/* * 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 "dataSinkInt.h" #include "dataSinkMgt.h" #include "executorimpl.h" #include "planner.h" #include "tcompression.h" #include "tdatablock.h" #include "tglobal.h" #include "tqueue.h" typedef struct SDataDispatchBuf { int32_t useSize; int32_t allocSize; char* pData; } SDataDispatchBuf; typedef struct SDataCacheEntry { int32_t dataLen; int32_t numOfRows; int32_t numOfCols; int8_t compressed; char data[]; } SDataCacheEntry; typedef struct SDataDispatchHandle { SDataSinkHandle sink; SDataSinkManager* pManager; SDataBlockDescNode* pSchema; STaosQueue* pDataBlocks; SDataDispatchBuf nextOutput; int32_t status; bool queryEnd; uint64_t useconds; TdThreadMutex mutex; } SDataDispatchHandle; static bool needCompress(const SSDataBlock* pData, int32_t numOfCols) { if (tsCompressColData < 0 || 0 == pData->info.rows) { return false; } for (int32_t col = 0; col < numOfCols; ++col) { SColumnInfoData* pColRes = taosArrayGet(pData->pDataBlock, col); int32_t colSize = pColRes->info.bytes * pData->info.rows; if (NEEDTO_COMPRESS_QUERY(colSize)) { return true; } } return false; } // data format: // +----------------+--------------+----------+--------------------------------------+-------------+-----------+-------------+-----------+ // |SDataCacheEntry | total length | group id | column#1 length, column#2 length ... | col1 bitmap | col1 data | col2 bitmap | col2 data | .... // | | (4 bytes) |(8 bytes) | sizeof(int32_t) * numOfCols | actual size | | actual size | | // +----------------+--------------+----------+--------------------------------------+-------------+-----------+-------------+-----------+ // The length of bitmap is decided by number of rows of this data block, and the length of each column data is // recorded in the first segment, next to the struct header static void toDataCacheEntry(const SDataDispatchHandle* pHandle, const SInputData* pInput, SDataDispatchBuf* pBuf) { int32_t numOfCols = LIST_LENGTH(pHandle->pSchema->pSlots); SDataCacheEntry* pEntry = (SDataCacheEntry*)pBuf->pData; pEntry->compressed = (int8_t)needCompress(pInput->pData, numOfCols); pEntry->numOfRows = pInput->pData->info.rows; pEntry->numOfCols = pInput->pData->info.numOfCols; pEntry->dataLen = 0; pBuf->useSize = sizeof(SRetrieveTableRsp); blockCompressEncode(pInput->pData, pEntry->data, &pEntry->dataLen, numOfCols, pEntry->compressed); pBuf->useSize += pEntry->dataLen; } static bool allocBuf(SDataDispatchHandle* pDispatcher, const SInputData* pInput, SDataDispatchBuf* pBuf) { uint32_t capacity = pDispatcher->pManager->cfg.maxDataBlockNumPerQuery; if (taosQueueItemSize(pDispatcher->pDataBlocks) > capacity) { qError("SinkNode queue is full, no capacity, max:%d, current:%d, no capacity", capacity, taosQueueItemSize(pDispatcher->pDataBlocks)); return false; } pBuf->allocSize = sizeof(SRetrieveTableRsp) + blockGetEncodeSize(pInput->pData); pBuf->pData = taosMemoryMalloc(pBuf->allocSize); if (pBuf->pData == NULL) { qError("SinkNode failed to malloc memory, size:%d, code:%d", pBuf->allocSize, TAOS_SYSTEM_ERROR(errno)); } return NULL != pBuf->pData; } static int32_t updateStatus(SDataDispatchHandle* pDispatcher) { taosThreadMutexLock(&pDispatcher->mutex); int32_t blockNums = taosQueueItemSize(pDispatcher->pDataBlocks); int32_t status = (0 == blockNums ? DS_BUF_EMPTY : (blockNums < pDispatcher->pManager->cfg.maxDataBlockNumPerQuery ? DS_BUF_LOW : DS_BUF_FULL)); pDispatcher->status = status; taosThreadMutexUnlock(&pDispatcher->mutex); return status; } static int32_t getStatus(SDataDispatchHandle* pDispatcher) { taosThreadMutexLock(&pDispatcher->mutex); int32_t status = pDispatcher->status; taosThreadMutexUnlock(&pDispatcher->mutex); return status; } static int32_t putDataBlock(SDataSinkHandle* pHandle, const