/* * Copyright (c) 2018-2023, Arm Limited. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause * */ #include #include #include "tfm_crypto_defs.h" #include "psa/client.h" #include "psa_manifest/sid.h" #define API_DISPATCH(in_vec, out_vec) \ psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, \ in_vec, IOVEC_LEN(in_vec), \ out_vec, IOVEC_LEN(out_vec)) #define API_DISPATCH_NO_OUTVEC(in_vec) \ psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, \ in_vec, IOVEC_LEN(in_vec), \ (psa_outvec *)NULL, 0) /*! * \def CONFIG_TFM_CRYPTO_API_RENAME * * \brief By setting this to 1, system integrators can rename the symbols of the * PSA Crypto APIs available in the TF-M interface. It allows flexibility * for some integration setups where multiple providers of the PSA Crypto * APIs are available at link time. Normally this configuration option * should not be enabled when building the Secure interface because the * secure partitions will just use the standard function names. By default * it prepends the "tfm_crypto__" prefix. * * \note This config option is not available through the TF-M configuration as * it's for NS applications and system integrators to enable. */ /*! * \def TFM_CRYPTO_API(ret, fun) * * \brief Define the function signature of a TF-M Crypto API with return * type \a ret and PSA Crypto API function name \a fun * * \param ret return type associated to the API * \param fun API name (e.g. a PSA Crypto API function name) * * \returns Function signature */ #if CONFIG_TFM_CRYPTO_API_RENAME == 1 #define TFM_CRYPTO_API(ret, fun) ret tfm_crypto__##fun #else #define TFM_CRYPTO_API(ret, fun) ret fun #endif /* CONFIG_TFM_CRYPTO_API_RENAME */ TFM_CRYPTO_API(psa_status_t, psa_crypto_init)(void) { /* Service init is performed during TFM boot up, * so application level initialisation is empty */ return PSA_SUCCESS; } TFM_CRYPTO_API(psa_status_t, psa_open_key)(psa_key_id_t id, psa_key_id_t *key) { const struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_OPEN_KEY_SID, .key_id = id, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = key, .len = sizeof(psa_key_id_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_close_key)(psa_key_id_t key) { const struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CLOSE_KEY_SID, .key_id = key, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_import_key)(const psa_key_attributes_t *attributes, const uint8_t *data, size_t data_length, psa_key_id_t *key) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_IMPORT_KEY_SID, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = attributes, .len = sizeof(psa_key_attributes_t)}, {.base = data, .len = data_length} }; psa_outvec out_vec[] = { {.base = key, .len = sizeof(psa_key_id_t)} }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_destroy_key)(psa_key_id_t key) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_DESTROY_KEY_SID, .key_id = key, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_get_key_attributes)(psa_key_id_t key, psa_key_attributes_t *attributes) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_GET_KEY_ATTRIBUTES_SID, .key_id = key, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = attributes, .len = sizeof(psa_key_attributes_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_export_key)(psa_key_id_t key, uint8_t *data, size_t data_size, size_t *data_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_EXPORT_KEY_SID, .key_id = key, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = data, .len = data_size} }; status = API_DISPATCH(in_vec, out_vec); *data_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_export_public_key)(psa_key_id_t key, uint8_t *data, size_t data_size, size_t *data_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_EXPORT_PUBLIC_KEY_SID, .key_id = key, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = data, .len = data_size} }; status = API_DISPATCH(in_vec, out_vec); *data_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_purge_key)(psa_key_id_t key) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_PURGE_KEY_SID, .key_id = key, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_copy_key)(psa_key_id_t source_key, const psa_key_attributes_t *attributes, psa_key_id_t *target_key) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_COPY_KEY_SID, .key_id = source_key, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = attributes, .len = sizeof(psa_key_attributes_t)}, }; psa_outvec out_vec[] = { {.base = target_key, .len = sizeof(psa_key_id_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_cipher_generate_iv)(psa_cipher_operation_t *operation, unsigned char *iv, size_t iv_size, size_t *iv_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CIPHER_GENERATE_IV_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = iv, .len = iv_size}, }; status = API_DISPATCH(in_vec, out_vec); *iv_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_cipher_set_iv)(psa_cipher_operation_t *operation, const unsigned char *iv, size_t iv_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CIPHER_SET_IV_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = iv, .len = iv_length}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_cipher_encrypt_setup)(psa_cipher_operation_t *operation, psa_key_id_t key, psa_algorithm_t alg) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CIPHER_ENCRYPT_SETUP_SID, .key_id = key, .alg = alg, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_cipher_decrypt_setup)(psa_cipher_operation_t *operation, psa_key_id_t key, psa_algorithm_t alg) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CIPHER_DECRYPT_SETUP_SID, .key_id = key, .alg = alg, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_cipher_update)(psa_cipher_operation_t *operation, const uint8_t *input, size_t input_length, unsigned char *output, size_t output_size, size_t *output_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CIPHER_UPDATE_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, }; psa_outvec out_vec[] = { {.base = output, .len = output_size} }; status = API_DISPATCH(in_vec, out_vec); *output_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_cipher_abort)(psa_cipher_operation_t *operation) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CIPHER_ABORT_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_cipher_finish)(psa_cipher_operation_t *operation, uint8_t *output, size_t output_size, size_t *output_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CIPHER_FINISH_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, {.base = output, .len = output_size}, }; status = API_DISPATCH(in_vec, out_vec); *output_length = out_vec[1].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_hash_setup)(psa_hash_operation_t *operation, psa_algorithm_t alg) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_HASH_SETUP_SID, .alg = alg, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_hash_update)(psa_hash_operation_t *operation, const uint8_t *input, size_t input_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_HASH_UPDATE_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_hash_finish)(psa_hash_operation_t *operation, uint8_t *hash, size_t hash_size, size_t *hash_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_HASH_FINISH_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, {.base = hash, .len = hash_size}, }; status = API_DISPATCH(in_vec, out_vec); *hash_length = out_vec[1].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_hash_verify)(psa_hash_operation_t *operation, const uint8_t *hash, size_t hash_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_HASH_VERIFY_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = hash, .len = hash_length}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_hash_abort)(psa_hash_operation_t *operation) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_HASH_ABORT_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_hash_clone)(const psa_hash_operation_t *source_operation, psa_hash_operation_t *target_operation) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_HASH_CLONE_SID, .op_handle = source_operation->handle, }; if (target_operation && (target_operation->handle != 0)) { return PSA_ERROR_BAD_STATE; } psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = &(target_operation->handle), .len = sizeof(target_operation->handle)}, }; psa_outvec out_vec[] = { {.base = &(target_operation->handle), .len = sizeof(target_operation->handle)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_hash_compute)(psa_algorithm_t alg, const uint8_t *input, size_t input_length, uint8_t *hash, size_t hash_size, size_t *hash_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_HASH_COMPUTE_SID, .alg = alg, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, }; psa_outvec out_vec[] = { {.base = hash, .len = hash_size} }; status = API_DISPATCH(in_vec, out_vec); *hash_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_hash_compare)(psa_algorithm_t alg, const uint8_t *input, size_t input_length, const uint8_t *hash, size_t hash_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_HASH_COMPARE_SID, .alg = alg, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, {.base = hash, .len = hash_length}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_mac_sign_setup)(psa_mac_operation_t *operation, psa_key_id_t key, psa_algorithm_t alg) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_MAC_SIGN_SETUP_SID, .key_id = key, .alg = alg, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_mac_verify_setup)(psa_mac_operation_t *operation, psa_key_id_t key, psa_algorithm_t alg) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_MAC_VERIFY_SETUP_SID, .key_id = key, .alg = alg, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_mac_update)(psa_mac_operation_t *operation, const uint8_t *input, size_t input_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_MAC_UPDATE_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_mac_sign_finish)(psa_mac_operation_t *operation, uint8_t *mac, size_t mac_size, size_t *mac_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_MAC_SIGN_FINISH_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, {.base = mac, .len = mac_size}, }; status = API_DISPATCH(in_vec, out_vec); *mac_length = out_vec[1].