/* * 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 . */ #ifdef USE_UV #include "transComm.h" // static TdThreadOnce transModuleInit = PTHREAD_ONCE_INIT; int transAuthenticateMsg(void* pMsg, int msgLen, void* pAuth, void* pKey) { T_MD5_CTX context; int ret = -1; tMD5Init(&context); tMD5Update(&context, (uint8_t*)pKey, TSDB_PASSWORD_LEN); tMD5Update(&context, (uint8_t*)pMsg, msgLen); tMD5Update(&context, (uint8_t*)pKey, TSDB_PASSWORD_LEN); tMD5Final(&context); if (memcmp(context.digest, pAuth, sizeof(context.digest)) == 0) ret = 0; return ret; } void transBuildAuthHead(void* pMsg, int msgLen, void* pAuth, void* pKey) { T_MD5_CTX context; tMD5Init(&context); tMD5Update(&context, (uint8_t*)pKey, TSDB_PASSWORD_LEN); tMD5Update(&context, (uint8_t*)pMsg, msgLen); tMD5Update(&context, (uint8_t*)pKey, TSDB_PASSWORD_LEN); tMD5Final(&context); memcpy(pAuth, context.digest, sizeof(context.digest)); } bool transCompressMsg(char* msg, int32_t len, int32_t* flen) { return false; // SRpcHead* pHead = rpcHeadFromCont(pCont); bool succ = false; int overhead = sizeof(STransCompMsg); if (!NEEDTO_COMPRESSS_MSG(len)) { return succ; } char* buf = taosMemoryMalloc(len + overhead + 8); // 8 extra bytes if (buf == NULL) { tError("failed to allocate memory for rpc msg compression, contLen:%d", len); *flen = len; return succ; } int32_t clen = LZ4_compress_default(msg, buf, len, len + overhead); tDebug("compress rpc msg, before:%d, after:%d, overhead:%d", len, clen, overhead); /* * only the compressed size is less than the value of contLen - overhead, the compression is applied * The first four bytes is set to 0, the second four bytes are utilized to keep the original length of message */ if (clen > 0 && clen < len - overhead) { STransCompMsg* pComp = (STransCompMsg*)msg; pComp->reserved = 0; pComp->contLen = htonl(len); memcpy(msg + overhead, buf, clen); tDebug("compress rpc msg, before:%d, after:%d", len, clen); *flen = clen + overhead; succ = true; } else { *flen = len; succ = false; } taosMemoryFree(buf); return succ; } bool transDecompressMsg(char* msg, int32_t len, int32_t* flen) { // impl later return false; STransCompMsg* pComp = (STransCompMsg*)msg; int overhead = sizeof(STransCompMsg); int clen = 0; return false; } void transFreeMsg(void* msg) { if (msg == NULL) { return; } taosMemoryFree((char*)msg - sizeof(STransMsgHead)); } int transInitBuffer(SConnBuffer* buf) { transClearBuffer(buf); return 0; } int transClearBuffer(SConnBuffer* buf) { memset(buf, 0, sizeof(*buf)); buf->total = -1; return 0; } int transAllocBuffer(SConnBuffer* connBuf, uv_buf_t* uvBuf) { /* * formate of data buffer: * |<--------------------------data from socket------------------------------->| * |<------STransMsgHead------->|<-------------------userdata--------------->|<-----auth data----->|<----user * info--->| */ static const int CAPACITY = sizeof(STransMsgHead); SConnBuffer* p = connBuf; if (p->cap == 0) { p->buf = (char*)taosMemoryCalloc(CAPACITY, sizeof(char)); p->len = 0; p->cap = CAPACITY; p->total = -1; uvBuf->base = p->buf; uvBuf->len = CAPACITY; } else if (p->total == -1 && p->len < CAPACITY) { uvBuf->base = p->buf + p->len; uvBuf->len = CAPACITY - p->len; } else { p->cap = p->total; p->buf = taosMemoryRealloc(p->buf, p->cap); uvBuf->base = p->buf + p->len; uvBuf->len = p->cap - p->len; } return 0; } // check whether already read complete bool transReadComplete(SConnBuffer* connBuf) { if (connBuf->total == -1 && connBuf->len >= sizeof(STransMsgHead)) { STransMsgHead