/* Copyright (C) 2007-2010 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 Victor Julien */ #include "suricata-common.h" #include "suricata.h" #include "debug.h" #include "detect.h" #include "flow.h" #include "flow-private.h" #include "flow-util.h" #include "flow-worker.h" #include "conf.h" #include "conf-yaml-loader.h" #include "app-layer-parser.h" #include "app-layer-htp.h" #include "detect-parse.h" #include "detect-engine-sigorder.h" #include "detect-engine-siggroup.h" #include "detect-engine-address.h" #include "detect-engine-port.h" #include "detect-engine-prefilter.h" #include "detect-engine-mpm.h" #include "detect-engine-iponly.h" #include "detect-engine-tag.h" #include "detect-engine-file.h" #include "detect-engine.h" #include "detect-engine-state.h" #include "detect-engine-payload.h" #include "detect-byte-extract.h" #include "detect-content.h" #include "detect-uricontent.h" #include "detect-engine-threshold.h" #include "detect-engine-content-inspection.h" #include "detect-engine-loader.h" #include "util-classification-config.h" #include "util-reference-config.h" #include "util-threshold-config.h" #include "util-error.h" #include "util-hash.h" #include "util-byte.h" #include "util-debug.h" #include "util-unittest.h" #include "util-action.h" #include "util-magic.h" #include "util-signal.h" #include "util-spm.h" #include "util-device.h" #include "util-var-name.h" #include "tm-threads.h" #include "runmodes.h" #ifdef PROFILING #include "util-profiling.h" #endif #include "reputation.h" #define DETECT_ENGINE_DEFAULT_INSPECTION_RECURSION_LIMIT 3000 static DetectEngineThreadCtx *DetectEngineThreadCtxInitForReload( ThreadVars *tv, DetectEngineCtx *new_de_ctx, int mt); static int DetectEngineCtxLoadConf(DetectEngineCtx *); static DetectEngineMasterCtx g_master_de_ctx = { SCMUTEX_INITIALIZER, 0, 99, NULL, NULL, TENANT_SELECTOR_UNKNOWN, NULL, NULL, 0}; static uint32_t TenantIdHash(HashTable *h, void *data, uint16_t data_len); static char TenantIdCompare(void *d1, uint16_t d1_len, void *d2, uint16_t d2_len); static void TenantIdFree(void *d); static uint32_t DetectEngineTentantGetIdFromLivedev(const void *ctx, const Packet *p); static uint32_t DetectEngineTentantGetIdFromVlanId(const void *ctx, const Packet *p); static uint32_t DetectEngineTentantGetIdFromPcap(const void *ctx, const Packet *p); static DetectEngineAppInspectionEngine *g_app_inspect_engines = NULL; SCEnumCharMap det_ctx_event_table[ ] = { #ifdef UNITTESTS { "TEST", DET_CTX_EVENT_TEST }, #endif { "NO_MEMORY", FILE_DECODER_EVENT_NO_MEM }, { "INVALID_SWF_LENGTH", FILE_DECODER_EVENT_INVALID_SWF_LENGTH }, { "INVALID_SWF_VERSION", FILE_DECODER_EVENT_INVALID_SWF_VERSION }, { "Z_DATA_ERROR", FILE_DECODER_EVENT_Z_DATA_ERROR }, { "Z_STREAM_ERROR", FILE_DECODER_EVENT_Z_STREAM_ERROR }, { "Z_BUF_ERROR", FILE_DECODER_EVENT_Z_BUF_ERROR }, { "Z_UNKNOWN_ERROR", FILE_DECODER_EVENT_Z_UNKNOWN_ERROR }, { "LZMA_DECODER_ERROR", FILE_DECODER_EVENT_LZMA_DECODER_ERROR }, { "LZMA_MEMLIMIT_ERROR", FILE_DECODER_EVENT_LZMA_MEMLIMIT_ERROR }, { "LZMA_OPTIONS_ERROR", FILE_DECODER_EVENT_LZMA_OPTIONS_ERROR }, { "LZMA_FORMAT_ERROR", FILE_DECODER_EVENT_LZMA_FORMAT_ERROR }, { "LZMA_DATA_ERROR", FILE_DECODER_EVENT_LZMA_DATA_ERROR }, { "LZMA_BUF_ERROR", FILE_DECODER_EVENT_LZMA_BUF_ERROR }, { "LZMA_UNKNOWN_ERROR", FILE_DECODER_EVENT_LZMA_UNKNOWN_ERROR }, { NULL, -1 }, }; /** \brief register inspect engine at start up time * * \note errors are fatal */ void DetectAppLayerInspectEngineRegister(const char *name, AppProto alproto, uint32_t dir, int progress, InspectEngineFuncPtr Callback) { DetectBufferTypeRegister(name); const int sm_list = DetectBufferTypeGetByName(name); if (sm_list == -1) { FatalError(SC_ERR_INITIALIZATION, "failed to register inspect engine %s", name); } if ((alproto >= ALPROTO_FAILED) || (!(dir == SIG_FLAG_TOSERVER || dir == SIG_FLAG_TOCLIENT)) || (sm_list < DETECT_SM_LIST_MATCH) || (sm_list >= SHRT_MAX) || (progress < 0 || progress >= SHRT_MAX) || (Callback == NULL)) { SCLogError(SC_ERR_INVALID_ARGUMENTS, "Invalid arguments"); BUG_ON(1); } int direction; if (dir == SIG_FLAG_TOSERVER) { direction = 0; } else { direction = 1; } DetectEngineAppInspectionEngine *new_engine = SCMalloc(sizeof(DetectEngineAppInspectionEngine)); if (unlikely(new_engine == NULL)) { exit(EXIT_FAILURE); } memset(new_engine, 0, sizeof(*new_engine)); new_engine->alproto = alproto; new_engine->dir = direction; new_engine->sm_list = sm_list; new_engine->progress = progress; new_engine->Callback = Callback; if (g_app_inspect_engines == NULL) { g_app_inspect_engines = new_engine; } else { DetectEngineAppInspectionEngine *t = g_app_inspect_engines; while (t->next != NULL) { t = t->next; } t->next = new_engine; } } /** \brief register inspect engine at start up time * * \note errors are fatal */ void DetectAppLayerInspectEngineRegister2(const char *name, AppProto alproto, uint32_t dir, int progress, InspectEngineFuncPtr2 Callback2, InspectionBufferGetDataPtr GetData) { DetectBufferTypeRegister(name); const int sm_list = DetectBufferTypeGetByName(name); if (sm_list == -1) { FatalError(SC_ERR_INITIALIZATION, "failed to register inspect engine %s", name); } if ((alproto >= ALPROTO_FAILED) || (!(dir == SIG_FLAG_TOSERVER || dir == SIG_FLAG_TOCLIENT)) || (sm_list < DETECT_SM_LIST_MATCH) || (sm_list >= SHRT_MAX) || (progress < 0 || progress >= SHRT_MAX) || (Callback2 == NULL)) { SCLogError(SC_ERR_INVALID_ARGUMENTS, "Invalid arguments"); BUG_ON(1); } else if (Callback2 == DetectEngineInspectBufferGeneric && GetData == NULL) { SCLogError(SC_ERR_INVALID_ARGUMENTS, "Invalid arguments: must register " "GetData with DetectEngineInspectBufferGeneric"); BUG_ON(1); } int direction; if (dir == SIG_FLAG_TOSERVER) { direction = 0; } else { direction = 1; } DetectEngineAppInspectionEngine *new_engine = SCMalloc(sizeof(DetectEngineAppInspectionEngine)); if (unlikely(new_engine == NULL)) { exit(EXIT_FAILURE); } memset(new_engine, 0, sizeof(*new_engine)); new_engine->alproto = alproto; new_engine->dir = direction; new_engine->sm_list = sm_list; new_engine->progress = progress; new_engine->v2.Callback = Callback2; new_engine->v2.GetData = GetData; if (g_app_inspect_engines == NULL) { g_app_inspect_engines = new_engine; } else { DetectEngineAppInspectionEngine *t = g_app_inspect_engines; while (t->next != NULL) { t = t->next; } t->next = new_engine; } } /* copy an inspect engine with transforms to a new list id. */ static void DetectAppLayerInspectEngineCopy( DetectEngineCtx *de_ctx, int sm_list, int new_list, const DetectEngineTransforms *transforms) { const DetectEngineAppInspectionEngine *t = g_app_inspect_engines; while (t) { if (t->sm_list == sm_list) { DetectEngineAppInspectionEngine *new_engine = SCCalloc(1, sizeof(DetectEngineAppInspectionEngine)); if (unlikely(new_engine == NULL)) { exit(EXIT_FAILURE); } new_engine->alproto = t->alproto; new_engine->dir = t->dir; new_engine->sm_list = new_list; /* use new list id */ new_engine->progress = t->progress; new_engine->Callback = t->Callback; new_engine->v2 = t->v2; new_engine->v2.transforms = transforms; /* assign transforms */ if (de_ctx->app_inspect_engines == NULL) { de_ctx->app_inspect_engines = new_engine; } else { DetectEngineAppInspectionEngine *list = de_ctx->app_inspect_engines; while (list->next != NULL) { list = list->next; } list->next = new_engine; } } t = t->next; } } /* copy inspect engines from global registrations to de_ctx list */ static void DetectAppLayerInspectEngineCopyListToDetectCtx(DetectEngineCtx *de_ctx) { const DetectEngineAppInspectionEngine *t = g_app_inspect_engines; while (t) { DetectEngineAppInspectionEngine *new_engine = SCCalloc(1, sizeof(DetectEngineAppInspectionEngine)); if (unlikely(new_engine == NULL)) { exit(EXIT_FAILURE); } new_engine->alproto = t->alproto; new_engine->dir = t->dir; new_engine->sm_list = t->sm_list; new_engine->progress = t->progress; new_engine->Callback = t->Callback; new_engine->v2 = t->v2; if (de_ctx->app_inspect_engines == NULL) { de_ctx->app_inspect_engines = new_engine; } else { DetectEngineAppInspectionEngine *list = de_ctx->app_inspect_engines; while (list->next != NULL) { list = list->next; } list->next = new_engine; } t = t->next; } } /** \internal * \brief append the stream inspection * * If stream inspection is MPM, then prepend it. */ static void AppendStreamInspectEngine(Signature *s, SigMatchData *stream, int direction, uint32_t id) { bool prepend = false; DetectEngineAppInspectionEngine *new_engine = SCCalloc(1, sizeof(DetectEngineAppInspectionEngine)); if (unlikely(new_engine == NULL)) { exit(EXIT_FAILURE); } if (SigMatchListSMBelongsTo(s, s->init_data->mpm_sm) == DETECT_SM_LIST_PMATCH) { SCLogDebug("stream is mpm"); prepend = true; new_engine->mpm = true; } new_engine->alproto = ALPROTO_UNKNOWN; /* all */ new_engine->dir = direction; new_engine->stream = true; new_engine->sm_list = DETECT_SM_LIST_PMATCH; new_engine->smd = stream; new_engine->Callback = DetectEngineInspectStream; new_engine->progress = 0; /* append */ if (s->app_inspect == NULL) { s->app_inspect = new_engine; new_engine->id = DE_STATE_FLAG_BASE; /* id is used as flag in stateful detect */ } else if (prepend) { new_engine->next = s->app_inspect; s->app_inspect = new_engine; new_engine->id = id; } else { DetectEngineAppInspectionEngine *a = s->app_inspect; while (a->next != NULL) { a = a->next; } a->next = new_engine; new_engine->id = id; } SCLogDebug("sid %u: engine %p/%u added", s->id, new_engine, new_engine->id); } /** * \note for the file inspect engine, the id DE_STATE_ID_FILE_INSPECT * is assigned. */ int DetectEngineAppInspectionEngine2Signature(DetectEngineCtx *de_ctx, Signature *s) { const int nlists = s->init_data->smlists_array_size; SigMatchData *ptrs[nlists]; memset(&ptrs, 0, (nlists * sizeof(SigMatchData *))); const int mpm_list = s->init_data->mpm_sm ? SigMatchListSMBelongsTo(s, s->init_data->mpm_sm) : -1; const int files_id = DetectBufferTypeGetByName("files"); /* convert lists to SigMatchData arrays */ int i = 0; for (i = DETECT_SM_LIST_DYNAMIC_START; i < nlists; i++) { if (s->init_data->smlists[i] == NULL) continue; ptrs[i] = SigMatchList2DataArray(s->init_data->smlists[i]); SCLogDebug("ptrs[%d] is set", i); } bool head_is_mpm = false; uint32_t last_id = DE_STATE_FLAG_BASE; const DetectEngineAppInspectionEngine *t = de_ctx->app_inspect_engines; while (t != NULL) { bool prepend = false; if (t->sm_list >= nlists) goto next; if (ptrs[t->sm_list] == NULL) goto next; SCLogDebug("ptrs[%d] is set", t->sm_list); if (t->alproto == ALPROTO_UNKNOWN) { /* special case, inspect engine applies to all protocols */ } else if (s->alproto != ALPROTO_UNKNOWN && s->alproto != t->alproto) goto next; if (s->flags & SIG_FLAG_TOSERVER && !(s->flags & SIG_FLAG_TOCLIENT)) { if (t->dir == 1) goto next; } else if (s->flags & SIG_FLAG_TOCLIENT && !(s->flags & SIG_FLAG_TOSERVER)) { if (t->dir == 0) goto next; } DetectEngineAppInspectionEngine *new_engine = SCCalloc(1, sizeof(DetectEngineAppInspectionEngine)); if (unlikely(new_engine == NULL)) { exit(EXIT_FAILURE); } if (mpm_list == t->sm_list) { SCLogDebug("%s is mpm", DetectBufferTypeGetNameById(de_ctx, t->sm_list)); prepend = true; head_is_mpm = true; new_engine->mpm = true; } new_engine->alproto = t->alproto; new_engine->dir = t->dir; new_engine->sm_list = t->sm_list; new_engine->smd = ptrs[new_engine->sm_list]; new_engine->Callback = t->Callback; new_engine->progress = t->progress; new_engine->v2 = t->v2; SCLogDebug("sm_list %d new_engine->v2 %p/%p/%p", new_engine->sm_list, new_engine->v2.Callback, new_engine->v2.GetData, new_engine->v2.transforms); if (s->app_inspect == NULL) { s->app_inspect = new_engine; if (new_engine->sm_list == files_id) { SCLogDebug("sid %u: engine %p/%u is FILE ENGINE", s->id, new_engine, new_engine->id); new_engine->id = DE_STATE_ID_FILE_INSPECT; } else { new_engine->id = DE_STATE_FLAG_BASE; /* id is used as flag in stateful detect */ } /* prepend engine if forced or if our engine has a lower progress. */ } else if (prepend || (!head_is_mpm && s->app_inspect->progress > new_engine->progress)) { new_engine->next = s->app_inspect; s->app_inspect = new_engine; if (new_engine->sm_list == files_id) { SCLogDebug("sid %u: engine %p/%u is FILE ENGINE", s->id, new_engine, new_engine->id); new_engine->id = DE_STATE_ID_FILE_INSPECT; } else { new_engine->id = ++last_id; } } else { DetectEngineAppInspectionEngine *a = s->app_inspect; while (a->next != NULL) { if (a->next && a->next->progress > new_engine->progress) { break; } a = a->next; } new_engine->next = a->next; a->next = new_engine; if (new_engine->sm_list == files_id) { SCLogDebug("sid %u: engine %p/%u is FILE ENGINE", s->id, new_engine, new_engine->id); new_engine->id = DE_STATE_ID_FILE_INSPECT; } else { new_engine->id = ++last_id; } } SCLogDebug("sid %u: engine %p/%u added", s->id, new_engine, new_engine->id); s->init_data->init_flags |= SIG_FLAG_INIT_STATE_MATCH; next: t = t->next; } if ((s->init_data->init_flags & SIG_FLAG_INIT_STATE_MATCH) && s->init_data->smlists[DETECT_SM_LIST_PMATCH] != NULL) { /* if engine is added multiple times, we pass it the same list */ SigMatchData *stream = SigMatchList2DataArray(s->init_data->smlists[DETECT_SM_LIST_PMATCH]); BUG_ON(stream == NULL); if (s->flags & SIG_FLAG_TOSERVER && !