/******************************************************************************/ /* SlunkCrypt, by LoRd_MuldeR */ /* This work has been released under the CC0 1.0 Universal license! */ /******************************************************************************/ #ifdef _WIN32 # define _CRT_SECURE_NO_WARNINGS 1 #else # define _GNU_SOURCE 1 #endif /* API */ #include /* CLI */ #include "utils.h" #include "blake2.h" #include "test.h" /* CRT */ #include #include #include #include #include #include // ========================================================================== // Constants // ========================================================================== #define BUFFER_SIZE 4096U #define MODE_HELP 0 #define MODE_VERS 1 #define MODE_ENCR 2 #define MODE_DECR 3 #define MODE_PASS 4 #define MODE_TEST 5 #define PW_FROM_ENV (!(argc > 4)) static const CHR* const ENV_PASSWORD = T("SLUNK_PASSPHRASE"); static const CHR* const ENV_KEEPFILE = T("SLUNK_KEEP_INCOMPLETE"); static const CHR* const PREFIX_PASS = T("pass:"); static const CHR* const PREFIX_FILE = T("file:"); static const char PASSWD_SYMBOLS[] = { '!', '#', '$', '%', '&', '(', ')', '*', '+', ',', '-', '.', '/', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', ':', ';', '<', '=', '>', '?', '@', 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P', 'Q', 'R', 'S', 'T', 'U', 'V', 'W', 'X', 'Y', 'Z', '[', ']', '^', '_', 'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h', 'i', 'j', 'k', 'l', 'm', 'n', 'o', 'p', 'q', 'r', 's', 't', 'u', 'v', 'w', 'x', 'y', 'z', '{', '|', '}', '~' }; static const size_t RCMD_PWDLEN_LENGTH = 12U; static const size_t DFLT_PWDLEN_LENGTH = 20U; static const clock_t UPDATE_INTERVAL = (clock_t)(1.5708 * CLOCKS_PER_SEC); static const uint64_t MAGIC_NUMBER = 0x243F6A8885A308D3ull; // ========================================================================== // Auxiliary functions // ========================================================================== static int parse_slunk_mode(const CHR* const command) { if ((!STRICMP(command, T("-h"))) || (!STRICMP(command, T("/?"))) || (!STRICMP(command, T("--help")))) { return MODE_HELP; } else if ((!STRICMP(command, T("-v"))) || (!STRICMP(command, T("--version")))) { return MODE_VERS; } else if ((!STRICMP(command, T("-e"))) || (!STRICMP(command, T("--encrypt")))) { return MODE_ENCR; } else if ((!STRICMP(command, T("-d"))) || (!STRICMP(command, T("--decrypt")))) { return MODE_DECR; } else if ((!STRICMP(command, T("-p"))) || (!STRICMP(command, T("--make-pw")))) { return MODE_PASS; } else if ((!STRICMP(command, T("-t"))) || (!STRICMP(command, T("--self-test")))) { return MODE_TEST; } else { return -1; /*invalid command*/ } } static void print_manpage(const CHR *const program) { FPUTS(T("====================================================================\n"), stderr); FPUTS(T("This software has been released under the CC0 1.0 Universal license:\n"), stderr); FPUTS(T("https://creativecommons.org/publicdomain/zero/1.0/legalcode\n"), stderr); FPUTS(T("====================================================================\n\n"), stderr); FPUTS(T("Usage:\n"), stderr); FPRINTF(stderr, T(" %") T(PRISTR) T(" --encrypt [pass:|file:] \n"), program); FPRINTF(stderr, T(" %") T(PRISTR) T(" --decrypt [pass:|file:] \n"), program); FPRINTF(stderr, T(" %") T(PRISTR) T(" --make-pw []\n\n"), program); FPRINTF(stderr, T("Optionally, reads passphrase from the %") T(PRISTR) T(" environment variable.