head; memcpy((char*)&head, connBuf->buf, sizeof(head)); int32_t msgLen = (int32_t)htonl(head.msgLen); connBuf->total = msgLen; } if (connBuf->len == connBuf->cap && connBuf->total == connBuf->cap) { return true; } return false; } int transPackMsg(STransMsgHead* msgHead, bool sercured, bool auth) { return 0; } int transUnpackMsg(STransMsgHead* msgHead) { return 0; } int transDestroyBuffer(SConnBuffer* buf) { if (buf->cap > 0) { taosMemoryFreeClear(buf->buf); } transClearBuffer(buf); return 0; } int transSetConnOption(uv_tcp_t* stream) { uv_tcp_nodelay(stream, 1); int ret = uv_tcp_keepalive(stream, 5, 5); return ret; } SAsyncPool* transCreateAsyncPool(uv_loop_t* loop, int sz, void* arg, AsyncCB cb) { SAsyncPool* pool = taosMemoryCalloc(1, sizeof(SAsyncPool)); pool->index = 0; pool->nAsync = sz; pool->asyncs = taosMemoryCalloc(1, sizeof(uv_async_t) * pool->nAsync); for (int i = 0; i < pool->nAsync; i++) { uv_async_t* async = &(pool->asyncs[i]); uv_async_init(loop, async, cb); SAsyncItem* item = taosMemoryCalloc(1, sizeof(SAsyncItem)); item->pThrd = arg; QUEUE_INIT(&item->qmsg); taosThreadMutexInit(&item->mtx, NULL); async->data = item; } return pool; } void transDestroyAsyncPool(SAsyncPool* pool) { for (int i = 0; i < pool->nAsync; i++) { uv_async_t* async = &(pool->asyncs[i]); // uv_close((uv_handle_t*)async, NULL); SAsyncItem* item = async->data; taosThreadMutexDestroy(&item->mtx); taosMemoryFree(item); } taosMemoryFree(pool->asyncs); taosMemoryFree(pool); } int transSendAsync(SAsyncPool* pool, queue* q) { int idx = pool->index; idx = idx % pool->nAsync; // no need mutex here if (pool->index++ > pool->nAsync) { pool->index = 0; } uv_async_t* async = &(pool->asyncs[idx]); SAsyncItem* item = async->data; int64_t st = taosGetTimestampUs(); taosThreadMutexLock(&item->mtx); QUEUE_PUSH(&item->qmsg, q); taosThreadMutexUnlock(&item->mtx); int64_t el = taosGetTimestampUs() - st; if (el > 50) { // tInfo("lock and unlock cost: %d", (int)el); } return uv_async_send(async); } void transCtxInit(STransCtx* ctx) { // init transCtx ctx->args = taosHashInit(2, taosGetDefaultHashFunction(TSDB_DATA_TYPE_UINT), true, HASH_NO_LOCK); } void transCtxCleanup(STransCtx* ctx) { if (ctx->args == NULL) { return; } STransCtxVal* iter = taosHashIterate(ctx->args, NULL); while (iter) { iter->freeFunc(iter->val); iter = taosHashIterate(ctx->args, iter); } taosHashCleanup(ctx->args); ctx->args = NULL; } void transCtxMerge(STransCtx* dst, STransCtx* src) { if (dst->args == NULL) { dst->args = src->args; dst->brokenVal = src->brokenVal; src->args = NULL; return; } void* key = NULL; size_t klen = 0; void* iter = taosHashIterate(src->args, NULL); while (iter) { STransCtxVal* sVal = (STransCtxVal*)iter; key = taosHashGetKey(sVal, &klen); STransCtxVal* dVal = taosHashGet(dst->args, key, klen); if (dVal) { dVal->freeFunc(dVal->val); } taosHashPut(dst->args, key, klen, sVal, sizeof(*sVal)); iter = taosHashIterate(src->args, iter); } taosHashCleanup(src->args); } void* transCtxDumpVal(STransCtx* ctx, int32_t key) { if (ctx->args == NULL) { return NULL; } STransCtxVal* cVal = taosHashGet(ctx->args, (const void*)&key, sizeof(key)); if (cVal == NULL) { return NULL; } void* ret = NULL; (*cVal->clone)(cVal->val, &ret); return ret; } void* transCtxDumpBrokenlinkVal(STransCtx* ctx, int32_t* msgType) { void* ret = NULL; if (ctx->brokenVal.clone == NULL) { return ret; } (*ctx->brokenVal.clone)(ctx->brokenVal.val, &ret); *msgType = ctx->brokenVal.msgType; return ret; } void transQueueInit(STransQueue* queue, void (*freeFunc)(const