(s->flags & SIG_FLAG_TOCLIENT)) { AppendStreamInspectEngine(s, stream, 0, last_id + 1); } else if (s->flags & SIG_FLAG_TOCLIENT && !(s->flags & SIG_FLAG_TOSERVER)) { AppendStreamInspectEngine(s, stream, 1, last_id + 1); } else { AppendStreamInspectEngine(s, stream, 0, last_id + 1); AppendStreamInspectEngine(s, stream, 1, last_id + 1); } if (s->init_data->init_flags & SIG_FLAG_INIT_NEED_FLUSH) { s->flags |= SIG_FLAG_FLUSH; } } #ifdef DEBUG const DetectEngineAppInspectionEngine *iter = s->app_inspect; while (iter) { SCLogDebug("%u: engine %s id %u progress %d %s", s->id, DetectBufferTypeGetNameById(de_ctx, iter->sm_list), iter->id, iter->progress, iter->sm_list == mpm_list ? "MPM":""); iter = iter->next; } #endif return 0; } /** \brief free app inspect engines for a signature * * For lists that are registered multiple times, like http_header and * http_cookie, making the engines owner of the lists is complicated. * Multiple engines in a sig may be pointing to the same list. To * address this the 'free' code needs to be extra careful about not * double freeing, so it takes an approach to first fill an array * of the to-free pointers before freeing them. */ void DetectEngineAppInspectionEngineSignatureFree(Signature *s) { int nlists = 0; DetectEngineAppInspectionEngine *ie = s->app_inspect; while (ie) { nlists = MAX(ie->sm_list, nlists); ie = ie->next; } if (nlists == 0) return; nlists++; SigMatchData *ptrs[nlists]; memset(&ptrs, 0, (nlists * sizeof(SigMatchData *))); /* free engines and put smd in the array */ ie = s->app_inspect; while (ie) { DetectEngineAppInspectionEngine *next = ie->next; BUG_ON(ptrs[ie->sm_list] != NULL && ptrs[ie->sm_list] != ie->smd); ptrs[ie->sm_list] = ie->smd; SCFree(ie); ie = next; } /* free the smds */ int i; for (i = 0; i < nlists; i++) { if (ptrs[i] == NULL) continue; SigMatchData *smd = ptrs[i]; while(1) { if (sigmatch_table[smd->type].Free != NULL) { sigmatch_table[smd->type].Free(smd->ctx); } if (smd->is_last) break; smd++; } SCFree(ptrs[i]); } } /* code for registering buffers */ #include "util-hash-lookup3.h" static HashListTable *g_buffer_type_hash = NULL; static int g_buffer_type_id = DETECT_SM_LIST_DYNAMIC_START; static int g_buffer_type_reg_closed = 0; static DetectEngineTransforms no_transforms = { .transforms = { 0 }, .cnt = 0, }; int DetectBufferTypeMaxId(void) { return g_buffer_type_id; } static uint32_t DetectBufferTypeHashFunc(HashListTable *ht, void *data, uint16_t datalen) { const DetectBufferType *map = (DetectBufferType *)data; uint32_t hash = 0; hash = hashlittle_safe(map->string, strlen(map->string), 0); hash += hashlittle_safe((uint8_t *)&map->transforms, sizeof(map->transforms), 0); hash %= ht->array_size; return hash; } static char DetectBufferTypeCompareFunc(void *data1, uint16_t len1, void *data2, uint16_t len2) { DetectBufferType *map1 = (DetectBufferType *)data1; DetectBufferType *map2 = (DetectBufferType *)data2; int r = (strcmp(map1->string, map2->string) == 0); r &= (memcmp((uint8_t *)&map1->transforms, (uint8_t *)&map2->transforms, sizeof(map2->transforms)) == 0); return r; } static void DetectBufferTypeFreeFunc(void *data) { DetectBufferType *map = (DetectBufferType *)data; if (map != NULL) { SCFree(map); } } static int DetectBufferTypeInit(void) { BUG_ON(g_buffer_type_hash); g_buffer_type_hash = HashListTableInit(256, DetectBufferTypeHashFunc, DetectBufferTypeCompareFunc, DetectBufferTypeFreeFunc); if (g_buffer_type_hash == NULL) return -1; return 0; } #if 0 static void DetectBufferTypeFree(void) { if (g_buffer_type_hash == NULL) return; HashListTableFree(g_buffer_type_hash); g_buffer_type_hash = NULL; return; } #endif static int DetectBufferTypeAdd(const char *string) { DetectBufferType *map = SCCalloc(1, sizeof(*map)); if (map == NULL) return -1; map->string = string; map->id = g_buffer_type_id++; BUG_ON(HashListTableAdd(g_buffer_type_hash, (void *)map, 0) != 0); SCLogDebug("buffer %s registered with id %d", map->string, map->id); return map->id; } static DetectBufferType *DetectBufferTypeLookupByName(const char *string) { DetectBufferType map = { (char *)string, NULL, 0, 0, 0, 0, false, NULL, NULL, no_transforms }; DetectBufferType *res = HashListTableLookup(g_buffer_type_hash, &map, 0); return res; } int DetectBufferTypeRegister(const char *name) { BUG_ON(g_buffer_type_reg_closed); if (g_buffer_type_hash == NULL) DetectBufferTypeInit(); DetectBufferType *exists = DetectBufferTypeLookupByName(name); if (!exists) { return DetectBufferTypeAdd(name); } else { return exists->id; } } void DetectBufferTypeSupportsPacket(const char *name) { BUG_ON(g_buffer_type_reg_closed); DetectBufferTypeRegister(name); DetectBufferType *exists = DetectBufferTypeLookupByName(name); BUG_ON(!exists); exists->packet = TRUE; SCLogDebug("%p %s -- %d supports packet inspection", exists, name, exists->id); } void DetectBufferTypeSupportsMpm(const char *name) { BUG_ON(g_buffer_type_reg_closed); DetectBufferTypeRegister(name); DetectBufferType *exists = DetectBufferTypeLookupByName(name); BUG_ON(!exists); exists->mpm = TRUE; SCLogDebug("%p %s -- %d supports mpm", exists, name, exists->id); } void DetectBufferTypeSupportsTransformations(const char *name) { BUG_ON(g_buffer_type_reg_closed); DetectBufferTypeRegister(name); DetectBufferType *exists = DetectBufferTypeLookupByName(name); BUG_ON(!exists); exists->supports_transforms = true; SCLogDebug("%p %s -- %d supports transformations", exists, name, exists->id); } int DetectBufferTypeGetByName(const char *name) { DetectBufferType *exists = DetectBufferTypeLookupByName(name); if (!exists) { return -1; } return exists->id; } const char *DetectBufferTypeGetNameById(const DetectEngineCtx *de_ctx, const int id) { BUG_ON(id < 0 || (uint32_t)id >= de_ctx->buffer_type_map_elements); BUG_ON(de_ctx->buffer_type_map == NULL); if (de_ctx->buffer_type_map[id] == NULL) return NULL; return de_ctx->buffer_type_map[id]->string; } static const DetectBufferType *DetectBufferTypeGetById(const DetectEngineCtx *de_ctx, const int id) { BUG_ON(id < 0 || (uint32_t)id >= de_ctx->buffer_type_map_elements); BUG_ON(de_ctx->buffer_type_map == NULL); return de_ctx->buffer_type_map[id]; } void DetectBufferTypeSetDescriptionByName(const char *name, const char *desc) { DetectBufferType *exists = DetectBufferTypeLookupByName(name); if (!exists) { return; } exists->description = desc; } const char *DetectBufferTypeGetDescriptionById(const DetectEngineCtx *de_ctx, const int id) { const DetectBufferType *exists = DetectBufferTypeGetById(de_ctx, id); if (!exists) { return NULL; } return exists->description; } const char *DetectBufferTypeGetDescriptionByName(const char *name) { const DetectBufferType *exists = DetectBufferTypeLookupByName(name); if (!exists) { return NULL; } return exists->description; } bool DetectBufferTypeSupportsPacketGetById(const DetectEngineCtx *de_ctx, const int id) { const DetectBufferType *map = DetectBufferTypeGetById(de_ctx, id); if (map == NULL) return FALSE; SCLogDebug("map %p id %d packet? %d", map, id, map->packet); return map->packet; } bool DetectBufferTypeSupportsMpmGetById(const DetectEngineCtx *de_ctx, const int id) { const DetectBufferType *map = DetectBufferTypeGetById(de_ctx, id); if (map == NULL) return FALSE; SCLogDebug("map %p id %d mpm? %d", map, id, map->mpm); return map->mpm; } void DetectBufferTypeRegisterSetupCallback(const char *name, void (*SetupCallback)(const DetectEngineCtx *, Signature *)) { BUG_ON(g_buffer_type_reg_closed); DetectBufferTypeRegister(name); DetectBufferType *exists = DetectBufferTypeLookupByName(name); BUG_ON(!exists); exists->SetupCallback = SetupCallback; } void DetectBufferRunSetupCallback(const DetectEngineCtx *de_ctx, const int id, Signature *s) { const DetectBufferType *map = DetectBufferTypeGetById(de_ctx, id); if (map && map->SetupCallback) { map->SetupCallback(de_ctx, s); } } void DetectBufferTypeRegisterValidateCallback(const char *name, _Bool (*ValidateCallback)(const Signature *, const char **sigerror)) { BUG_ON(g_buffer_type_reg_closed); DetectBufferTypeRegister(name); DetectBufferType *exists = DetectBufferTypeLookupByName(name); BUG_ON(!exists); exists->ValidateCallback = ValidateCallback; } bool DetectBufferRunValidateCallback(const DetectEngineCtx *de_ctx, const int id, const Signature *s, const char **sigerror) { const DetectBufferType *map = DetectBufferTypeGetById(de_ctx, id); if (map && map->ValidateCallback) { return map->ValidateCallback(s, sigerror); } return TRUE; } int DetectBufferSetActiveList(Signature *s, const int list) { BUG_ON(s->init_data == NULL); if (s->init_data->list && s->init_data->transform_cnt) { return -1; } s->init_data->list = list; s->init_data->list_set = true; return 0; } int DetectBufferGetActiveList(DetectEngineCtx *de_ctx, Signature *s) { BUG_ON(s->init_data == NULL); if (s->init_data->list && s->init_data->transform_cnt) { SCLogDebug("buffer %d has transform(s) registered: %d", s->init_data->list, s->init_data->transforms[0]); int new_list = DetectBufferTypeGetByIdTransforms(de_ctx, s->init_data->list, s->init_data->transforms, s->init_data->transform_cnt); if (new_list == -1) { return -1; } SCLogDebug("new_list %d", new_list); s->init_data->list = new_list; s->init_data->list_set = false; // reset transforms now that we've set up the list s->init_data->transform_cnt = 0; } return 0; } void InspectionBufferClean(DetectEngineThreadCtx *det_ctx) { /* single buffers */ for (uint32_t i = 0; i < det_ctx->inspect.to_clear_idx; i++) { const uint32_t idx = det_ctx->inspect.to_clear_queue[i]; InspectionBuffer *buffer = &det_ctx->inspect.buffers[idx]; buffer->inspect = NULL; } det_ctx->inspect.to_clear_idx = 0; /* multi buffers */ for (uint32_t i = 0; i < det_ctx->multi_inspect.to_clear_idx; i++) { const uint32_t idx = det_ctx->multi_inspect.to_clear_queue[i]; InspectionBufferMultipleForList *mbuffer = &det_ctx->multi_inspect.buffers[idx]; for (uint32_t x = 0; x <= mbuffer->max; x++) { InspectionBuffer *buffer = &mbuffer->inspection_buffers[x]; buffer->inspect = NULL; } mbuffer->init = 0; mbuffer->max = 0; } det_ctx->multi_inspect.to_clear_idx = 0; } InspectionBuffer *InspectionBufferGet(DetectEngineThreadCtx *det_ctx, const int list_id) { InspectionBuffer *buffer = &det_ctx->inspect.buffers[list_id]; if (buffer->inspect == NULL) { det_ctx->inspect.to_clear_queue[det_ctx->inspect.to_clear_idx++] = list_id; } return buffer; } /** \brief for a InspectionBufferMultipleForList get a InspectionBuffer * \param fb the multiple buffer array * \param local_id the index to get a buffer * \param buffer the inspect buffer or NULL in case of error */ InspectionBuffer *InspectionBufferMultipleForListGet(InspectionBufferMultipleForList *fb, uint32_t local_id) { if (local_id >= fb->size) { uint32_t old_size = fb->size; uint32_t new_size = local_id + 1; uint32_t grow_by = new_size - old_size; SCLogDebug("size is %u, need %u, so growing by %u", old_size, new_size, grow_by); SCLogDebug("fb->inspection_buffers %p", fb->inspection_buffers); void *ptr = SCRealloc(fb->inspection_buffers, (local_id + 1) * sizeof(InspectionBuffer)); if (ptr == NULL) return NULL; InspectionBuffer *to_zero = (InspectionBuffer *)ptr + old_size; SCLogDebug("ptr %p to_zero %p", ptr, to_zero); memset((uint8_t *)to_zero, 0, (grow_by * sizeof(InspectionBuffer))); fb->inspection_buffers = ptr; fb->size = new_size; } fb->max = MAX(fb->max, local_id); InspectionBuffer *buffer = &fb->inspection_buffers[local_id]; SCLogDebug("using file_data buffer %p", buffer); return buffer; } InspectionBufferMultipleForList *InspectionBufferGetMulti(DetectEngineThreadCtx *det_ctx, const int list_id) { InspectionBufferMultipleForList *buffer = &det_ctx->multi_inspect.buffers[list_id]; if (!buffer->init) { det_ctx->multi_inspect.to_clear_queue[det_ctx->multi_inspect.to_clear_idx++] = list_id; buffer->init = 1; } return buffer; } void InspectionBufferInit(InspectionBuffer *buffer, uint32_t initial_size) { memset(buffer, 0, sizeof(*buffer)); buffer->buf = SCCalloc(initial_size, sizeof(uint8_t)); if (buffer->buf != NULL) { buffer->size = initial_size; } } /** \brief setup the buffer with our initial data */ void InspectionBufferSetup(InspectionBuffer *buffer, const uint8_t *data, const uint32_t data_len) { buffer->inspect = buffer->orig = data; buffer->inspect_len = buffer->orig_len = data_len; buffer->len = 0; } void InspectionBufferFree(InspectionBuffer *buffer) { if (buffer->buf != NULL) { SCFree(buffer->buf); } memset(buffer, 0, sizeof(*buffer)); } /** * \brief make sure that the buffer has at least 'min_size' bytes * Expand the buffer if necessary */ void InspectionBufferCheckAndExpand(InspectionBuffer *buffer, uint32_t min_size) { if (likely(buffer->size >= min_size)) return; uint32_t new_size = (buffer->size == 0) ? 