/* * 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 "uv.h" #include "os.h" #include "fnLog.h" #include "tudf.h" #include "tudfInt.h" #include "tarray.h" #include "tdatablock.h" #include "querynodes.h" #include "builtinsimpl.h" #include "functionMgt.h" //TODO: network error processing. //TODO: add unit test //TODO: include all global variable under context struct /* Copyright (c) 2013, Ben Noordhuis * The QUEUE is copied from queue.h under libuv * */ typedef void *QUEUE[2]; /* Private macros. */ #define QUEUE_NEXT(q) (*(QUEUE **) &((*(q))[0])) #define QUEUE_PREV(q) (*(QUEUE **) &((*(q))[1])) #define QUEUE_PREV_NEXT(q) (QUEUE_NEXT(QUEUE_PREV(q))) #define QUEUE_NEXT_PREV(q) (QUEUE_PREV(QUEUE_NEXT(q))) /* Public macros. */ #define QUEUE_DATA(ptr, type, field) \ ((type *) ((char *) (ptr) - offsetof(type, field))) /* Important note: mutating the list while QUEUE_FOREACH is * iterating over its elements results in undefined behavior. */ #define QUEUE_FOREACH(q, h) \ for ((q) = QUEUE_NEXT(h); (q) != (h); (q) = QUEUE_NEXT(q)) #define QUEUE_EMPTY(q) \ ((const QUEUE *) (q) == (const QUEUE *) QUEUE_NEXT(q)) #define QUEUE_HEAD(q) \ (QUEUE_NEXT(q)) #define QUEUE_INIT(q) \ do { \ QUEUE_NEXT(q) = (q); \ QUEUE_PREV(q) = (q); \ } \ while (0) #define QUEUE_ADD(h, n) \ do { \ QUEUE_PREV_NEXT(h) = QUEUE_NEXT(n); \ QUEUE_NEXT_PREV(n) = QUEUE_PREV(h); \ QUEUE_PREV(h) = QUEUE_PREV(n); \ QUEUE_PREV_NEXT(h) = (h); \ } \ while (0) #define QUEUE_SPLIT(h, q, n) \ do { \ QUEUE_PREV(n) = QUEUE_PREV(h); \ QUEUE_PREV_NEXT(n) = (n); \ QUEUE_NEXT(n) = (q); \ QUEUE_PREV(h) = QUEUE_PREV(q); \ QUEUE_PREV_NEXT(h) = (h); \ QUEUE_PREV(q) = (n); \ } \ while (0) #define QUEUE_MOVE(h, n) \ do { \ if (QUEUE_EMPTY(h)) \ QUEUE_INIT(n); \ else { \ QUEUE* q = QUEUE_HEAD(h); \ QUEUE_SPLIT(h, q, n); \ } \ } \ while (0) #define QUEUE_INSERT_HEAD(h, q) \ do { \ QUEUE_NEXT(q) = QUEUE_NEXT(h); \ QUEUE_PREV(q) = (h); \ QUEUE_NEXT_PREV(q) = (q); \ QUEUE_NEXT(h) = (q); \ } \ while (0) #define QUEUE_INSERT_TAIL(h, q) \ do { \ QUEUE_NEXT(q) = (h); \ QUEUE_PREV(q) = QUEUE_PREV(h); \ QUEUE_PREV_NEXT(q) = (q); \ QUEUE_PREV(h) = (q); \ } \ while (0) #define QUEUE_REMOVE(q) \ do { \ QUEUE_PREV_NEXT(q) = QUEUE_NEXT(q); \ QUEUE_NEXT_PREV(q) = QUEUE_PREV(q); \ } \ while (0) enum { UV_TASK_CONNECT = 0, UV_TASK_REQ_RSP = 1, UV_TASK_DISCONNECT = 2 }; int64_t gUdfTaskSeqNum = 0; typedef struct SUdfdProxy { char udfdPipeName[PATH_MAX + UDF_LISTEN_PIPE_NAME_LEN + 2]; uv_barrier_t gUdfInitBarrier; uv_loop_t gUdfdLoop; uv_thread_t gUdfLoopThread; uv_async_t gUdfLoopTaskAync; uv_async_t gUdfLoopStopAsync; uv_mutex_t gUdfTaskQueueMutex; int8_t gUdfcState; QUEUE gUdfTaskQueue; QUEUE gUvProcTaskQueue; int8_t initialized; } SUdfdProxy; SUdfdProxy gUdfdProxy = {0}; typedef struct SClientUdfUvSession { SUdfdProxy *udfc; int64_t severHandle; uv_pipe_t *udfUvPipe; int8_t outputType; int32_t outputLen; int32_t bufSize; } SClientUdfUvSession; typedef struct SClientUvTaskNode { SUdfdProxy *udfc; int8_t type; int errCode; uv_pipe_t *pipe; int64_t seqNum; uv_buf_t reqBuf; uv_sem_t taskSem; uv_buf_t rspBuf; QUEUE recvTaskQueue; QUEUE procTaskQueue; QUEUE connTaskQueue; } SClientUvTaskNode; typedef struct SClientUdfTask { int8_t type; SClientUdfUvSession *session; int32_t errCode; union { struct { SUdfSetupRequest req; SUdfSetupResponse rsp; } _setup; struct { SUdfCallRequest req; SUdfCallResponse rsp; } _call; struct { SUdfTeardownRequest req; SUdfTeardownResponse rsp; } _teardown; }; } SClientUdfTask; typedef struct SClientConnBuf { char *buf; int32_t len; int32_t cap; int32_t total; } SClientConnBuf; typedef struct SClientUvConn { uv_pipe_t *pipe; QUEUE taskQueue; SClientConnBuf readBuf; SClientUdfUvSession *session; } SClientUvConn; enum { UDFC_STATE_INITAL = 0, // initial state UDFC_STATE_STARTNG, // starting after udfcOpen UDFC_STATE_READY, // started and begin to receive quests UDFC_STATE_STOPPING, // stopping after udfcClose }; int32_t getUdfdPipeName(char* pipeName, int32_t size) { char dnodeId[8] = {0}; size_t dnodeIdSize = sizeof(dnodeId); int32_t err = uv_os_getenv(UDF_DNODE_ID_ENV_NAME, dnodeId, &dnodeIdSize); if (err != 0) { fnError("get dnode id from env. error: %s.", uv_err_name(err)); dnodeId[0] = '1'; } #ifdef _WIN32 snprintf(pipeName, size, "%s%s", UDF_LISTEN_PIPE_NAME_PREFIX, dnodeId); #else snprintf(pipeName, size, "%s/%s%s", tsDataDir, UDF_LISTEN_PIPE_NAME_PREFIX, dnodeId); #endif fnInfo("get dnode id from env. dnode id: %s. pipe path: %s", dnodeId, pipeName); return 0; } int32_t encodeUdfSetupRequest(void **buf, const SUdfSetupRequest *setup) { int32_t len = 0; len += taosEncodeBinary(buf, setup->udfName, TSDB_FUNC_NAME_LEN); return len; } void* decodeUdfSetupRequest(const void* buf, SUdfSetupRequest *request) { buf = taosDecodeBinaryTo(buf, request->udfName, TSDB_FUNC_NAME_LEN); return (void*)buf; } int32_t encodeUdfInterBuf(void **buf, const SUdfInterBuf* state) { int32_t len = 0; len += taosEncodeFixedI8(buf, state->numOfResult); len += taosEncodeFixedI32(buf, state->bufLen); len += taosEncodeBinary(buf, state->buf, state->bufLen); return len; } void* decodeUdfInterBuf(const void* buf, SUdfInterBuf* state) { buf = taosDecodeFixedI8(buf, &state->numOfResult); buf = taosDecodeFixedI32(buf, &state->bufLen); buf = taosDecodeBinary(buf, (void**)&state->buf, state->bufLen); return (void*)buf; } int32_t encodeUdfCallRequest(void **buf, const SUdfCallRequest *call) { int32_t len = 0; len += taosEncodeFixedI64(buf, call->udfHandle); len += taosEncodeFixedI8(buf, call->callType); if (call->callType == TSDB_UDF_CALL_SCALA_PROC) { len += tEncodeDataBlock(buf, &call->block); } else if (call->callType == TSDB_UDF_CALL_AGG_INIT) { len += taosEncodeFixedI8(buf, call->initFirst); } else if (call->callType == TSDB_UDF_CALL_AGG_PROC) { len += tEncodeDataBlock(buf, &call->block); len += encodeUdfInterBuf(buf, &call->interBuf); } else if (call->callType == TSDB_UDF_CALL_AGG_MERGE) { len += encodeUdfInterBuf(buf, &call->interBuf); len += encodeUdfInterBuf(buf, &call->interBuf2); } else if (call->callType == TSDB_UDF_CALL_AGG_FIN) { len += encodeUdfInterBuf(buf, &call->interBuf); } return len; } void* decodeUdfCallRequest(const void* buf, SUdfCallRequest* call) { buf = taosDecodeFixedI64(buf, &call->udfHandle); buf = taosDecodeFixedI8(buf, &call->callType); switch (call->callType) { case TSDB_UDF_CALL_SCALA_PROC: buf = tDecodeDataBlock(buf, &call->block); break; case TSDB_UDF_CALL_AGG_INIT: buf = taosDecodeFixedI8(buf, &call->initFirst); break; case TSDB_UDF_CALL_AGG_PROC: buf = tDecodeDataBlock(buf, &call->block); buf = decodeUdfInterBuf(buf, &call->interBuf); break; case TSDB_UDF_CALL_AGG_MERGE: buf = decodeUdfInterBuf(buf, &call->interBuf); buf = decodeUdfInterBuf(buf, &call->interBuf2); break; case TSDB_UDF_CALL_AGG_FIN: buf = decodeUdfInterBuf(buf, &call->interBuf); break; } return (void*)buf; } int32_t encodeUdfTeardownRequest(void **buf, const SUdfTeardownRequest *teardown) { int32_t len = 0; len += taosEncodeFixedI64(buf, teardown->udfHandle); return len; } void* decodeUdfTeardownRequest(const void* buf, SUdfTeardownRequest *teardown) { buf = taosDecodeFixedI64(buf, &teardown->udfHandle); return (void*)buf; } int32_t encodeUdfRequest(void** buf, const SUdfRequest* request) { int32_t len = 0; if (buf == NULL) { len += sizeof(request->msgLen); } else { *(int32_t*)(*buf) = request->msgLen; *buf = POINTER_SHIFT(*buf, sizeof(request->msgLen)); } len += taosEncodeFixedI64(buf, request->seqNum); len += taosEncodeFixedI8(buf, request->type); if (request->type == UDF_TASK_SETUP) { len += encodeUdfSetupRequest(buf, &request->setup); } else if (request->type == UDF_TASK_CALL) { len += encodeUdfCallRequest(buf, &request->call); } else if (request->type == UDF_TASK_TEARDOWN) { len += encodeUdfTeardownRequest(buf, &request->teardown); } return len; } void* decodeUdfRequest(const void* buf, SUdfRequest* request) { request->msgLen = *(int32_t*)(buf); buf = POINTER_SHIFT(buf, sizeof(request->msgLen)); buf = taosDecodeFixedI64(buf, &request->seqNum); buf = taosDecodeFixedI8(buf, &request->type); if (request->type == UDF_TASK_SETUP) { buf = decodeUdfSetupRequest(buf, &request->setup); } else if (request->type == UDF_TASK_CALL) { buf = decodeUdfCallRequest(buf, &request->call); } else if (request->type == UDF_TASK_TEARDOWN) { buf = decodeUdfTeardownRequest(buf, &request->teardown); } return (void*)buf; } int32_t encodeUdfSetupResponse(void **buf, const SUdfSetupResponse *setupRsp) { int32_t len = 0; len += taosEncodeFixedI64(buf, setupRsp->udfHandle); len += taosEncodeFixedI8(buf, setupRsp->outputType); len += taosEncodeFixedI32(buf, setupRsp->outputLen); len += taosEncodeFixedI32(buf, setupRsp->bufSize); return len; } void* decodeUdfSetupResponse(const void* buf, SUdfSetupResponse* setupRsp) { buf = taosDecodeFixedI64(buf, &setupRsp->udfHandle); buf = taosDecodeFixedI8(buf, &setupRsp->outputType); buf = taosDecodeFixedI32(buf, &setupRsp->outputLen); buf = taosDecodeFixedI32(buf, &setupRsp->bufSize); return (void*)buf; } int32_t encodeUdfCallResponse(void **buf, const SUdfCallResponse *callRsp) { int32_t len = 0; len += taosEncodeFixedI8(buf, callRsp->callType); switch (callRsp->callType) { case TSDB_UDF_CALL_SCALA_PROC: len += tEncodeDataBlock(buf, &callRsp->resultData); break; case TSDB_UDF_CALL_AGG_INIT: len += encodeUdfInterBuf(buf, &callRsp->resultBuf); break; case TSDB_UDF_CALL_AGG_PROC: len += encodeUdfInterBuf(buf, &callRsp->resultBuf); break; case TSDB_UDF_CALL_AGG_MERGE: len += encodeUdfInterBuf(buf, &callRsp->resultBuf); break; case TSDB_UDF_CALL_AGG_FIN: len += encodeUdfInterBuf(buf, &callRsp->resultBuf); break; } return len; } void* decodeUdfCallResponse(const void* buf, SUdfCallResponse* callRsp) { buf = taosDecodeFixedI8(buf, &callRsp->callType); switch (callRsp->callType) { case TSDB_UDF_CALL_SCALA_PROC: buf = tDecodeDataBlock(buf, &callRsp->resultData); break; case TSDB_UDF_CALL_AGG_INIT: buf = decodeUdfInterBuf(buf, &callRsp->resultBuf); break; case TSDB_UDF_CALL_AGG_PROC: buf = decodeUdfInterBuf(buf, &callRsp->resultBuf); break; case TSDB_UDF_CALL_AGG_MERGE: buf = decodeUdfInterBuf(buf, &callRsp->resultBuf); break; case TSDB_UDF_CALL_AGG_FIN: buf = decodeUdfInterBuf(buf, &callRsp->resultBuf); break; } return (void*)buf; } int32_t encodeUdfTeardownResponse(void** buf, const SUdfTeardownResponse* teardownRsp) { return 0; } void* decodeUdfTeardownResponse(const void* buf, SUdfTeardownResponse* teardownResponse) { return (void*)buf; } int32_t encodeUdfResponse(void** buf, const SUdfResponse* rsp) { int32_t len = 0; if (buf == NULL) { len += sizeof(rsp->msgLen); } else { *(int32_t*)(*buf) = rsp->msgLen; *buf = POINTER_SHIFT(*buf, sizeof(rsp->msgLen)); } if (buf == NULL) { len += sizeof(rsp->seqNum); } else { *(int64_t*)(*buf) = rsp->seqNum; *buf = POINTER_SHIFT(*buf, sizeof(rsp->seqNum)); } len += taosEncodeFixedI64(buf, rsp->seqNum); len += taosEncodeFixedI8(buf, rsp->type); len += taosEncodeFixedI32(buf, rsp->code); switch (rsp->type) { case UDF_TASK_SETUP: len += encodeUdfSetupResponse(buf, &rsp->setupRsp); break; case UDF_TASK_CALL: len += encodeUdfCallResponse(buf, &rsp->callRsp); break; case UDF_TASK_TEARDOWN: len += encodeUdfTeardownResponse(buf, &rsp->teardownRsp); break; default: //TODO: log error break; } return len; } void* decodeUdfResponse(const void* buf, SUdfResponse* rsp) { rsp->msgLen = *(int32_t*)(buf); buf = POINTER_SHIFT(buf, sizeof(rsp->msgLen)); rsp->seqNum = *(int64_t*)(buf); buf = POINTER_SHIFT(buf, sizeof(rsp->seqNum)); buf = taosDecodeFixedI64(buf, &rsp->seqNum); buf = taosDecodeFixedI8(buf, &rsp->type); buf = taosDecodeFixedI32(buf, &rsp->code); switch (rsp->type) { case UDF_TASK_SETUP: buf = decodeUdfSetupResponse(buf, &rsp->setupRsp); break; case UDF_TASK_CALL: buf = decodeUdfCallResponse(buf, &rsp->callRsp); break; case UDF_TASK_TEARDOWN: buf = decodeUdfTeardownResponse(buf, &rsp->teardownRsp); break; default: //TODO: log error break; } return (void*)buf; } void freeUdfColumnData(SUdfColumnData *data, SUdfColumnMeta *meta) { if (IS_VAR_DATA_TYPE(meta->type)) { taosMemoryFree(data->varLenCol.varOffsets); data->varLenCol.varOffsets = NULL; taosMemoryFree(data->varLenCol.payload); data->varLenCol.payload = NULL; } else { taosMemoryFree(data->fixLenCol.nullBitmap); data->fixLenCol.nullBitmap = NULL; taosMemoryFree(data->fixLenCol.data); data->fixLenCol.data = NULL; } } void freeUdfColumn(SUdfColumn* col) { freeUdfColumnData(&col->colData, &col->colMeta); } void freeUdfDataDataBlock(SUdfDataBlock *block) { for (int32_t i = 0; i < block->numOfCols; ++i) { freeUdfColumn(block->udfCols[i]); taosMemoryFree(block->udfCols[i]); block->udfCols[i] = NULL; } taosMemoryFree(block->udfCols); block->udfCols = NULL; } void freeUdfInterBuf(SUdfInterBuf *buf) { taosMemoryFree(buf->buf); buf->buf = NULL; } int32_t convertDataBlockToUdfDataBlock(SSDataBlock *block, SUdfDataBlock *udfBlock) { udfBlock->numOfRows = block->info.rows; udfBlock->numOfCols = block->info.numOfCols; udfBlock->udfCols = taosMemoryCalloc(udfBlock->numOfCols, sizeof(SUdfColumn*)); for (int32_t i = 0; i < udfBlock->numOfCols; ++i) { udfBlock->udfCols[i] = taosMemoryCalloc(1, sizeof(SUdfColumn)); SColumnInfoData *col= (SColumnInfoData*)taosArrayGet(block->pDataBlock, i); SUdfColumn *udfCol = udfBlock->udfCols[i]; udfCol->colMeta.type = col->info.type; udfCol->colMeta.bytes = col->info.bytes; udfCol->colMeta.scale = col->info.scale; udfCol->colMeta.precision = col->info.precision; udfCol->colData.numOfRows = udfBlock->numOfRows; if (IS_VAR_DATA_TYPE(udfCol->colMeta.type)) { udfCol->colData.varLenCol.varOffsetsLen = sizeof(int32_t) * udfBlock->numOfRows; udfCol->colData.varLenCol.varOffsets = taosMemoryMalloc(udfCol->colData.varLenCol.varOffsetsLen); memcpy(udfCol->colData.varLenCol.varOffsets, col->varmeta.offset, udfCol->colData.varLenCol.varOffsetsLen); udfCol->colData.varLenCol.payloadLen = colDataGetLength(col, udfBlock->numOfRows); udfCol->colData.varLenCol.payload = taosMemoryMalloc(udfCol->colData.varLenCol.payloadLen); memcpy(udfCol->colData.varLenCol.payload, col->pData, udfCol->colData.varLenCol.payloadLen); } else { udfCol->colData.fixLenCol.nullBitmapLen = BitmapLen(udfCol->colData.numOfRows); int32_t bitmapLen = udfCol->colData.fixLenCol.nullBitmapLen; udfCol->colData.fixLenCol.nullBitmap = taosMemoryMalloc(udfCol->colData.fixLenCol.nullBitmapLen); char* bitmap = udfCol->colData.fixLenCol.nullBitmap; memcpy(bitmap, col->nullbitmap, bitmapLen); udfCol->colData.fixLenCol.dataLen = colDataGetLength(col, udfBlock->numOfRows); int32_t dataLen = udfCol->colData.fixLenCol.dataLen; udfCol->colData.fixLenCol.data = taosMemoryMalloc(udfCol->colData.fixLenCol.dataLen); char* data = udfCol->colData.fixLenCol.data; memcpy(data, col->pData, dataLen); } } return 0; } int32_t convertUdfColumnToDataBlock(SUdfColumn *udfCol, SSDataBlock *block) { block->info.numOfCols = 1; block->info.rows = udfCol->colData.numOfRows; block->info.hasVarCol = IS_VAR_DATA_TYPE(udfCol->colMeta.type); block->pDataBlock = taosArrayInit(1, sizeof(SColumnInfoData)); taosArraySetSize(block->pDataBlock, 1); SColumnInfoData *col = taosArrayGet(block->pDataBlock, 0); SUdfColumnMeta *meta = &udfCol->colMeta; col->info.precision = meta->precision; col->info.bytes = meta->bytes; col->info.scale = meta->scale; col->info.type = meta->type; SUdfColumnData *data = &udfCol->colData; if (!IS_VAR_DATA_TYPE(meta->type)) { col->nullbitmap = taosMemoryMalloc(data->fixLenCol.nullBitmapLen); memcpy(col->nullbitmap, data->fixLenCol.nullBitmap, data->fixLenCol.nullBitmapLen); col->pData = taosMemoryMalloc(data->fixLenCol.dataLen); memcpy(col->pData, data->fixLenCol.data, data->fixLenCol.dataLen); } else { col->varmeta.offset = taosMemoryMalloc(data->varLenCol.varOffsetsLen); memcpy(col->varmeta.offset, data->varLenCol.varOffsets, data->varLenCol.varOffsetsLen); col->pData = taosMemoryMalloc(data->varLenCol.payloadLen); memcpy(col->pData, data->varLenCol.payload, data->varLenCol.payloadLen); } return 0; } int32_t convertScalarParamToDataBlock(SScalarParam *input, int32_t numOfCols, SSDataBlock *output) { output->info.rows = input->numOfRows; output->info.numOfCols = numOfCols; bool hasVarCol = false; for (int32_t i = 0; i < numOfCols; ++i) { if (IS_VAR_DATA_TYPE((input+i)->columnData->info.type)) { hasVarCol = true; break; } } output->info.hasVarCol = hasVarCol; //TODO: free the array output->pDataBlock