/* * Copyright 2014-2023 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 #include #include #include enum { SM4_MODE_ECB = 1, SM4_MODE_CBC, SM4_MODE_CFB, SM4_MODE_OFB, SM4_MODE_CTR, SM4_MODE_XTS, SM4_MODE_CCM, SM4_MODE_GCM, SM4_MODE_CBC_SM3_HMAC, SM4_MODE_CTR_SM3_HMAC, }; static uint8_t *read_content(FILE *infp, size_t *outlen, const char *prog) { const size_t INITIAL_BUFFER_SIZE = 4096; const size_t MAX_BUFFER_SIZE = 512 * 1024 * 1024; uint8_t *buffer = NULL; size_t buffer_size = INITIAL_BUFFER_SIZE; size_t total_read = 0; if (!(buffer = (uint8_t *)malloc(INITIAL_BUFFER_SIZE))) { fprintf(stderr, "%s: malloc failure\n", prog); return NULL; } while (1) { size_t bytes_read; if (total_read == buffer_size) { uint8_t *new_buffer; if (buffer_size >= MAX_BUFFER_SIZE) { fprintf(stderr, "%s: input too long, should be less than %zu\n", prog, MAX_BUFFER_SIZE); free(buffer); return NULL; } buffer_size = buffer_size * 2; if (buffer_size > MAX_BUFFER_SIZE) { buffer_size = MAX_BUFFER_SIZE; } if (!(new_buffer = (uint8_t *)realloc(buffer, buffer_size))) { fprintf(stderr, "%s: realloc failure\n", prog); free(buffer); return NULL; } buffer = new_buffer; } bytes_read = fread(buffer + total_read, 1, buffer_size - total_read, infp); total_read += bytes_read; if (feof(infp)) { break; } if (ferror(infp)) { fprintf(stderr, "%s: fread error\n", prog); perror("error reading input"); free(buffer); return NULL; } } *outlen = total_read; return buffer; } #ifdef ENABLE_SM4_CCM static int sm4_ccm_crypt(const uint8_t *key, size_t keylen, const uint8_t *iv, size_t ivlen, const uint8_t *aad, size_t aadlen, size_t taglen, FILE *infp, FILE *outfp, int enc, const char *prog) { int ret = -1; SM4_KEY sm4_key; uint8_t *inbuf = NULL; uint8_t *outbuf = NULL; size_t inlen, outlen; uint8_t *tag; if (keylen != 16) { error_print(); return -1; } if (ivlen < SM4_CCM_MIN_IV_SIZE || ivlen > SM4_CCM_MAX_IV_SIZE) { fprintf(stderr, "%s: invalid SM4-CCM IV length, should be in [%d, %d]\n", prog, SM4_CCM_MIN_IV_SIZE, SM4_CCM_MAX_IV_SIZE); return -1; } if (taglen < SM4_CCM_MIN_TAG_SIZE || taglen > SM4_CCM_MAX_TAG_SIZE) { fprintf(stderr, "%s: invalid SM4-CCM MAC tag length, should be in [%d, %d]\n", prog, SM4_CCM_MIN_TAG_SIZE, SM4_CCM_MAX_TAG_SIZE); return -1; } if (enc < 0) { error_print(); return -1; } sm4_set_encrypt_key(&sm4_key, key); if (!(inbuf = read_content(infp, &inlen, prog))) { goto end; } if (enc) { outlen = inlen + taglen; if (!(outbuf = (uint8_t *)malloc(outlen))) { fprintf(stderr, "%s: malloc failure\n", prog); goto end; } tag = outbuf + inlen; if (sm4_ccm_encrypt(&sm4_key, iv, ivlen, aad, aadlen, inbuf, inlen, outbuf, taglen, tag) != 1) { error_print(); goto end; } } else { if (inlen < taglen) { fprintf(stderr, "%s: input length (%zu bytes) shorter than tag length (%zu bytes)\n", prog, inlen, taglen); goto end; } outlen = inlen - taglen; tag = inbuf + inlen - taglen; if (!