4096 : buffer->size; while (new_size < min_size) { new_size *= 2; } void *ptr = SCRealloc(buffer->buf, new_size); if (ptr != NULL) { buffer->buf = ptr; buffer->size = new_size; } } void InspectionBufferCopy(InspectionBuffer *buffer, uint8_t *buf, uint32_t buf_len) { InspectionBufferCheckAndExpand(buffer, buf_len); if (buffer->size) { uint32_t copy_size = MIN(buf_len, buffer->size); memcpy(buffer->buf, buf, copy_size); buffer->inspect = buffer->buf; buffer->inspect_len = copy_size; } } void InspectionBufferApplyTransforms(InspectionBuffer *buffer, const DetectEngineTransforms *transforms) { if (transforms) { for (int i = 0; i < DETECT_TRANSFORMS_MAX; i++) { const int id = transforms->transforms[i]; if (id == 0) break; BUG_ON(sigmatch_table[id].Transform == NULL); sigmatch_table[id].Transform(buffer); SCLogDebug("applied transform %s", sigmatch_table[id].name); } } } static void DetectBufferTypeSetupDetectEngine(DetectEngineCtx *de_ctx) { const int size = g_buffer_type_id; BUG_ON(!(size > 0)); de_ctx->buffer_type_map = SCCalloc(size, sizeof(DetectBufferType *)); BUG_ON(!de_ctx->buffer_type_map); de_ctx->buffer_type_map_elements = size; SCLogDebug("de_ctx->buffer_type_map %p with %u members", de_ctx->buffer_type_map, size); SCLogDebug("DETECT_SM_LIST_DYNAMIC_START %u", DETECT_SM_LIST_DYNAMIC_START); HashListTableBucket *b = HashListTableGetListHead(g_buffer_type_hash); while (b) { DetectBufferType *map = HashListTableGetListData(b); de_ctx->buffer_type_map[map->id] = map; SCLogDebug("name %s id %d mpm %s packet %s -- %s. " "Callbacks: Setup %p Validate %p", map->string, map->id, map->mpm ? "true" : "false", map->packet ? "true" : "false", map->description, map->SetupCallback, map->ValidateCallback); b = HashListTableGetListNext(b); } de_ctx->buffer_type_hash = HashListTableInit(256, DetectBufferTypeHashFunc, DetectBufferTypeCompareFunc, DetectBufferTypeFreeFunc); if (de_ctx->buffer_type_hash == NULL) { BUG_ON(1); } de_ctx->buffer_type_id = g_buffer_type_id; PrefilterInit(de_ctx); DetectMpmInitializeAppMpms(de_ctx); DetectAppLayerInspectEngineCopyListToDetectCtx(de_ctx); } static void DetectBufferTypeFreeDetectEngine(DetectEngineCtx *de_ctx) { if (de_ctx) { if (de_ctx->buffer_type_map) SCFree(de_ctx->buffer_type_map); if (de_ctx->buffer_type_hash) HashListTableFree(de_ctx->buffer_type_hash); DetectEngineAppInspectionEngine *ilist = de_ctx->app_inspect_engines; while (ilist) { DetectEngineAppInspectionEngine *next = ilist->next; SCFree(ilist); ilist = next; } DetectMpmAppLayerRegistery *mlist = de_ctx->app_mpms_list; while (mlist) { DetectMpmAppLayerRegistery *next = mlist->next; SCFree(mlist); mlist = next; } PrefilterDeinit(de_ctx); } } void DetectBufferTypeCloseRegistration(void) { BUG_ON(g_buffer_type_hash == NULL); g_buffer_type_reg_closed = 1; } int DetectBufferTypeGetByIdTransforms(DetectEngineCtx *de_ctx, const int id, int *transforms, int transform_cnt) { const DetectBufferType *base_map = DetectBufferTypeGetById(de_ctx, id); if (!base_map) { return -1; } if (!base_map->supports_transforms) { SCLogError(SC_ERR_INVALID_SIGNATURE, "buffer '%s' does not support transformations", base_map->string); return -1; } DetectEngineTransforms t; memset(&t, 0, sizeof(t)); for (int i = 0; i < transform_cnt; i++) { t.transforms[i] = transforms[i]; } t.cnt = transform_cnt; DetectBufferType lookup_map = { (char *)base_map->string, NULL, 0, 0, 0, 0, false, NULL, NULL, t }; DetectBufferType *res = HashListTableLookup(de_ctx->buffer_type_hash, &lookup_map, 0); SCLogDebug("res %p", res); if (res != NULL) { return res->id; } DetectBufferType *map = SCCalloc(1, sizeof(*map)); if (map == NULL) return -1; map->string = base_map->string; map->id = de_ctx->buffer_type_id++; map->parent_id = base_map->id; map->transforms = t; map->mpm = base_map->mpm; map->SetupCallback = base_map->SetupCallback; map->ValidateCallback = base_map->ValidateCallback; DetectAppLayerMpmRegisterByParentId(de_ctx, map->id, map->parent_id, &map->transforms); BUG_ON(HashListTableAdd(de_ctx->buffer_type_hash, (void *)map, 0) != 0); SCLogDebug("buffer %s registered with id %d, parent %d", map->string, map->id, map->parent_id); if (map->id >= 0 && (uint32_t)map->id >= de_ctx->buffer_type_map_elements) { void *ptr = SCRealloc(de_ctx->buffer_type_map, (map->id + 1) * sizeof(DetectBufferType *)); BUG_ON(ptr == NULL); SCLogDebug("de_ctx->buffer_type_map resized to %u (was %u)", (map->id + 1), de_ctx->buffer_type_map_elements); de_ctx->buffer_type_map = ptr; de_ctx->buffer_type_map[map->id] = map; de_ctx->buffer_type_map_elements = map->id + 1; DetectAppLayerInspectEngineCopy(de_ctx, map->parent_id, map->id, &map->transforms); } return map->id; } /* code to control the main thread to do a reload */ enum DetectEngineSyncState { IDLE, /**< ready to start a reload */ RELOAD, /**< command main thread to do the reload */ }; typedef struct DetectEngineSyncer_ { SCMutex m; enum DetectEngineSyncState state; } DetectEngineSyncer; static DetectEngineSyncer detect_sync = { SCMUTEX_INITIALIZER, IDLE }; /* tell main to start reloading */ int DetectEngineReloadStart(void) { int r = 0; SCMutexLock(&detect_sync.m); if (detect_sync.state == IDLE) { detect_sync.state = RELOAD; } else { r = -1; } SCMutexUnlock(&detect_sync.m); return r; } /* main thread checks this to see if it should start */ int DetectEngineReloadIsStart(void) { int r = 0; SCMutexLock(&detect_sync.m); if (detect_sync.state == RELOAD) { r = 1; } SCMutexUnlock(&detect_sync.m); return r; } /* main thread sets done when it's done */ void DetectEngineReloadSetIdle(void) { SCMutexLock(&detect_sync.m); detect_sync.state = IDLE; SCMutexUnlock(&detect_sync.m); } /* caller loops this until it returns 1 */ int DetectEngineReloadIsIdle(void) { int r = 0; SCMutexLock(&detect_sync.m); if (detect_sync.state == IDLE) { r = 1; } SCMutexUnlock(&detect_sync.m); return r; } /** \brief Do the content inspection & validation for a signature * * \param de_ctx Detection engine context * \param det_ctx Detection engine thread context * \param s Signature to inspect * \param sm SigMatch to inspect * \param f Flow * \param flags app layer flags * \param state App layer state * * \retval 0 no match * \retval 1 match */ int DetectEngineInspectGenericList(ThreadVars *tv, const DetectEngineCtx *de_ctx, DetectEngineThreadCtx *det_ctx, const Signature *s, const SigMatchData *smd, Flow *f, const uint8_t flags, void *alstate, void *txv, uint64_t tx_id) { SCLogDebug("running match functions, sm %p", smd); if (smd != NULL) { while (1) { int match = 0; #ifdef PROFILING KEYWORD_PROFILING_START; #endif match = sigmatch_table[smd->type]. AppLayerTxMatch(tv, det_ctx, f, flags, alstate, txv, s, smd->ctx); #ifdef PROFILING KEYWORD_PROFILING_END(det_ctx, smd->type, (match == 1)); #endif if (match == 0) return DETECT_ENGINE_INSPECT_SIG_NO_MATCH; if (match == 2) { return DETECT_ENGINE_INSPECT_SIG_CANT_MATCH; } if (smd->is_last) break; smd++; } } return DETECT_ENGINE_INSPECT_SIG_MATCH; } /** * \brief Do the content inspection & validation for a signature * * \param de_ctx Detection engine context * \param det_ctx Detection engine thread context * \param s Signature to inspect * \param f Flow * \param flags app layer flags * \param state App layer state * * \retval 0 no match. * \retval 1 match. * \retval 2 Sig can't match. */ int DetectEngineInspectBufferGeneric( DetectEngineCtx *de_ctx, DetectEngineThreadCtx *det_ctx, const DetectEngineAppInspectionEngine *engine, const Signature *s, Flow *f, uint8_t flags, void *alstate, void *txv, uint64_t tx_id) { const int list_id = engine->sm_list; SCLogDebug("running inspect on %d", list_id); const bool eof = (AppLayerParserGetStateProgress(f->proto, f->alproto, txv, flags) > engine->progress); SCLogDebug("list %d mpm? %s transforms %p", engine->sm_list, engine->mpm ? "true" : "false", engine->v2.transforms); /* if prefilter didn't already run, we need to consider transformations */ const DetectEngineTransforms *transforms = NULL; if (!engine->mpm) { transforms = engine->v2.transforms; } const InspectionBuffer *buffer = engine->v2.GetData(det_ctx, transforms, f, flags, txv, list_id); if (unlikely(buffer == NULL)) { return eof ? DETECT_ENGINE_INSPECT_SIG_CANT_MATCH : DETECT_ENGINE_INSPECT_SIG_NO_MATCH; } const uint32_t data_len = buffer->inspect_len; const uint8_t *data = buffer->inspect; const uint64_t offset = buffer->inspect_offset; uint8_t ci_flags = eof ? DETECT_CI_FLAGS_END : 0; ci_flags |= (offset == 0 ? DETECT_CI_FLAGS_START : 0); det_ctx->discontinue_matching = 0; det_ctx->buffer_offset = 0; det_ctx->inspection_recursion_counter = 0; /* Inspect all the uricontents fetched on each * transaction at the app layer */ int r = DetectEngineContentInspection(de_ctx, det_ctx, s, engine->smd, f, (uint8_t *)data, data_len, offset, ci_flags, DETECT_ENGINE_CONTENT_INSPECTION_MODE_STATE, NULL); if (r == 1) { return DETECT_ENGINE_INSPECT_SIG_MATCH; } else { return eof ? DETECT_ENGINE_INSPECT_SIG_CANT_MATCH : DETECT_ENGINE_INSPECT_SIG_NO_MATCH; } } /* nudge capture loops to wake up */ static void BreakCapture(void) { SCMutexLock(&tv_root_lock); ThreadVars *tv = tv_root[TVT_PPT]; while (tv) { /* find the correct slot */ TmSlot *slots = tv->tm_slots; while (slots != NULL) { if (suricata_ctl_flags != 0) { SCMutexUnlock(&tv_root_lock); return; } TmModule *tm = TmModuleGetById(slots->tm_id); if (!(tm->flags & TM_FLAG_RECEIVE_TM)) { slots = slots->slot_next; continue; } /* signal capture method that we need a packet. */ TmThreadsSetFlag(tv, THV_CAPTURE_INJECT_PKT); /* if the method supports it, BreakLoop. Otherwise we rely on * the capture method's recv timeout */ if (tm->PktAcqLoop && tm->PktAcqBreakLoop) { tm->PktAcqBreakLoop(tv, SC_ATOMIC_GET(slots->slot_data)); } break; } tv = tv->next; } SCMutexUnlock(&tv_root_lock); } /** \internal * \brief inject a pseudo packet into each detect thread that doesn't use the * new det_ctx yet */ static void InjectPackets(ThreadVars **detect_tvs, DetectEngineThreadCtx **new_det_ctx, int no_of_detect_tvs) { int i; /* inject a fake packet if the detect thread isn't using the new ctx yet, * this speeds up the process */ for (i = 0; i < no_of_detect_tvs; i++) { if (SC_ATOMIC_GET(new_det_ctx[i]->so_far_used_by_detect) != 1) { if (detect_tvs[i]->inq != NULL) { Packet *p = PacketGetFromAlloc(); if (p != NULL) { p->flags |= PKT_PSEUDO_STREAM_END; PacketQueue *q = &trans_q[detect_tvs[i]->inq->id]; SCMutexLock(&q->mutex_q); PacketEnqueue(q, p); SCCondSignal(&q->cond_q); SCMutexUnlock(&q->mutex_q); } } } } } /** \internal * \brief Update detect threads with new detect engine * * Atomically update each detect thread with a new thread context * that is associated to the new detection engine(s). * * If called in unix socket mode, it's possible that we don't have * detect threads yet. * * \retval -1 error * \retval 0 no detection threads * \retval 1 successful reload */ static int DetectEngineReloadThreads(DetectEngineCtx *new_de_ctx) { SCEnter(); int i = 0; int no_of_detect_tvs = 0; ThreadVars *tv = NULL; /* count detect threads in use */ SCMutexLock(&tv_root_lock); tv = tv_root[TVT_PPT]; while (tv) { /* obtain the slots for this TV */ TmSlot *slots = tv->tm_slots; while (slots != NULL) { TmModule *tm = TmModuleGetById(slots->tm_id); if (suricata_ctl_flags != 0) { SCLogInfo("rule reload interupted by engine shutdown"); SCMutexUnlock(&tv_root_lock); return -1; } if (!(tm->flags & TM_FLAG_DETECT_TM)) { slots = slots->slot_next; continue; } no_of_detect_tvs++; break; } tv = tv->next; } SCMutexUnlock(&tv_root_lock); /* can be zero in unix socket mode */ if (no_of_detect_tvs == 0) { return 0; } /* prepare swap structures */ DetectEngineThreadCtx *old_det_ctx[no_of_detect_tvs]; DetectEngineThreadCtx *new_det_ctx[no_of_detect_tvs]; ThreadVars *detect_tvs[no_of_detect_tvs]; memset(old_det_ctx, 0x00, (no_of_detect_tvs * sizeof(DetectEngineThreadCtx *))); memset(new_det_ctx, 0x00, (no_of_detect_tvs * sizeof(DetectEngineThreadCtx *))); memset(detect_tvs, 0x00, (no_of_detect_tvs * sizeof(ThreadVars *))); /* start the process of swapping detect threads ctxs */ /* get reference to tv's and setup new_det_ctx array */ SCMutexLock(&tv_root_lock); tv = tv_root[TVT_PPT]; while (tv) { /* obtain the slots for this TV */ TmSlot *slots = tv->tm_slots; while (slots != NULL) { TmModule *tm = TmModuleGetById(slots->tm_id); if (suricata_ctl_flags != 0) { SCMutexUnlock(&tv_root_lock); goto error; } if (!(tm->flags & TM_FLAG_DETECT_TM)) { slots = slots->slot_next; continue; } old_det_ctx[i] = FlowWorkerGetDetectCtxPtr(SC_ATOMIC_GET(slots->slot_data)); detect_tvs[i] = tv; new_det_ctx[i] = DetectEngineThreadCtxInitForReload(tv, new_de_ctx, 1); if (new_det_ctx[i] == NULL) { SCLogError(SC_ERR_LIVE_RULE_SWAP, "Detect engine thread init " "failure in live rule swap. Let's get out of here"); SCMutexUnlock(&tv_root_lock); goto error; } SCLogDebug("live rule swap created new det_ctx - %p and de_ctx " "- %p\n", new_det_ctx[i], new_de_ctx); i++; break; } tv = tv->next; } BUG_ON(i != no_of_detect_tvs); /* atomicly replace the det_ctx data */ i = 0; tv = tv_root[TVT_PPT]; while (tv) { /* find the correct slot */ TmSlot *slots = tv->tm_slots; while (slots != NULL) { if (suricata_ctl_flags != 0) { SCMutexUnlock(&tv_root_lock); return -1; } TmModule *tm = TmModuleGetById(slots->tm_id); if (!