\n\n"), ENV_PASSWORD); } static char *copy_passphrase(const CHR *const passphrase) { if ((!passphrase) || (!passphrase[0U])) { FPUTS(T("Error: The passphrase input string must not be empty!\n\n"), stderr); return NULL; } char *const buffer = CHR_to_utf8(passphrase); if (!buffer) { FPUTS(T("Error: Failed to allocate the string buffer!\n\n"), stderr); } return buffer; } static char *read_passphrase(const CHR *const file_name) { if ((!file_name) || (!file_name[0U])) { FPUTS(T("Error: The passphrase input file name must not be empty!\n\n"), stderr); return NULL; } const size_t max_len = SLUNKCRYPT_PWDLEN_MAX + 2U; char *const buffer = (char*) malloc(max_len * sizeof(char)); if (!buffer) { FPUTS(T("Error: Failed to allocate the passphrase buffer!\n\n"), stderr); return NULL; } const int use_stdin = (!file_name) || (!STRICMP(file_name, T("-"))); FILE *const file_in = use_stdin ? stdin : FOPEN(file_name, T("rb")); if (!file_in) { FPRINTF(stderr, T("Error: Failed to open input file \"%") T(PRISTR) T("\" for reading!\n\n"), file_name); free(buffer); return NULL; } do { if (!fgets(buffer, (int)max_len, file_in)) { buffer[0U] = '\0'; goto finish; } size_t length = strlen(buffer); while ((length > 0U) && ((buffer[length - 1U] == '\r') || (buffer[length - 1U] == '\n'))) { buffer[--length] = '\0'; } } while (!buffer[0U]); finish: if ((!use_stdin) && file_in) { fclose(file_in); } return buffer; } static int weak_passphrase(const char *str) { int flags[4U] = { 0, 0, 0, 0 }; while (*str) { const int c = *str++; if (isalpha(c)) { flags[isupper(c) ? 0U : 1U] = 1; } else { flags[isdigit(c) ? 2U : 3U] = 1; } } const int strong = flags[0U] && flags[1U] && flags[2U] && flags[3U]; return !strong; } static int generate_passphrase(const size_t length) { int result = EXIT_FAILURE; const size_t passwd_len = BOUND(SLUNKCRYPT_PWDLEN_MIN, length, SLUNKCRYPT_PWDLEN_MAX); char *const buffer = (char*) malloc((passwd_len + 1U) * sizeof(char)); if (!buffer) { FPUTS(T("Error: Failed to allocate memory buffer!\n\n"), stderr); return EXIT_FAILURE; } do { for (size_t i = 0U; i < passwd_len; ++i) { uint64_t value; if (slunkcrypt_generate_nonce(&value) != SLUNKCRYPT_SUCCESS) { FPUTS(T("Error: Failed to generate next random number!\n\n"), stderr); goto clean_up; } buffer[i] = PASSWD_SYMBOLS[value % ARRAY_SIZE(PASSWD_SYMBOLS)]; } buffer[passwd_len] = '\0'; } while ((!isalpha((int)buffer[0U])) || (!isalnum((int)buffer[passwd_len - 1U])) || weak_passphrase(buffer)); FPRINTF(stdout, T("%") T(PRIstr) T("\n\n"), buffer); fflush(stdout); result = EXIT_SUCCESS; clean_up: if (buffer) { slunkcrypt_bzero(buffer, passwd_len * sizeof(char)); free(buffer); } return result; } static int open_files(FILE **const file_in, FILE **const file_out, const CHR *const input_path, const CHR *const output_path) { if (!(*file_in = FOPEN(input_path, T("rb")))) { FPRINTF(stderr, T("Error: Failed to open input file \"%") T(PRISTR) T("\" for reading!\n\n"), input_path); *file_out = NULL; return EXIT_FAILURE; } if (!(*file_out = FOPEN(output_path, T("wb")))) { FPRINTF(stderr, T("Error: Failed to open output file \"%") T(PRISTR) T("\" for writing!