(outbuf = (uint8_t *)malloc(outlen))) { fprintf(stderr, "%s: malloc failure\n", prog); goto end; } if (sm4_ccm_decrypt(&sm4_key, iv, ivlen, aad, aadlen, inbuf, inlen - taglen, tag, taglen, outbuf) != 1) { error_print(); goto end; } } if (fwrite(outbuf, 1, outlen, outfp) != outlen) { fprintf(stderr, "%s: fwrite error\n", prog); goto end; } ret = 1; end: gmssl_secure_clear(&sm4_key, sizeof(sm4_key)); if (inbuf) free(inbuf); if (outbuf) free(outbuf); return ret; } #endif static const char *usage = "(-cbc|-ctr|-gcm|-cbc_sm3_hmac|-ctr_sm3_hmac)" " {-encrypt|-decrypt} -key hex -iv hex" " [-aad str| -aad_hex hex] [-taglen num] [-in file] [-out file]"; static const char *options = "Options\n" "\n" " Modes\n" "\n" " -ecb ECB mode\n" " -cbc CBC mode with padding, need 16-byte key and 16-byte iv\n" " -cfb CFB mode with padding, need 16-byte key and 16-byte iv\n" " -ofb OFB mode with padding, need 16-byte key and 16-byte iv\n" " -ctr CTR mode, need 16-byte key and 16-byte iv\n" " -ccm CCM mode, need 16-byte key and any iv length\n" " -gcm GCM mode, need 16-byte key and any iv length\n" " -cbc_sm3_hmac CBC mode with padding and HMAC-SM3 (encrypt-then-mac), need 48-byte key and 16-byte iv\n" " -ctr_sm3_hmac CTR mode with HMAC-SM3 (entrypt-then-mac), need 48-byte key and 16-byte iv\n" " -xts XTS mode\n" "\n" " -encrypt Encrypt\n" " -decrypt Decrypt\n" " -key hex Symmetric key in HEX format\n" " -iv hex IV in HEX format\n" " -aad str Authenticated-only message\n" " -aad_hex hex Authenticated-only data in HEX format\n" " -in file | stdin Input data\n" " -out file | stdout Output data\n" "\n" "Examples" "\n" " echo \"hello\" | gmssl sm4 -gcm -encrypt -key 11223344556677881122334455667788 -iv 112233445566778811223344 -out ciphertext.bin\n" " gmssl sm4 -gcm -decrypt -key 11223344556677881122334455667788 -iv 112233445566778811223344 -in ciphertext.bin\n" "\n" " echo \"hello\" | gmssl sm4 -cbc_sm3_hmac -encrypt \\\n" " -key 112233445566778811223344556677881122334455667788112233445566778811223344556677881122334455667788 \\\n" " -iv 11223344556677881122334455667788 -out ciphertext.bin\n" " gmssl sm4 -cbc_sm3_hmac -decrypt \\\n" " -key 112233445566778811223344556677881122334455667788112233445566778811223344556677881122334455667788 \\\n" " -iv 11223344556677881122334455667788 -in ciphertext.bin\n" "\n"; int sm4_main(int argc, char **argv) { int ret = 1; char *prog = argv[0]; char *keyhex = NULL; char *ivhex = NULL; uint8_t *aad = NULL; uint8_t *aad_buf = NULL; size_t aadlen = 0; char *infile = NULL; char *outfile = NULL; uint8_t key[48]; uint8_t iv[SM4_GCM_MAX_IV_SIZE]; size_t keylen = 0; size_t ivlen = 0; FILE *infp = stdin; FILE *outfp = stdout; int mode = 0; int