(tm->flags & TM_FLAG_DETECT_TM)) { slots = slots->slot_next; continue; } SCLogDebug("swapping new det_ctx - %p with older one - %p", new_det_ctx[i], SC_ATOMIC_GET(slots->slot_data)); FlowWorkerReplaceDetectCtx(SC_ATOMIC_GET(slots->slot_data), new_det_ctx[i++]); break; } tv = tv->next; } SCMutexUnlock(&tv_root_lock); /* threads now all have new data, however they may not have started using * it and may still use the old data */ SCLogDebug("Live rule swap has swapped %d old det_ctx's with new ones, " "along with the new de_ctx", no_of_detect_tvs); InjectPackets(detect_tvs, new_det_ctx, no_of_detect_tvs); for (i = 0; i < no_of_detect_tvs; i++) { int break_out = 0; usleep(1000); while (SC_ATOMIC_GET(new_det_ctx[i]->so_far_used_by_detect) != 1) { if (suricata_ctl_flags != 0) { break_out = 1; break; } BreakCapture(); usleep(1000); } if (break_out) break; SCLogDebug("new_det_ctx - %p used by detect engine", new_det_ctx[i]); } /* this is to make sure that if someone initiated shutdown during a live * rule swap, the live rule swap won't clean up the old det_ctx and * de_ctx, till all detect threads have stopped working and sitting * silently after setting RUNNING_DONE flag and while waiting for * THV_DEINIT flag */ if (i != no_of_detect_tvs) { // not all threads we swapped tv = tv_root[TVT_PPT]; while (tv) { /* obtain the slots for this TV */ TmSlot *slots = tv->tm_slots; while (slots != NULL) { TmModule *tm = TmModuleGetById(slots->tm_id); if (!(tm->flags & TM_FLAG_DETECT_TM)) { slots = slots->slot_next; continue; } while (!TmThreadsCheckFlag(tv, THV_RUNNING_DONE)) { usleep(100); } slots = slots->slot_next; } tv = tv->next; } } /* free all the ctxs */ for (i = 0; i < no_of_detect_tvs; i++) { SCLogDebug("Freeing old_det_ctx - %p used by detect", old_det_ctx[i]); DetectEngineThreadCtxDeinit(NULL, old_det_ctx[i]); } SRepReloadComplete(); return 1; error: for (i = 0; i < no_of_detect_tvs; i++) { if (new_det_ctx[i] != NULL) DetectEngineThreadCtxDeinit(NULL, new_det_ctx[i]); } return -1; } static DetectEngineCtx *DetectEngineCtxInitReal(enum DetectEngineType type, const char *prefix) { DetectEngineCtx *de_ctx = SCMalloc(sizeof(DetectEngineCtx)); if (unlikely(de_ctx == NULL)) goto error; memset(de_ctx,0,sizeof(DetectEngineCtx)); memset(&de_ctx->sig_stat, 0, sizeof(SigFileLoaderStat)); TAILQ_INIT(&de_ctx->sig_stat.failed_sigs); de_ctx->sigerror = NULL; de_ctx->type = type; if (type == DETECT_ENGINE_TYPE_DD_STUB || type == DETECT_ENGINE_TYPE_MT_STUB) { de_ctx->version = DetectEngineGetVersion(); SCLogDebug("stub %u with version %u", type, de_ctx->version); return de_ctx; } if (prefix != NULL) { strlcpy(de_ctx->config_prefix, prefix, sizeof(de_ctx->config_prefix)); } if (ConfGetBool("engine.init-failure-fatal", (int *)&(de_ctx->failure_fatal)) != 1) { SCLogDebug("ConfGetBool could not load the value."); } de_ctx->mpm_matcher = PatternMatchDefaultMatcher(); de_ctx->spm_matcher = SinglePatternMatchDefaultMatcher(); SCLogConfig("pattern matchers: MPM: %s, SPM: %s", mpm_table[de_ctx->mpm_matcher].name, spm_table[de_ctx->spm_matcher].name); de_ctx->spm_global_thread_ctx = SpmInitGlobalThreadCtx(de_ctx->spm_matcher); if (de_ctx->spm_global_thread_ctx == NULL) { SCLogDebug("Unable to alloc SpmGlobalThreadCtx."); goto error; } if (DetectEngineCtxLoadConf(de_ctx) == -1) { goto error; } SigGroupHeadHashInit(de_ctx); MpmStoreInit(de_ctx); ThresholdHashInit(de_ctx); DetectParseDupSigHashInit(de_ctx); DetectAddressMapInit(de_ctx); DetectMetadataHashInit(de_ctx); DetectBufferTypeSetupDetectEngine(de_ctx); /* init iprep... ignore errors for now */ (void)SRepInit(de_ctx); SCClassConfLoadClassficationConfigFile(de_ctx, NULL); SCRConfLoadReferenceConfigFile(de_ctx, NULL); if (ActionInitConfig() < 0) { goto error; } de_ctx->version = DetectEngineGetVersion(); VarNameStoreSetupStaging(de_ctx->version); SCLogDebug("dectx with version %u", de_ctx->version); return de_ctx; error: if (de_ctx != NULL) { DetectEngineCtxFree(de_ctx); } return NULL; } DetectEngineCtx *DetectEngineCtxInitStubForMT(void) { return DetectEngineCtxInitReal(DETECT_ENGINE_TYPE_MT_STUB, NULL); } DetectEngineCtx *DetectEngineCtxInitStubForDD(void) { return DetectEngineCtxInitReal(DETECT_ENGINE_TYPE_DD_STUB, NULL); } DetectEngineCtx *DetectEngineCtxInit(void) { return DetectEngineCtxInitReal(DETECT_ENGINE_TYPE_NORMAL, NULL); } DetectEngineCtx *DetectEngineCtxInitWithPrefix(const char *prefix) { if (prefix == NULL || strlen(prefix) == 0) return DetectEngineCtxInit(); else return DetectEngineCtxInitReal(DETECT_ENGINE_TYPE_NORMAL, prefix); } static void DetectEngineCtxFreeThreadKeywordData(DetectEngineCtx *de_ctx) { DetectEngineThreadKeywordCtxItem *item = de_ctx->keyword_list; while (item) { DetectEngineThreadKeywordCtxItem *next = item->next; SCFree(item); item = next; } de_ctx->keyword_list = NULL; } static void DetectEngineCtxFreeFailedSigs(DetectEngineCtx *de_ctx) { SigString *item = NULL; SigString *sitem; TAILQ_FOREACH_SAFE(item, &de_ctx->sig_stat.failed_sigs, next, sitem) { SCFree(item->filename); SCFree(item->sig_str); if (item->sig_error) { SCFree(item->sig_error); } TAILQ_REMOVE(&de_ctx->sig_stat.failed_sigs, item, next); SCFree(item); } } /** * \brief Free a DetectEngineCtx:: * * \param de_ctx DetectEngineCtx:: to be freed */ void DetectEngineCtxFree(DetectEngineCtx *de_ctx) { if (de_ctx == NULL) return; #ifdef PROFILING if (de_ctx->profile_ctx != NULL) { SCProfilingRuleDestroyCtx(de_ctx->profile_ctx); de_ctx->profile_ctx = NULL; } if (de_ctx->profile_keyword_ctx != NULL) { SCProfilingKeywordDestroyCtx(de_ctx);//->profile_keyword_ctx); // de_ctx->profile_keyword_ctx = NULL; } if (de_ctx->profile_sgh_ctx != NULL) { SCProfilingSghDestroyCtx(de_ctx); } SCProfilingPrefilterDestroyCtx(de_ctx); #endif /* Normally the hashes are freed elsewhere, but * to be sure look at them again here. */ SigGroupHeadHashFree(de_ctx); MpmStoreFree(de_ctx); DetectParseDupSigHashFree(de_ctx); SCSigSignatureOrderingModuleCleanup(de_ctx); ThresholdContextDestroy(de_ctx); SigCleanSignatures(de_ctx); SCFree(de_ctx->app_mpms); de_ctx->app_mpms = NULL; if (de_ctx->sig_array) SCFree(de_ctx->sig_array); SCClassConfDeInitContext(de_ctx); SCRConfDeInitContext(de_ctx); SigGroupCleanup(de_ctx); SpmDestroyGlobalThreadCtx(de_ctx->spm_global_thread_ctx); MpmFactoryDeRegisterAllMpmCtxProfiles(de_ctx); DetectEngineCtxFreeThreadKeywordData(de_ctx); SRepDestroy(de_ctx); DetectEngineCtxFreeFailedSigs(de_ctx); DetectAddressMapFree(de_ctx); DetectMetadataHashFree(de_ctx); /* if we have a config prefix, remove the config from the tree */ if (strlen(de_ctx->config_prefix) > 0) { /* remove config */ ConfNode *node = ConfGetNode(de_ctx->config_prefix); if (node != NULL) { ConfNodeRemove(node); /* frees node */ } #if 0 ConfDump(); #endif } DetectPortCleanupList(de_ctx, de_ctx->tcp_whitelist); DetectPortCleanupList(de_ctx, de_ctx->udp_whitelist); DetectBufferTypeFreeDetectEngine(de_ctx); /* freed our var name hash */ VarNameStoreFree(de_ctx->version); SCFree(de_ctx); //DetectAddressGroupPrintMemory(); //DetectSigGroupPrintMemory(); //DetectPortPrintMemory(); } /** \brief Function that load DetectEngineCtx config for grouping sigs * used by the engine * \retval 0 if no config provided, 1 if config was provided * and loaded successfuly */ static int DetectEngineCtxLoadConf(DetectEngineCtx *de_ctx) { uint8_t profile = ENGINE_PROFILE_MEDIUM; const char *max_uniq_toclient_groups_str = NULL; const char *max_uniq_toserver_groups_str = NULL; const char *sgh_mpm_context = NULL; const char *de_ctx_profile = NULL; (void)ConfGet("detect.profile", &de_ctx_profile); (void)ConfGet("detect.sgh-mpm-context", &sgh_mpm_context); ConfNode *de_ctx_custom = ConfGetNode("detect-engine"); ConfNode *opt = NULL; if (de_ctx_custom != NULL) { TAILQ_FOREACH(opt, &de_ctx_custom->head, next) { if (de_ctx_profile == NULL) { if (opt->val && strcmp(opt->val, "profile") == 0) { de_ctx_profile = opt->head.tqh_first->val; } } if (sgh_mpm_context == NULL) { if (opt->val && strcmp(opt->val, "sgh-mpm-context") == 0) { sgh_mpm_context = opt->head.tqh_first->val; } } } } if (de_ctx_profile != NULL) { if (strcmp(de_ctx_profile, "low") == 0 || strcmp(de_ctx_profile, "lowest") == 0) { // legacy profile = ENGINE_PROFILE_LOW; } else if (strcmp(de_ctx_profile, "medium") == 0) { profile = ENGINE_PROFILE_MEDIUM; } else if (strcmp(de_ctx_profile, "high") == 0 || strcmp(de_ctx_profile, "highest") == 0) { // legacy profile = ENGINE_PROFILE_HIGH; } else if (strcmp(de_ctx_profile, "custom") == 0) { profile = ENGINE_PROFILE_CUSTOM; } else { SCLogError(SC_ERR_INVALID_YAML_CONF_ENTRY, "invalid value for detect.profile: '%s'. " "Valid options: low, medium, high and custom.", de_ctx_profile); return -1; } SCLogDebug("Profile for detection engine groups is \"%s\"", de_ctx_profile); } else { SCLogDebug("Profile for detection engine groups not provided " "at suricata.yaml. Using default (\"medium\")."); } /* detect-engine.sgh-mpm-context option parsing */ if (sgh_mpm_context == NULL || strcmp(sgh_mpm_context, "auto") == 0) { /* for now, since we still haven't implemented any intelligence into * understanding the patterns and distributing mpm_ctx across sgh */ if (de_ctx->mpm_matcher == MPM_AC || de_ctx->mpm_matcher == MPM_AC_TILE || #ifdef BUILD_HYPERSCAN de_ctx->mpm_matcher == MPM_HS || #endif de_ctx->mpm_matcher == MPM_AC_BS) { de_ctx->sgh_mpm_context = ENGINE_SGH_MPM_FACTORY_CONTEXT_SINGLE; } else { de_ctx->sgh_mpm_context = ENGINE_SGH_MPM_FACTORY_CONTEXT_FULL; } } else { if (strcmp(sgh_mpm_context, "single") == 0) { de_ctx->sgh_mpm_context = ENGINE_SGH_MPM_FACTORY_CONTEXT_SINGLE; } else if (strcmp(sgh_mpm_context, "full") == 0) { de_ctx->sgh_mpm_context = ENGINE_SGH_MPM_FACTORY_CONTEXT_FULL; } else { SCLogError(SC_ERR_INVALID_YAML_CONF_ENTRY, "You have supplied an " "invalid conf value for detect-engine.sgh-mpm-context-" "%s", sgh_mpm_context); exit(EXIT_FAILURE); } } if (run_mode == RUNMODE_UNITTEST) { de_ctx->sgh_mpm_context = ENGINE_SGH_MPM_FACTORY_CONTEXT_FULL; } /* parse profile custom-values */ opt = NULL; switch (profile) { case ENGINE_PROFILE_LOW: de_ctx->max_uniq_toclient_groups = 15; de_ctx->max_uniq_toserver_groups = 25; break; case ENGINE_PROFILE_HIGH: de_ctx->max_uniq_toclient_groups = 75; de_ctx->max_uniq_toserver_groups = 75; break; case ENGINE_PROFILE_CUSTOM: (void)ConfGet("detect.custom-values.toclient-groups", &max_uniq_toclient_groups_str); (void)ConfGet("detect.custom-values.toserver-groups", &max_uniq_toserver_groups_str); if (de_ctx_custom != NULL) { TAILQ_FOREACH(opt, &de_ctx_custom->head, next) { if (opt->val && strcmp(opt->val, "custom-values") == 0) { if (max_uniq_toclient_groups_str == NULL) { max_uniq_toclient_groups_str = (char *)ConfNodeLookupChildValue (opt->head.tqh_first, "toclient-sp-groups"); } if (max_uniq_toclient_groups_str == NULL) { max_uniq_toclient_groups_str = (char *)ConfNodeLookupChildValue (opt->head.tqh_first, "toclient-groups"); } if (max_uniq_toserver_groups_str == NULL) { max_uniq_toserver_groups_str = (char *)ConfNodeLookupChildValue (opt->head.tqh_first, "toserver-dp-groups"); } if (max_uniq_toserver_groups_str == NULL) { max_uniq_toserver_groups_str = (char *)ConfNodeLookupChildValue (opt->head.tqh_first, "toserver-groups"); } } } } if (max_uniq_toclient_groups_str != NULL) { if (ByteExtractStringUint16(&de_ctx->max_uniq_toclient_groups, 10, strlen(max_uniq_toclient_groups_str), (const char *)max_uniq_toclient_groups_str) <= 0) { de_ctx->max_uniq_toclient_groups = 20; SCLogWarning(SC_ERR_SIZE_PARSE, "parsing '%s' for " "toclient-groups failed, using %u", max_uniq_toclient_groups_str, de_ctx->max_uniq_toclient_groups); } } else { de_ctx->max_uniq_toclient_groups = 20; } SCLogConfig("toclient-groups %u", de_ctx->max_uniq_toclient_groups); if (max_uniq_toserver_groups_str != NULL) { if (ByteExtractStringUint16(&de_ctx->max_uniq_toserver_groups, 10, strlen(max_uniq_toserver_groups_str), (const char *)max_uniq_toserver_groups_str) <= 0) { de_ctx->max_uniq_toserver_groups = 40; SCLogWarning(SC_ERR_SIZE_PARSE, "parsing '%s' for " "toserver-groups failed, using %u", max_uniq_toserver_groups_str, de_ctx->max_uniq_toserver_groups); } } else { de_ctx->max_uniq_toserver_groups = 40; } SCLogConfig("toserver-groups %u", de_ctx->max_uniq_toserver_groups); break; /* Default (or no config provided) is profile medium */ case ENGINE_PROFILE_MEDIUM: case ENGINE_PROFILE_UNKNOWN: default: de_ctx->max_uniq_toclient_groups = 20; de_ctx->max_uniq_toserver_groups = 40; break; } intmax_t value = 0; if (ConfGetInt("detect.inspection-recursion-limit", &value) == 1) { if (value >= 0 && value <= INT_MAX) { de_ctx->inspection_recursion_limit = (int)value; } /* fall back to old config parsing */ } else { ConfNode *insp_recursion_limit_node = NULL; char *insp_recursion_limit = NULL; if (de_ctx_custom != NULL) { opt = NULL; TAILQ_FOREACH(opt, &de_ctx_custom->head, next) { if (opt->val && strcmp(opt->val, "inspection-recursion-limit") != 0) continue; insp_recursion_limit_node = ConfNodeLookupChild(opt, opt->val); if (insp_recursion_limit_node == NULL) { SCLogError(SC_ERR_INVALID_YAML_CONF_ENTRY, "Error retrieving conf " "entry for detect-engine:inspection-recursion-limit"); break; } insp_recursion_limit = insp_recursion_limit_node->val; SCLogDebug("Found detect-engine.inspection-recursion-limit - %s:%s", insp_recursion_limit_node->name, insp_recursion_limit_node->val); break; } if (insp_recursion_limit != NULL) { de_ctx->inspection_recursion_limit = atoi(insp_recursion_limit); } else { de_ctx->inspection_recursion_limit = DETECT_ENGINE_DEFAULT_INSPECTION_RECURSION_LIMIT; } } } if (de_ctx->inspection_recursion_limit == 