/* * xfm.c * * Crypto transform implementation * * David A. McGrew * Cisco Systems, Inc. */ #include "cryptoalg.h" #include "aes_cbc.h" #include "hmac.h" #include "crypto_kernel.h" /* for crypto_get_random() */ #define KEY_LEN 16 #define ENC_KEY_LEN 16 #define MAC_KEY_LEN 16 #define IV_LEN 16 #define TAG_LEN 12 #define MAX_EXPAND 27 err_status_t aes_128_cbc_hmac_sha1_96_func(void *key, void *clear, unsigned clear_len, void *iv, void *opaque, unsigned *opaque_len, void *auth_tag) { aes_cbc_ctx_t aes_ctx; hmac_ctx_t hmac_ctx; unsigned char enc_key[ENC_KEY_LEN]; unsigned char mac_key[MAC_KEY_LEN]; err_status_t status; /* check if we're doing authentication only */ if ((iv == NULL) && (opaque == NULL) && (opaque_len == NULL)) { /* perform authentication only */ } else if ((iv == NULL) || (opaque == NULL) || (opaque_len == NULL)) { /* * bad parameter - we expect either all three pointers to be NULL, * or none of those pointers to be NULL */ return err_status_fail; } else { /* derive encryption and authentication keys from the input key */ status = hmac_init(&hmac_ctx, key, KEY_LEN); if (status) return status; status = hmac_compute(&hmac_ctx, "ENC", 3, ENC_KEY_LEN, enc_key); if (status) return status; status = hmac_init(&hmac_ctx, key, KEY_LEN); if (status) return status; status = hmac_compute(&hmac_ctx, "MAC", 3, MAC_KEY_LEN, mac_key); if (status) return status; /* perform encryption and authentication */ /* set aes key */ status = aes_cbc_context_init(&aes_ctx, key, ENC_KEY_LEN, direction_encrypt); if (status) return status; /* set iv */ status = crypto_get_random(iv, IV_LEN); if (status) return status; status = aes_cbc_set_iv(&aes_ctx, iv); /* encrypt the opaque data */ status = aes_cbc_nist_encrypt(&aes_ctx, opaque, opaque_len); if (status) return status; /* authenticate clear and opaque data */ status = hmac_init(&hmac_ctx, mac_key, MAC_KEY_LEN); if (status) return status; status = hmac_start(&hmac_ctx); if (status) return status; status = hmac_update(&hmac_ctx, clear, clear_len); if (status) return status; status = hmac_compute(&hmac_ctx, opaque, *opaque_len, TAG_LEN, auth_tag); if (status) return status; } return err_status_ok; } err_status_t aes_128_cbc_hmac_sha1_96_inv(void *key, void *clear, unsigned clear_len, void *iv, void *opaque, unsigned *opaque_len, void *auth_tag) { aes_cbc_ctx_t aes_ctx; hmac_ctx_t hmac_ctx; unsigned char enc_key[ENC_KEY_LEN]; unsigned char mac_key[MAC_KEY_LEN]; unsigned char tmp_tag[TAG_LEN]; unsigned char *tag = auth_tag; err_status_t status; int i; /* check if we're doing authentication only */ if ((iv == NULL) && (opaque == NULL) && (opaque_len == NULL)) { /* perform authentication only */ } else if ((iv == NULL) || (opaque == NULL) || (opaque_len == NULL)) { /* * bad parameter - we expect either all three pointers to be NULL, * or none of those pointers to be NULL */ return err_status_fail; } else { /* derive encryption and authentication keys from the input key */ status = hmac_init(&hmac_ctx, key, KEY_LEN); if (status) return status; status = hmac_compute(&hmac_ctx, "ENC", 3, ENC_KEY_LEN, enc_key); if (status) return status; status = hmac_init(&hmac_ctx, key, KEY_LEN); if (status) return status; status = hmac_compute(&hmac_ctx, "MAC", 3, MAC_KEY_LEN, mac_key); if (status) return status; /* perform encryption and authentication */ /* set aes key */ status = aes_cbc_context_init(&aes_ctx, key, ENC_KEY_LEN, direction_decrypt); if (status) return status; /* set iv */ status = rand_source_get_octet_string(iv, IV_LEN); if (status) return status; status = aes_cbc_set_iv(&aes_ctx, iv); /* encrypt the opaque data */ status = aes_cbc_nist_decrypt(&aes_ctx, opaque, opaque_len); if (status) return status; /* authenticate clear and opaque data */ status = hmac_init(&hmac_ctx, mac_key, MAC_KEY_LEN); if (status) return status; status = hmac_start(&hmac_ctx); if (status) return status; status = hmac_update(&hmac_ctx, clear, clear_len); if (status) return status; status = hmac_compute(&hmac_ctx, opaque, *opaque_len, TAG_LEN, tmp_tag); if (status) return status; /* compare the computed tag with the one provided as input */ for (i=0; i < TAG_LEN; i++) if (tmp_tag[i] != tag[i]) return err_status_auth_fail; } return err_status_ok; } #define ENC 1 #define DEBUG_PRINT 0 err_status_t aes_128_cbc_hmac_sha1_96_enc(void *key, const void *clear, unsigned clear_len, void *iv, void *opaque, unsigned *opaque_len) { aes_cbc_ctx_t aes_ctx; hmac_ctx_t hmac_ctx; unsigned char enc_key[ENC_KEY_LEN]; unsigned char mac_key[MAC_KEY_LEN]; unsigned char *auth_tag; err_status_t status; /* check if we're doing authentication only */ if ((iv == NULL) && (opaque == NULL) && (opaque_len == NULL)) { /* perform authentication only */ } else if ((iv == NULL) || (opaque == NULL) || (opaque_len == NULL)) { /* * bad parameter - we expect either all three pointers to be NULL, * or none of those pointers to be NULL */ return err_status_fail; } else { #if DEBUG_PRINT printf("ENC using key %s\n", octet_string_hex_string(key, KEY_LEN)); #endif /* derive encryption and authentication keys from the input key */ status = hmac_init(&hmac_ctx, key, KEY_LEN); if (status) return status; status = hmac_compute(&hmac_ctx, "ENC", 3, ENC_KEY_LEN, enc_key); if (status) return status; status = hmac_init(&hmac_ctx, key, KEY_LEN); if (status) return status; status = hmac_compute(&hmac_ctx, "MAC", 3, MAC_KEY_LEN, mac_key); if (status) return status; /* perform encryption and authentication */ /* set aes key */ status = aes_cbc_context_init(&aes_ctx, key, ENC_KEY_LEN, direction_encrypt); if (status) return status; /* set iv */ status = rand_source_get_octet_string(iv, IV_LEN); if (status) return status; status = aes_cbc_set_iv(&aes_ctx, iv); if (status) return status; #if DEBUG_PRINT printf("plaintext len: %d\n", *opaque_len); printf("iv: %s\n", octet_string_hex_string(iv, IV_LEN)); printf("plaintext: %s\n", octet_string_hex_string(opaque, *opaque_len)); #endif #if ENC /* encrypt the opaque data */ status = aes_cbc_nist_encrypt(&aes_ctx, opaque, opaque_len); if (status) return status; #endif #if DEBUG_PRINT printf("ciphertext len: %d\n", *opaque_len); printf("ciphertext: %s\n", octet_string_hex_string(opaque, *opaque_len)); #endif /* * authenticate clear and opaque data, then write the * authentication tag to the location immediately following the * ciphertext */ status = hmac_init(&hmac_ctx, mac_key, MAC_KEY_LEN); if (status) return status; status = hmac_start(&hmac_ctx); if (status) return status; status = hmac_update(&hmac_ctx, clear, clear_len); if (status) return status; #if DEBUG_PRINT printf("hmac input: %s\n", octet_string_hex_string(clear, clear_len)); #endif auth_tag = (unsigned char *)opaque; auth_tag += *opaque_len; status = hmac_compute(&hmac_ctx, opaque, *opaque_len, TAG_LEN, auth_tag); if (status) return status; #if DEBUG_PRINT printf("hmac input: %s\n", octet_string_hex_string(opaque, *opaque_len)); #endif /* bump up the opaque_len to reflect the authentication tag */ *opaque_len += TAG_LEN; #if DEBUG_PRINT printf("prot data len: %d\n", *opaque_len); printf("prot data: %s\n", octet_string_hex_string(opaque, *opaque_len)); #endif } return err_status_ok; } err_status_t aes_128_cbc_hmac_sha1_96_dec(void *key, const void *clear, unsigned clear_len, void *iv, void *opaque, unsigned *opaque_len) { aes_cbc_ctx_t aes_ctx; hmac_ctx_t hmac_ctx; unsigned char enc_key[ENC_KEY_LEN]; unsigned char mac_key[MAC_KEY_LEN]; unsigned char tmp_tag[TAG_LEN]; unsigned char *auth_tag; unsigned ciphertext_len; err_status_t status; int i; /* check if we're doing authentication only */ if ((iv == NULL) && (opaque == NULL) && (opaque_len == NULL)) { /* perform authentication only */ } else if ((iv == NULL) || (opaque == NULL) || (opaque_len == NULL)) { /* * bad parameter - we expect either all three pointers to be NULL, * or none of those pointers to be NULL */ return err_status_fail; } else { #if DEBUG_PRINT printf("DEC using key %s\n", octet_string_hex_string(key, KEY_LEN)); #endif /* derive encryption and authentication keys from the input key */ status = hmac_init(&hmac_ctx, key, KEY_LEN); if (status) return status; status = hmac_compute(&hmac_ctx, "ENC", 3, ENC_KEY_LEN, enc_key); if (status) return status; status = hmac_init(&hmac_ctx, key, KEY_LEN); if (status) return status; status = hmac_compute(&hmac_ctx, "MAC", 3, MAC_KEY_LEN, mac_key); if (status) return status; #if DEBUG_PRINT printf("prot data len: %d\n", *opaque_len); printf("prot data: %s\n", octet_string_hex_string(opaque, *opaque_len)); #endif /* * set the protected data length to that of the ciphertext, by * subtracting out the length of the authentication tag */ ciphertext_len = *opaque_len - TAG_LEN; #if DEBUG_PRINT printf("ciphertext len: %d\n", ciphertext_len); #endif /* verify the authentication tag */ /* * compute the authentication tag for the clear and opaque data, * and write it to a temporary location */ status = hmac_init(&hmac_ctx, mac_key, MAC_KEY_LEN); if (status) return status; status = hmac_start(&hmac_ctx); if (status) return status; status = hmac_update(&hmac_ctx, clear, clear_len); if (status) return status; #if DEBUG_PRINT printf("hmac input: %s\n", octet_string_hex_string(clear, clear_len)); #endif status = hmac_compute(&hmac_ctx, opaque, ciphertext_len, TAG_LEN, tmp_tag); if (status) return status; #if DEBUG_PRINT printf("hmac input: %s\n", octet_string_hex_string(opaque, ciphertext_len)); #endif /* * compare the computed tag with the one provided as input (which * immediately follows the ciphertext) */ auth_tag = (unsigned char *)opaque; auth_tag += ciphertext_len; #if DEBUG_PRINT printf("auth_tag: %s\n", octet_string_hex_string(auth_tag, TAG_LEN)); printf("tmp_tag: %s\n", octet_string_hex_string(tmp_tag, TAG_LEN)); #endif for (i=0; i < TAG_LEN; i++) { if (tmp_tag[i] != auth_tag[i]) return err_status_auth_fail; } /* bump down the opaque_len to reflect the authentication tag */ *opaque_len -= TAG_LEN; /* decrypt the confidential data */ status = aes_cbc_context_init(&aes_ctx, key, ENC_KEY_LEN, direction_decrypt); if (status) return status; status = aes_cbc_set_iv(&aes_ctx, iv); if (status) return