/* BEGIN_HEADER */ #include #if defined(MBEDTLS_PSA_CRYPTO_SPM) #include "spm/psa_defs.h" #endif #include "mbedtls/asn1.h" #include "mbedtls/asn1write.h" #include "mbedtls/oid.h" #include "psa/crypto.h" #define ARRAY_LENGTH( array ) ( sizeof( array ) / sizeof( *( array ) ) ) #if(UINT32_MAX > SIZE_MAX) #define PSA_CRYPTO_TEST_SIZE_T_RANGE( x ) ( ( x ) <= SIZE_MAX ) #else #define PSA_CRYPTO_TEST_SIZE_T_RANGE( x ) 1 #endif /** An invalid export length that will never be set by psa_export_key(). */ static const size_t INVALID_EXPORT_LENGTH = ~0U; /** Test if a buffer contains a constant byte value. * * `mem_is_char(buffer, c, size)` is true after `memset(buffer, c, size)`. * * \param buffer Pointer to the beginning of the buffer. * \param c Expected value of every byte. * \param size Size of the buffer in bytes. * * \return 1 if the buffer is all-bits-zero. * \return 0 if there is at least one nonzero byte. */ static int mem_is_char( void *buffer, unsigned char c, size_t size ) { size_t i; for( i = 0; i < size; i++ ) { if( ( (unsigned char *) buffer )[i] != c ) return( 0 ); } return( 1 ); } /* Write the ASN.1 INTEGER with the value 2^(bits-1)+x backwards from *p. */ static int asn1_write_10x( unsigned char **p, unsigned char *start, size_t bits, unsigned char x ) { int ret; int len = bits / 8 + 1; if( bits == 0 ) return( MBEDTLS_ERR_ASN1_INVALID_DATA ); if( bits <= 8 && x >= 1 << ( bits - 1 ) ) return( MBEDTLS_ERR_ASN1_INVALID_DATA ); if( *p < start || *p - start < (ptrdiff_t) len ) return( MBEDTLS_ERR_ASN1_BUF_TOO_SMALL ); *p -= len; ( *p )[len-1] = x; if( bits % 8 == 0 ) ( *p )[1] |= 1; else ( *p )[0] |= 1 << ( bits % 8 ); MBEDTLS_ASN1_CHK_ADD( len, mbedtls_asn1_write_len( p, start, len ) ); MBEDTLS_ASN1_CHK_ADD( len, mbedtls_asn1_write_tag( p, start, MBEDTLS_ASN1_INTEGER ) ); return( len ); } static int construct_fake_rsa_key( unsigned char *buffer, size_t buffer_size, unsigned char **p, size_t bits, int keypair ) { size_t half_bits = ( bits + 1 ) / 2; int ret; int len = 0; /* Construct something that looks like a DER encoding of * as defined by PKCS#1 v2.2 (RFC 8017) section A.1.2: * RSAPrivateKey ::= SEQUENCE { * version Version, * modulus INTEGER, -- n * publicExponent INTEGER, -- e * privateExponent INTEGER, -- d * prime1 INTEGER, -- p * prime2 INTEGER, -- q * exponent1 INTEGER, -- d mod (p-1) * exponent2 INTEGER, -- d mod (q-1) * coefficient INTEGER, -- (inverse of q) mod p * otherPrimeInfos OtherPrimeInfos OPTIONAL * } * Or, for a public key, the same structure with only * version, modulus and publicExponent. */ *p = buffer + buffer_size; if( keypair ) { MBEDTLS_ASN1_CHK_ADD( len, /* pq */ asn1_write_10x( p, buffer, half_bits, 1 ) ); MBEDTLS_ASN1_CHK_ADD( len, /* dq */ asn1_write_10x( p, buffer, half_bits, 1 ) ); MBEDTLS_ASN1_CHK_ADD( len, /* dp */ asn1_write_10x( p, buffer, half_bits, 1 ) ); MBEDTLS_ASN1_CHK_ADD( len, /* q */ asn1_write_10x( p, buffer, half_bits, 1 ) ); MBEDTLS_ASN1_CHK_ADD( len, /* p != q to pass mbedtls sanity checks */ asn1_write_10x( p, buffer, half_bits, 3 ) ); MBEDTLS_ASN1_CHK_ADD( len, /* d */ asn1_write_10x( p, buffer, bits, 1 ) ); } MBEDTLS_ASN1_CHK_ADD( len, /* e = 65537 */ asn1_write_10x( p, buffer, 17, 1 ) ); MBEDTLS_ASN1_CHK_ADD( len, /* n */ asn1_write_10x( p, buffer, bits, 1 ) ); if( keypair ) MBEDTLS_ASN1_CHK_ADD( len, /* version = 0 */ mbedtls_asn1_write_int( p, buffer, 0 ) ); MBEDTLS_ASN1_CHK_ADD( len, mbedtls_asn1_write_len( p, buffer, len ) ); { const unsigned char tag = MBEDTLS_ASN1_CONSTRUCTED | MBEDTLS_ASN1_SEQUENCE; MBEDTLS_ASN1_CHK_ADD( len, mbedtls_asn1_write_tag( p, buffer, tag ) ); } return( len ); } static int exercise_mac_key( psa_key_slot_t key, psa_key_usage_t usage, psa_algorithm_t alg ) { psa_mac_operation_t operation; const unsigned char input[] = "foo"; unsigned char mac[PSA_MAC_MAX_SIZE] = {0}; size_t mac_length = sizeof( mac ); if( usage & PSA_KEY_USAGE_SIGN ) { TEST_ASSERT( psa_mac_sign_setup( &operation, key, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_mac_update( &operation, input, sizeof( input ) ) == PSA_SUCCESS ); TEST_ASSERT( psa_mac_sign_finish( &operation, mac, sizeof( mac ), &mac_length ) == PSA_SUCCESS ); } if( usage & PSA_KEY_USAGE_VERIFY ) { psa_status_t verify_status = ( usage & PSA_KEY_USAGE_SIGN ? PSA_SUCCESS : PSA_ERROR_INVALID_SIGNATURE ); TEST_ASSERT( psa_mac_verify_setup( &operation, key, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_mac_update( &operation, input, sizeof( input ) ) == PSA_SUCCESS ); TEST_ASSERT( psa_mac_verify_finish( &operation, mac, mac_length ) == verify_status ); } return( 1 ); exit: psa_mac_abort( &operation ); return( 0 ); } static int exercise_cipher_key( psa_key_slot_t key, psa_key_usage_t usage, psa_algorithm_t alg ) { psa_cipher_operation_t operation; unsigned char iv[16] = {0}; size_t iv_length = sizeof( iv ); const unsigned char plaintext[16] = "Hello, world..."; unsigned char ciphertext[32] = "(wabblewebblewibblewobblewubble)"; size_t ciphertext_length = sizeof( ciphertext ); unsigned char decrypted[sizeof( ciphertext )]; size_t part_length; if( usage & PSA_KEY_USAGE_ENCRYPT ) { TEST_ASSERT( psa_cipher_encrypt_setup( &operation, key, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_generate_iv( &operation, iv, sizeof( iv ), &iv_length ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_update( &operation, plaintext, sizeof( plaintext ), ciphertext, sizeof( ciphertext ), &ciphertext_length ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_finish( &operation, ciphertext + ciphertext_length, sizeof( ciphertext ) - ciphertext_length, &part_length ) == PSA_SUCCESS ); ciphertext_length += part_length; } if( usage & PSA_KEY_USAGE_DECRYPT ) { psa_status_t status; psa_key_type_t type = PSA_KEY_TYPE_NONE; if( ! ( usage & PSA_KEY_USAGE_ENCRYPT ) ) { size_t bits; TEST_ASSERT( psa_get_key_information( key, &type, &bits ) ); iv_length = PSA_BLOCK_CIPHER_BLOCK_SIZE( type ); } TEST_ASSERT( psa_cipher_decrypt_setup( &operation, key, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_set_iv( &operation, iv, iv_length ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_update( &operation, ciphertext, ciphertext_length, decrypted, sizeof( decrypted ), &part_length ) == PSA_SUCCESS ); status = psa_cipher_finish( &operation, decrypted + part_length, sizeof( decrypted ) - part_length, &part_length ); /* For a stream cipher, all inputs are valid. For a block cipher, * if the input is some aribtrary data rather than an actual ciphertext, a padding error is likely. */ if( ( usage & PSA_KEY_USAGE_ENCRYPT ) || PSA_BLOCK_CIPHER_BLOCK_SIZE( type ) == 1 ) TEST_ASSERT( status == PSA_SUCCESS ); else TEST_ASSERT( status == PSA_SUCCESS || status == PSA_ERROR_INVALID_PADDING ); } return( 1 ); exit: psa_cipher_abort( &operation ); return( 0 ); } static int exercise_aead_key( psa_key_slot_t key, psa_key_usage_t usage, psa_algorithm_t alg ) { unsigned char nonce[16] = {0}; size_t nonce_length = sizeof( nonce ); unsigned char plaintext[16] = "Hello, world..."; unsigned char ciphertext[48] = "(wabblewebblewibblewobblewubble)"; size_t ciphertext_length = sizeof( ciphertext ); size_t plaintext_length = sizeof( ciphertext ); if( usage & PSA_KEY_USAGE_ENCRYPT ) { TEST_ASSERT( psa_aead_encrypt( key, alg, nonce, nonce_length, NULL, 0, plaintext, sizeof( plaintext ), ciphertext, sizeof( ciphertext ), &ciphertext_length ) == PSA_SUCCESS ); } if( usage & PSA_KEY_USAGE_DECRYPT ) { psa_status_t verify_status = ( usage & PSA_KEY_USAGE_ENCRYPT ? PSA_SUCCESS : PSA_ERROR_INVALID_SIGNATURE ); TEST_ASSERT( psa_aead_decrypt( key, alg, nonce, nonce_length, NULL, 0, ciphertext, ciphertext_length, plaintext, sizeof( plaintext ), &plaintext_length ) == verify_status ); } return( 1 ); exit: return( 0 ); } static int exercise_signature_key( psa_key_slot_t key, psa_key_usage_t usage, psa_algorithm_t alg ) { unsigned char payload[PSA_HASH_MAX_SIZE] = {1}; size_t payload_length = 16; unsigned char signature[PSA_ASYMMETRIC_SIGNATURE_MAX_SIZE] = {0}; size_t signature_length = sizeof( signature ); if( usage & PSA_KEY_USAGE_SIGN ) { /* Some algorithms require the payload to have the size of * the hash encoded in the algorithm. Use this input size * even for algorithms that allow other input sizes. */ psa_algorithm_t hash_alg = PSA_ALG_SIGN_GET_HASH( alg ); if( hash_alg != 0 ) payload_length = PSA_HASH_SIZE( hash_alg ); TEST_ASSERT( psa_asymmetric_sign( key, alg, payload, payload_length, signature, sizeof( signature ), &signature_length ) == PSA_SUCCESS ); } if( usage & PSA_KEY_USAGE_VERIFY ) { psa_status_t verify_status = ( usage & PSA_KEY_USAGE_SIGN ? PSA_SUCCESS : PSA_ERROR_INVALID_SIGNATURE ); TEST_ASSERT( psa_asymmetric_verify( key, alg, payload, payload_length, signature, signature_length ) == verify_status ); } return( 1 ); exit: return( 0 ); } static int exercise_asymmetric_encryption_key( psa_key_slot_t key, psa_key_usage_t usage, psa_algorithm_t alg ) { unsigned char plaintext[256] = "Hello, world..."; unsigned char ciphertext[256] = "(wabblewebblewibblewobblewubble)"; size_t ciphertext_length = sizeof( ciphertext ); size_t plaintext_length = 16; if( usage & PSA_KEY_USAGE_ENCRYPT ) { TEST_ASSERT( psa_asymmetric_encrypt( key, alg, plaintext, plaintext_length, NULL, 0, ciphertext, sizeof( ciphertext ), &ciphertext_length ) == PSA_SUCCESS ); } if( usage & PSA_KEY_USAGE_DECRYPT ) { psa_status_t status = psa_asymmetric_decrypt( key, alg, ciphertext, ciphertext_length, NULL, 0, plaintext, sizeof( plaintext ), &plaintext_length ); TEST_ASSERT( status == PSA_SUCCESS || ( ( usage & PSA_KEY_USAGE_ENCRYPT ) == 0 && ( status == PSA_ERROR_INVALID_ARGUMENT || status == PSA_ERROR_INVALID_PADDING ) ) ); } return( 1 ); exit: return( 0 ); } static int exercise_key_derivation_key( psa_key_slot_t key, psa_key_usage_t usage, psa_algorithm_t alg ) { psa_crypto_generator_t generator = PSA_CRYPTO_GENERATOR_INIT; unsigned char label[16] = "This is a label."; size_t label_length = sizeof( label ); unsigned char seed[16] = "abcdefghijklmnop"; size_t seed_length = sizeof( seed ); unsigned char output[1]; if( usage & PSA_KEY_USAGE_DERIVE ) { TEST_ASSERT( psa_key_derivation( &generator, key, alg, label, label_length, seed, seed_length, sizeof( output ) ) == PSA_SUCCESS ); TEST_ASSERT( psa_generator_read( &generator, output, sizeof( output ) ) == PSA_SUCCESS ); TEST_ASSERT( psa_generator_abort( &generator ) == PSA_SUCCESS ); } return( 1 ); exit: return( 0 ); } static int is_oid_of_key_type( psa_key_type_t type, const uint8_t *oid, size_t oid_length ) { const uint8_t *expected_oid = NULL; size_t expected_oid_length = 0; #if defined(MBEDTLS_RSA_C) if( PSA_KEY_TYPE_IS_RSA( type ) ) { expected_oid = (uint8_t *) MBEDTLS_OID_PKCS1_RSA; expected_oid_length = sizeof( MBEDTLS_OID_PKCS1_RSA ) - 1; } else #endif /* MBEDTLS_RSA_C */ #if defined(MBEDTLS_ECP_C) if( PSA_KEY_TYPE_IS_ECC( type ) ) { expected_oid = (uint8_t *) MBEDTLS_OID_EC_ALG_UNRESTRICTED; expected_oid_length = sizeof( MBEDTLS_OID_EC_ALG_UNRESTRICTED ) - 1; } else #endif /* MBEDTLS_ECP_C */ { char message[40]; mbedtls_snprintf( message, sizeof( message ), "OID not known for key type=0x%08lx", (unsigned long) type ); test_fail( message, __LINE__, __FILE__ ); return( 0 ); } ASSERT_COMPARE( expected_oid, expected_oid_length, oid, oid_length ); return( 1 ); exit: return( 0 ); } static int asn1_skip_integer( unsigned char **p, const unsigned char *end, size_t min_bits, size_t max_bits, int must_be_odd ) { size_t len; size_t actual_bits; unsigned char msb; TEST_ASSERT( mbedtls_asn1_get_tag( p, end, &len, MBEDTLS_ASN1_INTEGER ) == 0 ); /* Tolerate a slight departure from DER encoding: * - 0 may be represented by an empty string or a 1-byte string. * - The sign bit may be used as a value bit. */ if( ( len == 1 && ( *p )[0] == 0 ) || ( len > 1 && ( *p )[0] == 0 && ( ( *p )[1] & 0x80 ) != 0 ) ) { ++( *p ); --len; } if( min_bits == 0 && len == 0 ) return( 1 ); msb = ( *p )[0]; TEST_ASSERT( msb != 0 ); actual_bits = 8 * ( len - 1 ); while( msb != 0 ) { msb >>= 1; ++actual_bits; } TEST_ASSERT( actual_bits >= min_bits ); TEST_ASSERT( actual_bits <= max_bits ); if( must_be_odd ) TEST_ASSERT( ( ( *p )[len-1] & 1 ) != 0 ); *p += len; return( 1 ); exit: return( 0 ); } static int asn1_get_implicit_tag( unsigned char **p, const unsigned char *end, size_t *len, unsigned char n, unsigned char tag ) { int ret; ret = mbedtls_asn1_get_tag( p, end, len, MBEDTLS_ASN1_CONTEXT_SPECIFIC | MBEDTLS_ASN1_CONSTRUCTED | ( n ) ); if( ret != 0 ) return( ret ); end = *p + *len; ret = mbedtls_asn1_get_tag( p, end, len, tag ); if( ret != 0 ) return( ret ); if( *p + *len != end ) return( MBEDTLS_ERR_ASN1_LENGTH_MISMATCH ); return( 0 ); } static int exported_key_sanity_check( psa_key_type_t type, size_t bits, uint8_t *exported, size_t exported_length ) { if( PSA_KEY_TYPE_IS_UNSTRUCTURED( type ) ) TEST_ASSERT( exported_length == ( bits + 7 ) / 8 ); else TEST_ASSERT( exported_length <= PSA_KEY_EXPORT_MAX_SIZE( type, bits ) ); #if defined(MBEDTLS_DES_C) if( type == PSA_KEY_TYPE_DES ) { /* Check the parity bits. */ unsigned i; for( i = 0; i < bits / 8; i++ ) { unsigned bit_count = 0; unsigned m; for( m = 1; m <= 0x100; m <<= 1 ) { if( exported[i] & m ) ++bit_count; } TEST_ASSERT( bit_count % 2 != 0 ); } } else #endif #if defined(MBEDTLS_RSA_C) && defined(MBEDTLS_PK_PARSE_C) if( type == PSA_KEY_TYPE_RSA_KEYPAIR ) { uint8_t *p = exported; uint8_t *end = exported + exported_length; size_t len; /* RSAPrivateKey ::= SEQUENCE { * version INTEGER, -- must be 0 * modulus INTEGER, -- n * publicExponent INTEGER, -- e * privateExponent INTEGER, -- d * prime1 INTEGER, -- p * prime2 INTEGER, -- q * exponent1 INTEGER, -- d mod (p-1) * exponent2 INTEGER, -- d mod (q-1) * coefficient INTEGER, -- (inverse of q) mod p * } */ TEST_ASSERT( mbedtls_asn1_get_tag( &p, end, &len, MBEDTLS_ASN1_SEQUENCE | MBEDTLS_ASN1_CONSTRUCTED ) == 0 ); TEST_ASSERT( p + len == end ); if( ! asn1_skip_integer( &p, end, 0, 0, 0 ) ) goto exit; if( ! asn1_skip_integer( &p, end, bits, bits, 1 ) ) goto exit; if( ! asn1_skip_integer( &p, end, 2, bits, 1 ) ) goto exit; /* Require d to be at least half the size of n. */ if( ! asn1_skip_integer( &p, end, bits / 2, bits, 1 ) ) goto exit; /* Require p and q to be at most half the size of n, rounded up. */ if( ! asn1_skip_integer( &p, end, bits / 2, bits / 2 + 1, 1 ) ) goto exit; if( ! asn1_skip_integer( &p, end, bits / 2, bits / 2 + 1, 1 ) ) goto exit; if( ! asn1_skip_integer( &p, end, 1, bits / 2 + 1, 0 ) ) goto exit; if( ! asn1_skip_integer( &p, end, 1, bits / 2 + 1, 0 ) ) goto exit; if( ! asn1_skip_integer( &p, end, 1, bits / 2 + 1, 0 ) ) goto exit; TEST_ASSERT( p == end ); } else #endif /* MBEDTLS_RSA_C */ #if defined(MBEDTLS_ECP_C) if( PSA_KEY_TYPE_IS_ECC_KEYPAIR( type ) ) { uint8_t *p = exported; uint8_t *end = exported + exported_length; size_t len; int version; /* ECPrivateKey ::= SEQUENCE { * version INTEGER, -- must be 1 * privateKey OCTET STRING, * -- `ceiling(log_{256}(n))`-byte string, big endian, * -- where n is the order of the curve. * parameters ECParameters {{ NamedCurve }}, -- mandatory * publicKey BIT STRING -- mandatory * } */ TEST_ASSERT( mbedtls_asn1_get_tag( &p, end, &len, MBEDTLS_ASN1_SEQUENCE | MBEDTLS_ASN1_CONSTRUCTED ) == 0 ); TEST_ASSERT( p + len == end ); TEST_ASSERT( mbedtls_asn1_get_int( &p, end, &version ) == 0 ); TEST_ASSERT( version == 1 ); TEST_ASSERT( mbedtls_asn1_get_tag( &p, end, &len, MBEDTLS_ASN1_OCTET_STRING ) == 0 ); /* Bug in Mbed TLS: the length of the octet string depends on the value */ // TEST_ASSERT( len == PSA_BITS_TO_BYTES( bits ) ); p += len; TEST_ASSERT( asn1_get_implicit_tag( &p, end, &len, 0, MBEDTLS_ASN1_OID ) == 0 ); p += len; /* publicKey: ECPoint in uncompressed representation (as below) */ TEST_ASSERT( asn1_get_implicit_tag( &p, end, &len, 1, MBEDTLS_ASN1_BIT_STRING ) == 0 ); TEST_ASSERT( p + len == end ); TEST_ASSERT( p[0] == 0 ); /* 0 unused bits in the bit string */ ++p; TEST_ASSERT( p + 1 + 2 * PSA_BITS_TO_BYTES( bits ) == end ); TEST_ASSERT( p[0] == 4 ); } else #endif /* MBEDTLS_ECP_C */ if( PSA_KEY_TYPE_IS_PUBLIC_KEY( type ) ) { uint8_t *p = exported; uint8_t *end = exported + exported_length; size_t len; mbedtls_asn1_buf alg; mbedtls_asn1_buf params; mbedtls_asn1_bitstring bitstring; /* SubjectPublicKeyInfo ::= SEQUENCE { * algorithm AlgorithmIdentifier, * subjectPublicKey BIT STRING } * AlgorithmIdentifier ::= SEQUENCE { * algorithm OBJECT IDENTIFIER, * parameters ANY DEFINED BY algorithm OPTIONAL } */ TEST_ASSERT( mbedtls_asn1_get_tag( &p, end, &len, MBEDTLS_ASN1_SEQUENCE | MBEDTLS_ASN1_CONSTRUCTED ) == 0 ); TEST_ASSERT( p + len == end ); TEST_ASSERT( mbedtls_asn1_get_alg( &p, end, &alg, ¶ms ) == 0 ); if( ! is_oid_of_key_type( type, alg.p, alg.len ) ) goto exit; TEST_ASSERT( mbedtls_asn1_get_bitstring( &p, end, &bitstring ) == 0 ); TEST_ASSERT( p == end ); p = bitstring.p; #if defined(MBEDTLS_RSA_C) if( type == PSA_KEY_TYPE_RSA_PUBLIC_KEY ) { /* RSAPublicKey ::= SEQUENCE { * modulus INTEGER, -- n * publicExponent INTEGER } -- e */ TEST_ASSERT( bitstring.unused_bits == 0 ); TEST_ASSERT( mbedtls_asn1_get_tag( &p, end, &len, MBEDTLS_ASN1_SEQUENCE | MBEDTLS_ASN1_CONSTRUCTED ) == 0 ); TEST_ASSERT( p + len == end ); if( ! asn1_skip_integer( &p, end, bits, bits, 1 ) ) goto exit; if( ! asn1_skip_integer( &p, end, 2, bits, 1 ) ) goto exit; TEST_ASSERT( p == end ); } else #endif /* MBEDTLS_RSA_C */ #if defined(MBEDTLS_ECP_C) if( PSA_KEY_TYPE_IS_ECC_PUBLIC_KEY( type ) ) { /* ECPoint ::= ... * -- first 8 bits: 0x04 (uncompressed representation); * -- then x_P as an n-bit string, big endian; * -- then y_P as a n-bit string, big endian, * -- where n is the order of the curve. */ TEST_ASSERT( bitstring.unused_bits == 0 ); TEST_ASSERT( p + 1 + 2 * PSA_BITS_TO_BYTES( bits ) == end ); TEST_ASSERT( p[0] == 4 ); } else #endif /* MBEDTLS_ECP_C */ { char message[40]; mbedtls_snprintf( message, sizeof( message ), "No sanity check for public key type=0x%08lx", (unsigned long) type ); test_fail( message, __LINE__, __FILE__ ); return( 0 ); } } else { /* No sanity checks for other types */ } return( 1 ); exit: return( 0 ); } static int exercise_export_key( psa_key_slot_t slot, psa_key_usage_t usage ) { psa_key_type_t type; size_t bits; uint8_t *exported = NULL; size_t exported_size = 0; size_t exported_length = 0; int ok = 0; TEST_ASSERT( psa_get_key_information( slot, &type, &bits ) == PSA_SUCCESS ); if( ( usage & PSA_KEY_USAGE_EXPORT ) == 0 && ! PSA_KEY_TYPE_IS_PUBLIC_KEY( type ) ) { TEST_ASSERT( psa_export_key( slot, NULL, 0, &exported_length ) == PSA_ERROR_NOT_PERMITTED ); return( 1 ); } exported_size = PSA_KEY_EXPORT_MAX_SIZE( type, bits ); ASSERT_ALLOC( exported, exported_size ); TEST_ASSERT( psa_export_key( slot, exported, exported_size, &exported_length ) == PSA_SUCCESS ); ok = exported_key_sanity_check( type, bits, exported, exported_length ); exit: mbedtls_free( exported ); return( ok ); } static int exercise_export_public_key( psa_key_slot_t slot ) { psa_key_type_t type; psa_key_type_t public_type; size_t bits; uint8_t *exported = NULL; size_t exported_size = 0; size_t exported_length = 0; int ok = 0; TEST_ASSERT( psa_get_key_information( slot, &type, &bits ) == PSA_SUCCESS ); if( ! PSA_KEY_TYPE_IS_ASYMMETRIC( type ) ) { TEST_ASSERT( psa_export_public_key( slot, NULL, 0, &exported_length ) == PSA_ERROR_INVALID_ARGUMENT ); return( 1 ); } public_type = PSA_KEY_TYPE_PUBLIC_KEY_OF_KEYPAIR( type ); exported_size = PSA_KEY_EXPORT_MAX_SIZE( public_type, bits ); ASSERT_ALLOC( exported, exported_size ); TEST_ASSERT( psa_export_public_key( slot, exported, exported_size, &exported_length ) == PSA_SUCCESS ); ok = exported_key_sanity_check( public_type, bits, exported, exported_length ); exit: mbedtls_free( exported ); return( ok ); } static int exercise_key( psa_key_slot_t slot, psa_key_usage_t usage, psa_algorithm_t alg ) { int ok; if( alg == 0 ) ok = 1; /* If no algorihm, do nothing (used for raw data "keys"). */ else if( PSA_ALG_IS_MAC( alg ) ) ok = exercise_mac_key( slot, usage, alg ); else if( PSA_ALG_IS_CIPHER( alg ) ) ok = exercise_cipher_key( slot, usage, alg ); else if( PSA_ALG_IS_AEAD( alg ) ) ok = exercise_aead_key( slot, usage, alg ); else if( PSA_ALG_IS_SIGN( alg ) ) ok = exercise_signature_key( slot, usage, alg ); else if( PSA_ALG_IS_ASYMMETRIC_ENCRYPTION( alg ) ) ok = exercise_asymmetric_encryption_key( slot, usage, alg ); else if( PSA_ALG_IS_KEY_DERIVATION( alg ) ) ok = exercise_key_derivation_key( slot, usage, alg ); else { char message[40]; mbedtls_snprintf( message, sizeof( message ), "No code to exercise alg=0x%08lx", (unsigned long) alg ); test_fail( message, __LINE__, __FILE__ ); ok = 0; } ok = ok && exercise_export_key( slot, usage ); ok = ok && exercise_export_public_key( slot ); return( ok ); } /* END_HEADER */ /* BEGIN_DEPENDENCIES * depends_on:MBEDTLS_PSA_CRYPTO_C * END_DEPENDENCIES */ /* BEGIN_CASE */ void static_checks( ) { size_t max_truncated_mac_size = PSA_ALG_MAC_TRUNCATION_MASK >> PSA_MAC_TRUNCATION_OFFSET; /* Check that the length for a truncated MAC always fits in the algorithm * encoding. The shifted mask is the maximum truncated value. The * untruncated algorithm may be one byte larger. */ TEST_ASSERT( PSA_MAC_MAX_SIZE <= 1 + max_truncated_mac_size ); } /* END_CASE */ /* BEGIN_CASE */ void init_deinit( ) { psa_status_t status; int i; for( i = 0; i <= 1; i++ ) { status = psa_crypto_init( ); TEST_ASSERT( status == PSA_SUCCESS ); status = psa_crypto_init( ); TEST_ASSERT( status == PSA_SUCCESS ); mbedtls_psa_crypto_free( ); } } /* END_CASE */ /* BEGIN_CASE */ void fill_slots( int max_arg ) { /* Fill all the slots until we run out of memory or out of slots, * or until some limit specified in the test data for the sake of * implementations with an essentially unlimited number of slots. * This test assumes that available slots are numbered from 1. */ psa_key_slot_t slot; psa_key_slot_t max = 0; psa_key_policy_t policy; uint8_t exported[sizeof( max )]; size_t exported_size; psa_status_t status; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_EXPORT, 0 ); for( max = 1; max <= (size_t) max_arg; max++ ) { status = psa_set_key_policy( max, &policy ); /* Stop filling slots if we run out of memory or out of * available slots. */ TEST_ASSERT( status == PSA_SUCCESS || status == PSA_ERROR_INSUFFICIENT_MEMORY || status == PSA_ERROR_INVALID_ARGUMENT ); if( status != PSA_SUCCESS ) break; status = psa_import_key( max, PSA_KEY_TYPE_RAW_DATA, (uint8_t*) &max, sizeof( max ) ); /* Since psa_set_key_policy succeeded, we know that the slot * number is valid. But we may legitimately run out of memory. */ TEST_ASSERT( status == PSA_SUCCESS || status == PSA_ERROR_INSUFFICIENT_MEMORY ); if( status != PSA_SUCCESS ) break; } /* `max` is now the first slot number that wasn't filled. */ max -= 1; for( slot = 1; slot <= max; slot++ ) { TEST_ASSERT( psa_export_key( slot, exported, sizeof( exported ), &exported_size ) == PSA_SUCCESS ); ASSERT_COMPARE( &slot, sizeof( slot ), exported, exported_size ); } exit: /* Do not destroy the keys. mbedtls_psa_crypto_free() should do it. */ mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void import( data_t *data, int type, int expected_status_arg ) { int slot = 1; psa_status_t expected_status = expected_status_arg; psa_status_t status; TEST_ASSERT( data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( data->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); status = psa_import_key( slot, type, data->x, data->len ); TEST_ASSERT( status == expected_status ); if( status == PSA_SUCCESS ) TEST_ASSERT( psa_destroy_key( slot ) == PSA_SUCCESS ); exit: mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void import_rsa_made_up( int bits_arg, int keypair, int expected_status_arg ) { int slot = 1; size_t bits = bits_arg; psa_status_t expected_status = expected_status_arg; psa_status_t status; psa_key_type_t type = keypair ? PSA_KEY_TYPE_RSA_KEYPAIR : PSA_KEY_TYPE_RSA_PUBLIC_KEY; size_t buffer_size = /* Slight overapproximations */ keypair ? bits * 9 / 16 + 80 : bits / 8 + 20; unsigned char *buffer = NULL; unsigned char *p; int ret; size_t length; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); ASSERT_ALLOC( buffer, buffer_size ); TEST_ASSERT( ( ret = construct_fake_rsa_key( buffer, buffer_size, &p, bits, keypair ) ) >= 0 ); length = ret; /* Try importing the key */ status = psa_import_key( slot, type, p, length ); TEST_ASSERT( status == expected_status ); if( status == PSA_SUCCESS ) TEST_ASSERT( psa_destroy_key( slot ) == PSA_SUCCESS ); exit: mbedtls_free( buffer ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void import_export( data_t *data, int type_arg, int alg_arg, int usage_arg, int expected_bits, int export_size_delta, int expected_export_status_arg, int canonical_input ) { int slot = 1; int slot2 = slot + 1; psa_key_type_t type = type_arg; psa_algorithm_t alg = alg_arg; psa_status_t expected_export_status = expected_export_status_arg; psa_status_t status; unsigned char *exported = NULL; unsigned char *reexported = NULL; size_t export_size; size_t exported_length = INVALID_EXPORT_LENGTH; size_t reexported_length; psa_key_type_t got_type; size_t got_bits; psa_key_policy_t policy; TEST_ASSERT( data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( data->len ) ); export_size = (ptrdiff_t) data->len + export_size_delta; ASSERT_ALLOC( exported, export_size ); if( ! canonical_input ) ASSERT_ALLOC( reexported, export_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, usage_arg, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); /* Import the key */ TEST_ASSERT( psa_import_key( slot, type, data->x, data->len ) == PSA_SUCCESS ); /* Test the key information */ TEST_ASSERT( psa_get_key_information( slot, &got_type, &got_bits ) == PSA_SUCCESS ); TEST_ASSERT( got_type == type ); TEST_ASSERT( got_bits == (size_t) expected_bits ); /* Export the key */ status = psa_export_key( slot, exported, export_size, &exported_length ); TEST_ASSERT( status == expected_export_status ); /* The exported length must be set by psa_export_key() to a value between 0 * and export_size. On errors, the exported length must be 0. */ TEST_ASSERT( exported_length != INVALID_EXPORT_LENGTH ); TEST_ASSERT( status == PSA_SUCCESS || exported_length == 0 ); TEST_ASSERT( exported_length <= export_size ); TEST_ASSERT( mem_is_char( exported + exported_length, 0, export_size - exported_length ) ); if( status != PSA_SUCCESS ) { TEST_ASSERT( exported_length == 0 ); goto destroy; } if( ! exercise_export_key( slot, usage_arg ) ) goto exit; if( canonical_input ) ASSERT_COMPARE( data->x, data->len, exported, exported_length ); else { TEST_ASSERT( psa_set_key_policy( slot2, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot2, type, exported, exported_length ) == PSA_SUCCESS ); TEST_ASSERT( psa_export_key( slot2, reexported, export_size, &reexported_length ) == PSA_SUCCESS ); ASSERT_COMPARE( exported, exported_length, reexported, reexported_length ); } destroy: /* Destroy the key */ TEST_ASSERT( psa_destroy_key( slot ) == PSA_SUCCESS ); TEST_ASSERT( psa_get_key_information( slot, NULL, NULL ) == PSA_ERROR_EMPTY_SLOT ); exit: mbedtls_free( exported ); mbedtls_free( reexported ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void import_export_public_key( data_t *data, int type_arg, int alg_arg, int expected_bits, int public_key_expected_length, int expected_export_status_arg ) { int slot = 1; psa_key_type_t type = type_arg; psa_algorithm_t alg = alg_arg; psa_status_t expected_export_status = expected_export_status_arg; psa_status_t status; unsigned char *exported = NULL; size_t export_size; size_t exported_length = INVALID_EXPORT_LENGTH; psa_key_type_t got_type; size_t got_bits; psa_key_policy_t policy; TEST_ASSERT( data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( data->len ) ); export_size = (ptrdiff_t) data->len; ASSERT_ALLOC( exported, export_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_EXPORT, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); /* Import the key */ TEST_ASSERT( psa_import_key( slot, type, data->x, data->len ) == PSA_SUCCESS ); /* Test the key information */ TEST_ASSERT( psa_get_key_information( slot, &got_type, &got_bits ) == PSA_SUCCESS ); TEST_ASSERT( got_type == type ); TEST_ASSERT( got_bits == (size_t) expected_bits ); /* Export the key */ status = psa_export_public_key( slot, exported, export_size, &exported_length ); TEST_ASSERT( status == expected_export_status ); TEST_ASSERT( exported_length == (size_t) public_key_expected_length ); TEST_ASSERT( mem_is_char( exported + exported_length, 0, export_size - exported_length ) ); if( status != PSA_SUCCESS ) goto destroy; destroy: /* Destroy the key */ TEST_ASSERT( psa_destroy_key( slot ) == PSA_SUCCESS ); TEST_ASSERT( psa_get_key_information( slot, NULL, NULL ) == PSA_ERROR_EMPTY_SLOT ); exit: mbedtls_free( exported ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void import_and_exercise_key( data_t *data, int type_arg, int bits_arg, int alg_arg ) { int slot = 1; psa_key_type_t type = type_arg; size_t bits = bits_arg; psa_algorithm_t alg = alg_arg; psa_key_usage_t usage = ( PSA_ALG_IS_MAC( alg ) || PSA_ALG_IS_SIGN( alg ) ? ( PSA_KEY_TYPE_IS_PUBLIC_KEY( type ) ? PSA_KEY_USAGE_VERIFY : PSA_KEY_USAGE_SIGN | PSA_KEY_USAGE_VERIFY ) : PSA_ALG_IS_CIPHER( alg ) || PSA_ALG_IS_AEAD( alg ) || PSA_ALG_IS_ASYMMETRIC_ENCRYPTION( alg ) ? ( PSA_KEY_TYPE_IS_PUBLIC_KEY( type ) ? PSA_KEY_USAGE_ENCRYPT : PSA_KEY_USAGE_ENCRYPT | PSA_KEY_USAGE_DECRYPT ) : PSA_ALG_IS_KEY_DERIVATION( alg ) ? PSA_KEY_USAGE_DERIVE : 0 ); psa_key_policy_t policy; psa_key_type_t got_type; size_t got_bits; psa_status_t status; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, usage, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); /* Import the key */ status = psa_import_key( slot, type, data->x, data->len ); TEST_ASSERT( status == PSA_SUCCESS ); /* Test the key information */ TEST_ASSERT( psa_get_key_information( slot, &got_type, &got_bits ) == PSA_SUCCESS ); TEST_ASSERT( got_type == type ); TEST_ASSERT( got_bits == bits ); /* Do something with the key according to its type and permitted usage. */ if( ! exercise_key( slot, usage, alg ) ) goto exit; exit: psa_destroy_key( slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void key_policy( int usage_arg, int alg_arg ) { int key_slot = 1; psa_algorithm_t alg = alg_arg; psa_key_usage_t usage = usage_arg; psa_key_type_t key_type = PSA_KEY_TYPE_AES; unsigned char key[32] = {0}; psa_key_policy_t policy_set; psa_key_policy_t policy_get; memset( key, 0x2a, sizeof( key ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy_set ); psa_key_policy_init( &policy_get ); psa_key_policy_set_usage( &policy_set, usage, alg ); TEST_ASSERT( psa_key_policy_get_usage( &policy_set ) == usage ); TEST_ASSERT( psa_key_policy_get_algorithm( &policy_set ) == alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy_set ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key, sizeof( key ) ) == PSA_SUCCESS ); TEST_ASSERT( psa_get_key_policy( key_slot, &policy_get ) == PSA_SUCCESS ); TEST_ASSERT( policy_get.usage == policy_set.usage ); TEST_ASSERT( policy_get.alg == policy_set.alg ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void mac_key_policy( int policy_usage, int policy_alg, int key_type, data_t *key_data, int exercise_alg ) { int key_slot = 1; psa_key_policy_t policy; psa_mac_operation_t operation; psa_status_t status; unsigned char mac[PSA_MAC_MAX_SIZE]; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, policy_usage, policy_alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); status = psa_mac_sign_setup( &operation, key_slot, exercise_alg ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_SIGN ) != 0 ) TEST_ASSERT( status == PSA_SUCCESS ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); psa_mac_abort( &operation ); memset( mac, 0, sizeof( mac ) ); status = psa_mac_verify_setup( &operation, key_slot, exercise_alg ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_VERIFY ) != 0 ) TEST_ASSERT( status == PSA_SUCCESS ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); exit: psa_mac_abort( &operation ); psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void cipher_key_policy( int policy_usage, int policy_alg, int key_type, data_t *key_data, int exercise_alg ) { int key_slot = 1; psa_key_policy_t policy; psa_cipher_operation_t operation; psa_status_t status; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, policy_usage, policy_alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); status = psa_cipher_encrypt_setup( &operation, key_slot, exercise_alg ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_ENCRYPT ) != 0 ) TEST_ASSERT( status == PSA_SUCCESS ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); psa_cipher_abort( &operation ); status = psa_cipher_decrypt_setup( &operation, key_slot, exercise_alg ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_DECRYPT ) != 0 ) TEST_ASSERT( status == PSA_SUCCESS ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); exit: psa_cipher_abort( &operation ); psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void aead_key_policy( int policy_usage, int policy_alg, int key_type, data_t *key_data, int nonce_length_arg, int tag_length_arg, int exercise_alg ) { int key_slot = 1; psa_key_policy_t policy; psa_status_t status; unsigned char nonce[16] = {0}; size_t nonce_length = nonce_length_arg; unsigned char tag[16]; size_t tag_length = tag_length_arg; size_t output_length; TEST_ASSERT( nonce_length <= sizeof( nonce ) ); TEST_ASSERT( tag_length <= sizeof( tag ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, policy_usage, policy_alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); status = psa_aead_encrypt( key_slot, exercise_alg, nonce, nonce_length, NULL, 0, NULL, 0, tag, tag_length, &output_length ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_ENCRYPT ) != 0 ) TEST_ASSERT( status == PSA_SUCCESS ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); memset( tag, 0, sizeof( tag ) ); status = psa_aead_decrypt( key_slot, exercise_alg, nonce, nonce_length, NULL, 0, tag, tag_length, NULL, 0, &output_length ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_DECRYPT ) != 0 ) TEST_ASSERT( status == PSA_ERROR_INVALID_SIGNATURE ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void asymmetric_encryption_key_policy( int policy_usage, int policy_alg, int key_type, data_t *key_data, int exercise_alg ) { int key_slot = 1; psa_key_policy_t policy; psa_status_t status; size_t key_bits; size_t buffer_length; unsigned char *buffer = NULL; size_t output_length; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, policy_usage, policy_alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_get_key_information( key_slot, NULL, &key_bits ) == PSA_SUCCESS ); buffer_length = PSA_ASYMMETRIC_ENCRYPT_OUTPUT_SIZE( key_type, key_bits, exercise_alg ); ASSERT_ALLOC( buffer, buffer_length ); status = psa_asymmetric_encrypt( key_slot, exercise_alg, NULL, 0, NULL, 0, buffer, buffer_length, &output_length ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_ENCRYPT ) != 0 ) TEST_ASSERT( status == PSA_SUCCESS ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); if( buffer_length != 0 ) memset( buffer, 0, buffer_length ); status = psa_asymmetric_decrypt( key_slot, exercise_alg, buffer, buffer_length, NULL, 0, buffer, buffer_length, &output_length ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_DECRYPT ) != 0 ) TEST_ASSERT( status == PSA_ERROR_INVALID_PADDING ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); mbedtls_free( buffer ); } /* END_CASE */ /* BEGIN_CASE */ void asymmetric_signature_key_policy( int policy_usage, int policy_alg, int key_type, data_t *key_data, int exercise_alg ) { int key_slot = 1; psa_key_policy_t policy; psa_status_t status; unsigned char payload[16] = {1}; size_t payload_length = sizeof( payload ); unsigned char signature[PSA_ASYMMETRIC_SIGNATURE_MAX_SIZE] = {0}; size_t signature_length; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, policy_usage, policy_alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); status = psa_asymmetric_sign( key_slot, exercise_alg, payload, payload_length, signature, sizeof( signature ), &signature_length ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_SIGN ) != 0 ) TEST_ASSERT( status == PSA_SUCCESS ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); memset( signature, 0, sizeof( signature ) ); status = psa_asymmetric_verify( key_slot, exercise_alg, payload, payload_length, signature, sizeof( signature ) ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_VERIFY ) != 0 ) TEST_ASSERT( status == PSA_ERROR_INVALID_SIGNATURE ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void derive_key_policy( int policy_usage, int policy_alg, int key_type, data_t *key_data, int exercise_alg ) { int key_slot = 1; psa_key_policy_t policy; psa_crypto_generator_t generator = PSA_CRYPTO_GENERATOR_INIT; psa_status_t status; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, policy_usage, policy_alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); status = psa_key_derivation( &generator, key_slot, exercise_alg, NULL, 0, NULL, 0, 1 ); if( policy_alg == exercise_alg && ( policy_usage & PSA_KEY_USAGE_DERIVE ) != 0 ) TEST_ASSERT( status == PSA_SUCCESS ); else TEST_ASSERT( status == PSA_ERROR_NOT_PERMITTED ); exit: psa_generator_abort( &generator ); psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void key_lifetime( int lifetime_arg ) { int key_slot = 1; psa_key_type_t key_type = PSA_KEY_TYPE_RAW_DATA; unsigned char key[32] = {0}; psa_key_lifetime_t lifetime_set = lifetime_arg; psa_key_lifetime_t lifetime_get; memset( key, 0x2a, sizeof( key ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); TEST_ASSERT( psa_set_key_lifetime( key_slot, lifetime_set ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key, sizeof( key ) ) == PSA_SUCCESS ); TEST_ASSERT( psa_get_key_lifetime( key_slot, &lifetime_get ) == PSA_SUCCESS ); TEST_ASSERT( lifetime_get == lifetime_set ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void key_lifetime_set_fail( int key_slot_arg, int lifetime_arg, int expected_status_arg ) { psa_key_slot_t key_slot = key_slot_arg; psa_key_lifetime_t lifetime_set = lifetime_arg; psa_status_t actual_status; psa_status_t expected_status = expected_status_arg; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); actual_status = psa_set_key_lifetime( key_slot, lifetime_set ); if( actual_status == PSA_SUCCESS ) actual_status = psa_set_key_lifetime( key_slot, lifetime_set ); TEST_ASSERT( expected_status == actual_status ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void hash_setup( int alg_arg, int expected_status_arg ) { psa_algorithm_t alg = alg_arg; psa_status_t expected_status = expected_status_arg; psa_hash_operation_t operation; psa_status_t status; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); status = psa_hash_setup( &operation, alg ); psa_hash_abort( &operation ); TEST_ASSERT( status == expected_status ); exit: mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void hash_finish( int alg_arg, data_t *input, data_t *expected_hash ) { psa_algorithm_t alg = alg_arg; unsigned char actual_hash[PSA_HASH_MAX_SIZE]; size_t actual_hash_length; psa_hash_operation_t operation; TEST_ASSERT( expected_hash->len == PSA_HASH_SIZE( alg ) ); TEST_ASSERT( expected_hash->len <= PSA_HASH_MAX_SIZE ); TEST_ASSERT( input != NULL ); TEST_ASSERT( expected_hash != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_hash->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); TEST_ASSERT( psa_hash_setup( &operation, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_hash_update( &operation, input->x, input->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_hash_finish( &operation, actual_hash, sizeof( actual_hash ), &actual_hash_length ) == PSA_SUCCESS ); ASSERT_COMPARE( expected_hash->x, expected_hash->len, actual_hash, actual_hash_length ); exit: mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void hash_verify( int alg_arg, data_t *input, data_t *expected_hash ) { psa_algorithm_t alg = alg_arg; psa_hash_operation_t operation; TEST_ASSERT( expected_hash->len == PSA_HASH_SIZE( alg ) ); TEST_ASSERT( expected_hash->len <= PSA_HASH_MAX_SIZE ); TEST_ASSERT( input != NULL ); TEST_ASSERT( expected_hash != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_hash->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); TEST_ASSERT( psa_hash_setup( &operation, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_hash_update( &operation, input->x, input->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_hash_verify( &operation, expected_hash->x, expected_hash->len ) == PSA_SUCCESS ); exit: mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void mac_setup( int key_type_arg, data_t *key, int alg_arg, int expected_status_arg ) { int key_slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; psa_status_t expected_status = expected_status_arg; psa_mac_operation_t operation; psa_key_policy_t policy; psa_status_t status; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_SIGN | PSA_KEY_USAGE_VERIFY, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); status = psa_mac_sign_setup( &operation, key_slot, alg ); psa_mac_abort( &operation ); TEST_ASSERT( status == expected_status ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void mac_sign( int key_type_arg, data_t *key, int alg_arg, data_t *input, data_t *expected_mac ) { int key_slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; psa_mac_operation_t operation; psa_key_policy_t policy; /* Leave a little extra room in the output buffer. At the end of the * test, we'll check that the implementation didn't overwrite onto * this extra room. */ uint8_t actual_mac[PSA_MAC_MAX_SIZE + 10]; size_t mac_buffer_size = PSA_MAC_FINAL_SIZE( key_type, PSA_BYTES_TO_BITS( key->len ), alg ); size_t mac_length = 0; memset( actual_mac, '+', sizeof( actual_mac ) ); TEST_ASSERT( mac_buffer_size <= PSA_MAC_MAX_SIZE ); TEST_ASSERT( expected_mac->len <= mac_buffer_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_SIGN, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); /* Calculate the MAC. */ TEST_ASSERT( psa_mac_sign_setup( &operation, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_mac_update( &operation, input->x, input->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_mac_sign_finish( &operation, actual_mac, mac_buffer_size, &mac_length ) == PSA_SUCCESS ); /* Compare with the expected value. */ TEST_ASSERT( mac_length == expected_mac->len ); TEST_ASSERT( memcmp( actual_mac, expected_mac->x, mac_length ) == 0 ); /* Verify that the end of the buffer is untouched. */ TEST_ASSERT( mem_is_char( actual_mac + mac_length, '+', sizeof( actual_mac ) - mac_length ) ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void mac_verify( int key_type_arg, data_t *key, int alg_arg, data_t *input, data_t *expected_mac ) { int key_slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; psa_mac_operation_t operation; psa_key_policy_t policy; TEST_ASSERT( expected_mac->len <= PSA_MAC_MAX_SIZE ); TEST_ASSERT( key != NULL ); TEST_ASSERT( input != NULL ); TEST_ASSERT( expected_mac != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_mac->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_VERIFY, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_mac_verify_setup( &operation, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_destroy_key( key_slot ) == PSA_SUCCESS ); TEST_ASSERT( psa_mac_update( &operation, input->x, input->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_mac_verify_finish( &operation, expected_mac->x, expected_mac->len ) == PSA_SUCCESS ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void cipher_setup( int key_type_arg, data_t *key, int alg_arg, int expected_status_arg ) { int key_slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; psa_status_t expected_status = expected_status_arg; psa_cipher_operation_t operation; psa_key_policy_t policy; psa_status_t status; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_ENCRYPT, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); status = psa_cipher_encrypt_setup( &operation, key_slot, alg ); psa_cipher_abort( &operation ); TEST_ASSERT( status == expected_status ); exit: psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void cipher_encrypt( int alg_arg, int key_type_arg, data_t *key, data_t *input, data_t *expected_output, int expected_status_arg ) { int key_slot = 1; psa_status_t status; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; psa_status_t expected_status = expected_status_arg; unsigned char iv[16] = {0}; size_t iv_size; unsigned char *output = NULL; size_t output_buffer_size = 0; size_t function_output_length = 0; size_t total_output_length = 0; psa_cipher_operation_t operation; psa_key_policy_t policy; TEST_ASSERT( key != NULL ); TEST_ASSERT( input != NULL ); TEST_ASSERT( expected_output != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_output->len ) ); iv_size = PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); memset( iv, 0x2a, iv_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_ENCRYPT, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_encrypt_setup( &operation, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_set_iv( &operation, iv, iv_size ) == PSA_SUCCESS ); output_buffer_size = (size_t) input->len + PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); ASSERT_ALLOC( output, output_buffer_size ); TEST_ASSERT( psa_cipher_update( &operation, input->x, input->len, output, output_buffer_size, &function_output_length ) == PSA_SUCCESS ); total_output_length += function_output_length; status = psa_cipher_finish( &operation, output + function_output_length, output_buffer_size, &function_output_length ); total_output_length += function_output_length; TEST_ASSERT( status == expected_status ); if( expected_status == PSA_SUCCESS ) { TEST_ASSERT( psa_cipher_abort( &operation ) == PSA_SUCCESS ); ASSERT_COMPARE( expected_output->x, expected_output->len, output, total_output_length ); } exit: mbedtls_free( output ); psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void cipher_encrypt_multipart( int alg_arg, int key_type_arg, data_t *key, data_t *input, int first_part_size, data_t *expected_output ) { int key_slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; unsigned char iv[16] = {0}; size_t iv_size; unsigned char *output = NULL; size_t output_buffer_size = 0; size_t function_output_length = 0; size_t total_output_length = 0; psa_cipher_operation_t operation; psa_key_policy_t policy; TEST_ASSERT( key != NULL ); TEST_ASSERT( input != NULL ); TEST_ASSERT( expected_output != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_output->len ) ); iv_size = PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); memset( iv, 0x2a, iv_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_ENCRYPT, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_encrypt_setup( &operation, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_set_iv( &operation, iv, sizeof( iv ) ) == PSA_SUCCESS ); output_buffer_size = (size_t) input->len + PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); ASSERT_ALLOC( output, output_buffer_size ); TEST_ASSERT( (unsigned int) first_part_size < input->len ); TEST_ASSERT( psa_cipher_update( &operation, input->x, first_part_size, output, output_buffer_size, &function_output_length ) == PSA_SUCCESS ); total_output_length += function_output_length; TEST_ASSERT( psa_cipher_update( &operation, input->x + first_part_size, input->len - first_part_size, output, output_buffer_size, &function_output_length ) == PSA_SUCCESS ); total_output_length += function_output_length; TEST_ASSERT( psa_cipher_finish( &operation, output + function_output_length, output_buffer_size, &function_output_length ) == PSA_SUCCESS ); total_output_length += function_output_length; TEST_ASSERT( psa_cipher_abort( &operation ) == PSA_SUCCESS ); ASSERT_COMPARE( expected_output->x, expected_output->len, output, total_output_length ); exit: mbedtls_free( output ); psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void cipher_decrypt_multipart( int alg_arg, int key_type_arg, data_t *key, data_t *input, int first_part_size, data_t *expected_output ) { int key_slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; unsigned char iv[16] = {0}; size_t iv_size; unsigned char *output = NULL; size_t output_buffer_size = 0; size_t function_output_length = 0; size_t total_output_length = 0; psa_cipher_operation_t operation; psa_key_policy_t policy; TEST_ASSERT( key != NULL ); TEST_ASSERT( input != NULL ); TEST_ASSERT( expected_output != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_output->len ) ); iv_size = PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); memset( iv, 0x2a, iv_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DECRYPT, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_decrypt_setup( &operation, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_set_iv( &operation, iv, sizeof( iv ) ) == PSA_SUCCESS ); output_buffer_size = (size_t) input->len + PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); ASSERT_ALLOC( output, output_buffer_size ); TEST_ASSERT( (unsigned int) first_part_size < input->len ); TEST_ASSERT( psa_cipher_update( &operation, input->x, first_part_size, output, output_buffer_size, &function_output_length ) == PSA_SUCCESS ); total_output_length += function_output_length; TEST_ASSERT( psa_cipher_update( &operation, input->x + first_part_size, input->len - first_part_size, output, output_buffer_size, &function_output_length ) == PSA_SUCCESS ); total_output_length += function_output_length; TEST_ASSERT( psa_cipher_finish( &operation, output + function_output_length, output_buffer_size, &function_output_length ) == PSA_SUCCESS ); total_output_length += function_output_length; TEST_ASSERT( psa_cipher_abort( &operation ) == PSA_SUCCESS ); ASSERT_COMPARE( expected_output->x, expected_output->len, output, total_output_length ); exit: mbedtls_free( output ); psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void cipher_decrypt( int alg_arg, int key_type_arg, data_t *key, data_t *input, data_t *expected_output, int expected_status_arg ) { int key_slot = 1; psa_status_t status; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; psa_status_t expected_status = expected_status_arg; unsigned char iv[16] = {0}; size_t iv_size; unsigned char *output = NULL; size_t output_buffer_size = 0; size_t function_output_length = 0; size_t total_output_length = 0; psa_cipher_operation_t operation; psa_key_policy_t policy; TEST_ASSERT( key != NULL ); TEST_ASSERT( input != NULL ); TEST_ASSERT( expected_output != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_output->len ) ); iv_size = PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); memset( iv, 0x2a, iv_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DECRYPT, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_decrypt_setup( &operation, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_set_iv( &operation, iv, iv_size ) == PSA_SUCCESS ); output_buffer_size = (size_t) input->len + PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); ASSERT_ALLOC( output, output_buffer_size ); TEST_ASSERT( psa_cipher_update( &operation, input->x, input->len, output, output_buffer_size, &function_output_length ) == PSA_SUCCESS ); total_output_length += function_output_length; status = psa_cipher_finish( &operation, output + function_output_length, output_buffer_size, &function_output_length ); total_output_length += function_output_length; TEST_ASSERT( status == expected_status ); if( expected_status == PSA_SUCCESS ) { TEST_ASSERT( psa_cipher_abort( &operation ) == PSA_SUCCESS ); ASSERT_COMPARE( expected_output->x, expected_output->len, output, total_output_length ); } exit: mbedtls_free( output ); psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void cipher_verify_output( int alg_arg, int key_type_arg, data_t *key, data_t *input ) { int key_slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; unsigned char iv[16] = {0}; size_t iv_size = 16; size_t iv_length = 0; unsigned char *output1 = NULL; size_t output1_size = 0; size_t output1_length = 0; unsigned char *output2 = NULL; size_t output2_size = 0; size_t output2_length = 0; size_t function_output_length = 0; psa_cipher_operation_t operation1; psa_cipher_operation_t operation2; psa_key_policy_t policy; TEST_ASSERT( key != NULL ); TEST_ASSERT( input != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_ENCRYPT | PSA_KEY_USAGE_DECRYPT, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_encrypt_setup( &operation1, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_decrypt_setup( &operation2, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_generate_iv( &operation1, iv, iv_size, &iv_length ) == PSA_SUCCESS ); output1_size = (size_t) input->len + PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); ASSERT_ALLOC( output1, output1_size ); TEST_ASSERT( psa_cipher_update( &operation1, input->x, input->len, output1, output1_size, &output1_length ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_finish( &operation1, output1 + output1_length, output1_size, &function_output_length ) == PSA_SUCCESS ); output1_length += function_output_length; TEST_ASSERT( psa_cipher_abort( &operation1 ) == PSA_SUCCESS ); output2_size = output1_length; ASSERT_ALLOC( output2, output2_size ); TEST_ASSERT( psa_cipher_set_iv( &operation2, iv, iv_length ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_update( &operation2, output1, output1_length, output2, output2_size, &output2_length ) == PSA_SUCCESS ); function_output_length = 0; TEST_ASSERT( psa_cipher_finish( &operation2, output2 + output2_length, output2_size, &function_output_length ) == PSA_SUCCESS ); output2_length += function_output_length; TEST_ASSERT( psa_cipher_abort( &operation2 ) == PSA_SUCCESS ); ASSERT_COMPARE( input->x, input->len, output2, output2_length ); exit: mbedtls_free( output1 ); mbedtls_free( output2 ); psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void cipher_verify_output_multipart( int alg_arg, int key_type_arg, data_t *key, data_t *input, int first_part_size ) { int key_slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; unsigned char iv[16] = {0}; size_t iv_size = 16; size_t iv_length = 0; unsigned char *output1 = NULL; size_t output1_buffer_size = 0; size_t output1_length = 0; unsigned char *output2 = NULL; size_t output2_buffer_size = 0; size_t output2_length = 0; size_t function_output_length; psa_cipher_operation_t operation1; psa_cipher_operation_t operation2; psa_key_policy_t policy; TEST_ASSERT( key != NULL ); TEST_ASSERT( input != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_ENCRYPT | PSA_KEY_USAGE_DECRYPT, alg ); TEST_ASSERT( psa_set_key_policy( key_slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( key_slot, key_type, key->x, key->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_encrypt_setup( &operation1, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_decrypt_setup( &operation2, key_slot, alg ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_generate_iv( &operation1, iv, iv_size, &iv_length ) == PSA_SUCCESS ); output1_buffer_size = (size_t) input->len + PSA_BLOCK_CIPHER_BLOCK_SIZE( key_type ); ASSERT_ALLOC( output1, output1_buffer_size ); TEST_ASSERT( (unsigned int) first_part_size < input->len ); TEST_ASSERT( psa_cipher_update( &operation1, input->x, first_part_size, output1, output1_buffer_size, &function_output_length ) == PSA_SUCCESS ); output1_length += function_output_length; TEST_ASSERT( psa_cipher_update( &operation1, input->x + first_part_size, input->len - first_part_size, output1, output1_buffer_size, &function_output_length ) == PSA_SUCCESS ); output1_length += function_output_length; TEST_ASSERT( psa_cipher_finish( &operation1, output1 + output1_length, output1_buffer_size - output1_length, &function_output_length ) == PSA_SUCCESS ); output1_length += function_output_length; TEST_ASSERT( psa_cipher_abort( &operation1 ) == PSA_SUCCESS ); output2_buffer_size = output1_length; ASSERT_ALLOC( output2, output2_buffer_size ); TEST_ASSERT( psa_cipher_set_iv( &operation2, iv, iv_length ) == PSA_SUCCESS ); TEST_ASSERT( psa_cipher_update( &operation2, output1, first_part_size, output2, output2_buffer_size, &function_output_length ) == PSA_SUCCESS ); output2_length += function_output_length; TEST_ASSERT( psa_cipher_update( &operation2, output1 + first_part_size, output1_length - first_part_size, output2, output2_buffer_size, &function_output_length ) == PSA_SUCCESS ); output2_length += function_output_length; TEST_ASSERT( psa_cipher_finish( &operation2, output2 + output2_length, output2_buffer_size - output2_length, &function_output_length ) == PSA_SUCCESS ); output2_length += function_output_length; TEST_ASSERT( psa_cipher_abort( &operation2 ) == PSA_SUCCESS ); ASSERT_COMPARE( input->x, input->len, output2, output2_length ); exit: mbedtls_free( output1 ); mbedtls_free( output2 ); psa_destroy_key( key_slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void aead_encrypt_decrypt( int key_type_arg, data_t *key_data, int alg_arg, data_t *nonce, data_t *additional_data, data_t *input_data, int expected_result_arg ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; unsigned char *output_data = NULL; size_t output_size = 0; size_t output_length = 0; unsigned char *output_data2 = NULL; size_t output_length2 = 0; size_t tag_length = 16; psa_status_t expected_result = expected_result_arg; psa_key_policy_t policy; TEST_ASSERT( key_data != NULL ); TEST_ASSERT( input_data != NULL ); TEST_ASSERT( nonce != NULL ); TEST_ASSERT( additional_data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( nonce->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( additional_data->len ) ); output_size = input_data->len + tag_length; ASSERT_ALLOC( output_data, output_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_ENCRYPT | PSA_KEY_USAGE_DECRYPT, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_aead_encrypt( slot, alg, nonce->x, nonce->len, additional_data->x, additional_data->len, input_data->x, input_data->len, output_data, output_size, &output_length ) == expected_result ); if( PSA_SUCCESS == expected_result ) { ASSERT_ALLOC( output_data2, output_length ); TEST_ASSERT( psa_aead_decrypt( slot, alg, nonce->x, nonce->len, additional_data->x, additional_data->len, output_data, output_length, output_data2, output_length, &output_length2 ) == expected_result ); ASSERT_COMPARE( input_data->x, input_data->len, output_data2, output_length2 ); } exit: psa_destroy_key( slot ); mbedtls_free( output_data ); mbedtls_free( output_data2 ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void aead_encrypt( int key_type_arg, data_t *key_data, int alg_arg, data_t *nonce, data_t *additional_data, data_t *input_data, data_t *expected_result ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; unsigned char *output_data = NULL; size_t output_size = 0; size_t output_length = 0; size_t tag_length = 16; psa_key_policy_t policy; TEST_ASSERT( key_data != NULL ); TEST_ASSERT( input_data != NULL ); TEST_ASSERT( additional_data != NULL ); TEST_ASSERT( nonce != NULL ); TEST_ASSERT( expected_result != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( additional_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( nonce->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_result->len ) ); output_size = input_data->len + tag_length; ASSERT_ALLOC( output_data, output_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_ENCRYPT , alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_aead_encrypt( slot, alg, nonce->x, nonce->len, additional_data->x, additional_data->len, input_data->x, input_data->len, output_data, output_size, &output_length ) == PSA_SUCCESS ); ASSERT_COMPARE( expected_result->x, expected_result->len, output_data, output_length ); exit: psa_destroy_key( slot ); mbedtls_free( output_data ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void aead_decrypt( int key_type_arg, data_t *key_data, int alg_arg, data_t *nonce, data_t *additional_data, data_t *input_data, data_t *expected_data, int expected_result_arg ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; unsigned char *output_data = NULL; size_t output_size = 0; size_t output_length = 0; size_t tag_length = 16; psa_key_policy_t policy; psa_status_t expected_result = expected_result_arg; TEST_ASSERT( key_data != NULL ); TEST_ASSERT( input_data != NULL ); TEST_ASSERT( additional_data != NULL ); TEST_ASSERT( nonce != NULL ); TEST_ASSERT( expected_data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( additional_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( nonce->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_data->len ) ); output_size = input_data->len + tag_length; ASSERT_ALLOC( output_data, output_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DECRYPT , alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_aead_decrypt( slot, alg, nonce->x, nonce->len, additional_data->x, additional_data->len, input_data->x, input_data->len, output_data, output_size, &output_length ) == expected_result ); if( expected_result == PSA_SUCCESS ) ASSERT_COMPARE( expected_data->x, expected_data->len, output_data, output_length ); exit: psa_destroy_key( slot ); mbedtls_free( output_data ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void signature_size( int type_arg, int bits, int alg_arg, int expected_size_arg ) { psa_key_type_t type = type_arg; psa_algorithm_t alg = alg_arg; size_t actual_size = PSA_ASYMMETRIC_SIGN_OUTPUT_SIZE( type, bits, alg ); TEST_ASSERT( actual_size == (size_t) expected_size_arg ); exit: ; } /* END_CASE */ /* BEGIN_CASE */ void sign_deterministic( int key_type_arg, data_t *key_data, int alg_arg, data_t *input_data, data_t *output_data ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; size_t key_bits; unsigned char *signature = NULL; size_t signature_size; size_t signature_length = 0xdeadbeef; psa_key_policy_t policy; TEST_ASSERT( key_data != NULL ); TEST_ASSERT( input_data != NULL ); TEST_ASSERT( output_data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( output_data->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_SIGN, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_get_key_information( slot, NULL, &key_bits ) == PSA_SUCCESS ); /* Allocate a buffer which has the size advertized by the * library. */ signature_size = PSA_ASYMMETRIC_SIGN_OUTPUT_SIZE( key_type, key_bits, alg ); TEST_ASSERT( signature_size != 0 ); TEST_ASSERT( signature_size <= PSA_ASYMMETRIC_SIGNATURE_MAX_SIZE ); ASSERT_ALLOC( signature, signature_size ); /* Perform the signature. */ TEST_ASSERT( psa_asymmetric_sign( slot, alg, input_data->x, input_data->len, signature, signature_size, &signature_length ) == PSA_SUCCESS ); /* Verify that the signature is what is expected. */ ASSERT_COMPARE( output_data->x, output_data->len, signature, signature_length ); exit: psa_destroy_key( slot ); mbedtls_free( signature ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void sign_fail( int key_type_arg, data_t *key_data, int alg_arg, data_t *input_data, int signature_size_arg, int expected_status_arg ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; size_t signature_size = signature_size_arg; psa_status_t actual_status; psa_status_t expected_status = expected_status_arg; unsigned char *signature = NULL; size_t signature_length = 0xdeadbeef; psa_key_policy_t policy; TEST_ASSERT( key_data != NULL ); TEST_ASSERT( input_data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input_data->len ) ); ASSERT_ALLOC( signature, signature_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_SIGN, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); actual_status = psa_asymmetric_sign( slot, alg, input_data->x, input_data->len, signature, signature_size, &signature_length ); TEST_ASSERT( actual_status == expected_status ); /* The value of *signature_length is unspecified on error, but * whatever it is, it should be less than signature_size, so that * if the caller tries to read *signature_length bytes without * checking the error code then they don't overflow a buffer. */ TEST_ASSERT( signature_length <= signature_size ); exit: psa_destroy_key( slot ); mbedtls_free( signature ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void sign_verify( int key_type_arg, data_t *key_data, int alg_arg, data_t *input_data ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; size_t key_bits; unsigned char *signature = NULL; size_t signature_size; size_t signature_length = 0xdeadbeef; psa_key_policy_t policy; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_SIGN | PSA_KEY_USAGE_VERIFY, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_get_key_information( slot, NULL, &key_bits ) == PSA_SUCCESS ); /* Allocate a buffer which has the size advertized by the * library. */ signature_size = PSA_ASYMMETRIC_SIGN_OUTPUT_SIZE( key_type, key_bits, alg ); TEST_ASSERT( signature_size != 0 ); TEST_ASSERT( signature_size <= PSA_ASYMMETRIC_SIGNATURE_MAX_SIZE ); ASSERT_ALLOC( signature, signature_size ); /* Perform the signature. */ TEST_ASSERT( psa_asymmetric_sign( slot, alg, input_data->x, input_data->len, signature, signature_size, &signature_length ) == PSA_SUCCESS ); /* Check that the signature length looks sensible. */ TEST_ASSERT( signature_length <= signature_size ); TEST_ASSERT( signature_length > 0 ); /* Use the library to verify that the signature is correct. */ TEST_ASSERT( psa_asymmetric_verify( slot, alg, input_data->x, input_data->len, signature, signature_length ) == PSA_SUCCESS ); if( input_data->len != 0 ) { /* Flip a bit in the input and verify that the signature is now * detected as invalid. Flip a bit at the beginning, not at the end, * because ECDSA may ignore the last few bits of the input. */ input_data->x[0] ^= 1; TEST_ASSERT( psa_asymmetric_verify( slot, alg, input_data->x, input_data->len, signature, signature_length ) == PSA_ERROR_INVALID_SIGNATURE ); } exit: psa_destroy_key( slot ); mbedtls_free( signature ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void asymmetric_verify( int key_type_arg, data_t *key_data, int alg_arg, data_t *hash_data, data_t *signature_data ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; psa_key_policy_t policy; TEST_ASSERT( signature_data->len <= PSA_ASYMMETRIC_SIGNATURE_MAX_SIZE ); TEST_ASSERT( key_data != NULL ); TEST_ASSERT( hash_data != NULL ); TEST_ASSERT( signature_data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( hash_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( signature_data->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_VERIFY, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_asymmetric_verify( slot, alg, hash_data->x, hash_data->len, signature_data->x, signature_data->len ) == PSA_SUCCESS ); exit: psa_destroy_key( slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void asymmetric_verify_fail( int key_type_arg, data_t *key_data, int alg_arg, data_t *hash_data, data_t *signature_data, int expected_status_arg ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; psa_status_t actual_status; psa_status_t expected_status = expected_status_arg; psa_key_policy_t policy; TEST_ASSERT( key_data != NULL ); TEST_ASSERT( hash_data != NULL ); TEST_ASSERT( signature_data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( hash_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( signature_data->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_VERIFY, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); actual_status = psa_asymmetric_verify( slot, alg, hash_data->x, hash_data->len, signature_data->x, signature_data->len ); TEST_ASSERT( actual_status == expected_status ); exit: psa_destroy_key( slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void asymmetric_encrypt( int key_type_arg, data_t *key_data, int alg_arg, data_t *input_data, data_t *label, int expected_output_length_arg, int expected_status_arg ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; size_t expected_output_length = expected_output_length_arg; size_t key_bits; unsigned char *output = NULL; size_t output_size; size_t output_length = ~0; psa_status_t actual_status; psa_status_t expected_status = expected_status_arg; psa_key_policy_t policy; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); /* Import the key */ psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_ENCRYPT, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); /* Determine the maximum output length */ TEST_ASSERT( psa_get_key_information( slot, NULL, &key_bits ) == PSA_SUCCESS ); output_size = PSA_ASYMMETRIC_ENCRYPT_OUTPUT_SIZE( key_type, key_bits, alg ); ASSERT_ALLOC( output, output_size ); /* Encrypt the input */ actual_status = psa_asymmetric_encrypt( slot, alg, input_data->x, input_data->len, label->x, label->len, output, output_size, &output_length ); TEST_ASSERT( actual_status == expected_status ); TEST_ASSERT( output_length == expected_output_length ); /* If the label is empty, the test framework puts a non-null pointer * in label->x. Test that a null pointer works as well. */ if( label->len == 0 ) { output_length = ~0; if( output_size != 0 ) memset( output, 0, output_size ); actual_status = psa_asymmetric_encrypt( slot, alg, input_data->x, input_data->len, NULL, label->len, output, output_size, &output_length ); TEST_ASSERT( actual_status == expected_status ); TEST_ASSERT( output_length == expected_output_length ); } exit: psa_destroy_key( slot ); mbedtls_free( output ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void asymmetric_encrypt_decrypt( int key_type_arg, data_t *key_data, int alg_arg, data_t *input_data, data_t *label ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; size_t key_bits; unsigned char *output = NULL; size_t output_size; size_t output_length = ~0; unsigned char *output2 = NULL; size_t output2_size; size_t output2_length = ~0; psa_key_policy_t policy; TEST_ASSERT( key_data != NULL ); TEST_ASSERT( input_data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input_data->len ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_ENCRYPT | PSA_KEY_USAGE_DECRYPT, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); /* Determine the maximum ciphertext length */ TEST_ASSERT( psa_get_key_information( slot, NULL, &key_bits ) == PSA_SUCCESS ); output_size = PSA_ASYMMETRIC_ENCRYPT_OUTPUT_SIZE( key_type, key_bits, alg ); ASSERT_ALLOC( output, output_size ); output2_size = input_data->len; ASSERT_ALLOC( output2, output2_size ); /* We test encryption by checking that encrypt-then-decrypt gives back * the original plaintext because of the non-optional random * part of encryption process which prevents using fixed vectors. */ TEST_ASSERT( psa_asymmetric_encrypt( slot, alg, input_data->x, input_data->len, label->x, label->len, output, output_size, &output_length ) == PSA_SUCCESS ); /* We don't know what ciphertext length to expect, but check that * it looks sensible. */ TEST_ASSERT( output_length <= output_size ); TEST_ASSERT( psa_asymmetric_decrypt( slot, alg, output, output_length, label->x, label->len, output2, output2_size, &output2_length ) == PSA_SUCCESS ); ASSERT_COMPARE( input_data->x, input_data->len, output2, output2_length ); exit: psa_destroy_key( slot ); mbedtls_free( output ); mbedtls_free( output2 ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void asymmetric_decrypt( int key_type_arg, data_t *key_data, int alg_arg, data_t *input_data, data_t *label, data_t *expected_data ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; unsigned char *output = NULL; size_t output_size = 0; size_t output_length = ~0; psa_key_policy_t policy; TEST_ASSERT( key_data != NULL ); TEST_ASSERT( input_data != NULL ); TEST_ASSERT( expected_data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( expected_data->len ) ); output_size = key_data->len; ASSERT_ALLOC( output, output_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DECRYPT, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_asymmetric_decrypt( slot, alg, input_data->x, input_data->len, label->x, label->len, output, output_size, &output_length ) == PSA_SUCCESS ); ASSERT_COMPARE( expected_data->x, expected_data->len, output, output_length ); /* If the label is empty, the test framework puts a non-null pointer * in label->x. Test that a null pointer works as well. */ if( label->len == 0 ) { output_length = ~0; if( output_size != 0 ) memset( output, 0, output_size ); TEST_ASSERT( psa_asymmetric_decrypt( slot, alg, input_data->x, input_data->len, NULL, label->len, output, output_size, &output_length ) == PSA_SUCCESS ); ASSERT_COMPARE( expected_data->x, expected_data->len, output, output_length ); } exit: psa_destroy_key( slot ); mbedtls_free( output ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void asymmetric_decrypt_fail( int key_type_arg, data_t *key_data, int alg_arg, data_t *input_data, data_t *label, int expected_status_arg ) { int slot = 1; psa_key_type_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; unsigned char *output = NULL; size_t output_size = 0; size_t output_length = ~0; psa_status_t actual_status; psa_status_t expected_status = expected_status_arg; psa_key_policy_t policy; TEST_ASSERT( key_data != NULL ); TEST_ASSERT( input_data != NULL ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( key_data->len ) ); TEST_ASSERT( PSA_CRYPTO_TEST_SIZE_T_RANGE( input_data->len ) ); output_size = key_data->len; ASSERT_ALLOC( output, output_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DECRYPT, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); actual_status = psa_asymmetric_decrypt( slot, alg, input_data->x, input_data->len, label->x, label->len, output, output_size, &output_length ); TEST_ASSERT( actual_status == expected_status ); TEST_ASSERT( output_length <= output_size ); /* If the label is empty, the test framework puts a non-null pointer * in label->x. Test that a null pointer works as well. */ if( label->len == 0 ) { output_length = ~0; if( output_size != 0 ) memset( output, 0, output_size ); actual_status = psa_asymmetric_decrypt( slot, alg, input_data->x, input_data->len, NULL, label->len, output, output_size, &output_length ); TEST_ASSERT( actual_status == expected_status ); TEST_ASSERT( output_length <= output_size ); } exit: psa_destroy_key( slot ); mbedtls_free( output ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void derive_setup( int key_type_arg, data_t *key_data, int alg_arg, data_t *salt, data_t *label, int requested_capacity_arg, int expected_status_arg ) { psa_key_slot_t slot = 1; size_t key_type = key_type_arg; psa_algorithm_t alg = alg_arg; size_t requested_capacity = requested_capacity_arg; psa_status_t expected_status = expected_status_arg; psa_crypto_generator_t generator = PSA_CRYPTO_GENERATOR_INIT; psa_key_policy_t policy; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DERIVE, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, key_type, key_data->x, key_data->len ) == PSA_SUCCESS ); TEST_ASSERT( psa_key_derivation( &generator, slot, alg, salt->x, salt->len, label->x, label->len, requested_capacity ) == expected_status ); exit: psa_generator_abort( &generator ); psa_destroy_key( slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void derive_output( int alg_arg, data_t *key_data, data_t *salt, data_t *label, int requested_capacity_arg, data_t *expected_output1, data_t *expected_output2 ) { psa_key_slot_t slot = 1; psa_algorithm_t alg = alg_arg; size_t requested_capacity = requested_capacity_arg; psa_crypto_generator_t generator = PSA_CRYPTO_GENERATOR_INIT; uint8_t *expected_outputs[2] = {expected_output1->x, expected_output2->x}; size_t output_sizes[2] = {expected_output1->len, expected_output2->len}; size_t output_buffer_size = 0; uint8_t *output_buffer = NULL; size_t expected_capacity; size_t