\n\n"), output_path); return EXIT_FAILURE; } return EXIT_SUCCESS; } static int remove_incomplete_files(void) { const CHR* const keep_files = GETENV(ENV_KEEPFILE); if (keep_files) { return (!STRTOUL(keep_files)); } return 1; } static void sigint_handler(const int sig) { if (sig == SIGINT) { g_slunkcrypt_abort_flag = 1; } } // ========================================================================== // Encrypt // ========================================================================== static int encrypt(const char* const passphrase, const CHR* const input_path, const CHR* const output_path) { slunkcrypt_t ctx = SLUNKCRYPT_NULL; FILE *file_in = NULL, *file_out = NULL; int result = EXIT_FAILURE, status; if (open_files(&file_in, &file_out, input_path, output_path) != EXIT_SUCCESS) { goto clean_up; } const uint64_t file_size = get_file_size(file_in); if (file_size == UINT64_MAX) { FPUTS(T("I/O error: Failed to determine size of input file!\n\n"), stderr); goto clean_up; } else if (file_size < 1U) { FPUTS(T("Error: Input file is empty or an unsupported type!\n\n"), stderr); goto clean_up; } FPUTS(T("Encrypting file contents, please be patient... "), stderr); fflush(stderr); uint64_t nonce; if (slunkcrypt_generate_nonce(&nonce) != SLUNKCRYPT_SUCCESS) { FPUTS(T("\n\nSlunkCrypt error: Failed to generate nonce!\n\n"), stderr); goto clean_up; } ctx = slunkcrypt_alloc(nonce, (const uint8_t*)passphrase, strlen(passphrase), SLUNKCRYPT_ENCRYPT); if (!ctx) { FPUTS(g_slunkcrypt_abort_flag ? T("\n\nProcess interrupted!\n\n") : T("\n\nSlunkCrypt error: Failed to initialize encryption!\n\n"), stderr); goto clean_up; } if (fwrite_ui64(nonce ^ MAGIC_NUMBER, file_out) < 1U) { FPUTS(T("\n\nI/O error: Failed to write nonce value!\n\n"), stderr); goto clean_up; } unsigned refresh_cycles = 0U; clock_t clk_update = clock(); uint64_t bytes_read = 0U; uint8_t buffer[BUFFER_SIZE]; blake2s_t blake2s_state; blake2s_init(&blake2s_state); FPRINTF(stderr, T("%5.1f%% "), 0.0); fflush(stderr); while (bytes_read < file_size) { const uint64_t bytes_remaining = file_size - bytes_read; const size_t request_len = (bytes_remaining < BUFFER_SIZE) ? ((size_t)bytes_remaining) : BUFFER_SIZE; const size_t count = fread(buffer, sizeof(uint8_t), request_len, file_in); if (count > 0U) { blake2s_update(&blake2s_state, buffer, count); bytes_read += count; if ((status = slunkcrypt_inplace(ctx, buffer, count)) != SLUNKCRYPT_SUCCESS) { FPUTS((status == SLUNKCRYPT_ABORTED) ? T("\n\nProcess interrupted!\n\n") : T("\n\nSlunkCrypt error: Failed to encrypt data!\n\n"), stderr); goto clean_up; } if (fwrite(buffer, sizeof(uint8_t), count, file_out) < count) { FPUTS(T("\n\nI/O error: Failed to write encrypted data!\n\n"), stderr); goto clean_up; } } if (count < request_len) { break; /*EOF*/ } if (!(++refresh_cycles & 0x1F)) { const clock_t clk_now = clock(); if ((clk_now < clk_update) || (clk_now - clk_update > UPDATE_INTERVAL)) { FPRINTF(stderr, T("\b\b\b\b\b\b\b%5.1f%% "), (bytes_read / ((double)file_size)) * 100.0); fflush(stderr); clk_update = clk_now; } } } if (ferror(file_in)) { FPUTS(T("\n\nI/O error: Failed to read input data!\n\n"), stderr); goto clean_up; } if (bytes_read != file_size) { FPUTS(T("\n\nI/O error: Input file could not be fully read!\n\n"), stderr); goto clean_up; } const size_t padding = sizeof(uint64_t) - (file_size % sizeof(uint64_t)); assert(padding && (padding <= sizeof(uint64_t))); if (slunkcrypt_random_bytes(buffer, padding) < padding) { FPUTS(T("\n\nSlunkCrypt error: Failed to generate random data!