void* arg)) { queue->q = taosArrayInit(2, sizeof(void*)); queue->freeFunc = (void (*)(const void*))freeFunc; } bool transQueuePush(STransQueue* queue, void* arg) { if (queue->q == NULL) { return true; } taosArrayPush(queue->q, &arg); if (taosArrayGetSize(queue->q) > 1) { return false; } return true; } void* transQueuePop(STransQueue* queue) { if (queue->q == NULL || taosArrayGetSize(queue->q) == 0) { return NULL; } void* ptr = taosArrayGetP(queue->q, 0); taosArrayRemove(queue->q, 0); return ptr; } int32_t transQueueSize(STransQueue* queue) { if (queue->q == NULL) { return 0; } return taosArrayGetSize(queue->q); } void* transQueueGet(STransQueue* queue, int i) { if (queue->q == NULL || taosArrayGetSize(queue->q) == 0) { return NULL; } if (i >= taosArrayGetSize(queue->q)) { return NULL; } void* ptr = taosArrayGetP(queue->q, i); return ptr; } void* transQueueRm(STransQueue* queue, int i) { if (queue->q == NULL || taosArrayGetSize(queue->q) == 0) { return NULL; } if (i >= taosArrayGetSize(queue->q)) { return NULL; } void* ptr = taosArrayGetP(queue->q, i); taosArrayRemove(queue->q, i); return ptr; } bool transQueueEmpty(STransQueue* queue) { if (queue->q == NULL) { return true; } return taosArrayGetSize(queue->q) == 0; } void transQueueClear(STransQueue* queue) { if (queue->freeFunc != NULL) { for (int i = 0; i < taosArrayGetSize(queue->q); i++) { void* p = taosArrayGetP(queue->q, i); queue->freeFunc(p); } } taosArrayClear(queue->q); } void transQueueDestroy(STransQueue* queue) { transQueueClear(queue); taosArrayDestroy(queue->q); } static int32_t timeCompare(const HeapNode* a, const HeapNode* b) { SDelayTask* arg1 = container_of(a, SDelayTask, node); SDelayTask* arg2 = container_of(b, SDelayTask, node); if (arg1->execTime > arg2->execTime) { return 0; } else { return 1; } } static void transDQTimeout(uv_timer_t* timer) { SDelayQueue* queue = timer->data; tTrace("timer %p timeout", timer); uint64_t timeout = 0; do { HeapNode* minNode = heapMin(queue->heap); if (minNode == NULL) break; SDelayTask* task = container_of(minNode, SDelayTask, node); if (task->execTime <= taosGetTimestampMs()) { heapRemove(queue->heap, minNode); task->func(task->arg); taosMemoryFree(task); timeout = 0; } else { timeout = task->execTime - taosGetTimestampMs(); break; } } while (1); if (timeout != 0) { uv_timer_start(queue->timer, transDQTimeout, timeout, 0); } } int transDQCreate(uv_loop_t* loop, SDelayQueue** queue) { uv_timer_t* timer = taosMemoryCalloc(1, sizeof(uv_timer_t)); uv_timer_init(loop, timer); Heap* heap = heapCreate(timeCompare); SDelayQueue* q = taosMemoryCalloc(1, sizeof(SDelayQueue)); q->heap = heap; q->timer = timer; q->loop = loop; q->timer->data = q; *queue = q; return 0; } void transDQDestroy(SDelayQueue* queue) { taosMemoryFree(queue->timer); while (heapSize(queue->heap) > 0) { HeapNode* minNode = heapMin(queue->heap); if (minNode == NULL) { return; } heapRemove(queue->heap, minNode); SDelayTask* task = container_of(minNode, SDelayTask, node); taosMemoryFree(task); } heapDestroy(queue->heap); taosMemoryFree(queue); } int transDQSched(SDelayQueue* queue, void (*func)(void* arg), void* arg, uint64_t timeoutMs) { SDelayTask* task = taosMemoryCalloc(1, sizeof(SDelayTask)); task->func = func; task->arg = arg; task->execTime = taosGetTimestampMs() + timeoutMs; tTrace("timer %p put task into queue, timeoutMs: %" PRIu64 "", queue->timer, timeoutMs); heapInsert(queue->heap, &task->node); uv_timer_start(queue->timer, transDQTimeout, timeoutMs, 0); return 0; } #endif