0) de_ctx->inspection_recursion_limit = -1; SCLogDebug("de_ctx->inspection_recursion_limit: %d", de_ctx->inspection_recursion_limit); /* parse port grouping whitelisting settings */ const char *ports = NULL; (void)ConfGet("detect.grouping.tcp-whitelist", &ports); if (ports) { SCLogConfig("grouping: tcp-whitelist %s", ports); } else { ports = "53, 80, 139, 443, 445, 1433, 3306, 3389, 6666, 6667, 8080"; SCLogConfig("grouping: tcp-whitelist (default) %s", ports); } if (DetectPortParse(de_ctx, &de_ctx->tcp_whitelist, ports) != 0) { SCLogWarning(SC_ERR_INVALID_YAML_CONF_ENTRY, "'%s' is not a valid value " "for detect.grouping.tcp-whitelist", ports); } DetectPort *x = de_ctx->tcp_whitelist; for ( ; x != NULL; x = x->next) { if (x->port != x->port2) { SCLogWarning(SC_ERR_INVALID_YAML_CONF_ENTRY, "'%s' is not a valid value " "for detect.grouping.tcp-whitelist: only single ports allowed", ports); DetectPortCleanupList(de_ctx, de_ctx->tcp_whitelist); de_ctx->tcp_whitelist = NULL; break; } } ports = NULL; (void)ConfGet("detect.grouping.udp-whitelist", &ports); if (ports) { SCLogConfig("grouping: udp-whitelist %s", ports); } else { ports = "53, 135, 5060"; SCLogConfig("grouping: udp-whitelist (default) %s", ports); } if (DetectPortParse(de_ctx, &de_ctx->udp_whitelist, ports) != 0) { SCLogWarning(SC_ERR_INVALID_YAML_CONF_ENTRY, "'%s' is not a valid value " "forr detect.grouping.udp-whitelist", ports); } for (x = de_ctx->udp_whitelist; x != NULL; x = x->next) { if (x->port != x->port2) { SCLogWarning(SC_ERR_INVALID_YAML_CONF_ENTRY, "'%s' is not a valid value " "for detect.grouping.udp-whitelist: only single ports allowed", ports); DetectPortCleanupList(de_ctx, de_ctx->udp_whitelist); de_ctx->udp_whitelist = NULL; break; } } de_ctx->prefilter_setting = DETECT_PREFILTER_MPM; const char *pf_setting = NULL; if (ConfGet("detect.prefilter.default", &pf_setting) == 1 && pf_setting) { if (strcasecmp(pf_setting, "mpm") == 0) { de_ctx->prefilter_setting = DETECT_PREFILTER_MPM; } else if (strcasecmp(pf_setting, "auto") == 0) { de_ctx->prefilter_setting = DETECT_PREFILTER_AUTO; } } switch (de_ctx->prefilter_setting) { case DETECT_PREFILTER_MPM: SCLogConfig("prefilter engines: MPM"); break; case DETECT_PREFILTER_AUTO: SCLogConfig("prefilter engines: MPM and keywords"); break; } return 0; } /* * getting & (re)setting the internal sig i */ //inline uint32_t DetectEngineGetMaxSigId(DetectEngineCtx *de_ctx) //{ // return de_ctx->signum; //} void DetectEngineResetMaxSigId(DetectEngineCtx *de_ctx) { de_ctx->signum = 0; } static int DetectEngineThreadCtxInitGlobalKeywords(DetectEngineThreadCtx *det_ctx) { const DetectEngineMasterCtx *master = &g_master_de_ctx; if (master->keyword_id > 0) { // coverity[suspicious_sizeof : FALSE] det_ctx->global_keyword_ctxs_array = (void **)SCCalloc(master->keyword_id, sizeof(void *)); if (det_ctx->global_keyword_ctxs_array == NULL) { SCLogError(SC_ERR_DETECT_PREPARE, "setting up thread local detect ctx"); return TM_ECODE_FAILED; } det_ctx->global_keyword_ctxs_size = master->keyword_id; const DetectEngineThreadKeywordCtxItem *item = master->keyword_list; while (item) { det_ctx->global_keyword_ctxs_array[item->id] = item->InitFunc(item->data); if (det_ctx->global_keyword_ctxs_array[item->id] == NULL) { SCLogError(SC_ERR_DETECT_PREPARE, "setting up thread local detect ctx " "for keyword \"%s\" failed", item->name); return TM_ECODE_FAILED; } item = item->next; } } return TM_ECODE_OK; } static void DetectEngineThreadCtxDeinitGlobalKeywords(DetectEngineThreadCtx *det_ctx) { if (det_ctx->global_keyword_ctxs_array == NULL || det_ctx->global_keyword_ctxs_size == 0) { return; } const DetectEngineMasterCtx *master = &g_master_de_ctx; if (master->keyword_id > 0) { const DetectEngineThreadKeywordCtxItem *item = master->keyword_list; while (item) { if (det_ctx->global_keyword_ctxs_array[item->id] != NULL) item->FreeFunc(det_ctx->global_keyword_ctxs_array[item->id]); item = item->next; } det_ctx->global_keyword_ctxs_size = 0; SCFree(det_ctx->global_keyword_ctxs_array); det_ctx->global_keyword_ctxs_array = NULL; } } static int DetectEngineThreadCtxInitKeywords(DetectEngineCtx *de_ctx, DetectEngineThreadCtx *det_ctx) { if (de_ctx->keyword_id > 0) { // coverity[suspicious_sizeof : FALSE] det_ctx->keyword_ctxs_array = SCMalloc(de_ctx->keyword_id * sizeof(void *)); if (det_ctx->keyword_ctxs_array == NULL) { SCLogError(SC_ERR_DETECT_PREPARE, "setting up thread local detect ctx"); return TM_ECODE_FAILED; } memset(det_ctx->keyword_ctxs_array, 0x00, de_ctx->keyword_id * sizeof(void *)); det_ctx->keyword_ctxs_size = de_ctx->keyword_id; DetectEngineThreadKeywordCtxItem *item = de_ctx->keyword_list; while (item) { det_ctx->keyword_ctxs_array[item->id] = item->InitFunc(item->data); if (det_ctx->keyword_ctxs_array[item->id] == NULL) { SCLogError(SC_ERR_DETECT_PREPARE, "setting up thread local detect ctx " "for keyword \"%s\" failed", item->name); return TM_ECODE_FAILED; } item = item->next; } } return TM_ECODE_OK; } static void DetectEngineThreadCtxDeinitKeywords(DetectEngineCtx *de_ctx, DetectEngineThreadCtx *det_ctx) { if (de_ctx->keyword_id > 0) { DetectEngineThreadKeywordCtxItem *item = de_ctx->keyword_list; while (item) { if (det_ctx->keyword_ctxs_array[item->id] != NULL) item->FreeFunc(det_ctx->keyword_ctxs_array[item->id]); item = item->next; } det_ctx->keyword_ctxs_size = 0; SCFree(det_ctx->keyword_ctxs_array); det_ctx->keyword_ctxs_array = NULL; } } /** NOTE: master MUST be locked before calling this */ static TmEcode DetectEngineThreadCtxInitForMT(ThreadVars *tv, DetectEngineThreadCtx *det_ctx) { DetectEngineMasterCtx *master = &g_master_de_ctx; DetectEngineTenantMapping *map_array = NULL; uint32_t map_array_size = 0; uint32_t map_cnt = 0; int max_tenant_id = 0; DetectEngineCtx *list = master->list; HashTable *mt_det_ctxs_hash = NULL; if (master->tenant_selector == TENANT_SELECTOR_UNKNOWN) { SCLogError(SC_ERR_MT_NO_SELECTOR, "no tenant selector set: " "set using multi-detect.selector"); return TM_ECODE_FAILED; } uint32_t tcnt = 0; while (list) { if (list->tenant_id > max_tenant_id) max_tenant_id = list->tenant_id; list = list->next; tcnt++; } mt_det_ctxs_hash = HashTableInit(tcnt * 2, TenantIdHash, TenantIdCompare, TenantIdFree); if (mt_det_ctxs_hash == NULL) { goto error; } if (tcnt == 0) { SCLogInfo("no tenants left, or none registered yet"); } else { max_tenant_id++; DetectEngineTenantMapping *map = master->tenant_mapping_list; while (map) { map_cnt++; map = map->next; } if (map_cnt > 0) { map_array_size = map_cnt + 1; map_array = SCCalloc(map_array_size, sizeof(*map_array)); if (map_array == NULL) goto error; /* fill the array */ map_cnt = 0; map = master->tenant_mapping_list; while (map) { if (map_cnt >= map_array_size) { goto error; } map_array[map_cnt].traffic_id = map->traffic_id; map_array[map_cnt].tenant_id = map->tenant_id; map_cnt++; map = map->next; } } /* set up hash for tenant lookup */ list = master->list; while (list) { SCLogDebug("tenant-id %u", list->tenant_id); if (list->tenant_id != 0) { DetectEngineThreadCtx *mt_det_ctx = DetectEngineThreadCtxInitForReload(tv, list, 0); if (mt_det_ctx == NULL) goto error; if (HashTableAdd(mt_det_ctxs_hash, mt_det_ctx, 0) != 0) { goto error; } } list = list->next; } } det_ctx->mt_det_ctxs_hash = mt_det_ctxs_hash; mt_det_ctxs_hash = NULL; det_ctx->mt_det_ctxs_cnt = max_tenant_id; det_ctx->tenant_array = map_array; det_ctx->tenant_array_size = map_array_size; switch (master->tenant_selector) { case TENANT_SELECTOR_UNKNOWN: SCLogDebug("TENANT_SELECTOR_UNKNOWN"); break; case TENANT_SELECTOR_VLAN: det_ctx->TenantGetId = DetectEngineTentantGetIdFromVlanId; SCLogDebug("TENANT_SELECTOR_VLAN"); break; case TENANT_SELECTOR_LIVEDEV: det_ctx->TenantGetId = DetectEngineTentantGetIdFromLivedev; SCLogDebug("TENANT_SELECTOR_LIVEDEV"); break; case TENANT_SELECTOR_DIRECT: det_ctx->TenantGetId = DetectEngineTentantGetIdFromPcap; SCLogDebug("TENANT_SELECTOR_DIRECT"); break; } return TM_ECODE_OK; error: if (map_array != NULL) SCFree(map_array); if (mt_det_ctxs_hash != NULL) HashTableFree(mt_det_ctxs_hash); return TM_ECODE_FAILED; } /** \internal * \brief Helper for DetectThread setup functions */ static TmEcode ThreadCtxDoInit (DetectEngineCtx *de_ctx, DetectEngineThreadCtx *det_ctx) { PatternMatchThreadPrepare(&det_ctx->mtc, de_ctx->mpm_matcher); PatternMatchThreadPrepare(&det_ctx->mtcs, de_ctx->mpm_matcher); PatternMatchThreadPrepare(&det_ctx->mtcu, de_ctx->mpm_matcher); PmqSetup(&det_ctx->pmq); det_ctx->spm_thread_ctx = SpmMakeThreadCtx(de_ctx->spm_global_thread_ctx); if (det_ctx->spm_thread_ctx == NULL) { return TM_ECODE_FAILED; } /* sized to the max of our sgh settings. A max setting of 0 implies that all * sgh's have: sgh->non_pf_store_cnt == 0 */ if (de_ctx->non_pf_store_cnt_max > 0) { det_ctx->non_pf_id_array = SCCalloc(de_ctx->non_pf_store_cnt_max, sizeof(SigIntId)); BUG_ON(det_ctx->non_pf_id_array == NULL); } /* IP-ONLY */ DetectEngineIPOnlyThreadInit(de_ctx,&det_ctx->io_ctx); /* DeState */ if (de_ctx->sig_array_len > 0) { det_ctx->match_array_len = de_ctx->sig_array_len; det_ctx->match_array = SCMalloc(det_ctx->match_array_len * sizeof(Signature *)); if (det_ctx->match_array == NULL) { return TM_ECODE_FAILED; } memset(det_ctx->match_array, 0, det_ctx->match_array_len * sizeof(Signature *)); RuleMatchCandidateTxArrayInit(det_ctx, de_ctx->sig_array_len); } /* byte_extract storage */ det_ctx->bj_values = SCMalloc(sizeof(*det_ctx->bj_values) * (de_ctx->byte_extract_max_local_id + 1)); if (det_ctx->bj_values == NULL) { return TM_ECODE_FAILED; } /* Allocate space for base64 decoded data. */ if (de_ctx->base64_decode_max_len) { det_ctx->base64_decoded = SCMalloc(de_ctx->base64_decode_max_len); if (det_ctx->base64_decoded == NULL) { return TM_ECODE_FAILED; } det_ctx->base64_decoded_len_max = de_ctx->base64_decode_max_len; det_ctx->base64_decoded_len = 0; } det_ctx->inspect.buffers_size = de_ctx->buffer_type_id; det_ctx->inspect.buffers = SCCalloc(det_ctx->inspect.buffers_size, sizeof(InspectionBuffer)); if (det_ctx->inspect.buffers == NULL) { return TM_ECODE_FAILED; } det_ctx->inspect.to_clear_queue = SCCalloc(det_ctx->inspect.buffers_size, sizeof(uint32_t)); if (det_ctx->inspect.to_clear_queue == NULL) { return TM_ECODE_FAILED; } det_ctx->inspect.to_clear_idx = 0; det_ctx->multi_inspect.buffers_size = de_ctx->buffer_type_id; det_ctx->multi_inspect.buffers = SCCalloc(det_ctx->multi_inspect.buffers_size, sizeof(InspectionBufferMultipleForList)); if (det_ctx->multi_inspect.buffers == NULL) { return TM_ECODE_FAILED; } det_ctx->multi_inspect.to_clear_queue = SCCalloc(det_ctx->multi_inspect.buffers_size, sizeof(uint32_t)); if (det_ctx->multi_inspect.to_clear_queue == NULL) { return TM_ECODE_FAILED; } det_ctx->multi_inspect.to_clear_idx = 0; DetectEngineThreadCtxInitKeywords(de_ctx, det_ctx); DetectEngineThreadCtxInitGlobalKeywords(det_ctx); #ifdef PROFILING SCProfilingRuleThreadSetup(de_ctx->profile_ctx, det_ctx); SCProfilingKeywordThreadSetup(de_ctx->profile_keyword_ctx, det_ctx); SCProfilingPrefilterThreadSetup(de_ctx->profile_prefilter_ctx, det_ctx); SCProfilingSghThreadSetup(de_ctx->profile_sgh_ctx, det_ctx); #endif SC_ATOMIC_INIT(det_ctx->so_far_used_by_detect); return TM_ECODE_OK; } /** \brief initialize thread specific detection engine context * * \note there is a special case when using delayed detect. In this case the * function is called twice per thread. The first time the rules are not * yet loaded. de_ctx->delayed_detect_initialized will be 0. The 2nd * time they will be loaded. de_ctx->delayed_detect_initialized will be 1. * This is needed to do the per thread counter registration before the * packet runtime starts. In delayed detect mode, the first call will * return a NULL ptr through the data ptr. * * \param tv ThreadVars for this thread * \param initdata pointer to de_ctx * \param data[out] pointer to store our thread detection ctx * * \retval TM_ECODE_OK if all went well * \retval TM_ECODE_FAILED on serious erro */ TmEcode DetectEngineThreadCtxInit(ThreadVars *tv, void *initdata, void **data) { DetectEngineThreadCtx *det_ctx = SCMalloc(sizeof(DetectEngineThreadCtx)); if (unlikely(det_ctx == NULL)) return TM_ECODE_FAILED; memset(det_ctx, 0, sizeof(DetectEngineThreadCtx)); det_ctx->tv = tv; det_ctx->de_ctx = DetectEngineGetCurrent(); if (det_ctx->de_ctx == NULL) { #ifdef UNITTESTS if (RunmodeIsUnittests()) { det_ctx->de_ctx = (DetectEngineCtx *)initdata; } else { DetectEngineThreadCtxDeinit(tv, det_ctx); return TM_ECODE_FAILED; } #else DetectEngineThreadCtxDeinit(tv, det_ctx); return TM_ECODE_FAILED; #endif } if (det_ctx->de_ctx->type == DETECT_ENGINE_TYPE_NORMAL || det_ctx->de_ctx->type == DETECT_ENGINE_TYPE_TENANT) { if (ThreadCtxDoInit(det_ctx->de_ctx, det_ctx) != TM_ECODE_OK) { DetectEngineThreadCtxDeinit(tv, det_ctx); return TM_ECODE_FAILED; } } /** alert counter setup */ det_ctx->counter_alerts = StatsRegisterCounter("detect.alert", tv); #ifdef PROFILING det_ctx->counter_mpm_list = StatsRegisterAvgCounter("detect.mpm_list", tv); det_ctx->counter_nonmpm_list = StatsRegisterAvgCounter("detect.nonmpm_list", tv); det_ctx->counter_fnonmpm_list = StatsRegisterAvgCounter("detect.fnonmpm_list", tv); det_ctx->counter_match_list = StatsRegisterAvgCounter("detect.match_list", tv); #endif if (DetectEngineMultiTenantEnabled()) { if (DetectEngineThreadCtxInitForMT(tv, det_ctx) != TM_ECODE_OK) { DetectEngineThreadCtxDeinit(tv, det_ctx); return TM_ECODE_FAILED; } } /* pass thread data back to caller */ *data = (void *)det_ctx; return TM_ECODE_OK; } /** * \internal * \brief initialize a det_ctx for reload cases * \param new_de_ctx the new detection engine * \param mt flag to indicate if MT should be set up for this det_ctx * this should only be done for the 'root' det_ctx * * \retval det_ctx detection engine thread ctx or NULL in case of error */ static DetectEngineThreadCtx *DetectEngineThreadCtxInitForReload( ThreadVars *tv, DetectEngineCtx *new_de_ctx, int mt) { DetectEngineThreadCtx *det_ctx = SCMalloc(sizeof(DetectEngineThreadCtx)); if (unlikely(det_ctx == NULL)) return NULL; memset(det_ctx, 0, sizeof(DetectEngineThreadCtx)); det_ctx->tenant_id = new_de_ctx->tenant_id; det_ctx->tv = tv; det_ctx->de_ctx = DetectEngineReference(new_de_ctx); if (det_ctx->de_ctx == NULL) { SCFree(det_ctx); return NULL; } /* most of the init happens here */ if (det_ctx->de_ctx->type == DETECT_ENGINE_TYPE_NORMAL || det_ctx->de_ctx->type == DETECT_ENGINE_TYPE_TENANT) { if (ThreadCtxDoInit(det_ctx->de_ctx, det_ctx) != TM_ECODE_OK) { DetectEngineDeReference(&det_ctx->de_ctx); SCFree(det_ctx); return NULL; } } /** alert counter setup */ det_ctx->counter_alerts = StatsRegisterCounter("detect.alert", tv); #ifdef PROFILING uint16_t counter_mpm_list = StatsRegisterAvgCounter("detect.mpm_list", tv); uint16_t counter_nonmpm_list = StatsRegisterAvgCounter("detect.nonmpm_list", tv); uint16_t counter_fnonmpm_list = StatsRegisterAvgCounter("detect.fnonmpm_list", tv); uint16_t counter_match_list = StatsRegisterAvgCounter("detect.match_list", tv); det_ctx->counter_mpm_list = counter_mpm_list; det_ctx->counter_nonmpm_list = counter_nonmpm_list; det_ctx->counter_fnonmpm_list = counter_fnonmpm_list; det_ctx->counter_match_list = counter_match_list; #endif if (mt && DetectEngineMultiTenantEnabled()) { if (DetectEngineThreadCtxInitForMT(tv, det_ctx) != TM_ECODE_OK) { DetectEngineDeReference(&det_ctx->de_ctx); SCFree(det_ctx); return NULL; } } return det_ctx; } static void DetectEngineThreadCtxFree(DetectEngineThreadCtx *det_ctx) { #if DEBUG SCLogDebug("PACKET PKT_STREAM_ADD: %"PRIu64, det_ctx->pkt_stream_add_cnt); SCLogDebug("PAYLOAD MPM %"PRIu64"/%"PRIu64, det_ctx->payload_mpm_cnt, det_ctx->payload_mpm_size); SCLogDebug("STREAM MPM %"PRIu64"/%"PRIu64, det_ctx->stream_mpm_cnt, det_ctx->stream_mpm_size); SCLogDebug("PAYLOAD SIG %"PRIu64"/%"PRIu64, det_ctx->payload_persig_cnt, det_ctx->payload_persig_size); SCLogDebug("STREAM SIG %"PRIu64"/%"PRIu64, det_ctx->stream_persig_cnt, det_ctx->stream_persig_size); #endif if (det_ctx->tenant_array != NULL) { SCFree(det_ctx->tenant_array); det_ctx->tenant_array = NULL; } #ifdef PROFILING SCProfilingRuleThreadCleanup(det_ctx); SCProfilingKeywordThreadCleanup(det_ctx); SCProfilingPrefilterThreadCleanup(det_ctx); SCProfilingSghThreadCleanup(det_ctx); #endif DetectEngineIPOnlyThreadDeinit(&det_ctx->io_ctx); /** \todo get rid of this static */ if (det_ctx->de_ctx != NULL) { PatternMatchThreadDestroy(&det_ctx->mtc, det_ctx->de_ctx->mpm_matcher); PatternMatchThreadDestroy(&det_ctx->mtcs, det_ctx->de_ctx->mpm_matcher); PatternMatchThreadDestroy(&det_ctx->mtcu, det_ctx->de_ctx->mpm_matcher); } PmqFree(&det_ctx->pmq); if (det_ctx->spm_thread_ctx != NULL) { SpmDestroyThreadCtx(det_ctx->spm_thread_ctx); } if (det_ctx->non_pf_id_array != NULL) SCFree(det_ctx->non_pf_id_array); if (det_ctx->match_array != NULL) SCFree(det_ctx->match_array); RuleMatchCandidateTxArrayFree(det_ctx); if (det_ctx->bj_values != NULL) SCFree(det_ctx->bj_values); /* Decoded base64 data. */ if (det_ctx->base64_decoded != NULL) { SCFree(det_ctx->base64_decoded); } if (det_ctx->inspect.buffers) { for (uint32_t i = 0; i < det_ctx->inspect.buffers_size; i++) { InspectionBufferFree(&det_ctx->inspect.buffers[i]); } SCFree(det_ctx->inspect.buffers); } if (det_ctx->inspect.to_clear_queue) { SCFree(det_ctx->inspect.to_clear_queue); } if (det_ctx->multi_inspect.buffers) { for (uint32_t i = 0; i < det_ctx->multi_inspect.buffers_size; i++) { InspectionBufferMultipleForList *fb = &det_ctx->multi_inspect.buffers[i]; for (uint32_t x = 0; x < fb->size; x++) { InspectionBufferFree(&fb->inspection_buffers[x]); } SCFree(fb->inspection_buffers); } SCFree(det_ctx->multi_inspect.buffers); } if (det_ctx->multi_inspect.to_clear_queue) { SCFree(det_ctx->multi_inspect.to_clear_queue); } DetectEngineThreadCtxDeinitGlobalKeywords(det_ctx); if (det_ctx->de_ctx != NULL) { DetectEngineThreadCtxDeinitKeywords(det_ctx->de_ctx, det_ctx); #ifdef UNITTESTS if (!RunmodeIsUnittests() || det_ctx->de_ctx->ref_cnt > 0) DetectEngineDeReference(&det_ctx->de_ctx); #else DetectEngineDeReference(&det_ctx->de_ctx); #endif } AppLayerDecoderEventsFreeEvents(&det_ctx->decoder_events); SCFree(det_ctx); } TmEcode DetectEngineThreadCtxDeinit(ThreadVars *tv, void *data) { DetectEngineThreadCtx *det_ctx = (DetectEngineThreadCtx *)data; if (det_ctx == NULL) { SCLogWarning(SC_ERR_INVALID_ARGUMENTS, "argument \"data\" NULL"); return TM_ECODE_OK; } if (det_ctx->mt_det_ctxs_hash != NULL) { HashTableFree(det_ctx->mt_det_ctxs_hash); det_ctx->mt_det_ctxs_hash = NULL; } DetectEngineThreadCtxFree(det_ctx); return TM_ECODE_OK; } void DetectEngineThreadCtxInfo(ThreadVars *t, DetectEngineThreadCtx *det_ctx) { /* XXX */ PatternMatchThreadPrint(&det_ctx->mtc, det_ctx->de_ctx->mpm_matcher); PatternMatchThreadPrint(&det_ctx->mtcu, det_ctx->de_ctx->mpm_matcher); } /** \brief Register Thread keyword context Funcs * * \param de_ctx detection engine to register in * \param name keyword name for error printing * \param InitFunc function ptr * \param data keyword init data to pass to Func * \param FreeFunc function ptr * \param mode 0 normal (ctx per keyword instance) 1 shared (one ctx per det_ct) * * \retval id for retrieval of ctx at runtime * \retval -1 on error * * \note make sure "data" remains valid and it free'd elsewhere. It's * recommended to store it in the keywords global ctx so that * it's freed when the de_ctx is freed. */ int DetectRegisterThreadCtxFuncs(DetectEngineCtx *de_ctx, const char *name, void *(*InitFunc)(void *), void *data, void (*FreeFunc)(void *), int mode) { BUG_ON(de_ctx == NULL || InitFunc == NULL || FreeFunc == NULL || data == NULL); if (mode) { DetectEngineThreadKeywordCtxItem *item = de_ctx->keyword_list; while (item != NULL) { if (strcmp(name, item->name) == 0) { return item->id; } item = item->next; } } DetectEngineThreadKeywordCtxItem *item = SCMalloc(sizeof(DetectEngineThreadKeywordCtxItem)); if (unlikely(item == NULL)) return -1; memset(item, 0x00, sizeof(DetectEngineThreadKeywordCtxItem)); item->InitFunc = InitFunc; item->FreeFunc = FreeFunc; item->data = data; item->name = name; item->next = de_ctx->keyword_list; de_ctx->keyword_list = item; item->id = de_ctx->keyword_id++; return item->id; } /** \brief Retrieve thread local keyword ctx by id * * \param det_ctx detection engine thread ctx to retrieve the ctx from * \param id id of the ctx returned by DetectRegisterThreadCtxInitFunc at * keyword init. * * \retval ctx or NULL on error */ void *DetectThreadCtxGetKeywordThreadCtx(DetectEngineThreadCtx *det_ctx, int id) { if (id < 0 || id > det_ctx->keyword_ctxs_size || det_ctx->keyword_ctxs_array == NULL) return NULL; return det_ctx->keyword_ctxs_array[id]; } /** \brief Register Thread keyword context Funcs (Global) * * IDs stay static over reloads and between tenants * * \param name keyword name for error printing * \param InitFunc function ptr * \param FreeFunc function ptr * * \retval id for retrieval of ctx at runtime * \retval -1 on error */ int DetectRegisterThreadCtxGlobalFuncs(const char *name, void *(*InitFunc)(void *), void *data, void (*FreeFunc)(void *)) { int id; BUG_ON(InitFunc == NULL || FreeFunc == NULL); DetectEngineMasterCtx *master = &g_master_de_ctx; /* if already registered, return existing id */ DetectEngineThreadKeywordCtxItem *item = master->keyword_list; while (item != NULL) { if (strcmp(name, item->name) == 0) { id = item->id; return id; } item = item->next; } item = SCCalloc(1, sizeof(*item)); if (unlikely(item == NULL)) { return -1; } item->InitFunc = InitFunc; item->FreeFunc = FreeFunc; item->name = name; item->data = data; item->next = master->keyword_list; master->keyword_list = item; item->id = master->keyword_id++; id = item->id; return id; } /** \brief Retrieve thread local keyword ctx by id * * \param det_ctx detection engine thread ctx to retrieve the ctx from * \param id id of the ctx returned by DetectRegisterThreadCtxInitFunc at * keyword init. * * \retval ctx or NULL on error */ void *DetectThreadCtxGetGlobalKeywordThreadCtx(DetectEngineThreadCtx *det_ctx, int id) { if (id < 0 || id > det_ctx->global_keyword_ctxs_size || det_ctx->global_keyword_ctxs_array == NULL) { return NULL; } return det_ctx->global_keyword_ctxs_array[id]; } /** \brief Check if detection is enabled * \retval bool true or false */ int DetectEngineEnabled(void) { DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); if (master->list == NULL) { SCMutexUnlock(&master->lock); return 0; } SCMutexUnlock(&master->lock); return 1; } uint32_t DetectEngineGetVersion(void) { uint32_t version; DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); version = master->version; SCMutexUnlock(&master->lock); return version; } void DetectEngineBumpVersion(void) { DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); master->version++; SCLogDebug("master version now %u", master->version); SCMutexUnlock(&master->lock); } DetectEngineCtx *DetectEngineGetCurrent(void) { DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); DetectEngineCtx *de_ctx = master->list; while (de_ctx) { if (de_ctx->type == DETECT_ENGINE_TYPE_NORMAL || de_ctx->type == DETECT_ENGINE_TYPE_DD_STUB || de_ctx->type == DETECT_ENGINE_TYPE_MT_STUB) { de_ctx->ref_cnt++; SCLogDebug("de_ctx %p ref_cnt %u", de_ctx, de_ctx->ref_cnt); SCMutexUnlock(&master->lock); return de_ctx; } de_ctx = de_ctx->next; } SCMutexUnlock(&master->lock); return NULL; } DetectEngineCtx *DetectEngineReference(DetectEngineCtx *de_ctx) { if (de_ctx == NULL) return NULL; de_ctx->ref_cnt++; return de_ctx; } /** TODO locking? Not needed if this is a one time setting at startup */ int DetectEngineMultiTenantEnabled(void) { DetectEngineMasterCtx *master = &g_master_de_ctx; return (master->multi_tenant_enabled); } /** \internal * \brief load a tenant from a yaml file * * \param tenant_id the tenant id by which the config is known * \param filename full path of a yaml file * \param loader_id id of loader thread or -1 * * \retval 0 ok * \retval -1 failed */ static int DetectEngineMultiTenantLoadTenant(uint32_t tenant_id, const char *filename, int loader_id) { DetectEngineCtx *de_ctx = NULL; char prefix[64]; snprintf(prefix, sizeof(prefix), "multi-detect.%d", tenant_id); #ifdef OS_WIN32 struct _stat st; if(_stat(filename, &st) != 0) { #else struct stat st; if(stat(filename, &st) != 0) { #endif /* OS_WIN32 */ SCLogError(SC_ERR_FOPEN, "failed to stat file %s", filename); goto error; } de_ctx = DetectEngineGetByTenantId(tenant_id); if (de_ctx != NULL) { SCLogError(SC_ERR_MT_DUPLICATE_TENANT, "tenant %u already registered", tenant_id); DetectEngineDeReference(&de_ctx); goto error; } ConfNode *node = ConfGetNode(prefix); if (node == NULL) { SCLogError(SC_ERR_CONF_YAML_ERROR, "failed to properly setup yaml %s", filename); goto error; } de_ctx = DetectEngineCtxInitWithPrefix(prefix); if (de_ctx == NULL) { SCLogError(SC_ERR_INITIALIZATION, "initializing detection engine " "context failed."); goto error; } SCLogDebug("de_ctx %p with prefix %s", de_ctx, de_ctx->config_prefix); de_ctx->type = DETECT_ENGINE_TYPE_TENANT; de_ctx->tenant_id = tenant_id; de_ctx->loader_id = loader_id; if (SigLoadSignatures(de_ctx, NULL, 0) < 0) { SCLogError(SC_ERR_NO_RULES_LOADED, "Loading signatures failed."); goto error; } DetectEngineAddToMaster(de_ctx); return 0; error: if (de_ctx != NULL) { DetectEngineCtxFree(de_ctx); } return -1; } static int DetectEngineMultiTenantReloadTenant(uint32_t tenant_id, const char *filename, int reload_cnt) { DetectEngineCtx *old_de_ctx = DetectEngineGetByTenantId(tenant_id); if (old_de_ctx == NULL) { SCLogError(SC_ERR_INITIALIZATION, "tenant detect engine not found"); return -1; } char prefix[64]; snprintf(prefix, sizeof(prefix), "multi-detect.%d.reload.