\n\n"), stderr); goto clean_up; } SET_LOWBITS(buffer[padding - 1U], padding - 1U); if ((status = slunkcrypt_inplace(ctx, buffer, padding)) != SLUNKCRYPT_SUCCESS) { FPUTS((status == SLUNKCRYPT_ABORTED) ? T("\n\nProcess interrupted!\n\n") : T("\n\nSlunkCrypt error: Failed to encrypt data!\n\n"), stderr); goto clean_up; } if (fwrite(buffer, sizeof(uint8_t), padding, file_out) < padding) { FPUTS(T("\n\nI/O error: Failed to write padding data!\n\n"), stderr); goto clean_up; } uint8_t checksum_buffer[sizeof(uint64_t)]; store_ui64(checksum_buffer, blake2s_final(&blake2s_state)); if ((status = slunkcrypt_inplace(ctx, checksum_buffer, sizeof(uint64_t))) != SLUNKCRYPT_SUCCESS) { FPUTS((status == SLUNKCRYPT_ABORTED) ? T("\n\nProcess interrupted!\n\n") : T("\n\nSlunkCrypt error: Failed to encrypt checksum!\n\n"), stderr); goto clean_up; } if (fwrite(checksum_buffer, sizeof(uint8_t), sizeof(uint64_t), file_out) < sizeof(uint64_t)) { FPUTS(T("\n\nI/O error: Failed to write the checksum!\n\n"), stderr); goto clean_up; } FPRINTF(stderr, T("\b\b\b\b\b\b\b%5.1f%%\n\n"), 100.0); fflush(stderr); result = EXIT_SUCCESS; FPUTS(T("All is done.\n\n"), stderr); fflush(stderr); clean_up: if (ctx) { slunkcrypt_free(ctx); } if (file_out) { fclose(file_out); if ((result != EXIT_SUCCESS) && remove_incomplete_files()) { if (REMOVE(output_path)) { FPUTS(T("Warning: Failed to remove incomplete output file!\n\n"), stderr); } } } if (file_in) { fclose(file_in); } slunkcrypt_bzero(buffer, BUFFER_SIZE); slunkcrypt_bzero(checksum_buffer, sizeof(uint64_t)); slunkcrypt_bzero(&blake2s_state, sizeof(blake2s_t)); slunkcrypt_bzero(&nonce, sizeof(uint64_t)); return result; } // ========================================================================== // Decrypt // ========================================================================== static int decrypt(const char* const passphrase, const CHR* const input_path, const CHR* const output_path) { slunkcrypt_t ctx = SLUNKCRYPT_NULL; FILE *file_in = NULL, *file_out = NULL; int result = EXIT_FAILURE, status; if (open_files(&file_in, &file_out, input_path, output_path) != EXIT_SUCCESS) { goto clean_up; } const uint64_t file_size = get_file_size(file_in); if (file_size == UINT64_MAX) { FPUTS(T("I/O error: Failed to determine size of input file!\n\n"), stderr); goto clean_up; } else if (file_size < (3U * sizeof(uint64_t))) { FPUTS(T("Error: Input file is too small! Truncated?\n\n"), stderr); goto clean_up; } else if ((file_size % sizeof(uint64_t)) != 0) { FPRINTF(stderr, T("Warning: File size is *not* an integer multiple of %u, ignoring excess bytes!\n\n"), (unsigned)sizeof(uint64_t)); } FPUTS(T("Decrypting file contents, please be patient... "), stderr); fflush(stderr); uint64_t nonce; if (fread_ui64(&nonce, file_in) < 1U) { FPUTS(T("\n\nI/O error: Failed to read nonce value!\n\n"), stderr); goto clean_up; } ctx = slunkcrypt_alloc(nonce ^ MAGIC_NUMBER, (const uint8_t*)passphrase, strlen(passphrase), SLUNKCRYPT_DECRYPT); if (!ctx) { FPUTS(g_slunkcrypt_abort_flag ? T("\n\nProcess interrupted!\n\n") : T("\n\nSlunkCrypt error: Failed to initialize decryption!