enc = -1; int rv; union { #ifdef ENABLE_SM4_ECB SM4_ECB_CTX ecb; #endif SM4_CBC_CTX cbc; #ifdef ENABLE_SM4_CFB SM4_CFB_CTX cfb; #endif #ifdef ENABLE_SM4_OFB SM4_OFB_CTX ofb; #endif SM4_CTR_CTX ctr; #ifdef ENABLE_SM4_XTS SM4_XTS_CTX xts; #endif SM4_GCM_CTX gcm; SM4_CBC_SM3_HMAC_CTX cbc_sm3_hmac; SM4_CTR_SM3_HMAC_CTX ctr_sm3_hmac; } sm4_ctx; uint8_t inbuf[4096]; size_t inlen; uint8_t outbuf[41960]; size_t outlen; int taglen = -1; int xts_data_unit_size = 0; argc--; argv++; if (argc < 1) { fprintf(stderr, "usage: %s %s\n", prog, usage); return 1; } while (argc > 0) { if (!strcmp(*argv, "-help")) { printf("usage: %s %s\n", prog, usage); printf("%s\n", options); ret = 0; goto end; } else if (!strcmp(*argv, "-key")) { if (--argc < 1) goto bad; keyhex = *(++argv); if (strlen(keyhex) > sizeof(key) * 2) { fprintf(stderr, "%s: invalid key length\n", prog); goto end; } if (hex_to_bytes(keyhex, strlen(keyhex), key, &keylen) != 1) { fprintf(stderr, "%s: invalid key hex digits\n", prog); goto end; } } else if (!strcmp(*argv, "-iv")) { if (--argc < 1) goto bad; ivhex = *(++argv); if (strlen(ivhex) > sizeof(iv) * 2) { fprintf(stderr, "%s: IV length too long\n", prog); goto end; } if (hex_to_bytes(ivhex, strlen(ivhex), iv, &ivlen) != 1) { fprintf(stderr, "%s: invalid IV hex digits\n", prog); goto end; } } else if (!strcmp(*argv, "-encrypt")) { if (enc == 0) { fprintf(stderr, "%s: `-encrypt` `-decrypt` should not be used together\n", prog); goto end; } enc = 1; } else if (!strcmp(*argv, "-decrypt")) { if (enc == 1) { fprintf(stderr, "%s: `-encrypt` `-decrypt` should not be used together\n", prog); goto end; } enc = 0; } else if (!strcmp(*argv, "-cbc")) { if (mode) goto bad; mode = SM4_MODE_CBC; } else if (!strcmp(*argv, "-ctr")) { if (mode) goto bad; mode = SM4_MODE_CTR; } else if (!strcmp(*argv, "-cbc_sm3_hmac")) { if (mode) goto bad; mode = SM4_MODE_CBC_SM3_HMAC; } else if (!strcmp(*argv, "-ctr_sm3_hmac")) { if (mode) goto bad; mode = SM4_MODE_CTR_SM3_HMAC; } else if (!strcmp(*argv, "-gcm")) { if (mode) goto bad; mode = SM4_MODE_GCM; } else if (!strcmp(*argv, "-ecb")) { if (mode) goto bad; mode = SM4_MODE_ECB; } else if (!strcmp(*argv, "-cfb")) { if (mode) goto bad; mode = SM4_MODE_CFB; } else if (!strcmp(*argv, "-ofb")) { if (mode) goto bad; mode = SM4_MODE_OFB; } else if (!strcmp(*argv, "-ccm")) { if (mode) goto bad; mode = SM4_MODE_CCM; } else if (!strcmp(*argv, "-xts")) { if (mode) goto bad; mode = SM4_MODE_XTS; } else if (!strcmp(*argv, "-aad")) { if (--argc < 1) goto bad; if (aad) { fprintf(stderr, "%s: `-aad` or `aad_hex` has been specified\n", prog); goto bad; } aad = (uint8_t *)(*(++argv)); aadlen = strlen((char *)aad); } else if (!strcmp(*argv, "-aad_hex")) { if (--argc < 1) goto bad; if (aad) { fprintf(stderr, "%s: `-aad` or `aad_hex` has been specified\n", prog); goto bad; } aad = (uint8_t *)(*(++argv)); if (!