status; #if DEBUG_PRINT printf("ciphertext: %s\n", octet_string_hex_string(opaque, *opaque_len)); printf("iv: %s\n", octet_string_hex_string(iv, IV_LEN)); #endif #if ENC status = aes_cbc_nist_decrypt(&aes_ctx, opaque, &ciphertext_len); if (status) return status; #endif #if DEBUG_PRINT printf("plaintext len: %d\n", ciphertext_len); printf("plaintext: %s\n", octet_string_hex_string(opaque, ciphertext_len)); #endif /* indicate the length of the plaintext */ *opaque_len = ciphertext_len; } return err_status_ok; } cryptoalg_ctx_t cryptoalg_ctx = { aes_128_cbc_hmac_sha1_96_enc, aes_128_cbc_hmac_sha1_96_dec, KEY_LEN, IV_LEN, TAG_LEN, MAX_EXPAND, }; cryptoalg_t cryptoalg = &cryptoalg_ctx; #define NULL_TAG_LEN 12 err_status_t null_enc(void *key, const void *clear, unsigned clear_len, void *iv, void *opaque, unsigned *opaque_len) { int i; unsigned char *auth_tag; unsigned char *init_vec = iv; /* check if we're doing authentication only */ if ((iv == NULL) && (opaque == NULL) && (opaque_len == NULL)) { /* perform authentication only */ } else if ((iv == NULL) || (opaque == NULL) || (opaque_len == NULL)) { /* * bad parameter - we expect either all three pointers to be NULL, * or none of those pointers to be NULL */ return err_status_fail; } else { #if DEBUG_PRINT printf("NULL ENC using key %s\n", octet_string_hex_string(key, KEY_LEN)); printf("NULL_TAG_LEN: %d\n", NULL_TAG_LEN); printf("plaintext len: %d\n", *opaque_len); #endif for (i=0; i < IV_LEN; i++) init_vec[i] = i + (i * 16); #if DEBUG_PRINT printf("iv: %s\n", octet_string_hex_string(iv, IV_LEN)); printf("plaintext: %s\n", octet_string_hex_string(opaque, *opaque_len)); #endif auth_tag = opaque; auth_tag += *opaque_len; for (i=0; i < NULL_TAG_LEN; i++) auth_tag[i] = i + (i * 16); *opaque_len += NULL_TAG_LEN; #if DEBUG_PRINT printf("protected data len: %d\n", *opaque_len); printf("protected data: %s\n", octet_string_hex_string(opaque, *opaque_len)); #endif } return err_status_ok; } err_status_t null_dec(void *key, const void *clear, unsigned clear_len, void *iv, void *opaque, unsigned *opaque_len) { unsigned char *auth_tag; /* check if we're doing authentication only */ if ((iv == NULL) && (opaque == NULL) && (opaque_len == NULL)) { /* perform authentication only */ } else if ((iv == NULL) || (opaque == NULL) || (opaque_len == NULL)) { /* * bad parameter - we expect either all three pointers to be NULL, * or none of those pointers to be NULL */ return err_status_fail; } else { #if DEBUG_PRINT printf("NULL DEC using key %s\n", octet_string_hex_string(key, KEY_LEN)); printf("protected data len: %d\n", *opaque_len); printf("protected data: %s\n", octet_string_hex_string(opaque, *opaque_len)); #endif auth_tag = opaque; auth_tag += (*opaque_len - NULL_TAG_LEN); #if DEBUG_PRINT printf("iv: %s\n", octet_string_hex_string(iv, IV_LEN)); #endif *opaque_len -= NULL_TAG_LEN; #if DEBUG_PRINT printf("plaintext len: %d\n", *opaque_len); printf("plaintext: %s\n", octet_string_hex_string(opaque, *opaque_len)); #endif } return err_status_ok; } cryptoalg_ctx_t null_cryptoalg_ctx = { null_enc, null_dec, KEY_LEN, IV_LEN, NULL_TAG_LEN, MAX_EXPAND, }; cryptoalg_t null_cryptoalg = &null_cryptoalg_ctx; int cryptoalg_get_id(cryptoalg_t c) { if (c == cryptoalg) return 1; return 0; } cryptoalg_t cryptoalg_find_by_id(int id) { switch(id) { case 1: return cryptoalg; default: break; } return 0; }