\n\n"), stderr); goto clean_up; } unsigned refresh_cycles = 0U; clock_t clk_update = clock(); uint64_t bytes_read = sizeof(uint64_t); uint8_t buffer[BUFFER_SIZE]; const uint64_t read_limit = round_down(file_size, sizeof(uint64_t)) - (2U * sizeof(uint64_t)); blake2s_t blake2s_state; blake2s_init(&blake2s_state); FPRINTF(stderr, T("%5.1f%% "), 0.0); fflush(stderr); while (bytes_read < read_limit) { const uint64_t bytes_remaining = read_limit - bytes_read; const size_t request_len = (bytes_remaining < BUFFER_SIZE) ? ((size_t)bytes_remaining) : BUFFER_SIZE; const size_t count = fread(buffer, sizeof(uint8_t), request_len, file_in); if (count > 0U) { bytes_read += count; if ((status = slunkcrypt_inplace(ctx, buffer, count)) != SLUNKCRYPT_SUCCESS) { FPUTS((status == SLUNKCRYPT_ABORTED) ? T("\n\nProcess interrupted!\n\n") : T("\n\nSlunkCrypt error: Failed to decrypt data!\n\n"), stderr); goto clean_up; } blake2s_update(&blake2s_state, buffer, count); if (fwrite(buffer, sizeof(uint8_t), count, file_out) < count) { FPUTS(T("failed!\n\nI/O error: Failed to write decrypted data!\n\n"), stderr); goto clean_up; } } if (count < request_len) { break; /*EOF*/ } if (!(++refresh_cycles & 0x1F)) { const clock_t clk_now = clock(); if ((clk_now < clk_update) || (clk_now - clk_update > UPDATE_INTERVAL)) { FPRINTF(stderr, T("\b\b\b\b\b\b\b%5.1f%% "), (bytes_read / ((double)read_limit)) * 100.0); fflush(stderr); clk_update = clk_now; } } } if (ferror(file_in)) { FPUTS(T("\n\nI/O error: Failed to read input data!\n\n"), stderr); goto clean_up; } if (bytes_read != read_limit) { FPUTS(T("\n\nI/O error: Input file could not be fully read!\n\n"), stderr); goto clean_up; } if (fread(buffer, sizeof(uint8_t), sizeof(uint64_t), file_in) < sizeof(uint64_t)) { FPUTS(T("\n\nI/O error: Failed to read final block!\n\n"), stderr); goto clean_up; } if ((status = slunkcrypt_inplace(ctx, buffer, sizeof(uint64_t))) != SLUNKCRYPT_SUCCESS) { FPUTS((status == SLUNKCRYPT_ABORTED) ? T("\n\nProcess interrupted!\n\n") : T("\n\nSlunkCrypt error: Failed to decrypt data!\n\n"), stderr); goto clean_up; } const size_t padding = GET_LOWBITS(buffer[sizeof(uint64_t) - 1U]) + 1U; assert(padding && (padding <= sizeof(uint64_t))); if (padding != sizeof(uint64_t)) { const size_t count = sizeof(uint64_t) - padding; if (fwrite(buffer, sizeof(uint8_t), count, file_out) < count) { FPUTS(T("failed!\n\nI/O error: Failed to write decrypted data!\n\n"), stderr); goto clean_up; } blake2s_update(&blake2s_state, buffer, count); } const uint64_t checksum_actual = blake2s_final(&blake2s_state); uint8_t checksum_buffer[sizeof(uint64_t)]; if (fread(checksum_buffer, sizeof(uint8_t), sizeof(uint64_t), file_in) < sizeof(uint64_t)) { FPUTS(T("\n\nI/O error: Failed to read the checksum!\n\n"), stderr); goto clean_up; } if ((status = slunkcrypt_inplace(ctx, checksum_buffer, sizeof(uint64_t))) != SLUNKCRYPT_SUCCESS) { FPUTS((status == SLUNKCRYPT_ABORTED) ? T("\n\nProcess interrupted!\n\n") : T("\n\nSlunkCrypt error: Failed to decrypt checksum!\n\n"), stderr); goto clean_up; } FPRINTF(stderr, T("\b\b\b\b\b\b\b%5.1f%%\n\n"), 100.0); fflush(stderr); const uint64_t checksum_stored = load_ui64(checksum_buffer); if (checksum_actual != checksum_stored) { FPRINTF(stderr, T("Error: Checksum mismatch detected! [expected: 0x%016") T(PRIX64) T(", actual: 0x%016") T(PRIX64) T("]\n\n"), checksum_stored, checksum_actual); FPUTS(T("Wrong passphrase or corrupted file?\n\n"), stderr); goto clean_up; } result = EXIT_SUCCESS; FPUTS(T("Checksum is correct.