/* Copyright (C) 2013-2014 Open Information Security Foundation * * You can copy, redistribute or modify this Program under the terms of * the GNU General Public License version 2 as published by the Free * Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * version 2 along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA * 02110-1301, USA. */ /** * \file * * \author Ken Steele * \author Anoop Saldanha * * Aho-corasick MPM optimized for the Tilera Tile-Gx architecture. * * Efficient String Matching: An Aid to Bibliographic Search * Alfred V. Aho and Margaret J. Corasick * * - Started with util-mpm-ac.c: * - Uses the delta table for calculating transitions, * instead of having separate goto and failure * transitions. * - If we cross 2 ** 16 states, we use 4 bytes in the * transition table to hold each state, otherwise we use * 2 bytes. * - This version of the MPM is heavy on memory, but it * performs well. If you can fit the ruleset with this * mpm on your box without hitting swap, this is the MPM * to go for. * * - Added these optimizations: * - Compress the input alphabet from 256 characters down * to the actual characters used in the patterns, plus * one character for all the unused characters. * - Reduce the size of the delta table so that each state * is the smallest power of two that is larger than the * size of the compressed alphabet. * - Specialized the search function based on state count * (small for 8-bit large for 16-bit) and the size of * the alphabet, so that it is constant inside the * function for better optimization. * * \todo - Do a proper analysis of our existing MPMs and suggest a good * one based on the pattern distribution and the expected * traffic(say http). * - Irrespective of whether we cross 2 ** 16 states or * not,shift to using uint32_t for state type, so that we can * integrate it's status as a final state or not in the * topmost byte. We are already doing it if state_count is > * 2 ** 16. * - Test case-sensitive patterns if they have any ascii chars. * If they don't treat them as nocase. * - Reorder the compressed alphabet to put the most common characters * first. */ #include "suricata-common.h" #include "suricata.h" #include "detect.h" #include "detect-parse.h" #include "detect-engine.h" #include "detect-engine-build.h" #include "conf.h" #include "util-debug.h" #include "util-unittest.h" #include "util-unittest-helper.h" #include "util-memcmp.h" #include "util-memcpy.h" #include "util-validate.h" #include "util-mpm-ac-ks.h" #if __BYTE_ORDER == __LITTLE_ENDIAN void SCACTileInitCtx(MpmCtx *); void SCACTileInitThreadCtx(MpmCtx *, MpmThreadCtx *); void SCACTileDestroyCtx(MpmCtx *); void SCACTileDestroyThreadCtx(MpmCtx *, MpmThreadCtx *); int SCACTileAddPatternCI(MpmCtx *, uint8_t *, uint16_t, uint16_t, uint16_t, uint32_t, SigIntId, uint8_t); int SCACTileAddPatternCS(MpmCtx *, uint8_t *, uint16_t, uint16_t, uint16_t, uint32_t, SigIntId, uint8_t); int SCACTilePreparePatterns(MpmCtx *mpm_ctx); uint32_t SCACTileSearch(const MpmCtx *mpm_ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); void SCACTilePrintInfo(MpmCtx *mpm_ctx); void SCACTilePrintSearchStats(MpmThreadCtx *mpm_thread_ctx); void SCACTileRegisterTests(void); uint32_t SCACTileSearchLarge(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchSmall256(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchSmall128(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchSmall64(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchSmall32(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchSmall16(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchSmall8(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchTiny256(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchTiny128(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchTiny64(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchTiny32(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchTiny16(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); uint32_t SCACTileSearchTiny8(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen); static void SCACTileDestroyInitCtx(MpmCtx *mpm_ctx); /* a placeholder to denote a failure transition in the goto table */ #define SC_AC_TILE_FAIL (-1) #define STATE_QUEUE_CONTAINER_SIZE 65536 /** * \brief Helper structure used by AC during state table creation */ typedef struct StateQueue_ { int32_t store[STATE_QUEUE_CONTAINER_SIZE]; int top; int bot; } StateQueue; /** * \internal * \brief Initialize the AC context with user specified conf parameters. We * aren't retrieving anything for AC conf now, but we will certainly * need it, when we customize AC. */ static void SCACTileGetConfig(void) { } /** * \internal * \brief Count the occurrences of each character in the pattern and * accumulate into a histogram. Really only used to detect unused * characters, so could just set to 1 instead of counting. */ static inline void SCACTileHistogramAlphabet(SCACTileCtx *ctx, MpmPattern *p) { for (int i = 0; i < p->len; i++) { ctx->alpha_hist[p->ci[i]]++; } } /* Use Alphabet Histogram to create compressed alphabet. */ static void SCACTileInitTranslateTable(SCACTileCtx *ctx) { /* Count the number of ASCII values actually appearing in any * pattern. Create compressed mapping table with unused * characters mapping to zero. */ for (int i = 0; i < 256; i++) { /* Move all upper case counts to lower case */ if (i >= 'A' && i <= 'Z') { ctx->alpha_hist[i - 'A' + 'a'] += ctx->alpha_hist[i]; ctx->alpha_hist[i] = 0; } if (ctx->alpha_hist[i]) { ctx->alphabet_size++; DEBUG_VALIDATE_BUG_ON(ctx->alphabet_size > UINT8_MAX); ctx->translate_table[i] = (uint8_t)ctx->alphabet_size; } else ctx->translate_table[i] = 0; } /* Fix up translation table for uppercase */ for (int i = 'A'; i <= 'Z'; i++) ctx->translate_table[i] = ctx->translate_table[i - 'A' + 'a']; SCLogDebug(" Alphabet size %d", ctx->alphabet_size); /* Round alphabet size up to next power-of-two Leave one extra * space For the unused-characters = 0 mapping. */ ctx->alphabet_size += 1; /* Extra space for unused-character */ if (ctx->alphabet_size <= 