/* SPDX-License-Identifier: BSD-3-Clause * Copyright(c) 2018 Intel Corporation */ #include #include #include #include #include #include "fips_validation.h" #define MODE_STR "AESVS" #define ALGO_STR "test data for " #define OP_STR "State" #define KEY_SIZE_STR "Key Length : " #define COUNT_STR "COUNT = " #define KEY_STR "KEY = " #define IV_STR "IV = " #define PT_STR "PLAINTEXT = " #define CT_STR "CIPHERTEXT = " #define OP_ENC_STR "ENCRYPT" #define OP_DEC_STR "DECRYPT" #define ALGO_JSON_STR "algorithm" #define TESTTYPE_JSON_STR "testType" #define DIR_JSON_STR "direction" #define KEYLEN_JSON_STR "keyLen" #define OVERFLOW_JSON_STR "overflow" #define KEY_JSON_STR "key" #define PAYLOADLEN_JSON_STR "payloadLen" #define IV_JSON_STR "iv" #define PT_JSON_STR "pt" #define CT_JSON_STR "ct" #define OP_ENC_JSON_STR "encrypt" #define OP_DEC_JSON_STR "decrypt" struct { uint32_t type; const char *desc; } aes_test_types[] = { {AESAVS_TYPE_GFXBOX, "GFSbox"}, {AESAVS_TYPE_KEYSBOX, "KeySbox"}, {AESAVS_TYPE_VARKEY, "VarKey"}, {AESAVS_TYPE_VARTXT, "VarTxt"}, {TDES_VARIABLE_TEXT, "VARIABLE PLAINTEXT/CIPHERTEXT"}, {TDES_VARIABLE_TEXT, "KAT"}, {AESAVS_TYPE_MMT, "MMT"}, {AESAVS_TYPE_MCT, "MCT"}, {AESAVS_TYPE_AFT, "AFT"}, {AESAVS_TYPE_CTR, "CTR"}, }; struct aes_test_algo { const char *name; enum rte_crypto_cipher_algorithm algo; } const algo_con[] = { {"CBC", RTE_CRYPTO_CIPHER_AES_CBC}, {"ECB", RTE_CRYPTO_CIPHER_AES_ECB}, {"CTR", RTE_CRYPTO_CIPHER_AES_CTR}, }; static int parse_interim_enc_dec(const char *key, __rte_unused char *text, __rte_unused struct fips_val *val) { if (strcmp(key, OP_ENC_STR) == 0) info.op = FIPS_TEST_ENC_AUTH_GEN; else if (strcmp(key, OP_DEC_STR) == 0) info.op = FIPS_TEST_DEC_AUTH_VERIF; else return -1; return 0; } struct fips_test_callback aes_tests_interim[] = { {OP_ENC_STR, parse_interim_enc_dec, NULL}, {OP_DEC_STR, parse_interim_enc_dec, NULL}, {NULL, NULL, NULL} /**< end pointer */ }; struct fips_test_callback aes_tests_vectors[] = { {KEY_STR, parse_uint8_hex_str, &vec.cipher_auth.key}, {IV_STR, parse_uint8_hex_str, &vec.iv}, {PT_STR, parse_uint8_hex_str, &vec.pt}, {CT_STR, parse_uint8_hex_str, &vec.ct}, {NULL, NULL, NULL} /**< end pointer */ }; struct fips_test_callback aes_tests_interim_vectors[] = { {OP_ENC_STR, parse_interim_enc_dec, NULL}, {OP_DEC_STR, parse_interim_enc_dec, NULL}, {NULL, NULL, NULL} /**< end pointer */ }; struct fips_test_callback aes_writeback_callbacks[] = { /** First element is used to pass COUNT string */ {COUNT_STR, NULL, NULL}, {IV_STR, writeback_hex_str, &vec.iv}, {KEY_STR, writeback_hex_str, &vec.cipher_auth.key}, {PT_STR, writeback_hex_str, &vec.pt}, {CT_STR, writeback_hex_str, &vec.ct}, {NULL, NULL, NULL} /**< end pointer */ }; #ifdef USE_JANSSON struct fips_test_callback aes_dec_json_vectors[] = { {KEY_JSON_STR, parse_uint8_known_len_hex_str, &vec.cipher_auth.key}, {IV_JSON_STR, parse_uint8_hex_str, &vec.iv}, {CT_JSON_STR, parse_uint8_hex_str, &vec.ct}, {NULL, NULL, NULL} /**< end pointer */ }; struct fips_test_callback aes_interim_json_vectors[] = { {KEYLEN_JSON_STR, parser_read_uint32_bit_val, &vec.cipher_auth.key}, {NULL, NULL, NULL} /**< end pointer */ }; struct fips_test_callback aes_enc_json_vectors[] = { {KEY_JSON_STR, parse_uint8_known_len_hex_str, &vec.cipher_auth.key}, {IV_JSON_STR, parse_uint8_hex_str, &vec.iv}, {PT_JSON_STR, parse_uint8_hex_str, &vec.pt}, {NULL, NULL, NULL} /**< end