\n\n"), stderr); fflush(stderr); clean_up: if (ctx) { slunkcrypt_free(ctx); } if (file_out) { fclose(file_out); if ((result != EXIT_SUCCESS) && remove_incomplete_files()) { if (REMOVE(output_path)) { FPUTS(T("Warning: Failed to remove incomplete output file!\n\n"), stderr); } } } if (file_in) { fclose(file_in); } slunkcrypt_bzero(buffer, BUFFER_SIZE); slunkcrypt_bzero(checksum_buffer, sizeof(uint64_t)); slunkcrypt_bzero(&blake2s_state, sizeof(blake2s_t)); slunkcrypt_bzero(&nonce, sizeof(uint64_t)); slunkcrypt_bzero((void*)&checksum_stored, sizeof(uint64_t)); slunkcrypt_bzero((void*)&checksum_actual, sizeof(uint64_t)); return result; } // ========================================================================== // Self-test // ========================================================================== static int run_test_case(const char *const message, const uint64_t nonce, const uint64_t checksum_message, const uint64_t checksum_expected) { static const char* const TEST_PASSPHRASE = "OrpheanBeh0lderScry!Doubt"; int status, result = EXIT_FAILURE; const size_t length = strlen(message) + 1U; slunkcrypt_t ctx = SLUNKCRYPT_NULL; char* const text_temp = strdup(message); if (!text_temp) { FPUTS(T("\n\nWhoops: Failed to allocate text buffer!\n\n"), stderr); goto clean_up; } const uint64_t checksum_original = blake2s_compute((uint8_t*)text_temp, length); if (checksum_original != checksum_message) { FPRINTF(stderr, T("\n\nWhoops: Checksum mismatch detected! [expected: 0x%016") T(PRIX64) T(", actual: 0x%016") T(PRIX64) T("]\n\n"), checksum_message, checksum_original); goto clean_up; } ctx = slunkcrypt_alloc(nonce, (const uint8_t*)TEST_PASSPHRASE, strlen(TEST_PASSPHRASE), SLUNKCRYPT_ENCRYPT); if (!ctx) { FPUTS(g_slunkcrypt_abort_flag ? T("\n\nProcess interrupted!\n\n") : T("\n\nWhoops: Failed to initialize encoder!\n\n"), stderr); goto clean_up; } status = slunkcrypt_inplace(ctx, (uint8_t*)text_temp, length); if (status != SLUNKCRYPT_SUCCESS) { FPUTS((status == SLUNKCRYPT_ABORTED) ? T("\n\nProcess interrupted!\n\n") : T("\n\nWhoops: Failed to encrypt the message!\n\n"), stderr); goto clean_up; } if (strncmp(message, text_temp, length) == 0) { FPUTS(T("\n\nWhoops: Encrypted message equals the original message!\n\n"), stderr); goto clean_up; } const uint64_t checksum_encrypted = blake2s_compute((uint8_t*)text_temp, length); if (checksum_encrypted != checksum_expected) { FPRINTF(stderr, T("\n\nWhoops: Checksum mismatch detected! [expected: 0x%016") T(PRIX64) T(", actual: 0x%016") T(PRIX64) T("]\n\n"), checksum_expected, checksum_encrypted); goto clean_up; } status = slunkcrypt_reset(ctx, nonce, (const uint8_t*)TEST_PASSPHRASE, strlen(TEST_PASSPHRASE), SLUNKCRYPT_DECRYPT); if (status != SLUNKCRYPT_SUCCESS) { FPUTS((status == SLUNKCRYPT_ABORTED) ? T("\n\nProcess interrupted!\n\n") : T("\n\nWhoops: Failed to initialize decoder!\n\n"), stderr); goto clean_up; } status = slunkcrypt_inplace(ctx, (uint8_t*)text_temp, length); if (status != SLUNKCRYPT_SUCCESS) { FPUTS((status == SLUNKCRYPT_ABORTED) ? T("\n\nProcess interrupted!\n\n") : T("\n\nWhoops: Failed to decrypt the message!\n\n"), stderr); goto clean_up; } if (memcmp(message, text_temp, length * sizeof(char)) != 0) { FPUTS(T("\n\nWhoops: Decrypted message does *not* match the original message!