(aad_buf = malloc(strlen((char *)aad)/2 + 1))) { fprintf(stderr, "%s: malloc failure\n", prog); goto end; } if (hex_to_bytes((char *)aad, strlen((char *)aad), aad_buf, &aadlen) != 1) { fprintf(stderr, "%s: `-aad_hex` invalid HEX format argument\n", prog); goto end; } aad = aad_buf; } else if (!strcmp(*argv, "-taglen")) { if (--argc < 1) goto bad; taglen = atoi(*(++argv)); if (taglen < 0 || taglen > 32) { fprintf(stderr, "%s: `-taglen` invalid integer argument\n", prog); goto end; } } else if (!strcmp(*argv, "-xts_data_unit_size")) { if (--argc < 1) goto bad; xts_data_unit_size = atoi(*(++argv)); // FIXME: malloc outbuf for XTS if (xts_data_unit_size > sizeof(outbuf) - 1024) { error_print(); goto end; } } else if (!strcmp(*argv, "-in")) { if (--argc < 1) goto bad; infile = *(++argv); if (!(infp = fopen(infile, "rb"))) { fprintf(stderr, "%s: open '%s' failure : %s\n", prog, infile, strerror(errno)); goto end; } } else if (!strcmp(*argv, "-out")) { if (--argc < 1) goto bad; outfile = *(++argv); if (!(outfp = fopen(outfile, "wb"))) { fprintf(stderr, "%s: open '%s' failure : %s\n", prog, outfile, strerror(errno)); goto end; } } else { fprintf(stderr, "%s: illegal option `%s`\n", prog, *argv); goto end; bad: fprintf(stderr, "%s: `%s` option value missing\n", prog, *argv); goto end; } argc--; argv++; } if (!mode) { fprintf(stderr, "%s: mode not assigned, `-cbc`, `-ctr`, `-gcm`, `-cbc_sm3_hmac` or `-ctr_sm3_hmac` required\n", prog); goto end; } if (!keyhex) { fprintf(stderr, "%s: option `-key` missing\n", prog); goto end; } /* if (!ivhex) { fprintf(stderr, "%s: option `-iv` missing\n", prog); goto end; } */ // check if mode is supported switch (mode) { #ifdef ENABLE_SM4_ECB case SM4_MODE_ECB: #endif case SM4_MODE_CBC: #ifdef ENABLE_SM4_CFB case SM4_MODE_CFB: #endif #ifdef ENABLE_SM4_OFB case SM4_MODE_OFB: #endif case SM4_MODE_CTR: #ifdef ENABLE_SM4_CCM case SM4_MODE_CCM: #endif case SM4_MODE_GCM: #ifdef ENABLE_SM4_XTS case SM4_MODE_XTS: #endif case SM4_MODE_CBC_SM3_HMAC: case SM4_MODE_CTR_SM3_HMAC: break; default: fprintf(stderr, "%s: mode is not supported\n", prog); goto end; } // check key length switch (mode) { case SM4_MODE_ECB: case SM4_MODE_CBC: case SM4_MODE_CFB: case SM4_MODE_OFB: case SM4_MODE_CTR: case SM4_MODE_CCM: case SM4_MODE_GCM: if (keylen != 16) { fprintf(stderr, "%s: invalid key length, should be 32 hex digits\n", prog); goto end; } break; case SM4_MODE_XTS: if (keylen != 32) { fprintf(stderr, "%s: invalid key length, should be 64 hex digits\n", prog); goto end; } break; case SM4_MODE_CBC_SM3_HMAC: case SM4_MODE_CTR_SM3_HMAC: if (keylen != 48) { fprintf(stderr, "%s: invalid key length, should be 96 hex digits\n", prog); goto end; } break; } // check iv length