%d", tenant_id, reload_cnt); reload_cnt++; SCLogDebug("prefix %s", prefix); if (ConfYamlLoadFileWithPrefix(filename, prefix) != 0) { SCLogError(SC_ERR_INITIALIZATION,"failed to load yaml"); goto error; } ConfNode *node = ConfGetNode(prefix); if (node == NULL) { SCLogError(SC_ERR_CONF_YAML_ERROR, "failed to properly setup yaml %s", filename); goto error; } DetectEngineCtx *new_de_ctx = DetectEngineCtxInitWithPrefix(prefix); if (new_de_ctx == NULL) { SCLogError(SC_ERR_INITIALIZATION, "initializing detection engine " "context failed."); goto error; } SCLogDebug("de_ctx %p with prefix %s", new_de_ctx, new_de_ctx->config_prefix); new_de_ctx->type = DETECT_ENGINE_TYPE_TENANT; new_de_ctx->tenant_id = tenant_id; new_de_ctx->loader_id = old_de_ctx->loader_id; if (SigLoadSignatures(new_de_ctx, NULL, 0) < 0) { SCLogError(SC_ERR_NO_RULES_LOADED, "Loading signatures failed."); goto error; } DetectEngineAddToMaster(new_de_ctx); /* move to free list */ DetectEngineMoveToFreeList(old_de_ctx); DetectEngineDeReference(&old_de_ctx); return 0; error: DetectEngineDeReference(&old_de_ctx); return -1; } typedef struct TenantLoaderCtx_ { uint32_t tenant_id; int reload_cnt; /**< used by reload */ const char *yaml; } TenantLoaderCtx; static int DetectLoaderFuncLoadTenant(void *vctx, int loader_id) { TenantLoaderCtx *ctx = (TenantLoaderCtx *)vctx; SCLogDebug("loader %d", loader_id); if (DetectEngineMultiTenantLoadTenant(ctx->tenant_id, ctx->yaml, loader_id) != 0) { return -1; } return 0; } static int DetectLoaderSetupLoadTenant(uint32_t tenant_id, const char *yaml) { TenantLoaderCtx *t = SCCalloc(1, sizeof(*t)); if (t == NULL) return -ENOMEM; t->tenant_id = tenant_id; t->yaml = yaml; return DetectLoaderQueueTask(-1, DetectLoaderFuncLoadTenant, t); } static int DetectLoaderFuncReloadTenant(void *vctx, int loader_id) { TenantLoaderCtx *ctx = (TenantLoaderCtx *)vctx; SCLogDebug("loader_id %d", loader_id); if (DetectEngineMultiTenantReloadTenant(ctx->tenant_id, ctx->yaml, ctx->reload_cnt) != 0) { return -1; } return 0; } static int DetectLoaderSetupReloadTenant(uint32_t tenant_id, const char *yaml, int reload_cnt) { DetectEngineCtx *old_de_ctx = DetectEngineGetByTenantId(tenant_id); if (old_de_ctx == NULL) return -ENOENT; int loader_id = old_de_ctx->loader_id; DetectEngineDeReference(&old_de_ctx); TenantLoaderCtx *t = SCCalloc(1, sizeof(*t)); if (t == NULL) return -ENOMEM; t->tenant_id = tenant_id; t->yaml = yaml; t->reload_cnt = reload_cnt; SCLogDebug("loader_id %d", loader_id); return DetectLoaderQueueTask(loader_id, DetectLoaderFuncReloadTenant, t); } /** \brief Load a tenant and wait for loading to complete */ int DetectEngineLoadTenantBlocking(uint32_t tenant_id, const char *yaml) { int r = DetectLoaderSetupLoadTenant(tenant_id, yaml); if (r < 0) return r; if (DetectLoadersSync() != 0) return -1; return 0; } /** \brief Reload a tenant and wait for loading to complete */ int DetectEngineReloadTenantBlocking(uint32_t tenant_id, const char *yaml, int reload_cnt) { int r = DetectLoaderSetupReloadTenant(tenant_id, yaml, reload_cnt); if (r < 0) return r; if (DetectLoadersSync() != 0) return -1; return 0; } static int DetectEngineMultiTenantSetupLoadLivedevMappings(const ConfNode *mappings_root_node, bool failure_fatal) { ConfNode *mapping_node = NULL; int mapping_cnt = 0; if (mappings_root_node != NULL) { TAILQ_FOREACH(mapping_node, &mappings_root_node->head, next) { ConfNode *tenant_id_node = ConfNodeLookupChild(mapping_node, "tenant-id"); if (tenant_id_node == NULL) goto bad_mapping; ConfNode *device_node = ConfNodeLookupChild(mapping_node, "device"); if (device_node == NULL) goto bad_mapping; uint32_t tenant_id = 0; if (ByteExtractStringUint32(&tenant_id, 10, strlen(tenant_id_node->val), tenant_id_node->val) == -1) { SCLogError(SC_ERR_INVALID_ARGUMENT, "tenant-id " "of %s is invalid", tenant_id_node->val); goto bad_mapping; } const char *dev = device_node->val; LiveDevice *ld = LiveGetDevice(dev); if (ld == NULL) { SCLogWarning(SC_ERR_MT_NO_MAPPING, "device %s not found", dev); goto bad_mapping; } if (ld->tenant_id_set) { SCLogWarning(SC_ERR_MT_NO_MAPPING, "device %s already mapped to tenant-id %u", dev, ld->tenant_id); goto bad_mapping; } ld->tenant_id = tenant_id; ld->tenant_id_set = true; if (DetectEngineTentantRegisterLivedev(tenant_id, ld->id) != 0) { goto error; } SCLogConfig("device %s connected to tenant-id %u", dev, tenant_id); mapping_cnt++; continue; bad_mapping: if (failure_fatal) goto error; } } SCLogConfig("%d device - tenant-id mappings defined", mapping_cnt); return mapping_cnt; error: return 0; } static int DetectEngineMultiTenantSetupLoadVlanMappings(const ConfNode *mappings_root_node, bool failure_fatal) { ConfNode *mapping_node = NULL; int mapping_cnt = 0; if (mappings_root_node != NULL) { TAILQ_FOREACH(mapping_node, &mappings_root_node->head, next) { ConfNode *tenant_id_node = ConfNodeLookupChild(mapping_node, "tenant-id"); if (tenant_id_node == NULL) goto bad_mapping; ConfNode *vlan_id_node = ConfNodeLookupChild(mapping_node, "vlan-id"); if (vlan_id_node == NULL) goto bad_mapping; uint32_t tenant_id = 0; if (ByteExtractStringUint32(&tenant_id, 10, strlen(tenant_id_node->val), tenant_id_node->val) == -1) { SCLogError(SC_ERR_INVALID_ARGUMENT, "tenant-id " "of %s is invalid", tenant_id_node->val); goto bad_mapping; } uint16_t vlan_id = 0; if (ByteExtractStringUint16(&vlan_id, 10, strlen(vlan_id_node->val), vlan_id_node->val) == -1) { SCLogError(SC_ERR_INVALID_ARGUMENT, "vlan-id " "of %s is invalid", vlan_id_node->val); goto bad_mapping; } if (vlan_id == 0 || vlan_id >= 4095) { SCLogError(SC_ERR_INVALID_ARGUMENT, "vlan-id " "of %s is invalid. Valid range 1-4094.", vlan_id_node->val); goto bad_mapping; } if (DetectEngineTentantRegisterVlanId(tenant_id, (uint32_t)vlan_id) != 0) { goto error; } SCLogConfig("vlan %u connected to tenant-id %u", vlan_id, tenant_id); mapping_cnt++; continue; bad_mapping: if (failure_fatal) goto error; } } return mapping_cnt; error: return 0; } /** * \brief setup multi-detect / multi-tenancy * * See if MT is enabled. If so, setup the selector, tenants and mappings. * Tenants and mappings are optional, and can also dynamically be added * and removed from the unix socket. */ int DetectEngineMultiTenantSetup(void) { enum DetectEngineTenantSelectors tenant_selector = TENANT_SELECTOR_UNKNOWN; DetectEngineMasterCtx *master = &g_master_de_ctx; int unix_socket = ConfUnixSocketIsEnable(); int failure_fatal = 0; (void)ConfGetBool("engine.init-failure-fatal", &failure_fatal); int enabled = 0; (void)ConfGetBool("multi-detect.enabled", &enabled); if (enabled == 1) { DetectLoadersInit(); TmModuleDetectLoaderRegister(); DetectLoaderThreadSpawn(); TmThreadContinueDetectLoaderThreads(); SCMutexLock(&master->lock); master->multi_tenant_enabled = 1; const char *handler = NULL; if (ConfGet("multi-detect.selector", &handler) == 1) { SCLogConfig("multi-tenant selector type %s", handler); if (strcmp(handler, "vlan") == 0) { tenant_selector = master->tenant_selector = TENANT_SELECTOR_VLAN; int vlanbool = 0; if ((ConfGetBool("vlan.use-for-tracking", &vlanbool)) == 1 && vlanbool == 0) { SCLogError(SC_ERR_INVALID_VALUE, "vlan tracking is disabled, " "can't use multi-detect selector 'vlan'"); SCMutexUnlock(&master->lock); goto error; } } else if (strcmp(handler, "direct") == 0) { tenant_selector = master->tenant_selector = TENANT_SELECTOR_DIRECT; } else if (strcmp(handler, "device") == 0) { tenant_selector = master->tenant_selector = TENANT_SELECTOR_LIVEDEV; if (EngineModeIsIPS()) { SCLogWarning(SC_ERR_MT_NO_MAPPING, "multi-tenant 'device' mode not supported for IPS"); SCMutexUnlock(&master->lock); goto error; } } else { SCLogError(SC_ERR_INVALID_VALUE, "unknown value %s " "multi-detect.selector", handler); SCMutexUnlock(&master->lock); goto error; } } SCMutexUnlock(&master->lock); SCLogConfig("multi-detect is enabled (multi tenancy). Selector: %s", handler); /* traffic -- tenant mappings */ ConfNode *mappings_root_node = ConfGetNode("multi-detect.mappings"); if (tenant_selector == TENANT_SELECTOR_VLAN) { int mapping_cnt = DetectEngineMultiTenantSetupLoadVlanMappings(mappings_root_node, failure_fatal); if (mapping_cnt == 0) { /* no mappings are valid when we're in unix socket mode, * they can be added on the fly. Otherwise warn/error * depending on failure_fatal */ if (unix_socket) { SCLogNotice("no tenant traffic mappings defined, " "tenants won't be used until mappings are added"); } else { if (failure_fatal) { SCLogError(SC_ERR_MT_NO_MAPPING, "no multi-detect mappings defined"); goto error; } else { SCLogWarning(SC_ERR_MT_NO_MAPPING, "no multi-detect mappings defined"); } } } } else if (tenant_selector == TENANT_SELECTOR_LIVEDEV) { int mapping_cnt = DetectEngineMultiTenantSetupLoadLivedevMappings(mappings_root_node, failure_fatal); if (mapping_cnt == 0) { if (failure_fatal) { SCLogError(SC_ERR_MT_NO_MAPPING, "no multi-detect mappings defined"); goto error; } else { SCLogWarning(SC_ERR_MT_NO_MAPPING, "no multi-detect mappings defined"); } } } /* tenants */ ConfNode *tenants_root_node = ConfGetNode("multi-detect.tenants"); ConfNode *tenant_node = NULL; if (tenants_root_node != NULL) { TAILQ_FOREACH(tenant_node, &tenants_root_node->head, next) { ConfNode *id_node = ConfNodeLookupChild(tenant_node, "id"); if (id_node == NULL) { goto bad_tenant; } ConfNode *yaml_node = ConfNodeLookupChild(tenant_node, "yaml"); if (yaml_node == NULL) { goto bad_tenant; } uint32_t tenant_id = 0; if (ByteExtractStringUint32(&tenant_id, 10, strlen(id_node->val), id_node->val) == -1) { SCLogError(SC_ERR_INVALID_ARGUMENT, "tenant_id " "of %s is invalid", id_node->val); goto bad_tenant; } SCLogDebug("tenant id: %u, %s", tenant_id, yaml_node->val); /* setup the yaml in this loop so that it's not done by the loader * threads. ConfYamlLoadFileWithPrefix is not thread safe. */ char prefix[64]; snprintf(prefix, sizeof(prefix), "multi-detect.%d", tenant_id); if (ConfYamlLoadFileWithPrefix(yaml_node->val, prefix) != 0) { SCLogError(SC_ERR_CONF_YAML_ERROR, "failed to load yaml %s", yaml_node->val); goto bad_tenant; } int r = DetectLoaderSetupLoadTenant(tenant_id, yaml_node->val); if (r < 0) { /* error logged already */ goto bad_tenant; } continue; bad_tenant: if (failure_fatal) goto error; } } /* wait for our loaders to complete their tasks */ if (DetectLoadersSync() != 0) { goto error; } VarNameStoreActivateStaging(); } else { SCLogDebug("multi-detect not enabled (multi tenancy)"); } return 0; error: return -1; } static uint32_t DetectEngineTentantGetIdFromVlanId(const void *ctx, const Packet *p) { const DetectEngineThreadCtx *det_ctx = ctx; uint32_t x = 0; uint32_t vlan_id = 0; if (p->vlan_idx == 0) return 0; vlan_id = p->vlan_id[0]; if (det_ctx == NULL || det_ctx->tenant_array == NULL || det_ctx->tenant_array_size == 0) return 0; /* not very efficient, but for now we're targeting only limited amounts. * Can use hash/tree approach later. */ for (x = 0; x < det_ctx->tenant_array_size; x++) { if (det_ctx->tenant_array[x].traffic_id == vlan_id) return det_ctx->tenant_array[x].tenant_id; } return 0; } static uint32_t DetectEngineTentantGetIdFromLivedev(const void *ctx, const Packet *p) { const DetectEngineThreadCtx *det_ctx = ctx; const LiveDevice *ld = p->livedev; if (ld == NULL || det_ctx == NULL) return 0; SCLogDebug("using tenant-id %u for packet on device %s", ld->tenant_id, ld->dev); return ld->tenant_id; } static int DetectEngineTentantRegisterSelector(enum DetectEngineTenantSelectors selector, uint32_t tenant_id, uint32_t traffic_id) { DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); if (!(master->tenant_selector == TENANT_SELECTOR_UNKNOWN || master->tenant_selector == selector)) { SCLogInfo("conflicting selector already set"); SCMutexUnlock(&master->lock); return -1; } DetectEngineTenantMapping *m = master->tenant_mapping_list; while (m) { if (m->traffic_id == traffic_id) { SCLogInfo("traffic id already registered"); SCMutexUnlock(&master->lock); return -1; } m = m->next; } DetectEngineTenantMapping *map = SCCalloc(1, sizeof(*map)); if (map == NULL) { SCLogInfo("memory fail"); SCMutexUnlock(&master->lock); return -1; } map->traffic_id = traffic_id; map->tenant_id = tenant_id; map->next = master->tenant_mapping_list; master->tenant_mapping_list = map; master->tenant_selector = selector; SCLogDebug("tenant handler %u %u %u registered", selector, tenant_id, traffic_id); SCMutexUnlock(&master->lock); return 0; } static int DetectEngineTentantUnregisterSelector(enum DetectEngineTenantSelectors selector, uint32_t tenant_id, uint32_t traffic_id) { DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); if (master->tenant_mapping_list == NULL) { SCMutexUnlock(&master->lock); return -1; } DetectEngineTenantMapping *prev = NULL; DetectEngineTenantMapping *map = master->tenant_mapping_list; while (map) { if (map->traffic_id == traffic_id && map->tenant_id == tenant_id) { if (prev != NULL) prev->next = map->next; else master->tenant_mapping_list = map->next; map->next = NULL; SCFree(map); SCLogInfo("tenant handler %u %u %u unregistered", selector, tenant_id, traffic_id); SCMutexUnlock(&master->lock); return 0; } prev = map; map = map->next; } SCMutexUnlock(&master->lock); return -1; } int DetectEngineTentantRegisterLivedev(uint32_t tenant_id, int device_id) { return DetectEngineTentantRegisterSelector(TENANT_SELECTOR_LIVEDEV, tenant_id, (uint32_t)device_id); } int DetectEngineTentantRegisterVlanId(uint32_t tenant_id, uint16_t vlan_id) { return DetectEngineTentantRegisterSelector(TENANT_SELECTOR_VLAN, tenant_id, (uint32_t)vlan_id); } int DetectEngineTentantUnregisterVlanId(uint32_t tenant_id, uint16_t vlan_id) { return DetectEngineTentantUnregisterSelector(TENANT_SELECTOR_VLAN, tenant_id, (uint32_t)vlan_id); } int DetectEngineTentantRegisterPcapFile(uint32_t tenant_id) { SCLogInfo("registering %u %d 0", TENANT_SELECTOR_DIRECT, tenant_id); return DetectEngineTentantRegisterSelector(TENANT_SELECTOR_DIRECT, tenant_id, 0); } int DetectEngineTentantUnregisterPcapFile(uint32_t