\n\n"), stderr); goto clean_up; } const uint64_t checksum_decrypted = blake2s_compute((uint8_t*)text_temp, length); if (checksum_decrypted != checksum_original) { FPRINTF(stderr, T("\n\nWhoops: Checksum mismatch detected! [expected: 0x%016") T(PRIX64) T(", actual: 0x%016") T(PRIX64) T("]\n\n"), checksum_original, checksum_decrypted); goto clean_up; } result = EXIT_SUCCESS; clean_up: if (ctx) { slunkcrypt_free(ctx); } if (text_temp) { slunkcrypt_bzero(text_temp, strlen(text_temp)); free(text_temp); } return result; } static int run_self_test(void) { static const uint64_t TEST_NONCE[] = { 0x243F6A8885A308D3, 0x13198A2E03707344 }; const struct { const char* text; uint64_t check_orig, check_encr[2U]; } TEST_STAGE[] = { { TEST_DATA_0, TEST_CHCK_ORIG_0, { TEST_CHCK_ENCR_0[0U], TEST_CHCK_ENCR_0[1U] } }, { TEST_DATA_1, TEST_CHCK_ORIG_1, { TEST_CHCK_ENCR_1[0U], TEST_CHCK_ENCR_1[1U] } }, { TEST_DATA_2, TEST_CHCK_ORIG_2, { TEST_CHCK_ENCR_2[0U], TEST_CHCK_ENCR_2[1U] } }, { TEST_DATA_3, TEST_CHCK_ORIG_3, { TEST_CHCK_ENCR_3[0U], TEST_CHCK_ENCR_3[1U] } }, }; const size_t total = ARRAY_SIZE(TEST_NONCE) * ARRAY_SIZE(TEST_STAGE); FPRINTF(stderr, T("Self-test is in progress, please be patient... stage %u/%u "), 0U, (unsigned)total); fflush(stderr); for (size_t i = 0U, count = 0U; i < ARRAY_SIZE(TEST_STAGE); ++i) { for (size_t j = 0U; j < ARRAY_SIZE(TEST_NONCE); ++j) { FPRINTF(stderr, T("\b\b\b\b%u/%u "), (unsigned)++count, (unsigned)total); fflush(stderr); if (run_test_case(TEST_STAGE[i].text, TEST_NONCE[j], TEST_STAGE[i].check_orig, TEST_STAGE[i].check_encr[j]) != EXIT_SUCCESS) { return EXIT_FAILURE; } } } FPRINTF(stderr, T("\b\b\b\b%u/%u\n\nCompleted successfully.\n\n"), (unsigned)total, (unsigned)total); fflush(stderr); return EXIT_SUCCESS; } // ========================================================================== // Main function // ========================================================================== int MAIN(const int argc, CHR *const argv[]) { init_terminal(); setup_signal_handler(SIGINT, sigint_handler); int result = EXIT_FAILURE; char *passphrase_buffer = NULL; FPRINTF(stderr, T("SlunkCrypt Utility (%") T(PRIstr) T("-%") T(PRIstr) T("), by LoRd_MuldeR \n"), OS_TYPE, CPU_ARCH); FPRINTF(stderr, T("Using libSlunkCrypt v%u.%u.%u [%") T(PRIstr) T("]\n\n"), SLUNKCRYPT_VERSION_MAJOR, SLUNKCRYPT_VERSION_MINOR, SLUNKCRYPT_VERSION_PATCH, SLUNKCRYPT_BUILD); /* ----------------------------------------------------- */ /* Parse arguments */ /* ----------------------------------------------------- */ if (argc < 2) { FPRINTF(stderr, T("Error: Nothing to do. Please type '%") T(PRISTR) T(" --help' for details!\n\n"), get_file_name(argv[0U])); goto clean_up; } const int slunk_mode = parse_slunk_mode(argv[1U]); switch (slunk_mode) { case MODE_HELP: print_manpage(get_file_name(argv[0U])); case MODE_VERS: result = EXIT_SUCCESS; goto clean_up; case MODE_ENCR: case MODE_DECR: break; /*fallthrough*/ case MODE_PASS: result = generate_passphrase((argc > 2) ? STRTOUL(argv[2U]) : DFLT_PWDLEN_LENGTH); goto clean_up; case MODE_TEST: result = run_self_test(); goto clean_up; default: FPRINTF(stderr, T("Error: The specified command \"%") T(PRISTR) T("\" is unknown!\n\n"), argv[1U]); goto clean_up; } if (argc < 4) { FPRINTF(stderr, T("Error: Required argument is missing. Please type '%") T(PRISTR) T(" --help' for details!