current_capacity; psa_key_policy_t policy; psa_status_t status; unsigned i; for( i = 0; i < ARRAY_LENGTH( expected_outputs ); i++ ) { if( output_sizes[i] > output_buffer_size ) output_buffer_size = output_sizes[i]; if( output_sizes[i] == 0 ) expected_outputs[i] = NULL; } ASSERT_ALLOC( output_buffer, output_buffer_size ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DERIVE, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, PSA_KEY_TYPE_DERIVE, key_data->x, key_data->len ) == PSA_SUCCESS ); /* Extraction phase. */ TEST_ASSERT( psa_key_derivation( &generator, slot, alg, salt->x, salt->len, label->x, label->len, requested_capacity ) == PSA_SUCCESS ); TEST_ASSERT( psa_get_generator_capacity( &generator, ¤t_capacity ) == PSA_SUCCESS ); TEST_ASSERT( current_capacity == requested_capacity ); expected_capacity = requested_capacity; /* Expansion phase. */ for( i = 0; i < ARRAY_LENGTH( expected_outputs ); i++ ) { /* Read some bytes. */ status = psa_generator_read( &generator, output_buffer, output_sizes[i] ); if( expected_capacity == 0 && output_sizes[i] == 0 ) { /* Reading 0 bytes when 0 bytes are available can go either way. */ TEST_ASSERT( status == PSA_SUCCESS || status == PSA_ERROR_INSUFFICIENT_CAPACITY ); continue; } else if( expected_capacity == 0 || output_sizes[i] > expected_capacity ) { /* Capacity exceeded. */ TEST_ASSERT( status == PSA_ERROR_INSUFFICIENT_CAPACITY ); expected_capacity = 0; continue; } /* Success. Check the read data. */ TEST_ASSERT( status == PSA_SUCCESS ); if( output_sizes[i] != 0 ) TEST_ASSERT( memcmp( output_buffer, expected_outputs[i], output_sizes[i] ) == 0 ); /* Check the generator status. */ expected_capacity -= output_sizes[i]; TEST_ASSERT( psa_get_generator_capacity( &generator, ¤t_capacity ) == PSA_SUCCESS ); TEST_ASSERT( expected_capacity == current_capacity ); } TEST_ASSERT( psa_generator_abort( &generator ) == PSA_SUCCESS ); exit: mbedtls_free( output_buffer ); psa_generator_abort( &generator ); psa_destroy_key( slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void derive_full( int alg_arg, data_t *key_data, data_t *salt, data_t *label, int requested_capacity_arg ) { psa_key_slot_t slot = 1; psa_algorithm_t alg = alg_arg; size_t requested_capacity = requested_capacity_arg; psa_crypto_generator_t generator = PSA_CRYPTO_GENERATOR_INIT; unsigned char output_buffer[16]; size_t expected_capacity = requested_capacity; size_t current_capacity; psa_key_policy_t policy; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DERIVE, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( slot, PSA_KEY_TYPE_DERIVE, key_data->x, key_data->len ) == PSA_SUCCESS ); /* Extraction phase. */ TEST_ASSERT( psa_key_derivation( &generator, slot, alg, salt->x, salt->len, label->x, label->len, requested_capacity ) == PSA_SUCCESS ); TEST_ASSERT( psa_get_generator_capacity( &generator, ¤t_capacity ) == PSA_SUCCESS ); TEST_ASSERT( current_capacity == expected_capacity ); /* Expansion phase. */ while( current_capacity > 0 ) { size_t read_size = sizeof( output_buffer ); if( read_size > current_capacity ) read_size = current_capacity; TEST_ASSERT( psa_generator_read( &generator, output_buffer, read_size ) == PSA_SUCCESS ); expected_capacity -= read_size; TEST_ASSERT( psa_get_generator_capacity( &generator, ¤t_capacity ) == PSA_SUCCESS ); TEST_ASSERT( current_capacity == expected_capacity ); } /* Check that the generator refuses to go over capacity. */ TEST_ASSERT( psa_generator_read( &generator, output_buffer, 1 ) == PSA_ERROR_INSUFFICIENT_CAPACITY ); TEST_ASSERT( psa_generator_abort( &generator ) == PSA_SUCCESS ); exit: psa_generator_abort( &generator ); psa_destroy_key( slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void derive_key_exercise( int alg_arg, data_t *key_data, data_t *salt, data_t *label, int derived_type_arg, int derived_bits_arg, int derived_usage_arg, int derived_alg_arg ) { psa_key_slot_t base_key = 1; psa_key_slot_t derived_key = 2; psa_algorithm_t alg = alg_arg; psa_key_type_t derived_type = derived_type_arg; size_t derived_bits = derived_bits_arg; psa_key_usage_t derived_usage = derived_usage_arg; psa_algorithm_t derived_alg = derived_alg_arg; size_t capacity = PSA_BITS_TO_BYTES( derived_bits ); psa_crypto_generator_t generator = PSA_CRYPTO_GENERATOR_INIT; psa_key_policy_t policy; psa_key_type_t got_type; size_t got_bits; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DERIVE, alg ); TEST_ASSERT( psa_set_key_policy( base_key, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( base_key, PSA_KEY_TYPE_DERIVE, key_data->x, key_data->len ) == PSA_SUCCESS ); /* Derive a key. */ TEST_ASSERT( psa_key_derivation( &generator, base_key, alg, salt->x, salt->len, label->x, label->len, capacity ) == PSA_SUCCESS ); psa_key_policy_set_usage( &policy, derived_usage, derived_alg ); TEST_ASSERT( psa_set_key_policy( derived_key, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_generator_import_key( derived_key, derived_type, derived_bits, &generator ) == PSA_SUCCESS ); /* Test the key information */ TEST_ASSERT( psa_get_key_information( derived_key, &got_type, &got_bits ) == PSA_SUCCESS ); TEST_ASSERT( got_type == derived_type ); TEST_ASSERT( got_bits == derived_bits ); /* Exercise the derived key. */ if( ! exercise_key( derived_key, derived_usage, derived_alg ) ) goto exit; exit: psa_generator_abort( &generator ); psa_destroy_key( base_key ); psa_destroy_key( derived_key ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void derive_key_export( int alg_arg, data_t *key_data, data_t *salt, data_t *label, int bytes1_arg, int bytes2_arg ) { psa_key_slot_t base_key = 1; psa_key_slot_t derived_key = 2; psa_algorithm_t alg = alg_arg; size_t bytes1 = bytes1_arg; size_t bytes2 = bytes2_arg; size_t capacity = bytes1 + bytes2; psa_crypto_generator_t generator = PSA_CRYPTO_GENERATOR_INIT; uint8_t *output_buffer = NULL; uint8_t *export_buffer = NULL; psa_key_policy_t policy; size_t length; ASSERT_ALLOC( output_buffer, capacity ); ASSERT_ALLOC( export_buffer, capacity ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_DERIVE, alg ); TEST_ASSERT( psa_set_key_policy( base_key, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_import_key( base_key, PSA_KEY_TYPE_DERIVE, key_data->x, key_data->len ) == PSA_SUCCESS ); /* Derive some material and output it. */ TEST_ASSERT( psa_key_derivation( &generator, base_key, alg, salt->x, salt->len, label->x, label->len, capacity ) == PSA_SUCCESS ); TEST_ASSERT( psa_generator_read( &generator, output_buffer, capacity ) == PSA_SUCCESS ); TEST_ASSERT( psa_generator_abort( &generator ) == PSA_SUCCESS ); /* Derive the same output again, but this time store it in key objects. */ TEST_ASSERT( psa_key_derivation( &generator, base_key, alg, salt->x, salt->len, label->x, label->len, capacity ) == PSA_SUCCESS ); psa_key_policy_set_usage( &policy, PSA_KEY_USAGE_EXPORT, 0 ); TEST_ASSERT( psa_set_key_policy( derived_key, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_generator_import_key( derived_key, PSA_KEY_TYPE_RAW_DATA, PSA_BYTES_TO_BITS( bytes1 ), &generator ) == PSA_SUCCESS ); TEST_ASSERT( psa_export_key( derived_key, export_buffer, bytes1, &length ) == PSA_SUCCESS ); TEST_ASSERT( length == bytes1 ); TEST_ASSERT( psa_destroy_key( derived_key ) == PSA_SUCCESS ); TEST_ASSERT( psa_set_key_policy( derived_key, &policy ) == PSA_SUCCESS ); TEST_ASSERT( psa_generator_import_key( derived_key, PSA_KEY_TYPE_RAW_DATA, PSA_BYTES_TO_BITS( bytes2 ), &generator ) == PSA_SUCCESS ); TEST_ASSERT( psa_export_key( derived_key, export_buffer + bytes1, bytes2, &length ) == PSA_SUCCESS ); TEST_ASSERT( length == bytes2 ); /* Compare the outputs from the two runs. */ TEST_ASSERT( memcmp( output_buffer, export_buffer, capacity ) == 0 ); exit: mbedtls_free( output_buffer ); mbedtls_free( export_buffer ); psa_generator_abort( &generator ); psa_destroy_key( base_key ); psa_destroy_key( derived_key ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void generate_random( int bytes_arg ) { size_t bytes = bytes_arg; const unsigned char trail[] = "don't overwrite me"; unsigned char *output = NULL; unsigned char *changed = NULL; size_t i; unsigned run; ASSERT_ALLOC( output, bytes + sizeof( trail ) ); ASSERT_ALLOC( changed, bytes ); memcpy( output + bytes, trail, sizeof( trail ) ); TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); /* Run several times, to ensure that every output byte will be * nonzero at least once with overwhelming probability * (2^(-8*number_of_runs)). */ for( run = 0; run < 10; run++ ) { if( bytes != 0 ) memset( output, 0, bytes ); TEST_ASSERT( psa_generate_random( output, bytes ) == PSA_SUCCESS ); /* Check that no more than bytes have been overwritten */ TEST_ASSERT( memcmp( output + bytes, trail, sizeof( trail ) ) == 0 ); for( i = 0; i < bytes; i++ ) { if( output[i] != 0 ) ++changed[i]; } } /* Check that every byte was changed to nonzero at least once. This * validates that psa_generate_random is overwriting every byte of * the output buffer. */ for( i = 0; i < bytes; i++ ) { TEST_ASSERT( changed[i] != 0 ); } exit: mbedtls_psa_crypto_free( ); mbedtls_free( output ); mbedtls_free( changed ); } /* END_CASE */ /* BEGIN_CASE */ void generate_key( int type_arg, int bits_arg, int usage_arg, int alg_arg, int expected_status_arg ) { int slot = 1; psa_key_type_t type = type_arg; psa_key_usage_t usage = usage_arg; size_t bits = bits_arg; psa_algorithm_t alg = alg_arg; psa_status_t expected_status = expected_status_arg; psa_key_type_t got_type; size_t got_bits; psa_status_t expected_info_status = expected_status == PSA_SUCCESS ? PSA_SUCCESS : PSA_ERROR_EMPTY_SLOT; psa_key_policy_t policy; TEST_ASSERT( psa_crypto_init( ) == PSA_SUCCESS ); psa_key_policy_init( &policy ); psa_key_policy_set_usage( &policy, usage, alg ); TEST_ASSERT( psa_set_key_policy( slot, &policy ) == PSA_SUCCESS ); /* Generate a key */ TEST_ASSERT( psa_generate_key( slot, type, bits, NULL, 0 ) == expected_status ); /* Test the key information */ TEST_ASSERT( psa_get_key_information( slot, &got_type, &got_bits ) == expected_info_status ); if( expected_info_status != PSA_SUCCESS ) goto exit; TEST_ASSERT( got_type == type ); TEST_ASSERT( got_bits == bits ); /* Do something with the key according to its type and permitted usage. */ if( ! exercise_key( slot, usage, alg ) ) goto exit; exit: psa_destroy_key( slot ); mbedtls_psa_crypto_free( ); } /* END_CASE */ /* BEGIN_CASE */ void validate_module_init_generate_random( ) { psa_status_t status; uint8_t random[10] = { 0 }; status = psa_generate_random( random, sizeof( random ) ); TEST_ASSERT( status == PSA_ERROR_BAD_STATE ); } /* END_CASE */ /* BEGIN_CASE */ void validate_module_init_key_based( ) { psa_status_t status; uint8_t data[10] = { 0 }; status = psa_import_key( 1, PSA_KEY_TYPE_RAW_DATA, data, sizeof( data ) ); TEST_ASSERT( status == PSA_ERROR_BAD_STATE ); } /* END_CASE */