/* * Copyright (c) 2019 TAOS Data, Inc. * * This program is free software: you can use, redistribute, and/or modify * it under the terms of the GNU Affero General Public License, version 3 * or later ("AGPL"), 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. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . */ #include "os.h" #include "thash.h" #include "ulog.h" #include "taos.h" #include "tdef.h" #define EXT_SIZE 1024 #define HASH_NEED_RESIZE(_h) ((_h)->size >= (_h)->capacity * HASH_DEFAULT_LOAD_FACTOR) #define DO_FREE_HASH_NODE(_n) \ do { \ tfree(_n); \ } while (0) #define FREE_HASH_NODE(_h, _n) \ do { \ if ((_h)->freeFp) { \ (_h)->freeFp(GET_HASH_NODE_DATA(_n)); \ } \ \ DO_FREE_HASH_NODE(_n); \ } while (0); static FORCE_INLINE void __wr_lock(void *lock, int32_t type) { if (type == HASH_NO_LOCK) { return; } taosWLockLatch(lock); } static FORCE_INLINE void __rd_lock(void *lock, int32_t type) { if (type == HASH_NO_LOCK) { return; } taosRLockLatch(lock); } static FORCE_INLINE void __rd_unlock(void *lock, int32_t type) { if (type == HASH_NO_LOCK) { return; } taosRUnLockLatch(lock); } static FORCE_INLINE void __wr_unlock(void *lock, int32_t type) { if (type == HASH_NO_LOCK) { return; } taosWUnLockLatch(lock); } static FORCE_INLINE int32_t taosHashCapacity(int32_t length) { int32_t len = MIN(length, HASH_MAX_CAPACITY); int32_t i = 4; while (i < len) i = (i << 1u); return i; } static FORCE_INLINE SHashNode *doSearchInEntryList(SHashObj *pHashObj, SHashEntry *pe, const void *key, size_t keyLen, uint32_t hashVal) { SHashNode *pNode = pe->next; while (pNode) { if ((pNode->keyLen == keyLen) && ((*(pHashObj->equalFp))(GET_HASH_NODE_KEY(pNode), key, keyLen) == 0) && pNode->removed == 0) { assert(pNode->hashVal == hashVal); break; } pNode = pNode->next; } return pNode; } /** * Resize the hash list if the threshold is reached * * @param pHashObj */ static void taosHashTableResize(SHashObj *pHashObj); /** * @param key key of object for hash, usually a null-terminated string * @param keyLen length of key * @param pData actually data. Requires a consecutive memory block, no pointer is allowed in pData. * Pointer copy causes memory access error. * @param dsize size of data * @return SHashNode */ static SHashNode *doCreateHashNode(const void *key, size_t keyLen, const void *pData, size_t dsize, uint32_t hashVal); /** * Update the hash node * * @param pNode hash node * @param key key for generate hash value * @param keyLen key length * @param pData actual data * @param dsize size of actual data * @return hash node */ static FORCE_INLINE SHashNode *doUpdateHashNode(SHashObj *pHashObj, SHashEntry* pe, SHashNode* prev, SHashNode *pNode, SHashNode *pNewNode) { assert(pNode->keyLen == pNewNode->keyLen); pNode->count--; if (prev != NULL) { prev->next = pNewNode; } else { pe->next = pNewNode; } if (pNode->count <= 0) { pNewNode->next = pNode->next; DO_FREE_HASH_NODE(pNode); } else { pNewNode->next = pNode; pe->num++; atomic_add_fetch_64(&pHashObj->size, 1); } return pNewNode; } /** * insert the hash node at the front of the linked list * * @param pHashObj * @param pNode */ static void pushfrontNodeInEntryList(SHashEntry *pEntry, SHashNode *pNode); /** * Check whether the hash table is empty or not. * * @param pHashObj the hash table object * @return if the hash table is empty or not */ static FORCE_INLINE bool taosHashTableEmpty(const