\n\n"), get_file_name(argv[0U])); goto clean_up; } const CHR *const passphrase = PW_FROM_ENV ? GETENV(ENV_PASSWORD) : argv[2U]; const CHR *const input_file = argv[PW_FROM_ENV ? 2U : 3U], *const output_file = argv[PW_FROM_ENV ? 3U : 4U]; if ((!passphrase) || (!passphrase[0U])) { FPUTS(T("Error: The passphrase must be specified, directly or indirectly!\n\n"), stderr); goto clean_up; } if ((!PW_FROM_ENV) && STRICMP(passphrase, T("-"))) { if ((!STARTS_WITH(passphrase, PREFIX_PASS)) && (!STARTS_WITH(passphrase, PREFIX_FILE))) { FPRINTF(stderr, T("Error: The passphrase must start with a '%") T(PRISTR) T("' or '%") T(PRISTR) T("' prefix!\n\n"), PREFIX_PASS, PREFIX_FILE); goto clean_up; } } if ((!input_file[0U]) || (!output_file[0U])) { FPUTS(T("Error: The input file and/or output file must not be empty!\n\n"), stderr); goto clean_up; } /* ----------------------------------------------------- */ /* Initialize passphrase */ /* ----------------------------------------------------- */ if (!(passphrase_buffer = PW_FROM_ENV ? copy_passphrase(passphrase) : (STARTS_WITH(passphrase, PREFIX_PASS) ? copy_passphrase(passphrase + STRLEN(PREFIX_PASS)) : (STARTS_WITH(passphrase, PREFIX_FILE) ? read_passphrase(passphrase + STRLEN(PREFIX_FILE)) : read_passphrase(T("-")))))) { goto clean_up; } slunkcrypt_bzero((CHR*)passphrase, STRLEN(passphrase) * sizeof(CHR)); const size_t passphrase_len = strlen(passphrase_buffer); if (passphrase_len < SLUNKCRYPT_PWDLEN_MIN) { FPRINTF(stderr, T("Error: Passphrase must be at least %u characters in length!\n\n"), (unsigned)SLUNKCRYPT_PWDLEN_MIN); goto clean_up; } else if (passphrase_len > SLUNKCRYPT_PWDLEN_MAX) { FPRINTF(stderr, T("Error: Passphrase must be at most %u characters in length!\n\n"), (unsigned)SLUNKCRYPT_PWDLEN_MAX); goto clean_up; } if (passphrase_len < RCMD_PWDLEN_LENGTH) { FPRINTF(stderr, T("Warning: Using a *short* passphrase; a length of %u characters or more is recommended!\n\n"), (unsigned)RCMD_PWDLEN_LENGTH); } else if (weak_passphrase(passphrase_buffer)) { FPUTS(T("Warning: Using a *weak* passphrase; a mix of upper-case letters, lower-case letters, digits and 'special' characters is recommended!\n\n"), stderr); } /* ----------------------------------------------------- */ /* Encrypt or decrypt */ /* ----------------------------------------------------- */ const clock_t clk_start = clock(); switch (slunk_mode) { case MODE_ENCR: result = encrypt(passphrase_buffer, input_file, output_file); break; case MODE_DECR: result = decrypt(passphrase_buffer, input_file, output_file); break; default: FPUTS(T("Unexpected mode encountered!\n\n"), stderr); } if (!g_slunkcrypt_abort_flag) { FPUTS(T("--------\n\n"), stderr); fflush(stderr); const clock_t clk_end = clock(); FPRINTF(stderr, T("Operation completed after %.1f seconds.\n\n"), (clk_end - clk_start) / ((double)CLOCKS_PER_SEC)); } /* ----------------------------------------------------- */ /* Final clean-up */ /* ----------------------------------------------------- */ clean_up: if (passphrase_buffer) { slunkcrypt_bzero(passphrase_buffer, strlen(passphrase_buffer)); free(passphrase_buffer); } return result; } #if defined(_WIN32) && defined(__MINGW32__) && !defined(__MINGW64_VERSION_MAJOR) void __wgetmainargs(int*, wchar_t***, wchar_t***, int, int*); int main() { wchar_t** enpv, ** argv; int argc, si = 0; __wgetmainargs(&argc, &argv, &enpv, 1, &si); return wmain(argc, argv); } #endif