switch (mode) { case SM4_MODE_ECB: if (ivlen != 0) { fprintf(stderr, "%s: ECB mode need no IV\n", prog); goto end; } break; case SM4_MODE_CBC: case SM4_MODE_CFB: case SM4_MODE_OFB: case SM4_MODE_CTR: case SM4_MODE_CBC_SM3_HMAC: case SM4_MODE_CTR_SM3_HMAC: if (ivlen != 16) { fprintf(stderr, "%s: invalid IV length, should be 32 hex digits\n", prog); goto end; } break; } // check aad switch (mode) { case SM4_MODE_ECB: case SM4_MODE_CBC: case SM4_MODE_CFB: case SM4_MODE_OFB: case SM4_MODE_CTR: case SM4_MODE_XTS: if (aad) { fprintf(stderr, "%s: specified mode does not support `-aad` nor `-aad_hex`\n", prog); goto end; } break; } // encrypt/decrypt if (mode == SM4_MODE_CTR) { if (sm4_ctr_encrypt_init(&sm4_ctx.ctr, key, iv) != 1) { error_print(); goto end; } while ((inlen = fread(inbuf, 1, sizeof(inbuf), infp)) > 0) { if (sm4_ctr_encrypt_update(&sm4_ctx.ctr, inbuf, inlen, outbuf, &outlen) != 1) { error_print(); goto end; } if (fwrite(outbuf, 1, outlen, outfp) != outlen) { fprintf(stderr, "%s: output failure : %s\n", prog, strerror(errno)); goto end; } } if (sm4_ctr_encrypt_finish(&sm4_ctx.ctr, outbuf, &outlen) != 1) { error_print(); goto end; } if (fwrite(outbuf, 1, outlen, outfp) != outlen) { fprintf(stderr, "%s: output failure : %s\n", prog, strerror(errno)); goto end; } ret = 0; goto end; } if (enc < 0) { fprintf(stderr, "%s: option -encrypt or -decrypt should be set\n", prog); goto end; } #ifdef ENABLE_SM4_CCM if (mode == SM4_MODE_CCM) { if (sm4_ccm_crypt(key, keylen, iv, ivlen, aad, aadlen, taglen, infp, outfp, enc, prog) != 1) { goto end; } } #endif if (enc) { switch (mode) { #ifdef ENABLE_SM4_ECB case SM4_MODE_ECB: rv = sm4_ecb_encrypt_init(&sm4_ctx.ecb, key); break; #endif case SM4_MODE_CBC: rv = sm4_cbc_encrypt_init(&sm4_ctx.cbc, key, iv); break; #ifdef ENABLE_SM4_CFB case SM4_MODE_CFB: rv = sm4_cfb_encrypt_init(&sm4_ctx.cfb, 16, key, iv); break; #endif #ifdef ENABLE_SM4_OFB case SM4_MODE_OFB: rv = sm4_ofb_encrypt_init(&sm4_ctx.ofb, key, iv); break; #endif #ifdef ENABLE_SM4_XTS case SM4_MODE_XTS: rv = sm4_xts_encrypt_init(&sm4_ctx.xts, key, iv, xts_data_unit_size); break; #endif case SM4_MODE_GCM: rv = sm4_gcm_encrypt_init(&sm4_ctx.gcm, key, keylen, iv, ivlen, aad, aadlen, GHASH_SIZE); break; case SM4_MODE_CBC_SM3_HMAC: rv = sm4_cbc_sm3_hmac_encrypt_init(&sm4_ctx.cbc_sm3_hmac, key, iv, aad, aadlen); break; case SM4_MODE_CTR_SM3_HMAC: rv = sm4_ctr_sm3_hmac_encrypt_init(&sm4_ctx.ctr_sm3_hmac, key, iv, aad, aadlen); break; } if (rv != 1) { error_print(); goto end; } while ((inlen = fread(inbuf, 1, sizeof(inbuf), infp)) > 0) { switch (mode) { #ifdef ENABLE_SM4_ECB case SM4_MODE_ECB: rv = sm4_ecb_encrypt_update(&sm4_ctx.ecb, inbuf, inlen, outbuf, &outlen); break; #endif case SM4_MODE_CBC: rv = sm4_cbc_encrypt_update(&sm4_ctx.cbc, inbuf, inlen, outbuf, &outlen); break; #ifdef