SHashObj *pHashObj); /** * Get the next element in hash table for iterator * @param pIter * @return */ SHashObj *taosHashInit(size_t capacity, _hash_fn_t fn, bool update, SHashLockTypeE type) { assert(fn != NULL); if (capacity == 0) { capacity = 4; } SHashObj *pHashObj = (SHashObj *)calloc(1, sizeof(SHashObj)); if (pHashObj == NULL) { uError("failed to allocate memory, reason:%s", strerror(errno)); return NULL; } // the max slots is not defined by user pHashObj->capacity = taosHashCapacity((int32_t)capacity); assert((pHashObj->capacity & (pHashObj->capacity - 1)) == 0); pHashObj->equalFp = memcmp; pHashObj->hashFp = fn; pHashObj->type = type; pHashObj->enableUpdate = update; pHashObj->hashList = (SHashEntry **)calloc(pHashObj->capacity, sizeof(void *)); if (pHashObj->hashList == NULL) { free(pHashObj); uError("failed to allocate memory, reason:%s", strerror(errno)); return NULL; } else { pHashObj->pMemBlock = taosArrayInit(8, sizeof(void *)); void *p = calloc(pHashObj->capacity, sizeof(SHashEntry)); for (int32_t i = 0; i < pHashObj->capacity; ++i) { pHashObj->hashList[i] = (void *)((char *)p + i * sizeof(SHashEntry)); } taosArrayPush(pHashObj->pMemBlock, &p); } return pHashObj; } void taosHashSetEqualFp(SHashObj *pHashObj, _equal_fn_t fp) { if (pHashObj != NULL && fp != NULL) { pHashObj->equalFp = fp; } } int32_t taosHashGetSize(const SHashObj *pHashObj) { if (!pHashObj) { return 0; } return (int32_t)atomic_load_64(&pHashObj->size); } static FORCE_INLINE bool taosHashTableEmpty(const SHashObj *pHashObj) { return taosHashGetSize(pHashObj) == 0; } int32_t taosHashPut(SHashObj *pHashObj, const void *key, size_t keyLen, void *data, size_t size) { uint32_t hashVal = (*pHashObj->hashFp)(key, (uint32_t)keyLen); SHashNode *pNewNode = doCreateHashNode(key, keyLen, data, size, hashVal); if (pNewNode == NULL) { return -1; } // need the resize process, write lock applied if (HASH_NEED_RESIZE(pHashObj)) { __wr_lock(&pHashObj->lock, pHashObj->type); taosHashTableResize(pHashObj); __wr_unlock(&pHashObj->lock, pHashObj->type); } __rd_lock(&pHashObj->lock, pHashObj->type); int32_t slot = HASH_INDEX(hashVal, pHashObj->capacity); SHashEntry *pe = pHashObj->hashList[slot]; if (pHashObj->type == HASH_ENTRY_LOCK) { taosWLockLatch(&pe->latch); } SHashNode *pNode = pe->next; if (pe->num > 0) { assert(pNode != NULL); } else { assert(pNode == NULL); } SHashNode* prev = NULL; while (pNode) { if ((pNode->keyLen == keyLen) && ((*(pHashObj->equalFp))(GET_HASH_NODE_KEY(pNode), key, keyLen) == 0) && pNode->removed == 0) { assert(pNode->hashVal == hashVal); break; } prev = pNode; pNode = pNode->next; } if (pNode == NULL) { // no data in hash table with the specified key, add it into hash table pushfrontNodeInEntryList(pe, pNewNode); if (pe->num == 0) { assert(pe->next == NULL); } else { assert(pe->next != NULL); } if (pHashObj->type == HASH_ENTRY_LOCK) { taosWUnLockLatch(&pe->latch); } // enable resize __rd_unlock(&pHashObj->lock, pHashObj->type); atomic_add_fetch_64(&pHashObj->size, 1); return 0; } else { // not support the update operation, return error if (pHashObj->enableUpdate) { doUpdateHashNode(pHashObj, pe, prev, pNode, pNewNode); } else { DO_FREE_HASH_NODE(pNewNode); } if (pHashObj->type == HASH_ENTRY_LOCK) { taosWUnLockLatch(&pe->latch); } // enable resize __rd_unlock(&pHashObj->lock, pHashObj->type); return pHashObj->enableUpdate ? 