/** * Author......: See docs/credits.txt * License.....: MIT */ #if defined (__APPLE__) #include #endif // __APPLE__ #include "common.h" // basic tools #include "types.h" #include "folder.h" #include "locking.h" #include "logging.h" #include "memory.h" #include "shared.h" #include "thread.h" #include "timer.h" // features #include "affinity.h" #include "autotune.h" #include "bitmap.h" #include "combinator.h" #include "cpt.h" #include "debugfile.h" #include "dictstat.h" #include "dispatch.h" #include "hashes.h" #include "hwmon.h" #include "induct.h" #include "interface.h" #include "logfile.h" #include "loopback.h" #include "monitor.h" #include "mpsp.h" #include "opencl.h" #include "outfile_check.h" #include "outfile.h" #include "potfile.h" #include "restore.h" #include "rp.h" #include "status.h" #include "straight.h" #include "terminal.h" #include "tuningdb.h" #include "usage.h" #include "user_options.h" #include "weak_hash.h" #include "wordlist.h" extern hc_global_data_t data; extern int SUPPRESS_OUTPUT; extern const int DEFAULT_BENCHMARK_ALGORITHMS_CNT; extern const int DEFAULT_BENCHMARK_ALGORITHMS_BUF[]; const int comptime = COMPTIME; const char *version_tag = VERSION_TAG; // inner2_loop iterates through wordlists, then calls kernel execution static int inner2_loop (status_ctx_t *status_ctx, user_options_t *user_options, user_options_extra_t *user_options_extra, restore_ctx_t *restore_ctx, logfile_ctx_t *logfile_ctx, induct_ctx_t *induct_ctx, dictstat_ctx_t *dictstat_ctx, loopback_ctx_t *loopback_ctx, opencl_ctx_t *opencl_ctx, hwmon_ctx_t *hwmon_ctx, hashconfig_t *hashconfig, hashes_t *hashes, cpt_ctx_t *cpt_ctx, wl_data_t *wl_data, straight_ctx_t *straight_ctx, combinator_ctx_t *combinator_ctx, mask_ctx_t *mask_ctx) { //status_ctx->run_main_level1 = true; //status_ctx->run_main_level2 = true; //status_ctx->run_main_level3 = true; status_ctx->run_thread_level1 = true; status_ctx->run_thread_level2 = true; logfile_generate_subid (logfile_ctx); logfile_sub_msg ("START"); status_progress_reset (status_ctx, hashes); status_ctx->words_cur = 0; restore_data_t *rd = restore_ctx->rd; if (rd->words_cur) { status_ctx->words_cur = rd->words_cur; user_options->skip = 0; } if (user_options->skip) { status_ctx->words_cur = user_options->skip; user_options->skip = 0; } status_ctx->ms_paused = 0; opencl_session_reset (opencl_ctx); cpt_ctx_reset (cpt_ctx); // figure out wordlist based workload if (user_options->attack_mode == ATTACK_MODE_STRAIGHT) { if (user_options_extra->wordlist_mode == WL_MODE_FILE) { if (induct_ctx->induction_dictionaries_cnt) { straight_ctx->dict = induct_ctx->induction_dictionaries[induct_ctx->induction_dictionaries_pos]; } else { straight_ctx->dict = straight_ctx->dicts[straight_ctx->dicts_pos]; } logfile_sub_string (straight_ctx->dict); for (uint i = 0; i < user_options->rp_files_cnt; i++) { logfile_sub_var_string ("rulefile", user_options->rp_files[i]); } FILE *fd2 = fopen (straight_ctx->dict, "rb"); if (fd2 == NULL) { log_error ("ERROR: %s: %s", straight_ctx->dict, strerror (errno)); return -1; } status_ctx->words_cnt = count_words (wl_data, user_options, user_options_extra, straight_ctx, combinator_ctx, fd2, straight_ctx->dict, dictstat_ctx); fclose (fd2); if (status_ctx->words_cnt == 0) { logfile_sub_msg ("STOP"); return 0; } } } else if (user_options->attack_mode == ATTACK_MODE_COMBI) { logfile_sub_string (combinator_ctx->dict1); logfile_sub_string (combinator_ctx->dict2); if (combinator_ctx->combs_mode == COMBINATOR_MODE_BASE_LEFT) { FILE *fd2 = fopen (combinator_ctx->dict1, "rb"); if (fd2 == NULL) { log_error ("ERROR: %s: %s", combinator_ctx->dict1, strerror (errno)); return -1; } status_ctx->words_cnt = count_words (wl_data, user_options, user_options_extra, straight_ctx, combinator_ctx, fd2, combinator_ctx->dict1, dictstat_ctx); fclose (fd2); } else if (combinator_ctx->combs_mode == COMBINATOR_MODE_BASE_RIGHT) { FILE *fd2 = fopen (combinator_ctx->dict2, "rb"); if (fd2 == NULL) { log_error ("ERROR: %s: %s", combinator_ctx->dict2, strerror (errno)); return -1; } status_ctx->words_cnt = count_words (wl_data, user_options, user_options_extra, straight_ctx, combinator_ctx, fd2, combinator_ctx->dict2, dictstat_ctx); fclose (fd2); } if (status_ctx->words_cnt == 0) { logfile_sub_msg ("STOP"); return 0; } } else if ((user_options->attack_mode == ATTACK_MODE_HYBRID1) || (user_options->attack_mode == ATTACK_MODE_HYBRID2)) { if (induct_ctx->induction_dictionaries_cnt) { straight_ctx->dict = induct_ctx->induction_dictionaries[induct_ctx->induction_dictionaries_pos]; } else { straight_ctx->dict = straight_ctx->dicts[straight_ctx->dicts_pos]; } logfile_sub_string (straight_ctx->dict); logfile_sub_string (mask_ctx->mask); FILE *fd2 = fopen (straight_ctx->dict, "rb"); if (fd2 == NULL) { log_error ("ERROR: %s: %s", straight_ctx->dict, strerror (errno)); return -1; } status_ctx->words_cnt = count_words (wl_data, user_options, user_options_extra, straight_ctx, combinator_ctx, fd2, straight_ctx->dict, dictstat_ctx); fclose (fd2); if (status_ctx->words_cnt == 0) { logfile_sub_msg ("STOP"); return 0; } } else if (user_options->attack_mode == ATTACK_MODE_BF) { logfile_sub_string (mask_ctx->mask); } u64 words_base = status_ctx->words_cnt; if (user_options_extra->attack_kern == ATTACK_KERN_STRAIGHT) { if (straight_ctx->kernel_rules_cnt) { words_base /= straight_ctx->kernel_rules_cnt; } } else if (user_options_extra->attack_kern == ATTACK_KERN_COMBI) { if (combinator_ctx->combs_cnt) { words_base /= combinator_ctx->combs_cnt; } } else if (user_options_extra->attack_kern == ATTACK_KERN_BF) { if (mask_ctx->bfs_cnt) { words_base /= mask_ctx->bfs_cnt; } } status_ctx->words_base = words_base; if (user_options->keyspace == true) { log_info ("%" PRIu64 "", words_base); return 0; } if (status_ctx->words_cur > status_ctx->words_base) { log_error ("ERROR: Restore value greater keyspace"); return -1; } if (status_ctx->words_cur) { if (user_options_extra->attack_kern == ATTACK_KERN_STRAIGHT) { for (uint i = 0; i < hashes->salts_cnt; i++) { status_ctx->words_progress_restored[i] = status_ctx->words_cur * straight_ctx->kernel_rules_cnt; } } else if (user_options_extra->attack_kern == ATTACK_KERN_COMBI) { for (uint i = 0; i < hashes->salts_cnt; i++) { status_ctx->words_progress_restored[i] = status_ctx->words_cur * combinator_ctx->combs_cnt; } } else if (user_options_extra->attack_kern == ATTACK_KERN_BF) { for (uint i = 0; i < hashes->salts_cnt; i++) { status_ctx->words_progress_restored[i] = status_ctx->words_cur * mask_ctx->bfs_cnt; } } } /* * Update dictionary statistic */ dictstat_write (dictstat_ctx); /** * limit kernel loops by the amplification count we have from: * - straight_ctx, combinator_ctx or mask_ctx for fast hashes * - hash iteration count for slow hashes */ opencl_ctx_devices_kernel_loops (opencl_ctx, user_options_extra, hashconfig, hashes, straight_ctx, combinator_ctx, mask_ctx); /** * create autotune threads */ hc_thread_t *c_threads = (hc_thread_t *) mycalloc (opencl_ctx->devices_cnt, sizeof (hc_thread_t)); status_ctx->devices_status = STATUS_AUTOTUNE; for (uint device_id = 0; device_id < opencl_ctx->devices_cnt; device_id++) { hc_device_param_t *device_param = &opencl_ctx->devices_param[device_id]; hc_thread_create (c_threads[device_id], thread_autotune, device_param); } hc_thread_wait (opencl_ctx->devices_cnt, c_threads); /** * autotune modified kernel_accel, which modifies opencl_ctx->kernel_power_all */ opencl_ctx_devices_update_power (opencl_ctx, user_options, user_options_extra, status_ctx); /** * Begin loopback recording */ if (user_options->loopback == true) { loopback_write_open (loopback_ctx, induct_ctx); } /** * Tell user we're about to start */ if ((user_options_extra->wordlist_mode == WL_MODE_FILE) || (user_options_extra->wordlist_mode == WL_MODE_MASK)) { if ((user_options->quiet == false) && (user_options->status == false) && (user_options->benchmark == false)) { if (user_options->quiet == false) send_prompt (); } } else if (user_options_extra->wordlist_mode == WL_MODE_STDIN) { if (user_options->quiet == false) log_info ("Starting attack in stdin mode..."); if (user_options->quiet == false) log_info (""); } /** * Prepare cracking stats */ hc_timer_set (&status_ctx->timer_running); time_t runtime_start; time (&runtime_start); status_ctx->runtime_start = runtime_start; status_ctx->prepare_time = runtime_start - status_ctx->prepare_start; /** * create cracker threads */ status_ctx->devices_status = STATUS_RUNNING; for (uint device_id = 0; device_id < opencl_ctx->devices_cnt; device_id++) { hc_device_param_t *device_param = &opencl_ctx->devices_param[device_id]; if (user_options_extra->wordlist_mode == WL_MODE_STDIN) { hc_thread_create (c_threads[device_id], thread_calc_stdin, device_param); } else { hc_thread_create (c_threads[device_id], thread_calc, device_param); } } hc_thread_wait (opencl_ctx->devices_cnt, c_threads); myfree (c_threads); // calculate final status if ((status_ctx->devices_status != STATUS_CRACKED) && (status_ctx->devices_status != STATUS_ABORTED) && (status_ctx->devices_status != STATUS_QUIT) && (status_ctx->devices_status != STATUS_BYPASS)) { status_ctx->devices_status = STATUS_EXHAUSTED; } logfile_sub_var_uint ("status-after-work", status_ctx->devices_status); // update some timer time_t runtime_stop; time (&runtime_stop); status_ctx->runtime_stop = runtime_stop; logfile_sub_uint (runtime_start); logfile_sub_uint (runtime_stop); time (&status_ctx->prepare_start); logfile_sub_msg ("STOP"); // no more skip and restore from here if (status_ctx->devices_status == STATUS_EXHAUSTED) { rd->words_cur = 0; } // stop loopback recording if (user_options->loopback == true) { loopback_write_close (loopback_ctx); } // print final status if (user_options->benchmark == true) { status_benchmark (status_ctx, opencl_ctx, hashconfig, user_options); if (user_options->machine_readable == false) { log_info (""); } } else { if (user_options->quiet == false) { clear_prompt (); if (hashes->digests_saved != hashes->digests_done) log_info (""); status_display (status_ctx, opencl_ctx, hwmon_ctx, hashconfig, hashes, cpt_ctx, restore_ctx, user_options, user_options_extra, straight_ctx, combinator_ctx, mask_ctx); log_info (""); } else { if (user_options->status == true) { status_display (status_ctx, opencl_ctx, hwmon_ctx, hashconfig, hashes, cpt_ctx, restore_ctx, user_options, user_options_extra, straight_ctx, combinator_ctx, mask_ctx); log_info (""); } } } // New induction folder check if (induct_ctx->induction_dictionaries_cnt == 0) { induct_ctx_scan (induct_ctx); while (induct_ctx->induction_dictionaries_cnt) { for (induct_ctx->induction_dictionaries_pos = 0; induct_ctx->induction_dictionaries_pos < induct_ctx->induction_dictionaries_cnt; induct_ctx->induction_dictionaries_pos++) { const int rc_inner2_loop = inner2_loop (status_ctx, user_options, user_options_extra, restore_ctx, logfile_ctx, induct_ctx, dictstat_ctx, loopback_ctx, opencl_ctx, hwmon_ctx, hashconfig, hashes, cpt_ctx, wl_data, straight_ctx, combinator_ctx, mask_ctx); if (rc_inner2_loop == -1) return -1; if (status_ctx->run_main_level3 == false) break; unlink (induct_ctx->induction_dictionaries[induct_ctx->induction_dictionaries_pos]); } myfree (induct_ctx->induction_dictionaries); induct_ctx_scan (induct_ctx); } } return 0; } // inner1_loop iterates through masks, then calls inner2_loop static int inner1_loop (status_ctx_t *status_ctx, user_options_t *user_options, user_options_extra_t *user_options_extra, restore_ctx_t *restore_ctx, logfile_ctx_t *logfile_ctx, induct_ctx_t *induct_ctx, dictstat_ctx_t *dictstat_ctx, loopback_ctx_t *loopback_ctx, opencl_ctx_t *opencl_ctx, hwmon_ctx_t *hwmon_ctx, hashconfig_t *hashconfig, hashes_t *hashes, cpt_ctx_t *cpt_ctx, wl_data_t *wl_data, straight_ctx_t *straight_ctx, combinator_ctx_t *combinator_ctx, mask_ctx_t *mask_ctx) { //status_ctx->run_main_level1 = true; //status_ctx->run_main_level2 = true; status_ctx->run_main_level3 = true; status_ctx->run_thread_level1 = true; status_ctx->run_thread_level2 = true; /** * word len */ uint pw_min = hashconfig_general_pw_min (hashconfig); uint pw_max = hashconfig_general_pw_max (hashconfig); /** * If we have a NOOP rule then we can process words from wordlists > length 32 for slow hashes */ const bool has_noop = kernel_rules_has_noop (straight_ctx->kernel_rules_buf, straight_ctx->kernel_rules_cnt); if (has_noop == false) { switch (user_options_extra->attack_kern) { case ATTACK_KERN_STRAIGHT: if (pw_max > PW_DICTMAX) pw_max = PW_DICTMAX1; break; case ATTACK_KERN_COMBI: if (pw_max > PW_DICTMAX) pw_max = PW_DICTMAX1; break; } } else { if (hashconfig->attack_exec == ATTACK_EXEC_INSIDE_KERNEL) { switch (user_options_extra->attack_kern) { case ATTACK_KERN_STRAIGHT: if (pw_max > PW_DICTMAX) pw_max = PW_DICTMAX1; break; case ATTACK_KERN_COMBI: if (pw_max > PW_DICTMAX) pw_max = PW_DICTMAX1; break; } } else { // in this case we can process > 32 } } /** * Update attack-mode specific stuff */ if (user_options_extra->attack_kern == ATTACK_KERN_COMBI) { if (user_options->attack_mode == ATTACK_MODE_COMBI) { // nothing yet } else if ((user_options->attack_mode == ATTACK_MODE_HYBRID1) || (user_options->attack_mode == ATTACK_MODE_HYBRID2)) { mask_ctx->mask = mask_ctx->masks[mask_ctx->masks_pos]; const int rc_mask_file = mask_ctx_parse_maskfile (mask_ctx, user_options, hashconfig); if (rc_mask_file == -1) return -1; mask_ctx->css_buf = mp_gen_css (mask_ctx->mask, strlen (mask_ctx->mask), mask_ctx->mp_sys, mask_ctx->mp_usr, &mask_ctx->css_cnt, hashconfig, user_options); uint uniq_tbls[SP_PW_MAX][CHARSIZ] = { { 0 } }; mp_css_to_uniq_tbl (mask_ctx->css_cnt, mask_ctx->css_buf, uniq_tbls); sp_tbl_to_css (mask_ctx->root_table_buf, mask_ctx->markov_table_buf, mask_ctx->root_css_buf, mask_ctx->markov_css_buf, user_options->markov_threshold, uniq_tbls); combinator_ctx->combs_cnt = sp_get_sum (0, mask_ctx->css_cnt, mask_ctx->root_css_buf); const int rc_update_mp = opencl_session_update_mp (opencl_ctx, mask_ctx); if (rc_update_mp == -1) return -1; } //const int rc_update_combinator = opencl_session_update_combinator (opencl_ctx, hashconfig, combinator_ctx); //if (rc_update_combinator == -1) return -1; } else if (user_options_extra->attack_kern == ATTACK_KERN_BF) { mask_ctx->mask = mask_ctx->masks[mask_ctx->masks_pos]; const int rc_mask_file = mask_ctx_parse_maskfile (mask_ctx, user_options, hashconfig); if (rc_mask_file == -1) return -1; if (user_options->attack_mode == ATTACK_MODE_BF) // always true { mask_ctx->css_buf = mp_gen_css (mask_ctx->mask, strlen (mask_ctx->mask), mask_ctx->mp_sys, mask_ctx->mp_usr, &mask_ctx->css_cnt, hashconfig, user_options); if (hashconfig->opts_type & OPTS_TYPE_PT_UNICODE) { u32 css_cnt_unicode = mask_ctx->css_cnt * 2; cs_t *css_buf_unicode = (cs_t *) mycalloc (css_cnt_unicode, sizeof (cs_t)); for (uint i = 0, j = 0; i < mask_ctx->css_cnt; i += 1, j += 2) { memcpy (&css_buf_unicode[j + 0], &mask_ctx->css_buf[i], sizeof (cs_t)); css_buf_unicode[j + 1].cs_buf[0] = 0; css_buf_unicode[j + 1].cs_len = 1; } myfree (mask_ctx->css_buf); mask_ctx->css_buf = css_buf_unicode; mask_ctx->css_cnt = css_cnt_unicode; } // check if mask is not too large or too small for pw_min/pw_max (*2 if unicode) uint mask_min = pw_min; uint mask_max = pw_max; if (hashconfig->opts_type & OPTS_TYPE_PT_UNICODE) { mask_min *= 2; mask_max *= 2; } if ((mask_ctx->css_cnt < mask_min) || (mask_ctx->css_cnt > mask_max)) { if (mask_ctx->css_cnt < mask_min) { log_info ("WARNING: Skipping mask '%s' because it is smaller than the minimum password length", mask_ctx->mask); } if (mask_ctx->css_cnt > mask_max) { log_info ("WARNING: Skipping mask '%s' because it is larger than the maximum password length", mask_ctx->mask); } // skip to next mask logfile_sub_msg ("STOP"); return 0; } u32 css_cnt_orig = mask_ctx->css_cnt; if (hashconfig->opti_type & OPTI_TYPE_SINGLE_HASH) { if (hashconfig->opti_type & OPTI_TYPE_APPENDED_SALT) { uint salt_len = (uint) hashes->salts_buf[0].salt_len; char *salt_buf = (char *) hashes->salts_buf[0].salt_buf; uint css_cnt_salt = mask_ctx->css_cnt + salt_len; cs_t *css_buf_salt = (cs_t *) mycalloc (css_cnt_salt, sizeof (cs_t)); memcpy (css_buf_salt, mask_ctx->css_buf, mask_ctx->css_cnt * sizeof (cs_t)); for (uint i = 0, j = mask_ctx->css_cnt; i < salt_len; i++, j++) { css_buf_salt[j].cs_buf[0] = salt_buf[i]; css_buf_salt[j].cs_len = 1; } myfree (mask_ctx->css_buf); mask_ctx->css_buf = css_buf_salt; mask_ctx->css_cnt = css_cnt_salt; } } uint uniq_tbls[SP_PW_MAX][CHARSIZ] = { { 0 } }; mp_css_to_uniq_tbl (mask_ctx->css_cnt, mask_ctx->css_buf, uniq_tbls); sp_tbl_to_css (mask_ctx->root_table_buf, mask_ctx->markov_table_buf, mask_ctx->root_css_buf, mask_ctx->markov_css_buf, user_options->markov_threshold, uniq_tbls); status_ctx->words_cnt = sp_get_sum (0, mask_ctx->css_cnt, mask_ctx->root_css_buf); // copy + args uint css_cnt_l = mask_ctx->css_cnt; uint css_cnt_r; if (hashconfig->attack_exec == ATTACK_EXEC_INSIDE_KERNEL) { if (css_cnt_orig < 6) { css_cnt_r = 1; } else if (css_cnt_orig == 6) { css_cnt_r = 2; } else { if (hashconfig->opts_type & OPTS_TYPE_PT_UNICODE) { if (css_cnt_orig == 8 || css_cnt_orig == 10) { css_cnt_r = 2; } else { css_cnt_r = 4; } } else { if ((mask_ctx->css_buf[0].cs_len * mask_ctx->css_buf[1].cs_len * mask_ctx->css_buf[2].cs_len) > 256) { css_cnt_r = 3; } else { css_cnt_r = 4; } } } } else { css_cnt_r = 1; /* unfinished code? int sum = css_buf[css_cnt_r - 1].cs_len; for (uint i = 1; i < 4 && i < css_cnt; i++) { if (sum > 1) break; // we really don't need alot of amplifier them for slow hashes css_cnt_r++; sum *= css_buf[css_cnt_r - 1].cs_len; } */ } css_cnt_l -= css_cnt_r; mask_ctx->bfs_cnt = sp_get_sum (0, css_cnt_r, mask_ctx->root_css_buf); const int rc_update_mp_rl = opencl_session_update_mp_rl (opencl_ctx, mask_ctx, css_cnt_l, css_cnt_r); if (rc_update_mp_rl == -1) return -1; } } /** * dictstat read */ dictstat_read (dictstat_ctx); /** * dictionary pad */ if (user_options->attack_mode == ATTACK_MODE_STRAIGHT) { if (user_options_extra->wordlist_mode == WL_MODE_FILE) { int wls_left = restore_ctx->argc - (user_options_extra->optind + 1); for (int i = 0; i < wls_left; i++) { char *l0_filename = restore_ctx->argv[user_options_extra->optind + 1 + i]; struct stat l0_stat; if (stat (l0_filename, &l0_stat) == -1) { log_error ("ERROR: %s: %s", l0_filename, strerror (errno)); return -1; } if (S_ISDIR (l0_stat.st_mode)) { char **dictionary_files = NULL; dictionary_files = scan_directory (l0_filename); if (dictionary_files != NULL) { qsort (dictionary_files, count_dictionaries (dictionary_files), sizeof (char *), sort_by_stringptr); for (int d = 0; dictionary_files[d] != NULL; d++) { char *l1_filename = dictionary_files[d]; struct stat l1_stat; if (stat (l1_filename, &l1_stat) == -1) { log_error ("ERROR: %s: %s", l1_filename, strerror (errno)); return -1; } if (S_ISREG (l1_stat.st_mode)) { straight_append_dict (straight_ctx, l1_filename); } } } myfree (dictionary_files); } else { straight_append_dict (straight_ctx, l0_filename); } } if (straight_ctx->dicts_cnt == 0) { log_error ("ERROR: No usable dictionary file found."); return -1; } } } else if (user_options->attack_mode == ATTACK_MODE_COMBI) { // display char *dictfile1 = restore_ctx->argv[user_options_extra->optind + 1 + 0]; char *dictfile2 = restore_ctx->argv[user_options_extra->optind + 1 + 1]; // find the bigger dictionary and use as base FILE *fp1 = NULL; FILE *fp2 = NULL; struct stat tmp_stat; if ((fp1 = fopen (dictfile1, "rb")) == NULL) { log_error ("ERROR: %s: %s", dictfile1, strerror (errno)); return -1; } if (stat (dictfile1, &tmp_stat) == -1) { log_error ("ERROR: %s: %s", dictfile1, strerror (errno)); fclose (fp1); return -1; } if (S_ISDIR (tmp_stat.st_mode)) { log_error ("ERROR: %s must be a regular file", dictfile1, strerror (errno)); fclose (fp1); return -1; } if ((fp2 = fopen (dictfile2, "rb")) == NULL) { log_error ("ERROR: %s: %s", dictfile2, strerror (errno)); fclose (fp1); return -1; } if (stat (dictfile2, &tmp_stat) == -1) { log_error ("ERROR: %s: %s", dictfile2, strerror (errno)); fclose (fp1); fclose (fp2); return -1; } if (S_ISDIR (tmp_stat.st_mode)) { log_error ("ERROR: %s must be a regular file", dictfile2, strerror (errno)); fclose (fp1); fclose (fp2); return -1; } combinator_ctx->combs_cnt = 1; const u64 words1_cnt = count_words (wl_data, user_options, user_options_extra, straight_ctx, combinator_ctx, fp1, dictfile1, dictstat_ctx); if (words1_cnt == 0) { log_error ("ERROR: %s: empty file", dictfile1); fclose (fp1); fclose (fp2); return -1; } combinator_ctx->combs_cnt = 1; const u64 words2_cnt = count_words (wl_data, user_options, user_options_extra, straight_ctx, combinator_ctx, fp2, dictfile2, dictstat_ctx); if (words2_cnt == 0) { log_error ("ERROR: %s: empty file", dictfile2); fclose (fp1); fclose (fp2); return -1; } fclose (fp1); fclose (fp2); combinator_ctx->dict1 = dictfile1; combinator_ctx->dict2 = dictfile2; if (words1_cnt >= words2_cnt) { combinator_ctx->combs_mode = COMBINATOR_MODE_BASE_LEFT; combinator_ctx->combs_cnt = words2_cnt; } else { combinator_ctx->combs_mode = COMBINATOR_MODE_BASE_RIGHT; combinator_ctx->combs_cnt = words1_cnt; // we also have to switch wordlist related rules! char *tmpc = user_options->rule_buf_l; user_options->rule_buf_l = user_options->rule_buf_r; user_options->rule_buf_r = tmpc; int tmpi = user_options_extra->rule_len_l; user_options_extra->rule_len_l = user_options_extra->rule_len_r; user_options_extra->rule_len_r = tmpi; } const int rc_update_combinator = opencl_session_update_combinator (opencl_ctx, hashconfig, combinator_ctx); if (rc_update_combinator == -1) return -1; } else if (user_options->attack_mode == ATTACK_MODE_BF) { if (user_options->benchmark == true) { pw_min = mp_get_length (mask_ctx->mask); pw_max = pw_min; } } else if (user_options->attack_mode == ATTACK_MODE_HYBRID1) { combinator_ctx->combs_mode = COMBINATOR_MODE_BASE_LEFT; // mod -- moved to mpsp.c // base int wls_left = restore_ctx->argc - (user_options_extra->optind + 2); for (int i = 0; i < wls_left; i++) { char *l0_filename = restore_ctx->argv[user_options_extra->optind + 1 + i]; struct stat l0_stat; if (stat (l0_filename, &l0_stat) == -1) { log_error ("ERROR: %s: %s", l0_filename, strerror (errno)); return -1; } if (S_ISDIR (l0_stat.st_mode)) { char **dictionary_files = NULL; dictionary_files = scan_directory (l0_filename); if (dictionary_files != NULL) { qsort (dictionary_files, count_dictionaries (dictionary_files), sizeof (char *), sort_by_stringptr); for (int d = 0; dictionary_files[d] != NULL; d++) { char *l1_filename = dictionary_files[d]; struct stat l1_stat; if (stat (l1_filename, &l1_stat) == -1) { log_error ("ERROR: %s: %s", l1_filename, strerror (errno)); return -1; } if (S_ISREG (l1_stat.st_mode)) { straight_append_dict (straight_ctx, l1_filename); } } } myfree (dictionary_files); } else { straight_append_dict (straight_ctx, l0_filename); } } if (straight_ctx->dicts_cnt == 0) { log_error ("ERROR: No usable dictionary file found."); return -1; } const int rc_update_combinator = opencl_session_update_combinator (opencl_ctx, hashconfig, combinator_ctx); if (rc_update_combinator == -1) return -1; } else if (user_options->attack_mode == ATTACK_MODE_HYBRID2) { combinator_ctx->combs_mode = COMBINATOR_MODE_BASE_RIGHT; // mod -- moved to mpsp.c // base int wls_left = restore_ctx->argc - (user_options_extra->optind + 2); for (int i = 0; i < wls_left; i++) { char *l0_filename = restore_ctx->argv[user_options_extra->optind + 2 + i]; struct stat l0_stat; if (stat (l0_filename, &l0_stat) == -1) { log_error ("ERROR: %s: %s", l0_filename, strerror (errno)); return -1; } if (S_ISDIR (l0_stat.st_mode)) { char **dictionary_files = NULL; dictionary_files = scan_directory (l0_filename); if (dictionary_files != NULL) { qsort (dictionary_files, count_dictionaries (dictionary_files), sizeof (char *), sort_by_stringptr); for (int d = 0; dictionary_files[d] != NULL; d++) { char *l1_filename = dictionary_files[d]; struct stat l1_stat; if (stat (l1_filename, &l1_stat) == -1) { log_error ("ERROR: %s: %s", l1_filename, strerror (errno)); return -1; } if (S_ISREG (l1_stat.st_mode)) { straight_append_dict (straight_ctx, l1_filename); } } } myfree (dictionary_files); } else { straight_append_dict (straight_ctx, l0_filename); } } if (straight_ctx->dicts_cnt == 0) { log_error ("ERROR: No usable dictionary file found."); return -1; } const int rc_update_combinator = opencl_session_update_combinator (opencl_ctx, hashconfig, combinator_ctx); if (rc_update_combinator == -1) return -1; } hashconfig->pw_min = pw_min; hashconfig->pw_max = pw_max; /** * prevent the user from using --skip/--limit together w/ maskfile and or dictfile */ if (user_options->skip != 0 || user_options->limit != 0) { if ((mask_ctx->masks_cnt > 1) || (straight_ctx->dicts_cnt > 1)) { log_error ("ERROR: --skip/--limit are not supported with --increment or mask files"); return -1; } } /** * prevent the user from using --keyspace together w/ maskfile and or dictfile */ if (user_options->keyspace == true) { if ((mask_ctx->masks_cnt > 1) || (straight_ctx->dicts_cnt > 1)) { log_error ("ERROR: --keyspace is not supported with --increment or mask files"); return -1; } } /** * main inner loop */ restore_data_t *rd = restore_ctx->rd; if (straight_ctx->dicts_cnt) { for (uint dicts_pos = rd->dictpos; dicts_pos < straight_ctx->dicts_cnt; dicts_pos++) { rd->dictpos = dicts_pos; straight_ctx->dicts_pos = dicts_pos; const int rc_inner2_loop = inner2_loop (status_ctx, user_options, user_options_extra, restore_ctx, logfile_ctx, induct_ctx, dictstat_ctx, loopback_ctx, opencl_ctx, hwmon_ctx, hashconfig, hashes, cpt_ctx, wl_data, straight_ctx, combinator_ctx, mask_ctx); if (rc_inner2_loop == -1) return -1; if (status_ctx->run_main_level3 == false) break; } } else { const int rc_inner2_loop = inner2_loop (status_ctx, user_options, user_options_extra, restore_ctx, logfile_ctx, induct_ctx, dictstat_ctx, loopback_ctx, opencl_ctx, hwmon_ctx, hashconfig, hashes, cpt_ctx, wl_data, straight_ctx, combinator_ctx, mask_ctx); if (rc_inner2_loop == -1) return -1; } return 0; } // outer_loop iterates through hash_modes (in benchmark mode) static int outer_loop (status_ctx_t *status_ctx, user_options_t *user_options, user_options_extra_t *user_options_extra, restore_ctx_t *restore_ctx, folder_config_t *folder_config, logfile_ctx_t *logfile_ctx, tuning_db_t *tuning_db, induct_ctx_t *induct_ctx, outcheck_ctx_t *outcheck_ctx, outfile_ctx_t *outfile_ctx, potfile_ctx_t *potfile_ctx, dictstat_ctx_t *dictstat_ctx, loopback_ctx_t *loopback_ctx, opencl_ctx_t *opencl_ctx, hwmon_ctx_t *hwmon_ctx) { status_ctx->devices_status = STATUS_INIT; //status_ctx->run_main_level1 = true; status_ctx->run_main_level2 = true; status_ctx->run_main_level3 = true; status_ctx->run_thread_level1 = true; status_ctx->run_thread_level2 = true; /** * setup prepare timer */ time (&status_ctx->prepare_start); /** * setup variables and buffers depending on hash_mode */ hashconfig_t *hashconfig = (hashconfig_t *) mymalloc (sizeof (hashconfig_t)); data.hashconfig = hashconfig; const int rc_hashconfig = hashconfig_init (hashconfig, user_options); if (rc_hashconfig == -1) return -1; /** * potfile show/left depends on hash_mode, so it's called here first time */ if (user_options->show == true || user_options->left == true) { outfile_write_open (outfile_ctx); SUPPRESS_OUTPUT = 1; potfile_read_open (potfile_ctx); potfile_read_parse (potfile_ctx, hashconfig); potfile_read_close (potfile_ctx); SUPPRESS_OUTPUT = 0; } /** * load hashes, stage 1 */ hashes_t *hashes = (hashes_t *) mymalloc (sizeof (hashes_t)); data.hashes = hashes; const int rc_hashes_init_stage1 = hashes_init_stage1 (hashes, hashconfig, potfile_ctx, outfile_ctx, user_options, restore_ctx->argv[user_options_extra->optind]); if (rc_hashes_init_stage1 == -1) return -1; if ((user_options->keyspace == false) && (user_options->stdout_flag == false) && (user_options->opencl_info == false)) { if (hashes->hashes_cnt == 0) { log_error ("ERROR: No hashes loaded"); return -1; } } /** * potfile show/left final */ if (user_options->show == true || user_options->left == true) { outfile_write_close (outfile_ctx); potfile_hash_free (potfile_ctx, hashconfig); //if (user_options->quiet == false) log_info_nn (""); return 0; } /** * Potfile removes */ int potfile_remove_cracks = 0; if (user_options->potfile_disable == 0) { if (user_options->quiet == false) log_info_nn ("Comparing hashes