SInputData* pInput, bool* pContinue) { SDataDispatchHandle* pDispatcher = (SDataDispatchHandle*)pHandle; SDataDispatchBuf* pBuf = taosAllocateQitem(sizeof(SDataDispatchBuf), DEF_QITEM); if (NULL == pBuf || !allocBuf(pDispatcher, pInput, pBuf)) { return TSDB_CODE_QRY_OUT_OF_MEMORY; } toDataCacheEntry(pDispatcher, pInput, pBuf); taosWriteQitem(pDispatcher->pDataBlocks, pBuf); *pContinue = (DS_BUF_LOW == updateStatus(pDispatcher) ? true : false); return TSDB_CODE_SUCCESS; } static void endPut(struct SDataSinkHandle* pHandle, uint64_t useconds) { SDataDispatchHandle* pDispatcher = (SDataDispatchHandle*)pHandle; taosThreadMutexLock(&pDispatcher->mutex); pDispatcher->queryEnd = true; pDispatcher->useconds = useconds; taosThreadMutexUnlock(&pDispatcher->mutex); } static void getDataLength(SDataSinkHandle* pHandle, int32_t* pLen, bool* pQueryEnd) { SDataDispatchHandle* pDispatcher = (SDataDispatchHandle*)pHandle; if (taosQueueEmpty(pDispatcher->pDataBlocks)) { *pQueryEnd = pDispatcher->queryEnd; *pLen = 0; return; } SDataDispatchBuf* pBuf = NULL; taosReadQitem(pDispatcher->pDataBlocks, (void**)&pBuf); memcpy(&pDispatcher->nextOutput, pBuf, sizeof(SDataDispatchBuf)); taosFreeQitem(pBuf); *pLen = ((SDataCacheEntry*)(pDispatcher->nextOutput.pData))->dataLen; *pQueryEnd = pDispatcher->queryEnd; } static int32_t getDataBlock(SDataSinkHandle* pHandle, SOutputData* pOutput) { SDataDispatchHandle* pDispatcher = (SDataDispatchHandle*)pHandle; if (NULL == pDispatcher->nextOutput.pData) { assert(pDispatcher->queryEnd); pOutput->useconds = pDispatcher->useconds; pOutput->precision = pDispatcher->pSchema->precision; pOutput->bufStatus = DS_BUF_EMPTY; pOutput->queryEnd = pDispatcher->queryEnd; return TSDB_CODE_SUCCESS; } SDataCacheEntry* pEntry = (SDataCacheEntry*)(pDispatcher->nextOutput.pData); memcpy(pOutput->pData, pEntry->data, pEntry->dataLen); pOutput->numOfRows = pEntry->numOfRows; pOutput->numOfCols = pEntry->numOfCols; pOutput->compressed = pEntry->compressed; taosMemoryFreeClear(pDispatcher->nextOutput.pData); // todo persistent pOutput->bufStatus = updateStatus(pDispatcher); taosThreadMutexLock(&pDispatcher->mutex); pOutput->queryEnd = pDispatcher->queryEnd; pOutput->useconds = pDispatcher->useconds; pOutput->precision = pDispatcher->pSchema->precision; taosThreadMutexUnlock(&pDispatcher->mutex); return TSDB_CODE_SUCCESS; } static int32_t destroyDataSinker(SDataSinkHandle* pHandle) { SDataDispatchHandle* pDispatcher = (SDataDispatchHandle*)pHandle; taosMemoryFreeClear(pDispatcher->nextOutput.pData); while (!taosQueueEmpty(pDispatcher->pDataBlocks)) { SDataDispatchBuf* pBuf = NULL; taosReadQitem(pDispatcher->pDataBlocks, (void**)&pBuf); taosMemoryFreeClear(pBuf->pData); taosFreeQitem(pBuf); } taosCloseQueue(pDispatcher->pDataBlocks); taosThreadMutexDestroy(&pDispatcher->mutex); return TSDB_CODE_SUCCESS; } int32_t createDataDispatcher(SDataSinkManager* pManager, const SDataSinkNode* pDataSink, DataSinkHandle* pHandle) { SDataDispatchHandle* dispatcher = taosMemoryCalloc(1, sizeof(SDataDispatchHandle)); if (NULL == dispatcher) { terrno = TSDB_CODE_QRY_OUT_OF_MEMORY; return TSDB_CODE_QRY_OUT_OF_MEMORY; } dispatcher->sink.fPut = putDataBlock; dispatcher->sink.fEndPut = endPut; dispatcher->sink.fGetLen = getDataLength; dispatcher->sink.fGetData = getDataBlock; dispatcher->sink.fDestroy = destroyDataSinker; dispatcher->pManager = pManager; dispatcher->pSchema = pDataSink->pInputDataBlockDesc; dispatcher->status = DS_BUF_EMPTY; dispatcher->queryEnd = false; dispatcher->pDataBlocks = taosOpenQueue(); taosThreadMutexInit(&dispatcher->mutex, NULL); if (NULL == dispatcher->pDataBlocks) { terrno = TSDB_CODE_QRY_OUT_OF_MEMORY; return TSDB_CODE_QRY_OUT_OF_MEMORY; } *pHandle = dispatcher; return TSDB_CODE_SUCCESS; }