8) { ctx->alphabet_storage = 8; } else if (ctx->alphabet_size <= 16) { ctx->alphabet_storage = 16; } else if (ctx->alphabet_size <= 32) { ctx->alphabet_storage = 32; } else if (ctx->alphabet_size <= 64) { ctx->alphabet_storage = 64; } else if (ctx->alphabet_size <= 128) { ctx->alphabet_storage = 128; } else ctx->alphabet_storage = 256; } static void SCACTileReallocOutputTable(SCACTileCtx *ctx, int new_state_count) { /* reallocate space in the output table for the new state */ size_t size = ctx->allocated_state_count * sizeof(SCACTileOutputTable); void *ptmp = SCRealloc(ctx->output_table, size); if (ptmp == NULL) { SCFree(ctx->output_table); ctx->output_table = NULL; FatalError("Error allocating memory"); } ctx->output_table = ptmp; } static void SCACTileReallocState(SCACTileCtx *ctx, int new_state_count) { /* reallocate space in the goto table to include a new state */ size_t size = ctx->allocated_state_count * sizeof(int32_t) * 256; void *ptmp = SCRealloc(ctx->goto_table, size); if (ptmp == NULL) { SCFree(ctx->goto_table); ctx->goto_table = NULL; FatalError("Error allocating memory"); } ctx->goto_table = ptmp; SCACTileReallocOutputTable(ctx, new_state_count); } /** * \internal * \brief Initialize a new state in the goto and output tables. * * \param mpm_ctx Pointer to the mpm context. * * \retval The state id, of the newly created state. */ static inline int SCACTileInitNewState(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; int aa = 0; /* Exponentially increase the allocated space when needed. */ if (ctx->allocated_state_count < ctx->state_count + 1) { if (ctx->allocated_state_count == 0) ctx->allocated_state_count = 256; else ctx->allocated_state_count *= 2; SCACTileReallocState(ctx, ctx->allocated_state_count); } /* set all transitions for the newly assigned state as FAIL transitions */ for (aa = 0; aa < ctx->alphabet_size; aa++) { ctx->goto_table[ctx->state_count][aa] = SC_AC_TILE_FAIL; } memset(ctx->output_table + ctx->state_count, 0, sizeof(SCACTileOutputTable)); return ctx->state_count++; } /** * \internal * \brief Adds a pid to the output table for a state. * * \param state The state to whose output table we should add the pid. * \param pid The pattern id to add. * \param mpm_ctx Pointer to the mpm context. */ static void SCACTileSetOutputState(int32_t state, MpmPatternIndex pindex, MpmCtx *mpm_ctx) { void *ptmp; SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; SCACTileOutputTable *output_state = &ctx->output_table[state]; uint32_t i = 0; /* Don't add the pattern more than once to the same state. */ for (i = 0; i < output_state->no_of_entries; i++) { if (output_state->patterns[i] == pindex) return; } /* Increase the size of the array of pids for this state and add * the new pid. */ output_state->no_of_entries++; ptmp = SCRealloc(output_state->patterns, output_state->no_of_entries * sizeof(MpmPatternIndex)); if (ptmp == NULL) { SCFree(output_state->patterns); output_state->patterns = NULL; FatalError("Error allocating memory"); } output_state->patterns = ptmp; output_state->patterns[output_state->no_of_entries - 1] = pindex; } /** * \brief Helper function used by SCACTileCreateGotoTable. Adds a * pattern to the goto table. * * \param pattern Pointer to the pattern. * \param pattern_len Pattern length. * \param pid The pattern id, that corresponds to this pattern. We * need it to updated the output table for this pattern. * \param mpm_ctx Pointer to the mpm context. */ static void SCACTileEnter(uint8_t *pattern, uint16_t pattern_len, MpmPatternIndex pindex, MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; int32_t state = 0; int32_t newstate = 0; int i = 0; int p = 0; int tc; /* Walk down the trie till we have a match for the pattern prefix */ state = 0; for (i = 0; i < pattern_len; i++) { tc = ctx->translate_table[pattern[i]]; if (ctx->goto_table[state][tc] == SC_AC_TILE_FAIL) break; state = ctx->goto_table[state][tc]; } /* Add the non-matching pattern suffix to the trie, from the last state * we left off */ for (p = i; p < pattern_len; p++) { newstate = SCACTileInitNewState(mpm_ctx); tc = ctx->translate_table[pattern[p]]; ctx->goto_table[state][tc] = newstate; state = newstate; } /* Add this pattern id, to the output table of the last state, where the * pattern ends in the trie */ SCACTileSetOutputState(state, pindex, mpm_ctx); } /** * \internal * \brief Create the goto table. * * \param mpm_ctx Pointer to the mpm context. */ static void SCACTileCreateGotoTable(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; uint32_t i = 0; /* add each pattern to create the goto table */ for (i = 0; i < mpm_ctx->pattern_cnt; i++) { SCACTileEnter(ctx->parray[i]->ci, ctx->parray[i]->len, i, mpm_ctx); } int aa = 0; for (aa = 0; aa < ctx->alphabet_size; aa++) { if (ctx->goto_table[0][aa] == SC_AC_TILE_FAIL) { ctx->goto_table[0][aa] = 0; } } } static inline int SCACTileStateQueueIsEmpty(StateQueue *q) { if (q->top == q->bot) return 1; else return 0; } static inline void SCACTileEnqueue(StateQueue *q, int32_t state) { int i = 0; /*if we already have this */ for (i = q->bot; i < q->top; i++) { if (q->store[i] == state) return; } q->store[q->top++] = state; if (q->top == STATE_QUEUE_CONTAINER_SIZE) q->top = 0; if (q->top == q->bot) { FatalError("Just ran out of space in the queue. " "Fatal Error. Exiting. Please file a bug report on this"); } } static inline int32_t SCACTileDequeue(StateQueue *q) { if (q->bot == STATE_QUEUE_CONTAINER_SIZE) q->bot = 0; if (q->bot == q->top) { FatalError("StateQueue behaving weirdly. " "Fatal Error. Exiting. Please file a bug report on this"); } return q->store[q->bot++]; } /** * \internal * \brief Club the output data from 2 states and store it in the 1st state. * dst_state_data = {dst_state_data} UNION {src_state_data} * * \param dst_state First state(also the destination) for the union operation. * \param src_state Second state for the union operation. * \param mpm_ctx Pointer to the mpm context. */ static void SCACTileClubOutputStates(int32_t dst_state, int32_t src_state, MpmCtx *mpm_ctx) { void *ptmp; SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; uint32_t i = 0; uint32_t j = 0; SCACTileOutputTable *output_dst_state = &ctx->output_table[dst_state]; SCACTileOutputTable *output_src_state = &ctx->output_table[src_state]; for (i = 0; i < output_src_state->no_of_entries; i++) { for (j = 0; j < output_dst_state->no_of_entries; j++) { if (output_src_state->patterns[i] == output_dst_state->patterns[j]) { break; } } if (j == output_dst_state->no_of_entries) { output_dst_state->no_of_entries++; ptmp = SCRealloc(output_dst_state->patterns, (output_dst_state->no_of_entries * sizeof(uint32_t))); if (ptmp == NULL) { SCFree(output_dst_state->patterns); output_dst_state->patterns = NULL; FatalError("Error allocating memory"); } output_dst_state->patterns = ptmp; output_dst_state->patterns[output_dst_state->no_of_entries - 1] = output_src_state->patterns[i]; } } } /** * \internal * \brief Create the failure table. * * \param mpm_ctx Pointer to the mpm context. */ static void SCACTileCreateFailureTable(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; int aa = 0; int32_t state = 0; int32_t r_state = 0; StateQueue q; memset(&q, 0, sizeof(StateQueue)); /* Allocate space for the failure table. A failure entry in the table for * every state(SCACTileCtx->state_count) */ ctx->failure_table = SCMalloc(ctx->state_count * sizeof(int32_t)); if (ctx->failure_table == NULL) { FatalError("Error allocating memory"); } memset(ctx->failure_table, 0, ctx->state_count * sizeof(int32_t)); /* Add the failure transitions for the 0th state, and add every non-fail * transition from the 0th state to the queue for further processing * of failure states */ for (aa = 0; aa < ctx->alphabet_size; aa++) { int32_t temp_state = ctx->goto_table[0][aa]; if (temp_state != 0) { SCACTileEnqueue(&q, temp_state); ctx->failure_table[temp_state] = 0; } } while (!SCACTileStateQueueIsEmpty(&q)) { /* pick up every state from the queue and add failure transitions */ r_state = SCACTileDequeue(&q); for (aa = 0; aa < ctx->alphabet_size; aa++) { int32_t temp_state = ctx->goto_table[r_state][aa]; if (temp_state == SC_AC_TILE_FAIL) continue; SCACTileEnqueue(&q, temp_state); state = ctx->failure_table[r_state]; while(ctx->goto_table[state][aa] == SC_AC_TILE_FAIL) state = ctx->failure_table[state]; ctx->failure_table[temp_state] = ctx->goto_table[state][aa]; SCACTileClubOutputStates(temp_state, ctx->failure_table[temp_state], mpm_ctx); } } } /* * Set the next state for 1 byte next-state. */ static void SCACTileSetState1Byte(SCACTileCtx *ctx, int state, int aa, int next_state, int outputs) { uint8_t *state_table = (uint8_t*)ctx->state_table; DEBUG_VALIDATE_BUG_ON(next_state < 0 || next_state > UINT8_MAX); uint8_t encoded_next_state = (uint8_t)next_state; if (next_state == SC_AC_TILE_FAIL) { FatalError("Error FAIL state in output"); } if (outputs == 0) encoded_next_state |= (1 << 7); state_table[state * ctx->alphabet_storage + aa] = encoded_next_state; } /* * Set the next state for 2 byte next-state. */ static void SCACTileSetState2Bytes(SCACTileCtx *ctx, int state, int aa, int next_state, int outputs) { uint16_t *state_table = (uint16_t*)ctx->state_table; DEBUG_VALIDATE_BUG_ON(next_state < 0 || next_state > UINT16_MAX); uint16_t encoded_next_state = (uint16_t)next_state; if (next_state == SC_AC_TILE_FAIL) { FatalError("Error FAIL state in output"); } if (outputs == 0) encoded_next_state |= (1 << 15); state_table[state * ctx->alphabet_storage + aa] = encoded_next_state; } /* * Set the next state for 4 byte next-state. */ static void SCACTileSetState4Bytes(SCACTileCtx *ctx, int state, int aa, int next_state, int outputs) { uint32_t *state_table = (uint32_t*)ctx->state_table; uint32_t encoded_next_state = next_state; if (next_state == SC_AC_TILE_FAIL) { FatalError("Error FAIL state in output"); } if (outputs == 0) encoded_next_state |= (1UL << 31); state_table[state * ctx->alphabet_storage + aa] = encoded_next_state; } /** * \internal * \brief Create the delta table. * * \param mpm_ctx Pointer to the mpm context. */ static inline void SCACTileCreateDeltaTable(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; int aa = 0; int32_t r_state = 0; if (ctx->state_count < 32767) { if (ctx->state_count < 128) { ctx->bytes_per_state = 1; ctx->SetNextState = SCACTileSetState1Byte; switch(ctx->alphabet_storage) { case 8: ctx->Search = SCACTileSearchTiny8; break; case 16: ctx->Search = SCACTileSearchTiny16; break; case 32: ctx->Search = SCACTileSearchTiny32; break; case 64: ctx->Search = SCACTileSearchTiny64; break; case 128: ctx->Search = SCACTileSearchTiny128; break; default: ctx->Search = SCACTileSearchTiny256; } } else { /* 16-bit state needed */ ctx->bytes_per_state = 2; ctx->SetNextState = SCACTileSetState2Bytes; switch(ctx->alphabet_storage) { case 8: ctx->Search = SCACTileSearchSmall8; break; case 16: ctx->Search = SCACTileSearchSmall16; break; case 32: ctx->Search = SCACTileSearchSmall32; break; case 64: ctx->Search = SCACTileSearchSmall64; break; case 128: ctx->Search = SCACTileSearchSmall128; break; default: ctx->Search = SCACTileSearchSmall256; } } } else { /* 32-bit next state */ ctx->Search = SCACTileSearchLarge; ctx->bytes_per_state = 4; ctx->SetNextState = SCACTileSetState4Bytes; ctx->alphabet_storage = 256; /* Change? */ } StateQueue q; memset(&q, 0, sizeof(StateQueue)); for (aa = 0; aa < ctx->alphabet_size; aa++) { int temp_state = ctx->goto_table[0][aa]; if (temp_state != 0) SCACTileEnqueue(&q, temp_state); } while (!SCACTileStateQueueIsEmpty(&q)) { r_state = SCACTileDequeue(&q); for (aa = 0; aa < ctx->alphabet_size; aa++) { int temp_state = ctx->goto_table[r_state][aa]; if (temp_state != SC_AC_TILE_FAIL) { SCACTileEnqueue(&q, temp_state); } else { int f_state = ctx->failure_table[r_state]; ctx->goto_table[r_state][aa] = ctx->goto_table[f_state][aa]; } } } } static void SCACTileClubOutputStatePresenceWithDeltaTable(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; int aa = 0; uint32_t state = 0; /* Allocate next-state table. */ int size = ctx->state_count * ctx->bytes_per_state * ctx->alphabet_storage; void *state_table = SCMalloc(size); if (unlikely(state_table == NULL)) { FatalError("Error allocating memory"); } memset(state_table, 0, size); ctx->state_table = state_table; mpm_ctx->memory_cnt++; mpm_ctx->memory_size += size; SCLogDebug("Delta Table size %d, alphabet: %d, %d-byte states: %d", size, ctx->alphabet_size, ctx->bytes_per_state, ctx->state_count); /* Copy next state from Goto table, which is 32 bits and encode it into the next * state table, which can be 1, 2 or 4 bytes each and include if there is an * output. */ for (state = 0; state < ctx->state_count; state++) { for (aa = 0; aa < ctx->alphabet_size; aa++) { int next_state = ctx->goto_table[state][aa]; int next_state_outputs = ctx->output_table[next_state].no_of_entries; ctx->SetNextState(ctx, state, aa, next_state, next_state_outputs); } } } static inline void SCACTileInsertCaseSensitiveEntriesForPatterns(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; uint32_t state = 0; uint32_t k = 0; for (state = 0; state < ctx->state_count; state++) { if (ctx->output_table[state].no_of_entries == 0) continue; for (k = 0; k < ctx->output_table[state].no_of_entries; k++) { if (ctx->pattern_list[ctx->output_table[state].patterns[k]].cs != NULL) { /* TODO - Find better way to store this. */ ctx->output_table[state].patterns[k] &= 0x0FFFFFFF; ctx->output_table[state].patterns[k] |= (uint32_t)1 << 31; } } } } #if 0 static void SCACTilePrintDeltaTable(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; int i = 0, j = 0; printf("##############Delta Table##############\n"); for (i = 0; i < ctx->state_count; i++) { printf("%d: \n", i); for (j = 0; j < ctx->alphabet_size; j++) { if (SCACTileGetDelta(i, j, mpm_ctx) != 0) { printf(" %c -> %d\n", j, SCACTileGetDelta(i, j, mpm_ctx)); } } } } #endif /** * \brief Process the patterns and prepare the state table. * * \param mpm_ctx Pointer to the mpm context. */ static void SCACTilePrepareStateTable(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; /* Create Alphabet compression and Lower Case translation table. */ SCACTileInitTranslateTable(ctx); /* create the 0th state in the goto table and output_table */ SCACTileInitNewState(mpm_ctx); /* create the goto table */ SCACTileCreateGotoTable(mpm_ctx); /* create the failure table */ SCACTileCreateFailureTable(mpm_ctx); /* create the final state(delta) table */ SCACTileCreateDeltaTable(mpm_ctx); /* club the output state presence with delta transition entries */ SCACTileClubOutputStatePresenceWithDeltaTable(mpm_ctx); /* club nocase entries */ SCACTileInsertCaseSensitiveEntriesForPatterns(mpm_ctx); #if 0 SCACTilePrintDeltaTable(mpm_ctx); #endif /* we don't need these anymore */ SCFree(ctx->goto_table); ctx->goto_table = NULL; SCFree(ctx->failure_table); ctx->failure_table = NULL; } /** * \brief Process Internal AC MPM tables to create the Search Context * * The search context is only the data needed to search the MPM. * * \param mpm_ctx Pointer to the mpm context. */ static void SCACTilePrepareSearch(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; /* Resize the output table to be only as big as its final size. */ SCACTileReallocOutputTable(ctx, ctx->state_count); search_ctx->Search = ctx->Search; memcpy(search_ctx->translate_table, ctx->translate_table, sizeof(ctx->translate_table)); /* Move the state table from the Init context */ search_ctx->state_table = ctx->state_table; ctx->state_table = NULL; /* So that it won't get freed twice. */ /* Move the output_table from the Init context to the Search Context */ /* TODO: Could be made more compact */ search_ctx->output_table = ctx->output_table; ctx->output_table = NULL; search_ctx->state_count = ctx->state_count; search_ctx->pattern_list = ctx->pattern_list; ctx->pattern_list = NULL; search_ctx->pattern_cnt = mpm_ctx->pattern_cnt; /* One bit per pattern, rounded up to the next byte size. */ search_ctx->mpm_bitarray_size = (mpm_ctx->pattern_cnt + 7) / 8; /* Can now free the Initialization data */ SCACTileDestroyInitCtx(mpm_ctx); } /** * \brief Process the patterns added to the mpm, and create the internal tables. * * \param mpm_ctx Pointer to the mpm context. */ int SCACTilePreparePatterns(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; if (mpm_ctx->pattern_cnt == 0 || search_ctx->init_ctx == NULL) { SCLogDebug("no patterns supplied to this mpm_ctx"); return 0; } SCACTileCtx *ctx = search_ctx->init_ctx; if (mpm_ctx->init_hash == NULL) { SCLogDebug("no patterns supplied to this mpm_ctx"); return 0; } /* alloc the pattern array */ ctx->parray = (MpmPattern **)SCMalloc(mpm_ctx->pattern_cnt * sizeof(MpmPattern *)); if (ctx->parray == NULL) goto error; memset(ctx->parray, 0, mpm_ctx->pattern_cnt * sizeof(MpmPattern *)); /* populate it with the patterns in the hash */ uint32_t i = 0, p = 0; for (i = 0; i < MPM_INIT_HASH_SIZE; i++) { MpmPattern *node = mpm_ctx->init_hash[i], *nnode = NULL; while(node != NULL) { nnode = node->next; node->next = NULL; ctx->parray[p++] = node; SCACTileHistogramAlphabet(ctx, node); node = nnode; } } /* we no longer need the hash, so free it's memory */ SCFree(mpm_ctx->init_hash); mpm_ctx->init_hash = NULL; /* Handle case patterns by storing a copy of the pattern to compare * to each possible match (no-case). * * Allocate the memory for the array and each of the strings as one block. */ size_t string_space_needed = 0; for (i = 0; i < mpm_ctx->pattern_cnt; i++) { if (!(ctx->parray[i]->flags & MPM_PATTERN_FLAG_NOCASE)) { /* Round up to next 8 byte aligned length */ uint32_t space = ((ctx->parray[i]->len + 7) / 8) * 8; string_space_needed += space; } } size_t pattern_list_size = mpm_ctx->pattern_cnt * sizeof(SCACTilePatternList); size_t mem_size = string_space_needed + pattern_list_size; void *mem_block = SCCalloc(1, mem_size); if (mem_block == NULL) { FatalError("Error allocating memory"); } mpm_ctx->memory_cnt++; mpm_ctx->memory_size += mem_size; /* Split the allocated block into pattern list array and string space. */ ctx->pattern_list = mem_block; uint8_t *string_space = mem_block + pattern_list_size; /* Now make the copies of the no-case strings. */ for (i = 0; i < mpm_ctx->pattern_cnt; i++) { if (!