output->pDataBlock = taosArrayInit(numOfCols, sizeof(SColumnInfoData)); for (int32_t i = 0; i < numOfCols; ++i) { taosArrayPush(output->pDataBlock, (input + i)->columnData); } return 0; } int32_t convertDataBlockToScalarParm(SSDataBlock *input, SScalarParam *output) { if (input->info.numOfCols != 1) { fnError("scalar function only support one column"); return -1; } output->numOfRows = input->info.rows; //TODO: memory output->columnData = taosArrayGet(input->pDataBlock, 0); return 0; } void onUdfcPipeClose(uv_handle_t *handle) { SClientUvConn *conn = handle->data; if (!QUEUE_EMPTY(&conn->taskQueue)) { QUEUE* h = QUEUE_HEAD(&conn->taskQueue); SClientUvTaskNode *task = QUEUE_DATA(h, SClientUvTaskNode, connTaskQueue); task->errCode = 0; QUEUE_REMOVE(&task->procTaskQueue); uv_sem_post(&task->taskSem); } conn->session->udfUvPipe = NULL; taosMemoryFree(conn->readBuf.buf); taosMemoryFree(conn); taosMemoryFree((uv_pipe_t *) handle); } int32_t udfcGetUdfTaskResultFromUvTask(SClientUdfTask *task, SClientUvTaskNode *uvTask) { fnDebug("udfc get uv task result. task: %p, uvTask: %p", task, uvTask); if (uvTask->type == UV_TASK_REQ_RSP) { if (uvTask->rspBuf.base != NULL) { SUdfResponse rsp; void* buf = decodeUdfResponse(uvTask->rspBuf.base, &rsp); assert(uvTask->rspBuf.len == POINTER_DISTANCE(buf, uvTask->rspBuf.base)); task->errCode = rsp.code; switch (task->type) { case UDF_TASK_SETUP: { //TODO: copy or not task->_setup.rsp = rsp.setupRsp; break; } case UDF_TASK_CALL: { task->_call.rsp = rsp.callRsp; //TODO: copy or not break; } case UDF_TASK_TEARDOWN: { task->_teardown.rsp = rsp.teardownRsp; //TODO: copy or not? break; } default: { break; } } // TODO: the call buffer is setup and freed by udf invocation taosMemoryFree(uvTask->rspBuf.base); } else { task->errCode = uvTask->errCode; } } else if (uvTask->type == UV_TASK_CONNECT) { task->errCode = uvTask->errCode; } else if (uvTask->type == UV_TASK_DISCONNECT) { task->errCode = uvTask->errCode; } return 0; } void udfcAllocateBuffer(uv_handle_t *handle, size_t suggestedSize, uv_buf_t *buf) { SClientUvConn *conn = handle->data; SClientConnBuf *connBuf = &conn->readBuf; int32_t msgHeadSize = sizeof(int32_t) + sizeof(int64_t); if (connBuf->cap == 0) { connBuf->buf = taosMemoryMalloc(msgHeadSize); if (connBuf->buf) { connBuf->len = 0; connBuf->cap = msgHeadSize; connBuf->total = -1; buf->base = connBuf->buf; buf->len = connBuf->cap; } else { fnError("udfc allocate buffer failure. size: %d", msgHeadSize); buf->base = NULL; buf->len = 0; } } else { connBuf->cap = connBuf->total > connBuf->cap ? connBuf->total : connBuf->cap; void *resultBuf = taosMemoryRealloc(connBuf->buf, connBuf->cap); if (resultBuf) { connBuf->buf = resultBuf; buf->base = connBuf->buf + connBuf->len; buf->len = connBuf->cap - connBuf->len; } else { fnError("udfc re-allocate buffer failure. size: %d", connBuf->cap); buf->base = NULL; buf->len = 0; } } fnTrace("conn buf cap - len - total : %d - %d - %d", connBuf->cap, connBuf->len, connBuf->total); } bool isUdfcUvMsgComplete(SClientConnBuf *connBuf) { if (connBuf->total == -1 && connBuf->len >= sizeof(int32_t)) { connBuf->total = *(int32_t *) (connBuf->buf); } if (connBuf->len == connBuf->cap && connBuf->total == connBuf->cap) { fnTrace("udfc complete message is