with potfile entries..."); potfile_remove_cracks = potfile_remove_parse (potfile_ctx, hashconfig, hashes); } /** * load hashes, stage 2, remove duplicates, build base structure */ const u32 hashes_cnt_orig = hashes->hashes_cnt; const int rc_hashes_init_stage2 = hashes_init_stage2 (hashes, hashconfig, user_options, status_ctx); if (rc_hashes_init_stage2 == -1) return -1; /** * load hashes, stage 3, automatic Optimizers */ const int rc_hashes_init_stage3 = hashes_init_stage3 (hashes, hashconfig, user_options); if (rc_hashes_init_stage3 == -1) return -1; hashes_logger (hashes, logfile_ctx); /** * bitmaps */ bitmap_ctx_t *bitmap_ctx = (bitmap_ctx_t *) mymalloc (sizeof (bitmap_ctx_t)); data.bitmap_ctx = bitmap_ctx; bitmap_ctx_init (bitmap_ctx, user_options, hashconfig, hashes); /** * cracks-per-time allocate buffer */ cpt_ctx_t *cpt_ctx = (cpt_ctx_t *) mymalloc (sizeof (cpt_ctx_t)); data.cpt_ctx = cpt_ctx; cpt_ctx_init (cpt_ctx, user_options); /** * Wordlist allocate buffer */ wl_data_t *wl_data = (wl_data_t *) mymalloc (sizeof (wl_data_t)); wl_data_init (wl_data, user_options, hashconfig); /** * straight mode init */ straight_ctx_t *straight_ctx = (straight_ctx_t *) mymalloc (sizeof (straight_ctx_t)); data.straight_ctx = straight_ctx; const int rc_straight_init = straight_ctx_init (straight_ctx, user_options); if (rc_straight_init == -1) return -1; /** * straight mode init */ combinator_ctx_t *combinator_ctx = (combinator_ctx_t *) mymalloc (sizeof (combinator_ctx_t)); data.combinator_ctx = combinator_ctx; const int rc_combinator_init = combinator_ctx_init (combinator_ctx, user_options); if (rc_combinator_init == -1) return -1; /** * charsets : keep them together for more easy maintainnce */ mask_ctx_t *mask_ctx = (mask_ctx_t *) mymalloc (sizeof (mask_ctx_t)); data.mask_ctx = mask_ctx; const int rc_mask_init = mask_ctx_init (mask_ctx, user_options, user_options_extra, folder_config, restore_ctx, hashconfig); if (rc_mask_init == -1) return -1; /** * status progress init; needs hashes that's why we have to do it here and separate from status_ctx_init */ const int rc_status_init = status_progress_init (status_ctx, hashes); if (rc_status_init == -1) return -1; /** * enable custom signal handler(s) */ if (user_options->benchmark == false) { hc_signal (sigHandler_default); } else { hc_signal (sigHandler_benchmark); } /** * inform the user */ if (user_options->quiet == false) { log_info ("Hashes: %u digests; %u unique digests, %u unique salts", hashes_cnt_orig, hashes->digests_cnt, hashes->salts_cnt); log_info ("Bitmaps: %u bits, %u entries, 0x%08x mask, %u bytes, %u/%u rotates", bitmap_ctx->bitmap_bits, bitmap_ctx->bitmap_nums, bitmap_ctx->bitmap_mask, bitmap_ctx->bitmap_size, bitmap_ctx->bitmap_shift1, bitmap_ctx->bitmap_shift2); if (user_options->attack_mode == ATTACK_MODE_STRAIGHT) { log_info ("Rules: %u", straight_ctx->kernel_rules_cnt); } if (user_options->quiet == false) log_info (""); if (hashconfig->opti_type) { log_info ("Applicable Optimizers:"); for (uint i = 0; i < 32; i++) { const uint opti_bit = 1u << i; if (hashconfig->opti_type & opti_bit) log_info ("* %s", stroptitype (opti_bit)); } } if (user_options->quiet == false) log_info (""); /** * Watchdog and Temperature balance */ if (hwmon_ctx->enabled == false && user_options->gpu_temp_disable == false) { log_info ("Watchdog: Hardware Monitoring Interface not found on your system"); } if (hwmon_ctx->enabled == true && user_options->gpu_temp_abort > 0) { log_info ("Watchdog: Temperature abort trigger set to %uc", user_options->gpu_temp_abort); } else { log_info ("Watchdog: Temperature abort trigger disabled"); } if (hwmon_ctx->enabled == true && user_options->gpu_temp_retain > 0) { log_info ("Watchdog: Temperature retain trigger set to %uc", user_options->gpu_temp_retain); } else { log_info ("Watchdog: Temperature retain trigger disabled"); } if (user_options->quiet == false) log_info (""); } #if defined (DEBUG) if (user_options->benchmark == true) log_info ("Hashmode: %d", hashconfig->hash_mode); #endif if (user_options->quiet == false) log_info_nn ("Initializing device kernels and memory..."); opencl_session_begin (opencl_ctx, hashconfig, hashes, straight_ctx, user_options, user_options_extra, folder_config, bitmap_ctx, tuning_db); if (user_options->quiet == false) log_info_nn (""); /** * In benchmark-mode, inform user which algorithm is checked */ if (user_options->benchmark == true) { if (user_options->machine_readable == false) { char *hash_type = strhashtype (hashconfig->hash_mode); // not a bug log_info ("Hashtype: %s", hash_type); log_info (""); } } /** * weak hash check is the first to write to potfile, so open it for writing from here */ potfile_write_open (potfile_ctx); /** * weak hash check */ if (user_options->weak_hash_threshold >= hashes->salts_cnt) { hc_device_param_t *device_param = NULL; for (uint device_id = 0; device_id < opencl_ctx->devices_cnt; device_id++) { device_param = &opencl_ctx->devices_param[device_id]; if (device_param->skipped) continue; break; } if (user_options->quiet == false) log_info_nn ("Checking for weak hashes..."); for (uint salt_pos = 0; salt_pos < hashes->salts_cnt; salt_pos++) { weak_hash_check (opencl_ctx, device_param, user_options, user_options_extra, straight_ctx, combinator_ctx, hashconfig, hashes, cpt_ctx, status_ctx, salt_pos); } } /** * status and monitor threads */ uint inner_threads_cnt = 0; hc_thread_t *inner_threads = (hc_thread_t *) mycalloc (10, sizeof (hc_thread_t)); status_ctx->shutdown_inner = false; /** * Outfile remove */ if (user_options->keyspace == false && user_options->benchmark == false && user_options->stdout_flag == false) { hc_thread_create (inner_threads[inner_threads_cnt], thread_monitor, NULL); inner_threads_cnt++; if (outcheck_ctx->enabled == true) { hc_thread_create (inner_threads[inner_threads_cnt], thread_outfile_remove, NULL); inner_threads_cnt++; } } /** * Tell user about cracked hashes by potfile */ if (user_options->quiet == false) { if (potfile_remove_cracks > 0) { if (potfile_remove_cracks == 1) { log_info ("INFO: Removed 1 hash found in potfile"); log_info (""); } else { log_info ("INFO: Removed %d hashes found in potfile", potfile_remove_cracks); log_info (""); } } } // main call if (mask_ctx->masks_cnt) { restore_data_t *rd = restore_ctx->rd; for (uint masks_pos = rd->masks_pos; masks_pos < mask_ctx->masks_cnt; masks_pos++) { if (masks_pos > rd->masks_pos) { rd->dictpos = 0; } rd->masks_pos = masks_pos; mask_ctx->masks_pos = masks_pos; const int rc_inner1_loop = inner1_loop (status_ctx, user_options, user_options_extra, restore_ctx, logfile_ctx, induct_ctx, dictstat_ctx, loopback_ctx, opencl_ctx, hwmon_ctx, hashconfig, hashes, cpt_ctx, wl_data, straight_ctx, combinator_ctx, mask_ctx); if (rc_inner1_loop == -1) return -1; if (status_ctx->run_main_level2 == false) break; } } else { const int rc_inner1_loop = inner1_loop (status_ctx, user_options, user_options_extra, restore_ctx, logfile_ctx, induct_ctx, dictstat_ctx, loopback_ctx, opencl_ctx, hwmon_ctx, hashconfig, hashes, cpt_ctx, wl_data, straight_ctx, combinator_ctx, mask_ctx); if (rc_inner1_loop == -1) return -1; } // wait for inner threads status_ctx->shutdown_inner = true; for (uint thread_idx = 0; thread_idx < inner_threads_cnt; thread_idx++) { hc_thread_wait (1, &inner_threads[thread_idx]); } myfree (inner_threads); // we dont need restore file anymore if (restore_ctx->enabled == true) { if ((status_ctx->devices_status == STATUS_EXHAUSTED) || (status_ctx->devices_status == STATUS_CRACKED)) { if (status_ctx->run_thread_level1 == true) // this is to check for [c]heckpoint { unlink (restore_ctx->eff_restore_file); unlink (restore_ctx->new_restore_file); } else { cycle_restore (restore_ctx, opencl_ctx); } } else { cycle_restore (restore_ctx, opencl_ctx); } } // finally save left hashes if ((hashes->hashlist_mode == HL_MODE_FILE) && (user_options->remove == true) && (hashes->digests_saved != hashes->digests_done)) { save_hash (user_options, hashconfig, hashes); } /** * Clean up */ status_progress_destroy (status_ctx); opencl_session_destroy (opencl_ctx); potfile_write_close (potfile_ctx); bitmap_ctx_destroy (bitmap_ctx); mask_ctx_destroy (mask_ctx); combinator_ctx_destroy (combinator_ctx); straight_ctx_destroy (straight_ctx); hashes_destroy (hashes); hashconfig_destroy (hashconfig); wl_data_destroy (wl_data); cpt_ctx_destroy (cpt_ctx); return 0; } int main (int argc, char **argv) { /** * To help users a bit */ const int rc_console = setup_console (); if (rc_console == -1) return -1; setup_environment_variables (); setup_umask (); /** * status init */ status_ctx_t *status_ctx = (status_ctx_t *) mymalloc (sizeof (status_ctx_t)); data.status_ctx = status_ctx; const int rc_status_init = status_ctx_init (status_ctx); if (rc_status_init == -1) return -1; /** * folder */ char *install_folder = NULL; char *shared_folder = NULL; #if defined (INSTALL_FOLDER) install_folder = INSTALL_FOLDER; #endif #if defined (SHARED_FOLDER) shared_folder = SHARED_FOLDER; #endif folder_config_t *folder_config = (folder_config_t *) mymalloc (sizeof (folder_config_t)); folder_config_init (folder_config, install_folder, shared_folder); /** * commandline parameters */ user_options_t *user_options = (user_options_t *) mymalloc (sizeof (user_options_t)); data.user_options = user_options; user_options_init (user_options); const int rc_user_options_parse = user_options_parse (user_options, argc, argv); if (rc_user_options_parse == -1) return -1; /** * some early exits */ if (user_options->version == true) { log_info ("%s", VERSION_TAG); return 0; } if (user_options->usage == true) { usage_big_print (PROGNAME); return 0; } /** * restore */ restore_ctx_t *restore_ctx = (restore_ctx_t *) mymalloc (sizeof (restore_ctx_t)); data.restore_ctx = restore_ctx; const int rc_restore_init = restore_ctx_init (restore_ctx, user_options, folder_config, argc, argv); if (rc_restore_init == -1) return -1; /** * process user input */ user_options_extra_t *user_options_extra = (user_options_extra_t *) mymalloc (sizeof (user_options_extra_t)); data.user_options_extra = user_options_extra; const int rc_user_options_extra_init = user_options_extra_init (user_options, restore_ctx, user_options_extra); if (rc_user_options_extra_init == -1) return -1; const int rc_user_options_sanity = user_options_sanity (user_options, restore_ctx, user_options_extra); if (rc_user_options_sanity == -1) return -1; /** * prepare seeding for random number generator, required by logfile and rules generator */ setup_seeding (user_options->rp_gen_seed_chgd, user_options->rp_gen_seed); /** * Inform user things getting started, * - this is giving us a visual header before preparations start, so we do not need to clear them afterwards */ welcome_screen (user_options, status_ctx); /** * logfile init */ logfile_ctx_t *logfile_ctx = (logfile_ctx_t *) mymalloc (sizeof (logfile_ctx_t)); data.logfile_ctx = logfile_ctx; logfile_init (logfile_ctx, user_options, folder_config); logfile_generate_topid (logfile_ctx); logfile_top_msg ("START"); user_options_logger (user_options, logfile_ctx); /** * tuning db */ char tuning_db_file[256] = { 0 }; snprintf (tuning_db_file, sizeof (tuning_db_file) - 1, "%s/%s", folder_config->shared_dir, TUNING_DB_FILE); tuning_db_t *tuning_db = tuning_db_init (tuning_db_file); /** * induction directory */ induct_ctx_t *induct_ctx = (induct_ctx_t *) mymalloc (sizeof (induct_ctx_t)); data.induct_ctx = induct_ctx; const int rc_induct_ctx_init = induct_ctx_init (induct_ctx, user_options, folder_config, status_ctx); if (rc_induct_ctx_init == -1) return -1; /** * outfile-check directory */ outcheck_ctx_t *outcheck_ctx = (outcheck_ctx_t *) mymalloc (sizeof (outcheck_ctx_t)); data.outcheck_ctx = outcheck_ctx; const int rc_outcheck_ctx_init = outcheck_ctx_init (outcheck_ctx, user_options, folder_config); if (rc_outcheck_ctx_init == -1) return -1; /** * outfile itself */ outfile_ctx_t *outfile_ctx = mymalloc (sizeof (outfile_ctx_t)); data.outfile_ctx = outfile_ctx; outfile_init (outfile_ctx, user_options); /** * Sanity check for hashfile vs outfile (should not point to the same physical file) */ const int rc_outfile_and_hashfile = outfile_and_hashfile (outfile_ctx, restore_ctx->argv[user_options_extra->optind]); if (rc_outfile_and_hashfile == -1) return -1; /** * potfile init * this is only setting path because potfile can be used in read and write mode depending on user options * plus it depends on hash_mode, so we continue using it in outer_loop */ potfile_ctx_t *potfile_ctx = mymalloc (sizeof (potfile_ctx_t)); data.potfile_ctx = potfile_ctx; potfile_init (potfile_ctx, user_options, folder_config); /** * dictstat init */ dictstat_ctx_t *dictstat_ctx = mymalloc (sizeof (dictstat_ctx_t)); dictstat_init (dictstat_ctx, user_options, folder_config); /** * loopback init */ loopback_ctx_t *loopback_ctx = mymalloc (sizeof (loopback_ctx_t)); data.loopback_ctx = loopback_ctx; loopback_init (loopback_ctx, user_options); /** * debugfile init */ debugfile_ctx_t *debugfile_ctx = mymalloc (sizeof (debugfile_ctx_t)); data.debugfile_ctx = debugfile_ctx; debugfile_init (debugfile_ctx, user_options); /** * cpu affinity */ if (user_options->cpu_affinity) { set_cpu_affinity (user_options->cpu_affinity); } /** * Init OpenCL library loader */ opencl_ctx_t *opencl_ctx = (opencl_ctx_t *) mymalloc (sizeof (opencl_ctx_t)); data.opencl_ctx = opencl_ctx; const int rc_opencl_init = opencl_ctx_init (opencl_ctx, user_options); if (rc_opencl_init == -1) { log_error ("ERROR: opencl_ctx_init() failed"); return -1; } /** * Init OpenCL devices */ const int rc_devices_init = opencl_ctx_devices_init (opencl_ctx, user_options); if (rc_devices_init == -1) { log_error ("ERROR: opencl_ctx_devices_init() failed"); return -1; } /** * HM devices: init */ hwmon_ctx_t *hwmon_ctx = (hwmon_ctx_t *) mymalloc (sizeof (hwmon_ctx_t)); data.hwmon_ctx = hwmon_ctx; const int rc_hwmon_init = hwmon_ctx_init (hwmon_ctx, user_options, opencl_ctx); if (rc_hwmon_init == -1) { log_error ("ERROR: hwmon_ctx_init() failed"); return -1; } /** * keypress thread */ uint outer_threads_cnt = 0; hc_thread_t *outer_threads = (hc_thread_t *) mycalloc (10, sizeof (hc_thread_t)); status_ctx->shutdown_outer = false; if (user_options->keyspace == false && user_options->benchmark == false && user_options->stdout_flag == false) { if ((user_options_extra->wordlist_mode == WL_MODE_FILE) || (user_options_extra->wordlist_mode == WL_MODE_MASK)) { hc_thread_create (outer_threads[outer_threads_cnt], thread_keypress, NULL); outer_threads_cnt++; } } /** * outer loop */ if (user_options->benchmark == true) { user_options->quiet = true; if (user_options->hash_mode_chgd == true) { const int rc = outer_loop (status_ctx, user_options, user_options_extra, restore_ctx, folder_config, logfile_ctx, tuning_db, induct_ctx, outcheck_ctx, outfile_ctx, potfile_ctx, dictstat_ctx, loopback_ctx, opencl_ctx, hwmon_ctx); if (rc == -1) return -1; } else { for (int algorithm_pos = 0; algorithm_pos < DEFAULT_BENCHMARK_ALGORITHMS_CNT; algorithm_pos++) { user_options->hash_mode = DEFAULT_BENCHMARK_ALGORITHMS_BUF[algorithm_pos]; const int rc = outer_loop (status_ctx, user_options, user_options_extra, restore_ctx, folder_config, logfile_ctx, tuning_db, induct_ctx, outcheck_ctx, outfile_ctx, potfile_ctx, dictstat_ctx, loopback_ctx, opencl_ctx, hwmon_ctx); if (rc == -1) return -1; if (status_ctx->run_main_level1 == false) break; } } } else { const int rc = outer_loop (status_ctx, user_options, user_options_extra, restore_ctx, folder_config, logfile_ctx, tuning_db, induct_ctx, outcheck_ctx, outfile_ctx, potfile_ctx, dictstat_ctx, loopback_ctx, opencl_ctx, hwmon_ctx); if (rc == -1) return -1; } // wait for outer threads status_ctx->shutdown_outer = true; for (uint thread_idx = 0; thread_idx < outer_threads_cnt; thread_idx++) { hc_thread_wait (1, &outer_threads[thread_idx]); } myfree (outer_threads); if (user_options->benchmark == true) { user_options->quiet = false; } // free memory debugfile_destroy (debugfile_ctx); tuning_db_destroy (tuning_db); loopback_destroy (loopback_ctx); dictstat_destroy (dictstat_ctx); potfile_destroy (potfile_ctx); induct_ctx_destroy (induct_ctx); outfile_destroy (outfile_ctx); outcheck_ctx_destroy (outcheck_ctx); folder_config_destroy (folder_config); user_options_extra_destroy (user_options_extra); hwmon_ctx_destroy (hwmon_ctx, user_options, opencl_ctx); opencl_ctx_devices_destroy (opencl_ctx); opencl_ctx_destroy (opencl_ctx); restore_ctx_destroy (restore_ctx); time (&status_ctx->proc_stop); logfile_top_uint (status_ctx->proc_start); logfile_top_uint (status_ctx->proc_stop); logfile_top_msg ("STOP"); logfile_destroy (logfile_ctx); goodbye_screen (user_options, status_ctx); user_options_destroy (user_options); u32 rc_final = -1; if (status_ctx->devices_status == STATUS_ABORTED) rc_final = 2; if (status_ctx->devices_status == STATUS_QUIT) rc_final = 2; if (status_ctx->devices_status == STATUS_EXHAUSTED) rc_final = 1; if (status_ctx->devices_status == STATUS_CRACKED) rc_final = 0; status_ctx_destroy (status_ctx); return rc_final; }