(ctx->parray[i]->flags & MPM_PATTERN_FLAG_NOCASE)) { uint16_t len = ctx->parray[i]->len; uint32_t space = ((len + 7) / 8) * 8; memcpy(string_space, ctx->parray[i]->original_pat, len); ctx->pattern_list[i].cs = string_space; ctx->pattern_list[i].patlen = len; string_space += space; } ctx->pattern_list[i].offset = ctx->parray[i]->offset; ctx->pattern_list[i].depth = ctx->parray[i]->depth; ctx->pattern_list[i].pid = ctx->parray[i]->id; /* ACPatternList now owns this memory */ ctx->pattern_list[i].sids_size = ctx->parray[i]->sids_size; ctx->pattern_list[i].sids = ctx->parray[i]->sids; ctx->parray[i]->sids = NULL; ctx->parray[i]->sids_size = 0; } /* prepare the state table required by AC */ SCACTilePrepareStateTable(mpm_ctx); /* Convert to the Search Context structure */ SCACTilePrepareSearch(mpm_ctx); return 0; error: return -1; } /** * \brief Init the mpm thread context. * * \param mpm_ctx Pointer to the mpm context. * \param mpm_thread_ctx Pointer to the mpm thread context. */ void SCACTileInitThreadCtx(MpmCtx *mpm_ctx, MpmThreadCtx *mpm_thread_ctx) { memset(mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); mpm_thread_ctx->ctx = SCMalloc(sizeof(SCACTileThreadCtx)); if (mpm_thread_ctx->ctx == NULL) { exit(EXIT_FAILURE); } memset(mpm_thread_ctx->ctx, 0, sizeof(SCACTileThreadCtx)); mpm_thread_ctx->memory_cnt++; mpm_thread_ctx->memory_size += sizeof(SCACTileThreadCtx); } /** * \brief Initialize the AC context. * * \param mpm_ctx Mpm context. */ void SCACTileInitCtx(MpmCtx *mpm_ctx) { if (mpm_ctx->ctx != NULL) return; /* Search Context */ mpm_ctx->ctx = SCMalloc(sizeof(SCACTileSearchCtx)); if (mpm_ctx->ctx == NULL) { exit(EXIT_FAILURE); } memset(mpm_ctx->ctx, 0, sizeof(SCACTileSearchCtx)); mpm_ctx->memory_cnt++; mpm_ctx->memory_size += sizeof(SCACTileSearchCtx); SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; /* MPM Creation context */ search_ctx->init_ctx = SCMalloc(sizeof(SCACTileCtx)); if (search_ctx->init_ctx == NULL) { exit(EXIT_FAILURE); } memset(search_ctx->init_ctx, 0, sizeof(SCACTileCtx)); mpm_ctx->memory_cnt++; mpm_ctx->memory_size += sizeof(SCACTileCtx); /* initialize the hash we use to speed up pattern insertions */ mpm_ctx->init_hash = SCMalloc(sizeof(MpmPattern *) * MPM_INIT_HASH_SIZE); if (mpm_ctx->init_hash == NULL) { exit(EXIT_FAILURE); } memset(mpm_ctx->init_hash, 0, sizeof(MpmPattern *) * MPM_INIT_HASH_SIZE); /* get conf values for AC from our yaml file. We have no conf values for * now. We will certainly need this, as we develop the algo */ SCACTileGetConfig(); } /** * \brief Destroy the mpm thread context. * * \param mpm_ctx Pointer to the mpm context. * \param mpm_thread_ctx Pointer to the mpm thread context. */ void SCACTileDestroyThreadCtx(MpmCtx *mpm_ctx, MpmThreadCtx *mpm_thread_ctx) { SCACTilePrintSearchStats(mpm_thread_ctx); if (mpm_thread_ctx->ctx != NULL) { SCFree(mpm_thread_ctx->ctx); mpm_thread_ctx->ctx = NULL; mpm_thread_ctx->memory_cnt--; mpm_thread_ctx->memory_size -= sizeof(SCACTileThreadCtx); } } static void SCACTileDestroyInitCtx(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; if (ctx == NULL) return; if (mpm_ctx->init_hash != NULL) { SCFree(mpm_ctx->init_hash); mpm_ctx->init_hash = NULL; } if (ctx->parray != NULL) { uint32_t i; for (i = 0; i < mpm_ctx->pattern_cnt; i++) { if (ctx->parray[i] != NULL) { MpmFreePattern(mpm_ctx, ctx->parray[i]); } } SCFree(ctx->parray); ctx->parray = NULL; } if (ctx->state_table != NULL) { SCFree(ctx->state_table); mpm_ctx->memory_cnt--; mpm_ctx->memory_size -= (ctx->state_count * ctx->bytes_per_state * ctx->alphabet_storage); } if (ctx->output_table != NULL) { uint32_t state; for (state = 0; state < ctx->state_count; state++) { if (ctx->output_table[state].patterns != NULL) { SCFree(ctx->output_table[state].patterns); } } SCFree(ctx->output_table); } if (ctx->pattern_list != NULL) { uint32_t i; for (i = 0; i < mpm_ctx->pattern_cnt; i++) { if (ctx->pattern_list[i].cs != NULL) SCFree(ctx->pattern_list[i].cs); if (ctx->pattern_list[i].sids != NULL) SCFree(ctx->pattern_list[i].sids); } SCFree(ctx->pattern_list); } SCFree(ctx); search_ctx->init_ctx = NULL; mpm_ctx->memory_cnt--; mpm_ctx->memory_size -= sizeof(SCACTileCtx); } /** * \brief Destroy the mpm context. * * \param mpm_ctx Pointer to the mpm context. */ void SCACTileDestroyCtx(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; if (search_ctx == NULL) return; /* Destroy Initialization data */ SCACTileDestroyInitCtx(mpm_ctx); /* Free Search tables */ SCFree(search_ctx->state_table); if (search_ctx->pattern_list != NULL) { uint32_t i; for (i = 0; i < search_ctx->pattern_cnt; i++) { if (search_ctx->pattern_list[i].sids != NULL) SCFree(search_ctx->pattern_list[i].sids); } SCFree(search_ctx->pattern_list); } if (search_ctx->output_table != NULL) { uint32_t state; for (state = 0; state < search_ctx->state_count; state++) { if (search_ctx->output_table[state].patterns != NULL) { SCFree(search_ctx->output_table[state].patterns); } } SCFree(search_ctx->output_table); } SCFree(search_ctx); mpm_ctx->ctx = NULL; mpm_ctx->memory_cnt--; mpm_ctx->memory_size -= sizeof(SCACTileSearchCtx); } /* * Heavily optimized pattern matching routine for TILE-Gx. */ #define SCHECK(x) ((x) > 0) #define BUF_TYPE int32_t // Extract byte N=0,1,2,3 from x #define BYTE0(x) (((x) & 0x000000ff) >> 0) #define BYTE1(x) (((x) & 0x0000ff00) >> 8) #define BYTE2(x) (((x) & 0x00ff0000) >> 16) #define BYTE3(x) (((x) & 0xff000000) >> 24) #define EXTRA 4 // need 4 extra bytes to avoid OOB reads static int CheckMatch(const SCACTileSearchCtx *ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen, uint16_t state, int i, int matches, uint8_t *mpm_bitarray) { const SCACTilePatternList *pattern_list = ctx->pattern_list; const uint8_t *buf_offset = buf + i + 1; // Lift out of loop uint32_t no_of_entries = ctx->output_table[state].no_of_entries; MpmPatternIndex *patterns = ctx->output_table[state].patterns; uint32_t k; for (k = 0; k < no_of_entries; k++) { MpmPatternIndex pindex = patterns[k] & 0x0FFFFFFF; if (mpm_bitarray[pindex / 8] & (1 << (pindex % 8))) { /* Pattern