tenant_id) { SCLogInfo("unregistering %u %d 0", TENANT_SELECTOR_DIRECT, tenant_id); return DetectEngineTentantUnregisterSelector(TENANT_SELECTOR_DIRECT, tenant_id, 0); } static uint32_t DetectEngineTentantGetIdFromPcap(const void *ctx, const Packet *p) { return p->pcap_v.tenant_id; } DetectEngineCtx *DetectEngineGetByTenantId(int tenant_id) { DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); if (master->list == NULL) { SCMutexUnlock(&master->lock); return NULL; } DetectEngineCtx *de_ctx = master->list; while (de_ctx) { if (de_ctx->type == DETECT_ENGINE_TYPE_TENANT && de_ctx->tenant_id == tenant_id) { de_ctx->ref_cnt++; break; } de_ctx = de_ctx->next; } SCMutexUnlock(&master->lock); return de_ctx; } void DetectEngineDeReference(DetectEngineCtx **de_ctx) { BUG_ON((*de_ctx)->ref_cnt == 0); (*de_ctx)->ref_cnt--; *de_ctx = NULL; } static int DetectEngineAddToList(DetectEngineCtx *instance) { DetectEngineMasterCtx *master = &g_master_de_ctx; if (instance == NULL) return -1; if (master->list == NULL) { master->list = instance; } else { instance->next = master->list; master->list = instance; } return 0; } int DetectEngineAddToMaster(DetectEngineCtx *de_ctx) { int r; if (de_ctx == NULL) return -1; SCLogDebug("adding de_ctx %p to master", de_ctx); DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); r = DetectEngineAddToList(de_ctx); SCMutexUnlock(&master->lock); return r; } int DetectEngineMoveToFreeList(DetectEngineCtx *de_ctx) { DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); DetectEngineCtx *instance = master->list; if (instance == NULL) { SCMutexUnlock(&master->lock); return -1; } /* remove from active list */ if (instance == de_ctx) { master->list = instance->next; } else { DetectEngineCtx *prev = instance; instance = instance->next; /* already checked first element */ while (instance) { DetectEngineCtx *next = instance->next; if (instance == de_ctx) { prev->next = instance->next; break; } prev = instance; instance = next; } if (instance == NULL) { SCMutexUnlock(&master->lock); return -1; } } /* instance is now detached from list */ instance->next = NULL; /* add to free list */ if (master->free_list == NULL) { master->free_list = instance; } else { instance->next = master->free_list; master->free_list = instance; } SCLogDebug("detect engine %p moved to free list (%u refs)", de_ctx, de_ctx->ref_cnt); SCMutexUnlock(&master->lock); return 0; } void DetectEnginePruneFreeList(void) { DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); DetectEngineCtx *prev = NULL; DetectEngineCtx *instance = master->free_list; while (instance) { DetectEngineCtx *next = instance->next; SCLogDebug("detect engine %p has %u ref(s)", instance, instance->ref_cnt); if (instance->ref_cnt == 0) { if (prev == NULL) { master->free_list = next; } else { prev->next = next; } SCLogDebug("freeing detect engine %p", instance); DetectEngineCtxFree(instance); instance = NULL; } prev = instance; instance = next; } SCMutexUnlock(&master->lock); } static int reloads = 0; /** \brief Reload the detection engine * * \param filename YAML file to load for the detect config * * \retval -1 error * \retval 0 ok */ int DetectEngineReload(const SCInstance *suri) { DetectEngineCtx *new_de_ctx = NULL; DetectEngineCtx *old_de_ctx = NULL; char prefix[128]; memset(prefix, 0, sizeof(prefix)); SCLogNotice("rule reload starting"); if (suri->conf_filename != NULL) { snprintf(prefix, sizeof(prefix), "detect-engine-reloads.%d", reloads++); if (ConfYamlLoadFileWithPrefix(suri->conf_filename, prefix) != 0) { SCLogError(SC_ERR_CONF_YAML_ERROR, "failed to load yaml %s", suri->conf_filename); return -1; } ConfNode *node = ConfGetNode(prefix); if (node == NULL) { SCLogError(SC_ERR_CONF_YAML_ERROR, "failed to properly setup yaml %s", suri->conf_filename); return -1; } #if 0 ConfDump(); #endif } /* get a reference to the current de_ctx */ old_de_ctx = DetectEngineGetCurrent(); if (old_de_ctx == NULL) return -1; SCLogDebug("get ref to old_de_ctx %p", old_de_ctx); /* only reload a regular 'normal' and 'delayed detect stub' detect engines */ if (!(old_de_ctx->type == DETECT_ENGINE_TYPE_NORMAL || old_de_ctx->type == DETECT_ENGINE_TYPE_DD_STUB)) { DetectEngineDeReference(&old_de_ctx); SCLogNotice("rule reload complete"); return -1; } /* get new detection engine */ new_de_ctx = DetectEngineCtxInitWithPrefix(prefix); if (new_de_ctx == NULL) { SCLogError(SC_ERR_INITIALIZATION, "initializing detection engine " "context failed."); DetectEngineDeReference(&old_de_ctx); return -1; } if (SigLoadSignatures(new_de_ctx, suri->sig_file, suri->sig_file_exclusive) != 0) { DetectEngineCtxFree(new_de_ctx); DetectEngineDeReference(&old_de_ctx); return -1; } SCLogDebug("set up new_de_ctx %p", new_de_ctx); /* add to master */ DetectEngineAddToMaster(new_de_ctx); /* move to old free list */ DetectEngineMoveToFreeList(old_de_ctx); DetectEngineDeReference(&old_de_ctx); SCLogDebug("going to reload the threads to use new_de_ctx %p", new_de_ctx); /* update the threads */ DetectEngineReloadThreads(new_de_ctx); SCLogDebug("threads now run new_de_ctx %p", new_de_ctx); /* walk free list, freeing the old_de_ctx */ DetectEnginePruneFreeList(); DetectEngineBumpVersion(); SCLogDebug("old_de_ctx should have been freed"); SCLogNotice("rule reload complete"); return 0; } static uint32_t TenantIdHash(HashTable *h, void *data, uint16_t data_len) { DetectEngineThreadCtx *det_ctx = (DetectEngineThreadCtx *)data; return det_ctx->tenant_id % h->array_size; } static char TenantIdCompare(void *d1, uint16_t d1_len, void *d2, uint16_t d2_len) { DetectEngineThreadCtx *det1 = (DetectEngineThreadCtx *)d1; DetectEngineThreadCtx *det2 = (DetectEngineThreadCtx *)d2; return (det1->tenant_id == det2->tenant_id); } static void TenantIdFree(void *d) { DetectEngineThreadCtxFree(d); } int DetectEngineMTApply(void) { DetectEngineMasterCtx *master = &g_master_de_ctx; SCMutexLock(&master->lock); if (master->tenant_selector == TENANT_SELECTOR_UNKNOWN) { SCLogInfo("error, no tenant selector"); SCMutexUnlock(&master->lock); return -1; } DetectEngineCtx *stub_de_ctx = NULL; DetectEngineCtx *list = master->list; for ( ; list != NULL; list = list->next) { SCLogDebug("list %p tenant %u", list, list->tenant_id); if (list->type == DETECT_ENGINE_TYPE_NORMAL || list->type == DETECT_ENGINE_TYPE_MT_STUB || list->type == DETECT_ENGINE_TYPE_DD_STUB) { stub_de_ctx = list; break; } } if (stub_de_ctx == NULL) { stub_de_ctx = DetectEngineCtxInitStubForMT(); if (stub_de_ctx == NULL) { SCMutexUnlock(&master->lock); return -1; } if (master->list == NULL) { master->list = stub_de_ctx; } else { stub_de_ctx->next = master->list; master->list = stub_de_ctx; } } /* update the threads */ SCLogDebug("MT reload starting"); DetectEngineReloadThreads(stub_de_ctx); SCLogDebug("MT reload done"); SCMutexUnlock(&master->lock); /* walk free list, freeing the old_de_ctx */ DetectEnginePruneFreeList(); SCLogDebug("old_de_ctx should have been freed"); return 0; } static int g_parse_metadata = 0; void DetectEngineSetParseMetadata(void) { g_parse_metadata = 1; } void DetectEngineUnsetParseMetadata(void) { g_parse_metadata = 0; } int DetectEngineMustParseMetadata(void) { return g_parse_metadata; } const char *DetectSigmatchListEnumToString(enum DetectSigmatchListEnum type) { switch (type) { case DETECT_SM_LIST_MATCH: return "packet"; case DETECT_SM_LIST_PMATCH: return "packet/stream payload"; case DETECT_SM_LIST_TMATCH: return "tag"; case DETECT_SM_LIST_BASE64_DATA: return "base64_data"; case DETECT_SM_LIST_POSTMATCH: return "post-match"; case DETECT_SM_LIST_SUPPRESS: return "suppress"; case DETECT_SM_LIST_THRESHOLD: return "threshold"; case DETECT_SM_LIST_MAX: return "max (internal)"; } return "error"; } /* events api */ void DetectEngineSetEvent(DetectEngineThreadCtx *det_ctx, uint8_t e) { AppLayerDecoderEventsSetEventRaw(&det_ctx->decoder_events, e); det_ctx->events++; } AppLayerDecoderEvents *DetectEngineGetEvents(DetectEngineThreadCtx *det_ctx) { return det_ctx->decoder_events; } int DetectEngineGetEventInfo(const char *event_name, int *event_id, AppLayerEventType *event_type) { *event_id = SCMapEnumNameToValue(event_name, det_ctx_event_table); if (*event_id == -1) { SCLogError(SC_ERR_INVALID_ENUM_MAP, "event \"%s\" not present in " "det_ctx's enum map table.", event_name); /* this should be treated as fatal */ return -1; } *event_type = APP_LAYER_EVENT_TYPE_TRANSACTION; return 0; } /*************************************Unittest*********************************/ #ifdef UNITTESTS static int DetectEngineInitYamlConf(const char *conf) { ConfCreateContextBackup(); ConfInit(); return ConfYamlLoadString(conf, strlen(conf)); } static void DetectEngineDeInitYamlConf(void) { ConfDeInit(); ConfRestoreContextBackup(); return; } static int DetectEngineTest01(void) { const char *conf = "%YAML 1.1\n" "---\n" "detect-engine:\n" " - profile: medium\n" " - custom-values:\n" " toclient_src_groups: 2\n" " toclient_dst_groups: 2\n" " toclient_sp_groups: 2\n" " toclient_dp_groups: 3\n" " toserver_src_groups: 2\n" " toserver_dst_groups: 4\n" " toserver_sp_groups: 2\n" " toserver_dp_groups: 25\n" " - inspection-recursion-limit: 0\n"; DetectEngineCtx *de_ctx = NULL; int result = 0; if (DetectEngineInitYamlConf(conf) == -1) return 0; de_ctx = DetectEngineCtxInit(); if (de_ctx == NULL) goto end; result = (de_ctx->inspection_recursion_limit == -1); end: if (de_ctx != NULL) DetectEngineCtxFree(de_ctx); DetectEngineDeInitYamlConf(); return result; } static int DetectEngineTest02(void) { const char *conf = "%YAML 1.1\n" "---\n" "detect-engine:\n" " - profile: medium\n" " - custom-values:\n" " toclient_src_groups: 2\n" " toclient_dst_groups: 2\n" " toclient_sp_groups: 2\n" " toclient_dp_groups: 3\n" " toserver_src_groups: 2\n" " toserver_dst_groups: 4\n" " toserver_sp_groups: 2\n" " toserver_dp_groups: 25\n" " - inspection-recursion-limit:\n"; DetectEngineCtx *de_ctx = NULL; int result = 0; if (DetectEngineInitYamlConf(conf) == -1) return 0; de_ctx = DetectEngineCtxInit(); if (de_ctx == NULL) goto end; result = (de_ctx->inspection_recursion_limit == -1); end: if (de_ctx != NULL) DetectEngineCtxFree(de_ctx); DetectEngineDeInitYamlConf(); return result; } static int DetectEngineTest03(void) { const char *conf = "%YAML 1.1\n" "---\n" "detect-engine:\n" " - profile: medium\n" " - custom-values:\n" " toclient_src_groups: 2\n" " toclient_dst_groups: 2\n" " toclient_sp_groups: 2\n" " toclient_dp_groups: 3\n" " toserver_src_groups: 2\n" " toserver_dst_groups: 4\n" " toserver_sp_groups: 2\n" " toserver_dp_groups: 25\n"; DetectEngineCtx *de_ctx = NULL; int result = 0; if (DetectEngineInitYamlConf(conf) == -1) return 0; de_ctx = DetectEngineCtxInit(); if (de_ctx == NULL) goto end; result = (de_ctx->inspection_recursion_limit == DETECT_ENGINE_DEFAULT_INSPECTION_RECURSION_LIMIT); end: if (de_ctx != NULL) DetectEngineCtxFree(de_ctx); DetectEngineDeInitYamlConf(); return result; } static int DetectEngineTest04(void) { const char *conf = "%YAML 1.1\n" "---\n" "detect-engine:\n" " - profile: medium\n" " - custom-values:\n" " toclient_src_groups: 2\n" " toclient_dst_groups: 2\n" " toclient_sp_groups: 2\n" " toclient_dp_groups: 3\n" " toserver_src_groups: 2\n" " toserver_dst_groups: 4\n" " toserver_sp_groups: 2\n" " toserver_dp_groups: 25\n" " - inspection-recursion-limit: 10\n"; DetectEngineCtx *de_ctx = NULL; int result = 0; if (DetectEngineInitYamlConf(conf) == -1) return 0; de_ctx = DetectEngineCtxInit(); if (de_ctx == NULL) goto end; result = (de_ctx->inspection_recursion_limit == 10); end: if (de_ctx != NULL) DetectEngineCtxFree(de_ctx); DetectEngineDeInitYamlConf(); return result; } static int DetectEngineTest08(void) { const char *conf = "%YAML 1.1\n" "---\n" "detect-engine:\n" " - profile: custom\n" " - custom-values:\n" " toclient-groups: 23\n" " toserver-groups: 27\n"; DetectEngineCtx *de_ctx = NULL; int result = 0; if (DetectEngineInitYamlConf(conf) == -1) return 0; de_ctx = DetectEngineCtxInit(); if (de_ctx == NULL) goto end; if (de_ctx->max_uniq_toclient_groups == 23 && de_ctx->max_uniq_toserver_groups == 27) result = 1; end: if (de_ctx != NULL) DetectEngineCtxFree(de_ctx); DetectEngineDeInitYamlConf(); return result; } /** \test bug 892 bad values */ static int DetectEngineTest09(void) { const char *conf = "%YAML 1.1\n" "---\n" "detect-engine:\n" " - profile: custom\n" " - custom-values:\n" " toclient-groups: BA\n" " toserver-groups: BA\n" " - inspection-recursion-limit: 10\n"; DetectEngineCtx *de_ctx = NULL; int result = 0; if (DetectEngineInitYamlConf(conf) == -1) return 0; de_ctx = DetectEngineCtxInit(); if (de_ctx == NULL) goto end; if (de_ctx->max_uniq_toclient_groups == 20 && de_ctx->max_uniq_toserver_groups == 40) result = 1; end: if (de_ctx != NULL) DetectEngineCtxFree(de_ctx); DetectEngineDeInitYamlConf(); return result; } #endif void DetectEngineRegisterTests() { #ifdef UNITTESTS UtRegisterTest("DetectEngineTest01", DetectEngineTest01); UtRegisterTest("DetectEngineTest02", DetectEngineTest02); UtRegisterTest("DetectEngineTest03", DetectEngineTest03); UtRegisterTest("DetectEngineTest04", DetectEngineTest04); UtRegisterTest("DetectEngineTest08", DetectEngineTest08); UtRegisterTest("DetectEngineTest09", DetectEngineTest09); #endif return; }