ENABLE_SM4_CFB case SM4_MODE_CFB: rv = sm4_cfb_encrypt_update(&sm4_ctx.cfb, inbuf, inlen, outbuf, &outlen); break; #endif #ifdef ENABLE_SM4_OFB case SM4_MODE_OFB: rv = sm4_ofb_encrypt_update(&sm4_ctx.ofb, inbuf, inlen, outbuf, &outlen); break; #endif #ifdef ENABLE_SM4_XTS case SM4_MODE_XTS: rv = sm4_xts_encrypt_update(&sm4_ctx.xts, inbuf, inlen, outbuf, &outlen); break; #endif case SM4_MODE_GCM: rv = sm4_gcm_encrypt_update(&sm4_ctx.gcm, inbuf, inlen, outbuf, &outlen); break; case SM4_MODE_CBC_SM3_HMAC: rv = sm4_cbc_sm3_hmac_encrypt_update(&sm4_ctx.cbc_sm3_hmac, inbuf, inlen, outbuf, &outlen); break; case SM4_MODE_CTR_SM3_HMAC: rv = sm4_ctr_sm3_hmac_encrypt_update(&sm4_ctx.ctr_sm3_hmac, inbuf, inlen, outbuf, &outlen); break; } if (rv != 1) { error_print(); goto end; } if (fwrite(outbuf, 1, outlen, outfp) != outlen) { fprintf(stderr, "%s: output failure : %s\n", prog, strerror(errno)); goto end; } } switch (mode) { #ifdef ENABLE_SM4_ECB case SM4_MODE_ECB: rv = sm4_ecb_encrypt_finish(&sm4_ctx.ecb, outbuf, &outlen); break; #endif case SM4_MODE_CBC: rv = sm4_cbc_encrypt_finish(&sm4_ctx.cbc, outbuf, &outlen); break; #ifdef ENABLE_SM4_CFB case SM4_MODE_CFB: rv = sm4_cfb_encrypt_finish(&sm4_ctx.cfb, outbuf, &outlen); break; #endif #ifdef ENABLE_SM4_OFB case SM4_MODE_OFB: rv = sm4_ofb_encrypt_finish(&sm4_ctx.ofb, outbuf, &outlen); break; #endif #ifdef ENABLE_SM4_XTS case SM4_MODE_XTS: rv = sm4_xts_encrypt_finish(&sm4_ctx.xts, outbuf, &outlen); break; #endif case SM4_MODE_GCM: rv = sm4_gcm_encrypt_finish(&sm4_ctx.gcm, outbuf, &outlen); break; case SM4_MODE_CBC_SM3_HMAC: rv = sm4_cbc_sm3_hmac_encrypt_finish(&sm4_ctx.cbc_sm3_hmac, outbuf, &outlen); break; case SM4_MODE_CTR_SM3_HMAC: rv = sm4_ctr_sm3_hmac_encrypt_finish(&sm4_ctx.ctr_sm3_hmac, outbuf, &outlen); break; } if (rv != 1) { error_print(); goto end; } if (fwrite(outbuf, 1, outlen, outfp) != outlen) { fprintf(stderr, "%s: output failure : %s\n", prog, strerror(errno)); goto end; } } else { switch (mode) { #ifdef ENABLE_SM4_ECB case SM4_MODE_ECB: rv = sm4_ecb_decrypt_init(&sm4_ctx.ecb, key); break; #endif case SM4_MODE_CBC: rv = sm4_cbc_decrypt_init(&sm4_ctx.cbc, key, iv); break; #ifdef ENABLE_SM4_CFB case SM4_MODE_CFB: rv = sm4_cfb_decrypt_init(&sm4_ctx.cfb, 16, key, iv); break; #endif #ifdef ENABLE_SM4_OFB case SM4_MODE_OFB: rv = sm4_ofb_encrypt_init(&sm4_ctx.ofb, key, iv); break; #endif #ifdef ENABLE_SM4_XTS case SM4_MODE_XTS: rv = sm4_xts_decrypt_init(&sm4_ctx.xts, key, iv, xts_data_unit_size); break; #endif case SM4_MODE_GCM: rv = sm4_gcm_decrypt_init(&sm4_ctx.gcm, key, keylen, iv, ivlen, aad, aadlen, GHASH_SIZE); break; case SM4_MODE_CBC_SM3_HMAC: rv = sm4_cbc_sm3_hmac_decrypt_init(&sm4_ctx.cbc_sm3_hmac, key, iv, aad, aadlen); break; case SM4_MODE_CTR_SM3_HMAC: rv = sm4_ctr_sm3_hmac_decrypt_init(&sm4_ctx.ctr_sm3_hmac, key, iv, aad, aadlen); break; } if (rv != 1) { error_print(); goto end; } while ((inlen = fread(inbuf, 1, sizeof(inbuf), infp)) > 0) { switch (mode) { #ifdef ENABLE_SM4_ECB case SM4_MODE_ECB: rv = sm4_ecb_decrypt_update(&sm4_ctx.ecb, inbuf, inlen, outbuf, &outlen); break; #endif case SM4_MODE_CBC: rv = sm4_cbc_decrypt_update(&sm4_ctx.cbc, inbuf, inlen, outbuf, &outlen); break; #ifdef ENABLE_SM4_CFB case SM4_MODE_CFB: rv = sm4_cfb_decrypt_update(&sm4_ctx.cfb, inbuf, inlen, outbuf, &outlen); break; #endif #ifdef ENABLE_SM4_OFB case SM4_MODE_OFB: rv = sm4_ofb_encrypt_update(&sm4_ctx.ofb, inbuf, inlen, outbuf, &outlen); break; #endif #ifdef ENABLE_SM4_XTS case SM4_MODE_XTS: rv = sm4_xts_encrypt_update(&sm4_ctx.xts, inbuf, inlen, outbuf, &outlen); break; #endif case SM4_MODE_GCM: rv = sm4_gcm_decrypt_update(&sm4_ctx.gcm, inbuf, inlen, outbuf, &outlen); break; case SM4_MODE_CBC_SM3_HMAC: rv = sm4_cbc_sm3_hmac_decrypt_update(&sm4_ctx.cbc_sm3_hmac, inbuf, inlen, outbuf, &outlen); break; case SM4_MODE_CTR_SM3_HMAC: rv = sm4_ctr_sm3_hmac_decrypt_update(&sm4_ctx.ctr_sm3_hmac, inbuf, inlen, outbuf, &outlen); break; } if (rv != 1) { error_print(); goto end; } if (fwrite(outbuf, 1, outlen, outfp) != outlen) { fprintf(stderr, "%s: output failure : %s\n", prog, strerror(errno)); goto end; } } switch (mode) { #ifdef ENABLE_SM4_ECB case SM4_MODE_ECB: rv = sm4_ecb_decrypt_finish(&sm4_ctx.ecb, outbuf, &outlen); break; #endif case SM4_MODE_CBC: rv = sm4_cbc_decrypt_finish(&sm4_ctx.cbc, outbuf, &outlen); break; #ifdef ENABLE_SM4_CFB case SM4_MODE_CFB: rv = sm4_cfb_decrypt_finish(&sm4_ctx.cfb, outbuf, &outlen); break; #endif #ifdef ENABLE_SM4_OFB case SM4_MODE_OFB: rv = sm4_ofb_encrypt_finish(&sm4_ctx.ofb, outbuf, &outlen); break; #endif #ifdef ENABLE_SM4_XTS case SM4_MODE_XTS: rv = sm4_xts_decrypt_finish(&sm4_ctx.xts, outbuf, &outlen); break; #endif case SM4_MODE_GCM: rv = sm4_gcm_decrypt_finish(&sm4_ctx.gcm, outbuf, &outlen); break; case SM4_MODE_CBC_SM3_HMAC: rv = sm4_cbc_sm3_hmac_decrypt_finish(&sm4_ctx.cbc_sm3_hmac, outbuf, &outlen); break; case SM4_MODE_CTR_SM3_HMAC: rv = sm4_ctr_sm3_hmac_decrypt_finish(&sm4_ctx.ctr_sm3_hmac, outbuf, &outlen); break; } if (rv != 1) { error_print(); goto end; } if (fwrite(outbuf, 1, outlen, outfp) != outlen) { fprintf(stderr, "%s: output failure : %s\n", prog, strerror(errno)); goto end; } } ret = 0; end: gmssl_secure_clear(&sm4_ctx, sizeof(sm4_ctx)); gmssl_secure_clear(key, sizeof(key)); gmssl_secure_clear(iv, sizeof(iv)); gmssl_secure_clear(inbuf, sizeof(inbuf)); gmssl_secure_clear(outbuf, sizeof(outbuf)); if (aad_buf) { gmssl_secure_clear(aad_buf, aadlen); free(aad_buf); } if (infile && infp) fclose(infp); if (outfile && outfp) fclose(outfp); return ret; }