already seen by this MPM. */ /* NOTE: This is faster then rechecking if it is a case-sensitive match * since we know this pattern has already been seen, but incrementing * matches here could over report matches. For example if the case-sensitive * pattern is "Foo" and the string is "Foo bar foo", matches would be reported * as 2, when it should really be 1, since "foo" is not a true match. */ matches++; continue; } const SCACTilePatternList *pat = &pattern_list[pindex]; const int offset = i - pat->patlen + 1; if (offset < (int)pat->offset || (pat->depth && i > pat->depth)) continue; /* Double check case-sensitive match now. */ if (patterns[k] >> 31) { const uint16_t patlen = pat->patlen; if (SCMemcmp(pat->cs, buf_offset - patlen, patlen) != 0) { /* Case-sensitive match failed. */ continue; } } /* New match found */ mpm_bitarray[pindex / 8] |= (1 << (pindex % 8)); /* Always add the Signature IDs, since they could be different in the current MPM * than in a previous MPM on the same PMQ when finding the same pattern. */ PrefilterAddSids(pmq, pattern_list[pindex].sids, pattern_list[pindex].sids_size); matches++; } return matches; } /** * \brief The aho corasick search function. * * \param mpm_ctx Pointer to the mpm context. * \param mpm_thread_ctx Pointer to the mpm thread context. * \param pmq Pointer to the Pattern Matcher Queue to hold * search matches. * \param buf Buffer to be searched. * \param buflen Buffer length. * * \retval matches Match count. */ uint32_t SCACTileSearch(const MpmCtx *mpm_ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen) { const SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; if (buflen == 0) return 0; /* Context specific matching function. */ return search_ctx->Search(search_ctx, mpm_thread_ctx, pmq, buf, buflen); } /* This function handles (ctx->state_count >= 32767) */ uint32_t SCACTileSearchLarge(const SCACTileSearchCtx *ctx, MpmThreadCtx *mpm_thread_ctx, PrefilterRuleStore *pmq, const uint8_t *buf, uint32_t buflen) { uint32_t i = 0; int matches = 0; uint8_t mpm_bitarray[ctx->mpm_bitarray_size]; memset(mpm_bitarray, 0, ctx->mpm_bitarray_size); const uint8_t* restrict xlate = ctx->translate_table; register int state = 0; int32_t (*state_table_u32)[256] = ctx->state_table; for (i = 0; i < buflen; i++) { state = state_table_u32[state & 0x00FFFFFF][xlate[buf[i]]]; if (SCHECK(state)) { DEBUG_VALIDATE_BUG_ON(state < 0 || state > UINT16_MAX); matches = CheckMatch(ctx, pmq, buf, buflen, (uint16_t)state, i, matches, mpm_bitarray); } } /* for (i = 0; i < buflen; i++) */ return matches; } /* * Search with Alphabet size of 256 and 16-bit next-state entries. * Next state entry has MSB as "match" and 15 LSB bits as next-state index. */ // y = 1<ctx; printf("AC Thread Search stats (ctx %p)\n", ctx); printf("Total calls: %" PRIu32 "\n", ctx->total_calls); printf("Total matches: %" PRIu64 "\n", ctx->total_matches); #endif /* SC_AC_TILE_COUNTERS */ } void SCACTilePrintInfo(MpmCtx *mpm_ctx) { SCACTileSearchCtx *search_ctx = (SCACTileSearchCtx *)mpm_ctx->ctx; SCACTileCtx *ctx = search_ctx->init_ctx; printf("MPM AC Information:\n"); printf("Memory allocs: %" PRIu32 "\n", mpm_ctx->memory_cnt); printf("Memory alloced: %" PRIu32 "\n", mpm_ctx->memory_size); printf(" Sizeof:\n"); printf(" MpmCtx %" PRIuMAX "\n", (uintmax_t)sizeof(MpmCtx)); printf(" SCACTileCtx: %" PRIuMAX "\n", (uintmax_t)sizeof(SCACTileCtx)); printf(" MpmPattern %" PRIuMAX "\n", (uintmax_t)sizeof(MpmPattern)); printf(" MpmPattern %" PRIuMAX "\n", (uintmax_t)sizeof(MpmPattern)); printf("Unique Patterns: %" PRIu32 "\n", mpm_ctx->pattern_cnt); printf("Smallest: %" PRIu32 "\n", mpm_ctx->minlen); printf("Largest: %" PRIu32 "\n", mpm_ctx->maxlen); printf("Total states in the state table: %u\n", ctx->state_count); printf("\n"); } /************************** Mpm Registration ***************************/ /** * \brief Register the aho-corasick mpm 'ks' originally developed by * Ken Steele for Tilera Tile-Gx processor. */ void MpmACTileRegister(void) { mpm_table[MPM_AC_KS].name = "ac-ks"; mpm_table[MPM_AC_KS].InitCtx = SCACTileInitCtx; mpm_table[MPM_AC_KS].InitThreadCtx = SCACTileInitThreadCtx; mpm_table[MPM_AC_KS].DestroyCtx = SCACTileDestroyCtx; mpm_table[MPM_AC_KS].DestroyThreadCtx = SCACTileDestroyThreadCtx; mpm_table[MPM_AC_KS].AddPattern = SCACTileAddPatternCS; mpm_table[MPM_AC_KS].AddPatternNocase = SCACTileAddPatternCI; mpm_table[MPM_AC_KS].Prepare = SCACTilePreparePatterns; mpm_table[MPM_AC_KS].Search = SCACTileSearch; mpm_table[MPM_AC_KS].PrintCtx = SCACTilePrintInfo; mpm_table[MPM_AC_KS].PrintThreadCtx = SCACTilePrintSearchStats; mpm_table[MPM_AC_KS].RegisterUnittests = SCACTileRegisterTests; } /*************************************Unittests********************************/ #ifdef UNITTESTS #include "detect-engine-alert.h" static int SCACTileTest01(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"abcd", 4, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghjiklmnopqrstuvwxyz"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest02(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"abce", 4, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghjiklmnopqrstuvwxyz"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 0) result = 1; else printf("0 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest03(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"abcd", 4, 0, 0, 0, 0, 0); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"bcde", 4, 0, 0, 1, 0, 0); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"fghj", 4, 0, 0, 2, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghjiklmnopqrstuvwxyz"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 3) result = 1; else printf("3 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest04(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); MpmAddPatternCS(&mpm_ctx, (uint8_t *)"abcd", 4, 0, 0, 0, 0, 0); MpmAddPatternCS(&mpm_ctx, (uint8_t *)"bcdegh", 6, 0, 0, 1, 0, 0); MpmAddPatternCS(&mpm_ctx, (uint8_t *)"fghjxyz", 7, 0, 0, 2, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghjiklmnopqrstuvwxyz"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest05(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); MpmAddPatternCI(&mpm_ctx, (uint8_t *)"ABCD", 4, 0, 0, 0, 0, 0); MpmAddPatternCI(&mpm_ctx, (uint8_t *)"bCdEfG", 6, 0, 0, 1, 0, 0); MpmAddPatternCI(&mpm_ctx, (uint8_t *)"fghJikl", 7, 0, 0, 2, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghjiklmnopqrstuvwxyz"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 3) result = 1; else printf("3 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest06(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); MpmAddPatternCS(&mpm_ctx, (uint8_t *)"abcd", 4, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcd"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest07(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* should match 30 times */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"A", 1, 0, 0, 0, 0, 0); /* should match 29 times */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"AA", 2, 0, 0, 1, 0, 0); /* should match 28 times */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"AAA", 3, 0, 0, 2, 0, 0); /* 26 */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"AAAAA", 5, 0, 0, 3, 0, 0); /* 21 */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"AAAAAAAAAA", 10, 0, 0, 4, 0, 0); /* 1 */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"AAAAAAAAAAAAAAAAAAAAAAAAAAAAAA", 30, 0, 0, 5, 0, 0); PmqSetup(&pmq); /* total matches: 135 */ SCACTilePreparePatterns(&mpm_ctx); const char *buf = "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAA"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 135) result = 1; else printf("135 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest08(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"abcd", 4, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)"a", 1); if (cnt == 0) result = 1; else printf("0 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest09(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"ab", 2, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)"ab", 2); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest10(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"abcdefgh", 8, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "01234567890123456789012345678901234567890123456789" "01234567890123456789012345678901234567890123456789" "abcdefgh" "01234567890123456789012345678901234567890123456789" "01234567890123456789012345678901234567890123456789"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest11(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); if (MpmAddPatternCS(&mpm_ctx, (uint8_t *)"he", 2, 0, 0, 1, 0, 0) == -1) goto end; if (MpmAddPatternCS(&mpm_ctx, (uint8_t *)"she", 3, 0, 0, 2, 0, 0) == -1) goto end; if (MpmAddPatternCS(&mpm_ctx, (uint8_t *)"his", 3, 0, 0, 3, 0, 0) == -1) goto end; if (MpmAddPatternCS(&mpm_ctx, (uint8_t *)"hers", 4, 0, 0, 4, 0, 0) == -1) goto end; PmqSetup(&pmq); if (SCACTilePreparePatterns(&mpm_ctx) == -1) goto end; result = 1; const char *buf = "he"; result &= (SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)) == 1); buf = "she"; result &= (SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)) == 2); buf = "his"; result &= (SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)) == 1); buf = "hers"; result &= (SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)) == 2); end: SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest12(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"wxyz", 4, 0, 0, 0, 0, 0); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"vwxyz", 5, 0, 0, 1, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghijklmnopqrstuvwxyz"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 2) result = 1; else printf("2 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest13(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ const char pat[] = "abcdefghijklmnopqrstuvwxyzABCD"; MpmAddPatternCS(&mpm_ctx, (uint8_t *)pat, sizeof(pat) - 1, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghijklmnopqrstuvwxyzABCD"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest14(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ const char pat[] = "abcdefghijklmnopqrstuvwxyzABCDE"; MpmAddPatternCS(&mpm_ctx, (uint8_t *)pat, sizeof(pat) - 1, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghijklmnopqrstuvwxyzABCDE"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest15(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ const char pat[] = "abcdefghijklmnopqrstuvwxyzABCDEF"; MpmAddPatternCS(&mpm_ctx, (uint8_t *)pat, sizeof(pat) - 1, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghijklmnopqrstuvwxyzABCDEF"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest16(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ const char pat[] = "abcdefghijklmnopqrstuvwxyzABC"; MpmAddPatternCS(&mpm_ctx, (uint8_t *)pat, sizeof(pat) - 1, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghijklmnopqrstuvwxyzABC"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest17(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ const char pat[] = "abcdefghijklmnopqrstuvwxyzAB"; MpmAddPatternCS(&mpm_ctx, (uint8_t *)pat, sizeof(pat) - 1, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghijklmnopqrstuvwxyzAB"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest18(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ const char pat[] = "abcde" "fghij" "klmno" "pqrst" "uvwxy" "z"; MpmAddPatternCS(&mpm_ctx, (uint8_t *)pat, sizeof(pat) - 1, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcde""fghij""klmno""pqrst""uvwxy""z"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest19(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 */ const char pat[] = "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAA"; MpmAddPatternCS(&mpm_ctx, (uint8_t *)pat, sizeof(pat) - 1, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAA"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest20(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 */ const char pat[] = "AAAAA" "AAAAA" "AAAAA" "AAAAA" "AAAAA" "AAAAA" "AA"; MpmAddPatternCS(&mpm_ctx, (uint8_t *)pat, sizeof(pat) - 1, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "AAAAA""AAAAA""AAAAA""AAAAA""AAAAA""AAAAA""AA"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest21(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"AA", 2, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)"AA", 2); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest22(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"abcd", 4, 0, 0, 0, 0, 0); /* 1 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"abcde", 5, 0, 0, 1, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "abcdefghijklmnopqrstuvwxyz"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 2) result = 1; else printf("2 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest23(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"AA", 2, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)"aa", 2); if (cnt == 0) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest24(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 1 */ MpmAddPatternCI(&mpm_ctx, (uint8_t *)"AA", 2, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)"aa", 2); if (cnt == 1) result = 1; else printf("1 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest25(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); MpmAddPatternCI(&mpm_ctx, (uint8_t *)"ABCD", 4, 0, 0, 0, 0, 0); MpmAddPatternCI(&mpm_ctx, (uint8_t *)"bCdEfG", 6, 0, 0, 1, 0, 0); MpmAddPatternCI(&mpm_ctx, (uint8_t *)"fghiJkl", 7, 0, 0, 2, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "ABCDEFGHIJKLMNOPQRSTUVWXYZ"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 3) result = 1; else printf("3 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest26(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0x00, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); MpmAddPatternCI(&mpm_ctx, (uint8_t *)"Works", 5, 0, 0, 0, 0, 0); MpmAddPatternCS(&mpm_ctx, (uint8_t *)"Works", 5, 0, 0, 1, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "works"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 1) result = 1; else printf("3 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest27(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 0 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"ONE", 3, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "tone"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 0) result = 1; else printf("0 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest28(void) { int result = 0; MpmCtx mpm_ctx; MpmThreadCtx mpm_thread_ctx; PrefilterRuleStore pmq; memset(&mpm_ctx, 0, sizeof(MpmCtx)); memset(&mpm_thread_ctx, 0, sizeof(MpmThreadCtx)); MpmInitCtx(&mpm_ctx, MPM_AC_KS); SCACTileInitThreadCtx(&mpm_ctx, &mpm_thread_ctx); /* 0 match */ MpmAddPatternCS(&mpm_ctx, (uint8_t *)"one", 3, 0, 0, 0, 0, 0); PmqSetup(&pmq); SCACTilePreparePatterns(&mpm_ctx); const char *buf = "tONE"; uint32_t cnt = SCACTileSearch(&mpm_ctx, &mpm_thread_ctx, &pmq, (uint8_t *)buf, strlen(buf)); if (cnt == 0) result = 1; else printf("0 != %" PRIu32 " ",cnt); SCACTileDestroyCtx(&mpm_ctx); SCACTileDestroyThreadCtx(&mpm_ctx, &mpm_thread_ctx); PmqFree(&pmq); return result; } static int SCACTileTest29(void) { uint8_t buf[] = "onetwothreefourfivesixseveneightnine"; uint16_t buflen = sizeof(buf) - 1; Packet *p = NULL; ThreadVars th_v; DetectEngineThreadCtx *det_ctx = NULL; int result = 0; memset(&th_v, 0, sizeof(th_v)); p = UTHBuildPacket(buf, buflen, IPPROTO_TCP); DetectEngineCtx *de_ctx = DetectEngineCtxInit(); if (de_ctx == NULL) goto end; de_ctx->flags |= DE_QUIET; de_ctx->sig_list = SigInit(de_ctx, "alert tcp any any -> any any " "(content:\"onetwothreefourfivesixseveneightnine\"; sid:1;)"); if (de_ctx->sig_list == NULL) goto end; de_ctx->sig_list->next = SigInit(de_ctx, "alert tcp any any -> any any " "(content:\"onetwothreefourfivesixseveneightnine\"; fast_pattern:3,3; sid:2;)"); if (de_ctx->sig_list->next == NULL) goto end; SigGroupBuild(de_ctx); DetectEngineThreadCtxInit(&th_v, (void *)de_ctx, (void *)&det_ctx); SigMatchSignatures(&th_v, de_ctx, det_ctx, p); if (PacketAlertCheck(p, 1) != 1) { printf("if (PacketAlertCheck(p, 1) != 1) failure\n"); goto end; } if (PacketAlertCheck(p, 2) != 1) { printf("if (PacketAlertCheck(p, 1) != 2) failure\n"); goto end; } result = 1; end: if (de_ctx != NULL) { SigGroupCleanup(de_ctx); SigCleanSignatures(de_ctx); DetectEngineThreadCtxDeinit(&th_v, (void *)det_ctx); DetectEngineCtxFree(de_ctx); } UTHFreePackets(&p, 1); return result; } #endif /* UNITTESTS */ void SCACTileRegisterTests(void) { #ifdef UNITTESTS UtRegisterTest("SCACTileTest01", SCACTileTest01); UtRegisterTest("SCACTileTest02", SCACTileTest02); UtRegisterTest("SCACTileTest03", SCACTileTest03); UtRegisterTest("SCACTileTest04", SCACTileTest04); UtRegisterTest("SCACTileTest05", SCACTileTest05); UtRegisterTest("SCACTileTest06", SCACTileTest06); UtRegisterTest("SCACTileTest07", SCACTileTest07); UtRegisterTest("SCACTileTest08", SCACTileTest08); UtRegisterTest("SCACTileTest09", SCACTileTest09); UtRegisterTest("SCACTileTest10", SCACTileTest10); UtRegisterTest("SCACTileTest11", SCACTileTest11); UtRegisterTest("SCACTileTest12", SCACTileTest12); UtRegisterTest("SCACTileTest13", SCACTileTest13); UtRegisterTest("SCACTileTest14", SCACTileTest14); UtRegisterTest("SCACTileTest15", SCACTileTest15); UtRegisterTest("SCACTileTest16", SCACTileTest16); UtRegisterTest("SCACTileTest17", SCACTileTest17); UtRegisterTest("SCACTileTest18", SCACTileTest18); UtRegisterTest("SCACTileTest19", SCACTileTest19); UtRegisterTest("SCACTileTest20", SCACTileTest20); UtRegisterTest("SCACTileTest21", SCACTileTest21); UtRegisterTest("SCACTileTest22", SCACTileTest22); UtRegisterTest("SCACTileTest23", SCACTileTest23); UtRegisterTest("SCACTileTest24", SCACTileTest24); UtRegisterTest("SCACTileTest25", SCACTileTest25); UtRegisterTest("SCACTileTest26", SCACTileTest26); UtRegisterTest("SCACTileTest27", SCACTileTest27); UtRegisterTest("SCACTileTest28", SCACTileTest28); UtRegisterTest("SCACTileTest29", SCACTileTest29); #endif } #else /* we're big endian */ void MpmACTileRegister(void) { /* no-op on big endian */ } #endif /* little endian check */