0 : -2; } } void *taosHashGet(SHashObj *pHashObj, const void *key, size_t keyLen) { return taosHashGetClone(pHashObj, key, keyLen, NULL); } //TODO(yihaoDeng), merge with taosHashGetClone void* taosHashGetCloneExt(SHashObj *pHashObj, const void *key, size_t keyLen, void (*fp)(void *), void** d, size_t *sz) { if (taosHashTableEmpty(pHashObj) || keyLen == 0 || key == NULL) { return NULL; } uint32_t hashVal = (*pHashObj->hashFp)(key, (uint32_t)keyLen); // only add the read lock to disable the resize process __rd_lock(&pHashObj->lock, pHashObj->type); int32_t slot = HASH_INDEX(hashVal, pHashObj->capacity); SHashEntry *pe = pHashObj->hashList[slot]; // no data, return directly if (atomic_load_32(&pe->num) == 0) { __rd_unlock(&pHashObj->lock, pHashObj->type); return NULL; } char *data = NULL; // lock entry if (pHashObj->type == HASH_ENTRY_LOCK) { taosRLockLatch(&pe->latch); } if (pe->num > 0) { assert(pe->next != NULL); } else { assert(pe->next == NULL); } SHashNode *pNode = doSearchInEntryList(pHashObj, pe, key, keyLen, hashVal); if (pNode != NULL) { if (fp != NULL) { fp(GET_HASH_NODE_DATA(pNode)); } if (*d == NULL) { *sz = pNode->dataLen + EXT_SIZE; *d = calloc(1, *sz); } else if (*sz < pNode->dataLen){ *sz = pNode->dataLen + EXT_SIZE; *d = realloc(*d, *sz); } memcpy((char *)(*d), GET_HASH_NODE_DATA(pNode), pNode->dataLen); // just make runtime happy if ((*sz) - pNode->dataLen > 0) { memset((char *)(*d) + pNode->dataLen, 0, (*sz) - pNode->dataLen); } data = GET_HASH_NODE_DATA(pNode); } if (pHashObj->type == HASH_ENTRY_LOCK) { taosRUnLockLatch(&pe->latch); } __rd_unlock(&pHashObj->lock, pHashObj->type); return data; } void* taosHashGetCloneImpl(SHashObj *pHashObj, const void *key, size_t keyLen, void* d, bool acquire) { if (taosHashTableEmpty(pHashObj) || keyLen == 0 || key == NULL) { return NULL; } uint32_t hashVal = (*pHashObj->hashFp)(key, (uint32_t)keyLen); // only add the read lock to disable the resize process __rd_lock(&pHashObj->lock, pHashObj->type); int32_t slot = HASH_INDEX(hashVal, pHashObj->capacity); SHashEntry *pe = pHashObj->hashList[slot]; // no data, return directly if (atomic_load_32(&pe->num) == 0) { __rd_unlock(&pHashObj->lock, pHashObj->type); return NULL; } char *data = NULL; // lock entry if (pHashObj->type == HASH_ENTRY_LOCK) { taosRLockLatch(&pe->latch); } if (pe->num > 0) { assert(pe->next != NULL); } else { assert(pe->next == NULL); } SHashNode *pNode = doSearchInEntryList(pHashObj, pe, key, keyLen, hashVal); if (pNode != NULL) { if (pHashObj->callbackFp != NULL) { pHashObj->callbackFp(GET_HASH_NODE_DATA(pNode)); } if (d != NULL) { memcpy(d, GET_HASH_NODE_DATA(pNode), pNode->dataLen); } if (acquire) { pNode->count++; } data = GET_HASH_NODE_DATA(pNode); } if (pHashObj->type == HASH_ENTRY_LOCK) { taosRUnLockLatch(&pe->latch); } __rd_unlock(&pHashObj->lock, pHashObj->type); return data; } void* taosHashGetClone(SHashObj *pHashObj, const void *key, size_t keyLen, void* d) { return taosHashGetCloneImpl(pHashObj, key, keyLen, d, false); } void* taosHashAcquire(SHashObj *pHashObj, const void *key, size_t keyLen) { return taosHashGetCloneImpl(pHashObj, key, keyLen, NULL, true); } int32_t taosHashRemove(SHashObj *pHashObj, const void *key, size_t keyLen/*, void *data, size_t dsize*/) { if (pHashObj == NULL || taosHashTableEmpty(pHashObj)) { return -1; } uint32_t hashVal = (*pHashObj->hashFp)(key, (uint32_t)keyLen); // disable the resize process __rd_lock(&pHashObj->lock, pHashObj->type); int32_t slot = HASH_INDEX(hashVal, pHashObj->capacity); SHashEntry *pe = pHashObj->hashList[slot]; if (pHashObj->type == HASH_ENTRY_LOCK) { taosWLockLatch(&pe->latch); } // double check after locked if (pe->num == 0) { assert(pe->next == NULL); taosWUnLockLatch(&pe->latch); __rd_unlock(&pHashObj->lock, pHashObj->type); return -1; } int code = -1; SHashNode *pNode = pe->next; SHashNode *prevNode = NULL; while (pNode) { if ((pNode->keyLen == keyLen) && ((*(pHashObj->equalFp))(GET_HASH_NODE_KEY(pNode), key, keyLen) == 0) && pNode->removed == 0) break; prevNode = pNode; pNode = pNode->next; } if (pNode) { code = 0; // it is found pNode->count--; pNode->removed = 1; if (pNode->count <= 0) { if (prevNode) { prevNode->next = pNode->next; } else { pe->next = pNode->next; } // if (data) memcpy(data, GET_HASH_NODE_DATA(pNode), dsize); pe->num--; atomic_sub_fetch_64(&pHashObj->size, 1); FREE_HASH_NODE(pHashObj, pNode); } } if (pHashObj->type == HASH_ENTRY_LOCK) { taosWUnLockLatch(&pe->latch); } __rd_unlock(&pHashObj->lock, pHashObj->type); return code; } int32_t taosHashCondTraverse(SHashObj *pHashObj, bool (*fp)(void *, void *), void *param) { if (pHashObj == NULL || taosHashTableEmpty(pHashObj)) { return 0; } // disable the resize process __rd_lock(&pHashObj->lock, pHashObj->type); int32_t numOfEntries = (int32_t)pHashObj->capacity; for (int32_t i = 0; i < numOfEntries; ++i) { SHashEntry *pEntry = pHashObj->hashList[i]; if (pEntry->num == 0) { continue; } if (pHashObj->type == HASH_ENTRY_LOCK) { taosWLockLatch(&pEntry->latch); } // todo remove the first node SHashNode *pNode = NULL; while((pNode = pEntry->next) != NULL) { if (fp && (!fp(param, GET_HASH_NODE_DATA(pNode)))) { pEntry->num -= 1; atomic_sub_fetch_64(&pHashObj->size, 1); pEntry->next = pNode->next; if (pEntry->num == 0) { assert(pEntry->next == NULL); } else { assert(pEntry->next != NULL); } FREE_HASH_NODE(pHashObj, pNode); } else { break; } } // handle the following node if (pNode != NULL) { assert(pNode == pEntry->next); SHashNode *pNext = NULL; while ((pNext = pNode->next) != NULL) { // not qualified, remove it if (fp && (!fp(param, GET_HASH_NODE_DATA(pNext)))) { pNode->next = pNext->next; pEntry->num -= 1; atomic_sub_fetch_64(&pHashObj->size, 1); if (pEntry->num == 0) { assert(pEntry->next == NULL); } else { assert(pEntry->next != NULL); } FREE_HASH_NODE(pHashObj, pNext); } else { pNode = pNext; } } } if (pHashObj->type == HASH_ENTRY_LOCK) { taosWUnLockLatch(&pEntry->latch); } } __rd_unlock(&pHashObj->lock, pHashObj->type); return 0; } void taosHashClear(SHashObj *pHashObj) { if (pHashObj == NULL) { return; } SHashNode *pNode, *pNext; __wr_lock(&pHashObj->lock, pHashObj->type); for (int32_t i = 0; i < pHashObj->capacity; ++i) { SHashEntry *pEntry = pHashObj->hashList[i]; if (pEntry->num == 0) { assert(pEntry->next == 0); continue; } pNode = pEntry->next; assert(pNode != NULL); while (pNode) { pNext = pNode->next; FREE_HASH_NODE(pHashObj, pNode); pNode = pNext; } pEntry->num = 0; pEntry->next = NULL; } pHashObj->size = 0; __wr_unlock(&pHashObj->lock, pHashObj->type); } void taosHashCleanup(SHashObj *pHashObj) { if (pHashObj == NULL) { return; } taosHashClear(pHashObj); tfree(pHashObj->hashList); // destroy mem block size_t memBlock = taosArrayGetSize(pHashObj->pMemBlock); for (int32_t i = 0; i < memBlock; ++i) { void *p = taosArrayGetP(pHashObj->pMemBlock, i); tfree(p); } taosArrayDestroy(pHashObj->pMemBlock); memset(pHashObj, 0, sizeof(SHashObj)); free(pHashObj); } // for profile only int32_t taosHashGetMaxOverflowLinkLength(const SHashObj *pHashObj) { if (pHashObj == NULL || taosHashTableEmpty(pHashObj)) { return 0; } int32_t num = 0; for (int32_t i = 0; i < pHashObj->size; ++i) { SHashEntry *pEntry = pHashObj->hashList[i]; if (num < pEntry->num) { num = pEntry->num; } } return num; } void taosHashTableResize(SHashObj *pHashObj) { if (!HASH_NEED_RESIZE(pHashObj)) { return; } // double the original capacity SHashNode *pNode = NULL; SHashNode *pNext = NULL; int32_t newSize = (int32_t)(pHashObj->capacity << 1u); if (newSize > HASH_MAX_CAPACITY) { // uDebug("current capacity:%d, maximum capacity:%d, no resize applied due to limitation is reached", // pHashObj->capacity, HASH_MAX_CAPACITY); return; } int64_t st = taosGetTimestampUs(); void *pNewEntryList = realloc(pHashObj->hashList, sizeof(void *) * newSize); if (pNewEntryList == NULL) { // todo handle error // uDebug("cache resize failed due to out of memory, capacity remain:%d", pHashObj->capacity); return; } pHashObj->hashList = pNewEntryList; size_t inc = newSize - pHashObj->capacity; void * p = calloc(inc, sizeof(SHashEntry)); for (int32_t i = 0; i < inc; ++i) { pHashObj->hashList[i + pHashObj->capacity] = (void *)((char *)p + i * sizeof(SHashEntry)); } taosArrayPush(pHashObj->pMemBlock, &p); pHashObj->capacity = newSize; for (int32_t i = 0; i < pHashObj->capacity; ++i) { SHashEntry *pe = pHashObj->hashList[i]; if (pe->num == 0) { assert(pe->next == NULL); } else { assert(pe->next != NULL); } if (pe->num == 0) { assert(pe->next == NULL); continue; } while ((pNode = pe->next) != NULL) { int32_t j = HASH_INDEX(pNode->hashVal, pHashObj->capacity); if (j != i) { pe->num -= 1; pe->next = pNode->next; if (pe->num == 0) { assert(pe->next == NULL); } else { assert(pe->next != NULL); } SHashEntry *pNewEntry = pHashObj->hashList[j]; pushfrontNodeInEntryList(pNewEntry, pNode); } else { break; } } if (pNode != NULL) { while ((pNext = pNode->next) != NULL) { int32_t j = HASH_INDEX(pNext->hashVal, pHashObj->capacity); if (j != i) { pe->num -= 1; pNode->next = pNext->next; pNext->next = NULL; // added into new slot SHashEntry *pNewEntry = pHashObj->hashList[j]; if (pNewEntry->num == 0) { assert(pNewEntry->next == NULL); } else { assert(pNewEntry->next != NULL); } pushfrontNodeInEntryList(pNewEntry, pNext); } else { pNode = pNext; } } if (pe->num == 0) { assert(pe->next == NULL); } else { assert(pe->next != NULL); } } } int64_t et = taosGetTimestampUs(); uDebug("hash table resize completed, new capacity:%d, load factor:%f, elapsed time:%fms", (int32_t)pHashObj->capacity, ((double)pHashObj->size) / pHashObj->capacity, (et - st) / 1000.0); } SHashNode *doCreateHashNode(const void *key, size_t keyLen, const void *pData, size_t dsize, uint32_t hashVal) { SHashNode *pNewNode = malloc(sizeof(SHashNode) + keyLen + dsize); if (pNewNode == NULL) { uError("failed to allocate memory, reason:%s", strerror(errno)); return NULL; } pNewNode->keyLen = (uint32_t)keyLen; pNewNode->hashVal = hashVal; pNewNode->dataLen = (uint32_t) dsize; pNewNode->count = 1; pNewNode->removed = 0; pNewNode->next = NULL; memcpy(GET_HASH_NODE_DATA(pNewNode), pData, dsize); memcpy(GET_HASH_NODE_KEY(pNewNode), key, keyLen); return pNewNode; } void pushfrontNodeInEntryList(SHashEntry *pEntry, SHashNode *pNode) { assert(pNode != NULL && pEntry != NULL); pNode->next = pEntry->next; pEntry->next = pNode; pEntry->num += 1; } size_t taosHashGetMemSize(const SHashObj *pHashObj) { if (pHashObj == NULL) { return 0; } return (pHashObj->capacity * (sizeof(SHashEntry) + POINTER_BYTES)) + sizeof(SHashNode) * taosHashGetSize(pHashObj) + sizeof(SHashObj); } FORCE_INLINE int32_t taosHashGetKey(void *data, void** key, size_t* keyLen) { if (NULL == data || NULL == key) { return -1; } SHashNode * node = GET_HASH_PNODE(data); *key = GET_HASH_NODE_KEY(node); *keyLen = node->keyLen; return 0; } FORCE_INLINE uint32_t taosHashGetDataKeyLen(SHashObj *pHashObj, void *data) { SHashNode * node = GET_HASH_PNODE(data); return node->keyLen; } // release the pNode, return next pNode, and lock the current entry static void *taosHashReleaseNode(SHashObj *pHashObj, void *p, int *slot) { SHashNode *pOld = (SHashNode *)GET_HASH_PNODE(p); SHashNode *prevNode = NULL; *slot = HASH_INDEX(pOld->hashVal, pHashObj->capacity); SHashEntry *pe = pHashObj->hashList[*slot]; // lock entry if (pHashObj->type == HASH_ENTRY_LOCK) { taosWLockLatch(&pe->latch); } SHashNode *pNode = pe->next; while (pNode) { if (pNode == pOld) break; prevNode = pNode; pNode = pNode->next; } if (pNode) { pNode = pNode->next; while (pNode) { if (pNode->removed == 0) break; pNode = pNode->next; } pOld->count--; if (pOld->count <=0) { if (prevNode) { prevNode->next = pOld->next; } else { pe->next = pOld->next; } pe->num--; atomic_sub_fetch_64(&pHashObj->size, 1); FREE_HASH_NODE(pHashObj, pOld); } } else { uError("pNode:%p data:%p is not there!!!", pNode, p); } return pNode; } void *taosHashIterate(SHashObj *pHashObj, void *p) { if (pHashObj == NULL) return NULL; int slot = 0; char *data = NULL; // only add the read lock to disable the resize process __rd_lock(&pHashObj->lock, pHashObj->type); SHashNode *pNode = NULL; if (p) { pNode = taosHashReleaseNode(pHashObj, p, &slot); if (pNode == NULL) { SHashEntry *pe = pHashObj->hashList[slot]; if (pHashObj->type == HASH_ENTRY_LOCK) { taosWUnLockLatch(&pe->latch); } slot = slot + 1; } } if (pNode == NULL) { for (; slot < pHashObj->capacity; ++slot) { SHashEntry *pe = pHashObj->hashList[slot]; // lock entry if (pHashObj->type == HASH_ENTRY_LOCK) { taosWLockLatch(&pe->latch); } pNode = pe->next; while (pNode) { if (pNode->removed == 0) break; pNode = pNode->next; } if (pNode) break; if (pHashObj->type == HASH_ENTRY_LOCK) { taosWUnLockLatch(&pe->latch); } } } if (pNode) { SHashEntry *pe = pHashObj->hashList[slot]; pNode->count++; data = GET_HASH_NODE_DATA(pNode); if (pHashObj->type == HASH_ENTRY_LOCK) { taosWUnLockLatch(&pe->latch); } } __rd_unlock(&pHashObj->lock, pHashObj->type); return data; } void taosHashCancelIterate(SHashObj *pHashObj, void *p) { if (pHashObj == NULL || p == NULL) return; // only add the read lock to disable the resize process __rd_lock(&pHashObj->lock, pHashObj->type); int slot; taosHashReleaseNode(pHashObj, p, &slot); SHashEntry *pe = pHashObj->hashList[slot]; if (pHashObj->type == HASH_ENTRY_LOCK) { taosWUnLockLatch(&pe->latch); } __rd_unlock(&pHashObj->lock, pHashObj->type); } void taosHashRelease(SHashObj *pHashObj, void *p) { taosHashCancelIterate(pHashObj, p); }