify a digital signature
	*
	* Parameters:
	*
	* data_ptr, data_len: signed data
	* sig_ptr, sig_len: the digital signature
	* sig_alg_ptr, sig_alg_len: the digital signature algorithm
	* pk_ptr, pk_len: the public key
	*/
	int crypto_mod_verify_signature(void *data_ptr, unsigned int data_len,
	void *sig_ptr, unsigned int sig_len,
	void *sig_alg_ptr, unsigned int sig_alg_len,
	void *pk_ptr, unsigned int pk_len)
	{
	assert(data_ptr != NULL);
	assert(data_len != 0);
	assert(sig_ptr != NULL);
	assert(sig_len != 0);
	assert(sig_alg_ptr != NULL);
	assert(sig_alg_len != 0);
	assert(pk_ptr != NULL);
	assert(pk_len != 0);

	return crypto_lib_desc.verify_signature(data_ptr, data_len,
	sig_ptr, sig_len,
	sig_alg_ptr, sig_alg_len,
	pk_ptr, pk_len);
	}

	/*
	* Verify a hash by comparison
	*
	* Parameters:
	*
	* data_ptr, data_len: data to be hashed
	* digest_info_ptr, digest_info_len: hash to be compared
	*/
	int crypto_mod_verify_hash(void *data_ptr, unsigned int data_len,
	void *digest_info_ptr, unsigned int digest_info_len)
	{
	assert(data_ptr != NULL);
	assert(data_len != 0);
	assert(digest_info_ptr != NULL);
	assert(digest_info_len != 0);

	return crypto_lib_desc.verify_hash(data_ptr, data_len,
	digest_info_ptr, digest_info_len);
	}
	#endif /* CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_ONLY \|\| \
	CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC */

	#if CRYPTO_SUPPORT == CRYPTO_HASH_CALC_ONLY \|\| \
	CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC
	/*
	* Calculate a hash
	*
	* Parameters:
	*
	* alg: message digest algorithm
	* data_ptr, data_len: data to be hashed
	* output: resulting hash
	*/
	int crypto_mod_calc_hash(enum crypto_md_algo alg, void *data_ptr,
	unsigned int data_len,
	unsigned char output[CRYPTO_MD_MAX_SIZE])
	{
	assert(data_ptr != NULL);
	assert(data_len != 0);
	assert(output != NULL);

	return crypto_lib_desc.calc_hash(alg, data_ptr, data_len, output);
	}
	#endif /* CRYPTO_SUPPORT == CRYPTO_HASH_CALC_ONLY \|\| \
	CRYPTO_SUPPORT == CRYPTO_AUTH_VERIFY_AND_HASH_CALC */

	int crypto_mod_convert_pk(void *full_pk_ptr, unsigned int full_pk_len,
	void *hashed_pk_ptr, unsigned int hashed_pk_len)
	{
	if (crypto_lib_desc.convert_pk != NULL) {
	return crypto_lib_desc.convert_pk(full_pk_ptr, full_pk_len,
	hashed_pk_ptr, hashed_pk_len);
	}

	*hashed_pk_ptr = full_pk_ptr;
	*hashed_pk_len = full_pk_len;

	return 0;
	}

	/*
	* Authenticated decryption of data
	*
	* Parameters:
	*
	* dec_algo: authenticated decryption algorithm
	* data_ptr, len: data to be decrypted (inout param)
	* key, key_len, key_flags: symmetric decryption key
	* iv, iv_len: initialization vector
	* tag, tag_len: authentication tag
	*/
	int crypto_mod_auth_decrypt(enum crypto_dec_algo dec_algo, void *data_ptr,
	size_t len, const void *key, unsigned int key_len,
	unsigned int key_flags, const void *iv,
	unsigned int iv_len, const void *tag,
	unsigned int tag_len)
	{
	assert(crypto_lib_desc.auth_decrypt != NULL);
	assert(data_ptr != NULL);
	assert(len != 0U);
	assert(key != NULL);
	assert(key_len != 0U);
	assert(iv != NULL);
	assert((iv_len != 0U) && (iv_len <= CRYPTO_MAX_IV_SIZE));
	assert(tag != NULL);
	assert((tag_len != 0U) && (tag_len <= CRYPTO_MAX_TAG_SIZE));

	return crypto_lib_desc.auth_decrypt(dec_algo, data_ptr, len, key,
	key_len, key_flags, iv, iv_len, tag,
	tag_len);
	}