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_mac_verify_finish)(psa_mac_operation_t *operation, const uint8_t *mac, size_t mac_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_MAC_VERIFY_FINISH_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = mac, .len = mac_length}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_mac_abort)(psa_mac_operation_t *operation) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_MAC_ABORT_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_aead_encrypt)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *nonce, size_t nonce_length, const uint8_t *additional_data, size_t additional_data_length, const uint8_t *plaintext, size_t plaintext_length, uint8_t *ciphertext, size_t ciphertext_size, size_t *ciphertext_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_ENCRYPT_SID, .key_id = key, .alg = alg, .aead_in = {.nonce = {0}, .nonce_length = 0} }; /* Sanitize the optional input */ if ((additional_data == NULL) && (additional_data_length != 0)) { return PSA_ERROR_INVALID_ARGUMENT; } psa_invec in_vec[] = { {.base = NULL, .len = 0}, {.base = plaintext, .len = plaintext_length}, {.base = additional_data, .len = additional_data_length}, }; psa_outvec out_vec[] = { {.base = ciphertext, .len = ciphertext_size}, }; if (nonce_length > TFM_CRYPTO_MAX_NONCE_LENGTH) { return PSA_ERROR_INVALID_ARGUMENT; } if (nonce != NULL) { for (size_t idx = 0; idx < nonce_length; idx++) { iov.aead_in.nonce[idx] = nonce[idx]; } iov.aead_in.nonce_length = nonce_length; } in_vec[0].base = &iov; in_vec[0].len = sizeof(struct tfm_crypto_pack_iovec); size_t in_len = IOVEC_LEN(in_vec); if (additional_data == NULL) { in_len--; } status = psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, in_vec, in_len, out_vec, IOVEC_LEN(out_vec)); *ciphertext_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_decrypt)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *nonce, size_t nonce_length, const uint8_t *additional_data, size_t additional_data_length, const uint8_t *ciphertext, size_t ciphertext_length, uint8_t *plaintext, size_t plaintext_size, size_t *plaintext_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_DECRYPT_SID, .key_id = key, .alg = alg, .aead_in = {.nonce = {0}, .nonce_length = 0} }; /* Sanitize the optional input */ if ((additional_data == NULL) && (additional_data_length != 0)) { return PSA_ERROR_INVALID_ARGUMENT; } psa_invec in_vec[] = { {.base = NULL, .len = 0}, {.base = ciphertext, .len = ciphertext_length}, {.base = additional_data, .len = additional_data_length}, }; psa_outvec out_vec[] = { {.base = plaintext, .len = plaintext_size}, }; if (nonce_length > TFM_CRYPTO_MAX_NONCE_LENGTH) { return PSA_ERROR_INVALID_ARGUMENT; } if (nonce != NULL) { for (size_t idx = 0; idx < nonce_length; idx++) { iov.aead_in.nonce[idx] = nonce[idx]; } iov.aead_in.nonce_length = nonce_length; } in_vec[0].base = &iov; in_vec[0].len = sizeof(struct tfm_crypto_pack_iovec); size_t in_len = IOVEC_LEN(in_vec); if (additional_data == NULL) { in_len--; } status = psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, in_vec, in_len, out_vec, IOVEC_LEN(out_vec)); *plaintext_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_encrypt_setup)(psa_aead_operation_t *operation, psa_key_id_t key, psa_algorithm_t alg) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_ENCRYPT_SETUP_SID, .key_id = key, .alg = alg, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)} }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)} }; status = API_DISPATCH(in_vec, out_vec); return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_decrypt_setup)(psa_aead_operation_t *operation, psa_key_id_t key, psa_algorithm_t alg) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_DECRYPT_SETUP_SID, .key_id = key, .alg = alg, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)} }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)} }; status = API_DISPATCH(in_vec, out_vec); return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_generate_nonce)(psa_aead_operation_t *operation, uint8_t *nonce, size_t nonce_size, size_t *nonce_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_GENERATE_NONCE_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = nonce, .len = nonce_size} }; status = API_DISPATCH(in_vec, out_vec); *nonce_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_set_nonce)(psa_aead_operation_t *operation, const uint8_t *nonce, size_t nonce_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_SET_NONCE_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = nonce, .len = nonce_length} }; status = API_DISPATCH_NO_OUTVEC(in_vec); return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_set_lengths)(psa_aead_operation_t *operation, size_t ad_length, size_t plaintext_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_SET_LENGTHS_SID, .ad_length = ad_length, .plaintext_length = plaintext_length, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; status = API_DISPATCH_NO_OUTVEC(in_vec); return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_update_ad)(psa_aead_operation_t *operation, const uint8_t *input, size_t input_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_UPDATE_AD_SID, .op_handle = operation->handle, }; /* Sanitize the optional input */ if ((input == NULL) && (input_length != 0)) { return PSA_ERROR_INVALID_ARGUMENT; } psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length} }; size_t in_len = IOVEC_LEN(in_vec); if (input == NULL) { in_len--; } status = psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, in_vec, in_len, NULL, 0); return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_update)(psa_aead_operation_t *operation, const uint8_t *input, size_t input_length, uint8_t *output, size_t output_size, size_t *output_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_UPDATE_SID, .op_handle = operation->handle, }; /* Sanitize the optional input */ if ((input == NULL) && (input_length != 0)) { return PSA_ERROR_INVALID_ARGUMENT; } psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length} }; psa_outvec out_vec[] = { {.base = output, .len = output_size}, }; size_t in_len = IOVEC_LEN(in_vec); if (input == NULL) { in_len--; } status = psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, in_vec, in_len, out_vec, IOVEC_LEN(out_vec)); *output_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_finish)(psa_aead_operation_t *operation, uint8_t *ciphertext, size_t ciphertext_size, size_t *ciphertext_length, uint8_t *tag, size_t tag_size, size_t *tag_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_FINISH_SID, .op_handle = operation->handle, }; /* Sanitize the optional output */ if ((ciphertext == NULL) && (ciphertext_size != 0)) { return PSA_ERROR_INVALID_ARGUMENT; } psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, {.base = tag, .len = tag_size}, {.base = ciphertext, .len = ciphertext_size} }; size_t out_len = IOVEC_LEN(out_vec); if (ciphertext == NULL || ciphertext_size == 0) { out_len--; } if ((out_len == 3) && (ciphertext_length == NULL)) { return PSA_ERROR_INVALID_ARGUMENT; } status = psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, in_vec, IOVEC_LEN(in_vec), out_vec, out_len); if (out_len == 3) { *ciphertext_length = out_vec[2].len; } else { *ciphertext_length = 0; } *tag_length = out_vec[1].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_verify)(psa_aead_operation_t *operation, uint8_t *plaintext, size_t plaintext_size, size_t *plaintext_length, const uint8_t *tag, size_t tag_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_VERIFY_SID, .op_handle = operation->handle, }; /* Sanitize the optional output */ if ((plaintext == NULL) && (plaintext_size != 0)) { return PSA_ERROR_INVALID_ARGUMENT; } psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = tag, .len = tag_length} }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, {.base = plaintext, .len = plaintext_size} }; size_t out_len = IOVEC_LEN(out_vec); if (plaintext == NULL || plaintext_size == 0) { out_len--; } if ((out_len == 2) && (plaintext_length == NULL)) { return PSA_ERROR_INVALID_ARGUMENT; } status = psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, in_vec, IOVEC_LEN(in_vec), out_vec, out_len); if (out_len == 2) { *plaintext_length = out_vec[1].len; } else { *plaintext_length = 0; } return status; } TFM_CRYPTO_API(psa_status_t, psa_aead_abort)(psa_aead_operation_t *operation) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_AEAD_ABORT_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_sign_message)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *input, size_t input_length, uint8_t *signature, size_t signature_size, size_t *signature_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_ASYMMETRIC_SIGN_MESSAGE_SID, .key_id = key, .alg = alg, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, }; psa_outvec out_vec[] = { {.base = signature, .len = signature_size}, }; status = API_DISPATCH(in_vec, out_vec); *signature_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_verify_message)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *input, size_t input_length, const uint8_t *signature, size_t signature_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_ASYMMETRIC_VERIFY_MESSAGE_SID, .key_id = key, .alg = alg }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, {.base = signature, .len = signature_length} }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_sign_hash)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *hash, size_t hash_length, uint8_t *signature, size_t signature_size, size_t *signature_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_ASYMMETRIC_SIGN_HASH_SID, .key_id = key, .alg = alg, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = hash, .len = hash_length}, }; psa_outvec out_vec[] = { {.base = signature, .len = signature_size}, }; status = API_DISPATCH(in_vec, out_vec); *signature_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_verify_hash)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *hash, size_t hash_length, const uint8_t *signature, size_t signature_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_ASYMMETRIC_VERIFY_HASH_SID, .key_id = key, .alg = alg }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = hash, .len = hash_length}, {.base = signature, .len = signature_length} }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_asymmetric_encrypt)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *input, size_t input_length, const uint8_t *salt, size_t salt_length, uint8_t *output, size_t output_size, size_t *output_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_ASYMMETRIC_ENCRYPT_SID, .key_id = key, .alg = alg }; /* Sanitize the optional input */ if ((salt == NULL) && (salt_length != 0)) { return PSA_ERROR_INVALID_ARGUMENT; } psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, {.base = salt, .len = salt_length} }; psa_outvec out_vec[] = { {.base = output, .len = output_size}, }; size_t in_len = IOVEC_LEN(in_vec); if (salt == NULL) { in_len--; } status = psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, in_vec, in_len, out_vec, IOVEC_LEN(out_vec)); *output_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_asymmetric_decrypt)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *input, size_t input_length, const uint8_t *salt, size_t salt_length, uint8_t *output, size_t output_size, size_t *output_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_ASYMMETRIC_DECRYPT_SID, .key_id = key, .alg = alg }; /* Sanitize the optional input */ if ((salt == NULL) && (salt_length != 0)) { return PSA_ERROR_INVALID_ARGUMENT; } psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, {.base = salt, .len = salt_length} }; psa_outvec out_vec[] = { {.base = output, .len = output_size}, }; size_t in_len = IOVEC_LEN(in_vec); if (salt == NULL) { in_len--; } status = psa_call(TFM_CRYPTO_HANDLE, PSA_IPC_CALL, in_vec, in_len, out_vec, IOVEC_LEN(out_vec)); *output_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_get_capacity)( const psa_key_derivation_operation_t *operation, size_t *capacity) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_GET_CAPACITY_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = capacity, .len = sizeof(size_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_output_bytes)( psa_key_derivation_operation_t *operation, uint8_t *output, size_t output_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_OUTPUT_BYTES_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = output, .len = output_length}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_input_key)( psa_key_derivation_operation_t *operation, psa_key_derivation_step_t step, psa_key_id_t key) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_INPUT_KEY_SID, .key_id = key, .step = step, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_abort)(psa_key_derivation_operation_t *operation) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_ABORT_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_key_agreement)( psa_key_derivation_operation_t *operation, psa_key_derivation_step_t step, psa_key_id_t private_key, const uint8_t *peer_key, size_t peer_key_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_KEY_AGREEMENT_SID, .key_id = private_key, .step = step, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = peer_key, .len = peer_key_length}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_generate_random)(uint8_t *output, size_t output_size) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_GENERATE_RANDOM_SID, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = output, .len = output_size}, }; if (output_size == 0) { return PSA_SUCCESS; } return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_generate_key)(const psa_key_attributes_t *attributes, psa_key_id_t *key) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_GENERATE_KEY_SID, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = attributes, .len = sizeof(psa_key_attributes_t)}, }; psa_outvec out_vec[] = { {.base = key, .len = sizeof(psa_key_id_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_mac_compute)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *input, size_t input_length, uint8_t *mac, size_t mac_size, size_t *mac_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_MAC_COMPUTE_SID, .key_id = key, .alg = alg, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, }; psa_outvec out_vec[] = { {.base = mac, .len = mac_size}, }; status = API_DISPATCH(in_vec, out_vec); *mac_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_mac_verify)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *input, size_t input_length, const uint8_t *mac, const size_t mac_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_MAC_VERIFY_SID, .key_id = key, .alg = alg, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, {.base = mac, .len = mac_length}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_cipher_encrypt)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *input, size_t input_length, uint8_t *output, size_t output_size, size_t *output_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CIPHER_ENCRYPT_SID, .key_id = key, .alg = alg, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, }; psa_outvec out_vec[] = { {.base = output, .len = output_size} }; status = API_DISPATCH(in_vec, out_vec); *output_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_cipher_decrypt)(psa_key_id_t key, psa_algorithm_t alg, const uint8_t *input, size_t input_length, uint8_t *output, size_t output_size, size_t *output_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_CIPHER_DECRYPT_SID, .key_id = key, .alg = alg, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = input, .len = input_length}, }; psa_outvec out_vec[] = { {.base = output, .len = output_size} }; status = API_DISPATCH(in_vec, out_vec); *output_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_raw_key_agreement)(psa_algorithm_t alg, psa_key_id_t private_key, const uint8_t *peer_key, size_t peer_key_length, uint8_t *output, size_t output_size, size_t *output_length) { psa_status_t status; struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_RAW_KEY_AGREEMENT_SID, .alg = alg, .key_id = private_key }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = peer_key, .len = peer_key_length}, }; psa_outvec out_vec[] = { {.base = output, .len = output_size}, }; status = API_DISPATCH(in_vec, out_vec); *output_length = out_vec[0].len; return status; } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_setup)(psa_key_derivation_operation_t *operation, psa_algorithm_t alg) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_SETUP_SID, .alg = alg, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; psa_outvec out_vec[] = { {.base = &(operation->handle), .len = sizeof(uint32_t)}, }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_set_capacity)( psa_key_derivation_operation_t *operation, size_t capacity) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_SET_CAPACITY_SID, .capacity = capacity, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_input_bytes)( psa_key_derivation_operation_t *operation, psa_key_derivation_step_t step, const uint8_t *data, size_t data_length) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_INPUT_BYTES_SID, .step = step, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = data, .len = data_length}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_output_key)( const psa_key_attributes_t *attributes, psa_key_derivation_operation_t *operation, psa_key_id_t *key) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_OUTPUT_KEY_SID, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, {.base = attributes, .len = sizeof(psa_key_attributes_t)}, }; psa_outvec out_vec[] = { {.base = key, .len = sizeof(psa_key_id_t)} }; return API_DISPATCH(in_vec, out_vec); } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_input_integer)( psa_key_derivation_operation_t *operation, psa_key_derivation_step_t step, uint64_t value) { struct tfm_crypto_pack_iovec iov = { .function_id = TFM_CRYPTO_KEY_DERIVATION_INPUT_INTEGER_SID, .step = step, .value = value, .op_handle = operation->handle, }; psa_invec in_vec[] = { {.base = &iov, .len = sizeof(struct tfm_crypto_pack_iovec)}, }; return API_DISPATCH_NO_OUTVEC(in_vec); } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_verify_bytes)( psa_key_derivation_operation_t *operation, const uint8_t *expected_output, size_t output_length) { /* To be implemented when the PSA backend supports it */ return PSA_ERROR_NOT_SUPPORTED; } TFM_CRYPTO_API(psa_status_t, psa_key_derivation_verify_key)( psa_key_derivation_operation_t *operation, psa_key_id_t expected) { /* To be implemented when the PSA backend supports it */ return PSA_ERROR_NOT_SUPPORTED; } /* The implementation of the following helper function is marked * weak to allow for those integrations where this is directly * provided by the psa_crypto_client.c module of Mbed TLS */ __attribute__((weak)) TFM_CRYPTO_API(void, psa_reset_key_attributes)( psa_key_attributes_t *attributes) { memset(attributes, 0, sizeof(*attributes)); }