pointer */ }; static int parse_test_aes_json_writeback(struct fips_val *val) { struct fips_val tmp_val; json_t *tcId; tcId = json_object_get(json_info.json_test_case, "tcId"); json_info.json_write_case = json_object(); json_object_set(json_info.json_write_case, "tcId", tcId); if (info.op == FIPS_TEST_ENC_AUTH_GEN) { json_t *ct; tmp_val.val = val->val; tmp_val.len = vec.pt.len; writeback_hex_str("", info.one_line_text, &tmp_val); ct = json_string(info.one_line_text); json_object_set_new(json_info.json_write_case, CT_JSON_STR, ct); tmp_val.val = val->val + vec.pt.len; tmp_val.len = val->len - vec.pt.len; writeback_hex_str("", info.one_line_text, &tmp_val); } else { if (vec.status == RTE_CRYPTO_OP_STATUS_SUCCESS) { tmp_val.val = val->val; tmp_val.len = vec.ct.len; writeback_hex_str("", info.one_line_text, &tmp_val); json_object_set_new(json_info.json_write_case, PT_JSON_STR, json_string(info.one_line_text)); } else { json_object_set_new(json_info.json_write_case, "testPassed", json_false()); } } return 0; } static int parse_test_aes_mct_json_writeback(struct fips_val *val) { json_t *tcId, *resArr, *res, *ct, *pt, *key, *iv; struct fips_val tmp_val; tcId = json_object_get(json_info.json_test_case, "tcId"); if (json_info.json_write_case) { json_t *wcId; wcId = json_object_get(json_info.json_write_case, "tcId"); if (!json_equal(tcId, wcId)) { json_info.json_write_case = json_object(); json_object_set(json_info.json_write_case, "tcId", tcId); json_object_set(json_info.json_write_case, "resultsArray", json_array()); } } else { json_info.json_write_case = json_object(); json_object_set(json_info.json_write_case, "tcId", tcId); json_object_set(json_info.json_write_case, "resultsArray", json_array()); } resArr = json_object_get(json_info.json_write_case, "resultsArray"); if (!json_is_array(resArr)) return -EINVAL; res = json_object(); if (info .op == FIPS_TEST_ENC_AUTH_GEN) { writeback_hex_str("", info.one_line_text, &vec.cipher_auth.key); key = json_string(info.one_line_text); json_object_set_new(res, KEY_JSON_STR, key); writeback_hex_str("", info.one_line_text, &val[2]); iv = json_string(info.one_line_text); json_object_set_new(res, IV_JSON_STR, iv); writeback_hex_str("", info.one_line_text, &val[1]); pt = json_string(info.one_line_text); json_object_set_new(res, PT_JSON_STR, pt); tmp_val.val = val->val; tmp_val.len = vec.pt.len; writeback_hex_str("", info.one_line_text, &tmp_val); ct = json_string(info.one_line_text); json_object_set_new(res, CT_JSON_STR, ct); tmp_val.val = val->val + vec.pt.len; tmp_val.len = val->len - vec.pt.len; writeback_hex_str("", info.one_line_text, &tmp_val); } else { if (vec.status == RTE_CRYPTO_OP_STATUS_SUCCESS) { writeback_hex_str("", info.one_line_text, &vec.cipher_auth.key); key = json_string(info.one_line_text); json_object_set_new(res, KEY_JSON_STR, key); writeback_hex_str("", info.one_line_text, &val[2]); iv = json_string(info.one_line_text); json_object_set_new(res, IV_JSON_STR, iv); tmp_val.val = val->val; tmp_val.len = vec.ct.len; writeback_hex_str("", info.one_line_text, &tmp_val); pt = json_string(info.one_line_text); json_object_set_new(res, PT_JSON_STR, pt); writeback_hex_str("", info.one_line_text, &val[1]); ct = json_string(info.one_line_text); json_object_set_new(res, CT_JSON_STR, ct); } else { json_object_set_new(json_info.json_write_case, "testPassed", json_false()); } } json_array_append_new(resArr, res); return 