/* * Copyright 2014-2026 The GmSSL Project. All Rights Reserved. * * Licensed under the Apache License, Version 2.0 (the License); you may * not use this file except in compliance with the License. * * http://www.apache.org/licenses/LICENSE-2.0 */ #include #include #include #include #include #include #include void aes_cbc_encrypt(const AES_KEY *key, const uint8_t iv[16], const uint8_t *in, size_t nblocks, uint8_t *out) { while (nblocks--) { gmssl_memxor(out, in, iv, 16); aes_encrypt(key, out, out); iv = out; in += 16; out += 16; } } void aes_cbc_decrypt(const AES_KEY *key, const uint8_t iv[16], const uint8_t *in, size_t nblocks, uint8_t *out) { while (nblocks--) { aes_decrypt(key, in, out); memxor(out, iv, 16); iv = in; in += 16; out += 16; } } int aes_cbc_padding_encrypt(const AES_KEY *key, const uint8_t iv[16], const uint8_t *in, size_t inlen, uint8_t *out, size_t *outlen) { uint8_t block[16]; size_t rem = inlen % 16; int padding = 16 - inlen % 16; if (in) { memcpy(block, in + inlen - rem, rem); } memset(block + rem, padding, padding); if (inlen/16) { aes_cbc_encrypt(key, iv, in, inlen/16, out); out += inlen - rem; iv = out - 16; } aes_cbc_encrypt(key, iv, block, 1, out); *outlen = inlen - rem + 16; return 1; } int aes_cbc_padding_decrypt(const AES_KEY *key, const uint8_t iv[16], const uint8_t *in, size_t inlen, uint8_t *out, size_t *outlen) { uint8_t block[16]; size_t len = sizeof(block); int padding; int i; if (inlen == 0) { error_print(); return 0; } if (inlen%16 != 0 || inlen < 16) { error_print(); return -1; } if (inlen > 16) { aes_cbc_decrypt(key, iv, in, inlen/16 - 1, out); iv = in + inlen - 32; } aes_cbc_decrypt(key, iv, in + inlen - 16, 1, block); padding = block[15]; if (padding < 1 || padding > 16) { error_print(); return -1; } for (i = 16 - padding; i < 16; i++) { if (block[i] != padding) { error_print(); return -1; } } len -= padding; memcpy(out + inlen - 16, block, len); *outlen = inlen - padding; return 1; } static void ctr_incr(uint8_t a[16]) { int i; for (i = 15; i >= 0; i--) { a[i]++; if (a[i]) break; } } void aes_ctr_encrypt(const AES_KEY *key, uint8_t ctr[16], const uint8_t *in, size_t inlen, uint8_t *out) { uint8_t block[16]; size_t len; while (inlen) { len = inlen < 16 ? inlen : 16; aes_encrypt(key, ctr, block); gmssl_memxor(out, in, block, len); ctr_incr(ctr); in += len; out += len; inlen -= len; } } #ifdef ENABLE_AES_CCM static void length_to_bytes(size_t len, size_t nbytes, uint8_t *out) { uint8_t *p = out + nbytes - 1; while (nbytes--) { *p-- = len & 0xff; len >>= 8; } } static void ctr_n_incr(uint8_t a[16], size_t n) { size_t i; for (i = 15; i >= 16 - n; i--) { a[i]++; if (a[i]) break; } } static void aes_ctr_n_encrypt(const AES_KEY *key, uint8_t ctr[16], size_t n, const uint8_t *in, size_t inlen, uint8_t *out) { uint8_t block[16]; size_t len; while (inlen) { len = inlen < 16 ? inlen : 16; aes_encrypt(key, ctr, block); gmssl_memxor(out, in, block, len); ctr_n_incr(ctr, n); in += len; out += len; inlen -= len; } } typedef struct { AES_KEY key; uint8_t iv[16]; size_t ivlen; } AES_CBC_MAC_CTX; static int aes_cbc_mac_update(AES_CBC_MAC_CTX *ctx, const uint8_t *data, size_t datalen) { if (!ctx || (!data && datalen)) { error_print(); return -1; } if (ctx->ivlen >= 16) { error_print(); return -1; } if (!data || !datalen) { return 1; } while (datalen) { size_t ivleft = 16 - ctx->ivlen; size_t len = datalen < ivleft ? datalen : ivleft; gmssl_memxor(ctx->iv + ctx->ivlen, ctx->iv + ctx->ivlen, data, len); ctx->ivlen += len; if (ctx->ivlen >= 16) { aes_encrypt(&ctx->key, ctx->iv, ctx->iv); ctx->ivlen = 0; } data += len; datalen -= len; } return 1; } static int aes_cbc_mac_finish(AES_CBC_MAC_CTX *ctx, uint8_t mac[16]) { if (!ctx || !mac) { error_print(); return -1; } if (ctx->ivlen >= 16) { error_print(); return -1; } if (ctx->ivlen) { aes_encrypt(&ctx->key, ctx->iv, ctx->iv); ctx->ivlen = 0; } memcpy(mac, ctx->iv, 16); return 1; } int aes_ccm_encrypt(const AES_KEY *key, const uint8_t *iv, size_t ivlen, const uint8_t *aad, size_t aadlen, const uint8_t *in, size_t inlen, uint8_t *out, size_t taglen, uint8_t *tag) { AES_CBC_MAC_CTX mac_ctx; const uint8_t zeros[16] = {0}; uint8_t block[16] = {0}; uint8_t ctr[16] = {0}; uint8_t mac[16]; size_t inlen_size; if (!key || !iv || (!aad && aadlen) || (!in && inlen) || !out || !tag) { error_print(); return -1; } if (ivlen < 7 || ivlen > 13) { error_print(); return -1; } if (taglen < 4 || taglen > 16 || taglen & 1) { error_print(); return -1; } inlen_size = 15 - ivlen; if (inlen_size < 8 && inlen >= ((size_t)1 << (inlen_size * 8))) { error_print(); return -1; } memset(&mac_ctx, 0, sizeof(mac_ctx)); mac_ctx.key = *key; block[0] |= ((aadlen > 0) & 0x1) << 6; block[0] |= (((taglen - 2)/2) & 0x7) << 3; block[0] |= (inlen_size - 1) & 0x7; memcpy(block + 1, iv, ivlen); length_to_bytes(inlen, inlen_size, block + 1 + ivlen); aes_cbc_mac_update(&mac_ctx, block, 16); if (aad && aadlen) { size_t alen; if (aadlen < ((1<<16) - (1<<8))) { length_to_bytes(aadlen, 2, block); alen = 2; } else if ((uint64_t)aadlen < ((uint64_t)1<<32)) { block[0] = 0xff; block[1] = 0xfe; length_to_bytes(aadlen, 4, block + 2); alen = 6; } else { block[0] = 0xff; block[1] = 0xff; length_to_bytes(aadlen, 8, block + 2); alen = 10; } aes_cbc_mac_update(&mac_ctx, block, alen); aes_cbc_mac_update(&mac_ctx, aad, aadlen); if ((alen + aadlen) % 16) { aes_cbc_mac_update(&mac_ctx, zeros, 16 - (alen + aadlen)%16); } } ctr[0] = 0; ctr[0] |= (inlen_size - 1) & 0x7; memcpy(ctr + 1, iv, ivlen); memset(ctr + 1 + ivlen, 0, 15 - ivlen); aes_encrypt(key, ctr, block); ctr[15] = 1; aes_ctr_n_encrypt(key, ctr, 15 - ivlen, in, inlen, out); aes_cbc_mac_update(&mac_ctx, in, inlen); if (inlen % 16) { aes_cbc_mac_update(&mac_ctx, zeros, 16 - inlen % 16); } aes_cbc_mac_finish(&mac_ctx, mac); gmssl_memxor(tag, mac, block, taglen); gmssl_secure_clear(&mac_ctx, sizeof(mac_ctx)); return 1; } int aes_ccm_decrypt(const AES_KEY *key, const uint8_t *iv, size_t ivlen, const uint8_t *aad, size_t aadlen, const uint8_t *in, size_t inlen, const uint8_t *tag, size_t taglen, uint8_t *out) { AES_CBC_MAC_CTX mac_ctx; const uint8_t zeros[16] = {0}; uint8_t block[16] = {0}; uint8_t ctr[16] = {0}; uint8_t mac[16]; size_t inlen_size; if (!key || !iv || (!aad && aadlen) || (!in && inlen) || !tag || !out) { error_print(); return -1; } if (ivlen < 7 || ivlen > 13) { error_print(); return -1; } if (taglen < 4 || taglen > 16 || taglen & 1) { error_print(); return -1; } inlen_size = 15 - ivlen; if (inlen_size < 8 && inlen >= ((size_t)1 << (inlen_size * 8))) { error_print(); return -1; } memset(&mac_ctx, 0, sizeof(mac_ctx)); mac_ctx.key = *key; block[0] |= ((aadlen > 0) & 0x1) << 6; block[0] |= (((taglen - 2)/2) & 0x7) << 3; block[0] |= (inlen_size - 1) & 0x7; memcpy(block + 1, iv, ivlen); length_to_bytes(inlen, inlen_size, block + 1 + ivlen); aes_cbc_mac_update(&mac_ctx, block, 16); if (aad && aadlen) { size_t alen; if (aadlen < ((1<<16) - (1<<8))) { length_to_bytes(aadlen, 2, block); alen = 2; } else if ((uint64_t)aadlen < ((uint64_t)1<<32)) { block[0] = 0xff; block[1] = 0xfe; length_to_bytes(aadlen, 4, block + 2); alen = 6; } else { block[0] = 0xff; block[1] = 0xff; length_to_bytes(aadlen, 8, block + 2); alen = 10; } aes_cbc_mac_update(&mac_ctx, block, alen); aes_cbc_mac_update(&mac_ctx, aad, aadlen); if ((alen + aadlen) % 16) { aes_cbc_mac_update(&mac_ctx, zeros, 16 - (alen + aadlen)%16); } } ctr[0] = 0; ctr[0] |= (inlen_size - 1) & 0x7; memcpy(ctr + 1, iv, ivlen); memset(ctr + 1 + ivlen, 0, 15 - ivlen); aes_encrypt(key, ctr, block); ctr[15] = 1; aes_ctr_n_encrypt(key, ctr, 15 - ivlen, in, inlen, out); aes_cbc_mac_update(&mac_ctx, out, inlen); if (inlen % 16) { aes_cbc_mac_update(&mac_ctx, zeros, 16 - inlen % 16); } aes_cbc_mac_finish(&mac_ctx, mac); gmssl_memxor(mac, mac, block, taglen); if (gmssl_secure_memcmp(mac, tag, taglen) != 0) { error_print(); gmssl_secure_clear(&mac_ctx, sizeof(mac_ctx)); return -1; } gmssl_secure_clear(&mac_ctx, sizeof(mac_ctx)); return 1; } #endif static void ctr32_incr(uint8_t a[16]) { int i; for (i = 15; i >= 12; i--) { a[i]++; if (a[i]) break; } } static void aes_ctr32_encrypt(const AES_KEY *key, uint8_t ctr[16], const uint8_t *in, size_t inlen, uint8_t *out) { uint8_t block[16]; size_t len; while (inlen) { len = inlen < 16 ? inlen : 16; aes_encrypt(key, ctr, block); gmssl_memxor(out, in, block, len); ctr32_incr(ctr); in += len; out += len; inlen -= len; } gmssl_secure_clear(block, sizeof(block)); } int aes_gcm_encrypt(const AES_KEY *key, const uint8_t *iv, size_t ivlen, const uint8_t *aad, size_t aadlen, const uint8_t *in, size_t inlen, uint8_t *out, size_t taglen, uint8_t *tag) { const uint8_t *pin = in; uint8_t *pout = out; size_t left = inlen; uint8_t H[16] = {0}; uint8_t Y[16]; uint8_t T[16]; if (taglen > AES_GCM_MAX_TAG_SIZE) { error_print(); return -1; } aes_encrypt(key, H, H); if (ivlen == 12) { memcpy(Y, iv, 12); Y[12] = Y[13] = Y[14] = 0; Y[15] = 1; } else { ghash(H, NULL, 0, iv, ivlen, Y); } aes_encrypt(key, Y, T); ctr32_incr(Y); aes_ctr32_encrypt(key, Y, in, inlen, out); ghash(H, aad, aadlen, out, inlen, H); gmssl_memxor(tag, T, H, taglen); gmssl_secure_clear(H, sizeof(H)); gmssl_secure_clear(Y, sizeof(Y)); gmssl_secure_clear(T, sizeof(T)); return 1; } int aes_gcm_decrypt(const AES_KEY *key, const uint8_t *iv, size_t ivlen, const uint8_t *aad, size_t aadlen, const uint8_t *in, size_t inlen, const uint8_t *tag, size_t taglen, uint8_t *out) { const uint8_t *pin = in; uint8_t *pout = out; size_t left = inlen; uint8_t H[16] = {0}; uint8_t Y[16]; uint8_t T[16]; if (taglen > AES_GCM_MAX_TAG_SIZE) { error_print(); return -1; } aes_encrypt(key, H, H); if (ivlen == 12) { memcpy(Y, iv, 12); Y[12] = Y[13] = Y[14] = 0; Y[15] = 1; } else { ghash(H, NULL, 0, iv, ivlen, Y); } ghash(H, aad, aadlen, in, inlen, H); aes_encrypt(key, Y, T); gmssl_memxor(T, T, H, taglen); if (gmssl_secure_memcmp(T, tag, taglen) != 0) { gmssl_secure_clear(H, sizeof(H)); gmssl_secure_clear(Y, sizeof(Y)); gmssl_secure_clear(T, sizeof(T)); error_print(); return -1; } ctr32_incr(Y); aes_ctr32_encrypt(key, Y, in, inlen, out); gmssl_secure_clear(H, sizeof(H)); gmssl_secure_clear(Y, sizeof(Y)); gmssl_secure_clear(T, sizeof(T)); return 1; }