0; } int parse_test_aes_json_init(void) { json_t *type_obj = json_object_get(json_info.json_test_group, TESTTYPE_JSON_STR); json_t *algo_obj = json_object_get(json_info.json_vector_set, ALGO_JSON_STR); const char *type_str = json_string_value(type_obj); const char *algo_str = json_string_value(algo_obj); uint32_t i; if (json_info.json_test_group) { json_t *direction_obj; const char *direction_str; direction_obj = json_object_get(json_info.json_test_group, DIR_JSON_STR); direction_str = json_string_value(direction_obj); if (strcmp(direction_str, OP_ENC_JSON_STR) == 0) { info.op = FIPS_TEST_ENC_AUTH_GEN; info.callbacks = aes_enc_json_vectors; } else if (strcmp(direction_str, OP_DEC_JSON_STR) == 0) { info.op = FIPS_TEST_DEC_AUTH_VERIF; info.callbacks = aes_dec_json_vectors; } else { return -EINVAL; } info.interim_callbacks = aes_interim_json_vectors; } for (i = 0; i < RTE_DIM(aes_test_types); i++) if (strstr(type_str, aes_test_types[i].desc)) { info.interim_info.aes_data.test_type = aes_test_types[i].type; break; } if (i >= RTE_DIM(aes_test_types)) return -EINVAL; switch (info.interim_info.aes_data.test_type) { case AESAVS_TYPE_MCT: info.parse_writeback = parse_test_aes_mct_json_writeback; break; case AESAVS_TYPE_CTR: case AESAVS_TYPE_AFT: info.parse_writeback = parse_test_aes_json_writeback; break; default: info.parse_writeback = NULL; } if (!info.parse_writeback) return -EINVAL; for (i = 0; i < RTE_DIM(algo_con); i++) if (strstr(algo_str, algo_con[i].name)) { info.interim_info.aes_data.cipher_algo = (uint32_t)algo_con[i].algo; break; } if (i >= RTE_DIM(algo_con)) return -EINVAL; return 0; } #endif /* USE_JANSSON */ static int parse_test_aes_writeback(struct fips_val *val) { if (info.op == FIPS_TEST_ENC_AUTH_GEN) fprintf(info.fp_wr, "%s", CT_STR); else fprintf(info.fp_wr, "%s", PT_STR); parse_write_hex_str(val); return 0; } static int rsp_test_aes_check(struct fips_val *val) { struct fips_val *data; if (info.op == FIPS_TEST_ENC_AUTH_GEN) data = &vec.ct; else data = &vec.pt; if (memcmp(val->val, data->val, val->len) == 0) fprintf(info.fp_wr, "Success\n"); else fprintf(info.fp_wr, "Failed\n"); return 0; } int parse_test_aes_init(void) { char *tmp; uint32_t i, j; for (i = 0; i < info.nb_vec_lines; i++) { char *line = info.vec[i]; tmp = strstr(line, MODE_STR); if (tmp) { for (j = 0; j < RTE_DIM(aes_test_types); j++) if (strstr(line, aes_test_types[j].desc)) { info.interim_info.aes_data.test_type = aes_test_types[j].type; break; } if (j >= RTE_DIM(aes_test_types)) return -EINVAL; tmp = strstr(line, ALGO_STR); if (!tmp) return -EINVAL; tmp += strlen(ALGO_STR); for (j = 0; j < RTE_DIM(algo_con); j++) if (strcmp(algo_con[j].name, tmp) == 0) { info.interim_info.aes_data.cipher_algo = (uint32_t)algo_con[j].algo; break; } if (j >= RTE_DIM(algo_con)) return -EINVAL; continue; } tmp = strstr(line, OP_STR); if (tmp) continue; tmp = strstr(line, KEY_SIZE_STR); if (tmp) { tmp += strlen(KEY_SIZE_STR); if (parser_read_uint32 (&info.interim_info.aes_data.key_len, tmp) < 0) return -EINVAL; info.interim_info.aes_data.key_len /= 8; continue; } } info.parse_writeback = parse_test_aes_writeback; info.callbacks = aes_tests_vectors; info.interim_callbacks = aes_tests_interim_vectors; info.writeback_callbacks = aes_writeback_callbacks; info.kat_check = rsp_test_aes_check; return 0; }