received, now handle it"); return true; } return false; } void udfcUvHandleRsp(SClientUvConn *conn) { SClientConnBuf *connBuf = &conn->readBuf; int64_t seqNum = *(int64_t *) (connBuf->buf + sizeof(int32_t)); // msglen then seqnum if (QUEUE_EMPTY(&conn->taskQueue)) { fnError("udfc no task waiting for response on connection"); return; } bool found = false; SClientUvTaskNode *taskFound = NULL; QUEUE* h = QUEUE_NEXT(&conn->taskQueue); SClientUvTaskNode *task = QUEUE_DATA(h, SClientUvTaskNode, connTaskQueue); while (h != &conn->taskQueue) { if (task->seqNum == seqNum) { if (found == false) { found = true; taskFound = task; } else { fnError("udfc more than one task waiting for the same response"); continue; } } h = QUEUE_NEXT(h); task = QUEUE_DATA(h, SClientUvTaskNode, connTaskQueue); } if (taskFound) { taskFound->rspBuf = uv_buf_init(connBuf->buf, connBuf->len); QUEUE_REMOVE(&taskFound->connTaskQueue); QUEUE_REMOVE(&taskFound->procTaskQueue); uv_sem_post(&taskFound->taskSem); } else { fnError("no task is waiting for the response."); } connBuf->buf = NULL; connBuf->total = -1; connBuf->len = 0; connBuf->cap = 0; } void udfcUvHandleError(SClientUvConn *conn) { while (!QUEUE_EMPTY(&conn->taskQueue)) { QUEUE* h = QUEUE_HEAD(&conn->taskQueue); SClientUvTaskNode *task = QUEUE_DATA(h, SClientUvTaskNode, connTaskQueue); task->errCode = UDFC_CODE_PIPE_READ_ERR; QUEUE_REMOVE(&task->connTaskQueue); QUEUE_REMOVE(&task->procTaskQueue); uv_sem_post(&task->taskSem); } uv_close((uv_handle_t *) conn->pipe, onUdfcPipeClose); } void onUdfcRead(uv_stream_t *client, ssize_t nread, const uv_buf_t *buf) { fnTrace("udfc client %p, client read from pipe. nread: %zd", client, nread); if (nread == 0) return; SClientUvConn *conn = client->data; SClientConnBuf *connBuf = &conn->readBuf; if (nread > 0) { connBuf->len += nread; if (isUdfcUvMsgComplete(connBuf)) { udfcUvHandleRsp(conn); } } if (nread < 0) { fnError("udfc client pipe %p read error: %zd, %s.", client, nread, uv_strerror(nread)); if (nread == UV_EOF) { fnError("\tudfc client pipe %p closed", client); } udfcUvHandleError(conn); } } void onUdfClientWrite(uv_write_t *write, int status) { SClientUvTaskNode *uvTask = write->data; uv_pipe_t *pipe = uvTask->pipe; if (status == 0) { SClientUvConn *conn = pipe->data; QUEUE_INSERT_TAIL(&conn->taskQueue, &uvTask->connTaskQueue); } else { fnError("udfc client %p write error.", pipe); } fnTrace("udfc client %p write length:%zu", pipe, uvTask->reqBuf.len); taosMemoryFree(write); taosMemoryFree(uvTask->reqBuf.base); } void onUdfClientConnect(uv_connect_t *connect, int status) { SClientUvTaskNode *uvTask = connect->data; uvTask->errCode = status; if (status != 0) { //TODO: LOG error } uv_read_start((uv_stream_t *) uvTask->pipe, udfcAllocateBuffer, onUdfcRead); taosMemoryFree(connect); uv_sem_post(&uvTask->taskSem); QUEUE_REMOVE(&uvTask->procTaskQueue); } int32_t udfcCreateUvTask(SClientUdfTask *task, int8_t uvTaskType, SClientUvTaskNode **pUvTask) { SClientUvTaskNode *uvTask = taosMemoryCalloc(1, sizeof(SClientUvTaskNode)); uvTask->type = uvTaskType; uvTask->udfc = task->session->udfc; if (uvTaskType == UV_TASK_CONNECT) { } else if (uvTaskType == UV_TASK_REQ_RSP) { uvTask->pipe = task->session->udfUvPipe; SUdfRequest request; request.type = task->type; request.seqNum = atomic_fetch_add_64(&gUdfTaskSeqNum, 1); if (task->type == UDF_TASK_SETUP) { request.setup = task->_setup.req; request.type = UDF_TASK_SETUP; } else if (task->type == UDF_TASK_CALL) { request.call = task->_call.req; request.type = UDF_TASK_CALL; } else if (task->type == UDF_TASK_TEARDOWN) { request.teardown = task->_teardown.req; request.type = UDF_TASK_TEARDOWN; } else { //TODO log and return error } int32_t bufLen = encodeUdfRequest(NULL, &request); request.msgLen = bufLen; void *bufBegin = taosMemoryMalloc(bufLen); void *buf = bufBegin; encodeUdfRequest(&buf, &request); uvTask->reqBuf = uv_buf_init(bufBegin, bufLen); uvTask->seqNum = request.seqNum; } else if (uvTaskType == UV_TASK_DISCONNECT) { uvTask->pipe = task->session->udfUvPipe; } uv_sem_init(&uvTask->taskSem, 0); *pUvTask = uvTask; return 0; } int32_t udfcQueueUvTask(SClientUvTaskNode *uvTask) { fnTrace("queue uv task to event loop, task: %d, %p", uvTask->type, uvTask); SUdfdProxy *udfc = uvTask->udfc; uv_mutex_lock(&udfc->gUdfTaskQueueMutex); QUEUE_INSERT_TAIL(&udfc->gUdfTaskQueue, &uvTask->recvTaskQueue); uv_mutex_unlock(&udfc->gUdfTaskQueueMutex); uv_async_send(&udfc->gUdfLoopTaskAync); uv_sem_wait(&uvTask->taskSem); fnInfo("udfc uv task finished. task: %d, %p", uvTask->type, uvTask); uv_sem_destroy(&uvTask->taskSem); return 0; } int32_t udfcStartUvTask(SClientUvTaskNode *uvTask) { fnTrace("event loop start uv task. task: %d, %p", uvTask->type, uvTask); switch (uvTask->type) { case UV_TASK_CONNECT: { uv_pipe_t *pipe = taosMemoryMalloc(sizeof(uv_pipe_t)); uv_pipe_init(&uvTask->udfc->gUdfdLoop, pipe, 0); uvTask->pipe = pipe; SClientUvConn *conn = taosMemoryCalloc(1, sizeof(SClientUvConn)); conn->pipe = pipe; conn->readBuf.len = 0; conn->readBuf.cap = 0; conn->readBuf.buf = 0; conn->readBuf.total = -1; QUEUE_INIT(&conn->taskQueue); pipe->data = conn; uv_connect_t *connReq = taosMemoryMalloc(sizeof(uv_connect_t)); connReq->data = uvTask; uv_pipe_connect(connReq, pipe, uvTask->udfc->udfdPipeName, onUdfClientConnect); break; } case UV_TASK_REQ_RSP: { uv_pipe_t *pipe = uvTask->pipe; uv_write_t *write = taosMemoryMalloc(sizeof(uv_write_t)); write->data = uvTask; uv_write(write, (uv_stream_t *) pipe, &uvTask->reqBuf, 1, onUdfClientWrite); break; } case UV_TASK_DISCONNECT: { SClientUvConn *conn = uvTask->pipe->data; QUEUE_INSERT_TAIL(&conn->taskQueue, &uvTask->connTaskQueue); uv_close((uv_handle_t *) uvTask->pipe, onUdfcPipeClose); break; } default: { break; } } return 0; } void udfClientAsyncCb(uv_async_t *async) { SUdfdProxy *udfc = async->data; QUEUE wq; uv_mutex_lock(&udfc->gUdfTaskQueueMutex); QUEUE_MOVE(&udfc->gUdfTaskQueue, &wq); uv_mutex_unlock(&udfc->gUdfTaskQueueMutex); while (!QUEUE_EMPTY(&wq)) { QUEUE* h = QUEUE_HEAD(&wq); QUEUE_REMOVE(h); SClientUvTaskNode *task = QUEUE_DATA(h, SClientUvTaskNode, recvTaskQueue); udfcStartUvTask(task); QUEUE_INSERT_TAIL(&udfc->gUvProcTaskQueue, &task->procTaskQueue); } } void cleanUpUvTasks(SUdfdProxy *udfc) { fnDebug("clean up uv tasks") QUEUE wq; uv_mutex_lock(&udfc->gUdfTaskQueueMutex); QUEUE_MOVE(&udfc->gUdfTaskQueue, &wq); uv_mutex_unlock(&udfc->gUdfTaskQueueMutex); while (!QUEUE_EMPTY(&wq)) { QUEUE* h = QUEUE_HEAD(&wq); QUEUE_REMOVE(h); SClientUvTaskNode *task = QUEUE_DATA(h, SClientUvTaskNode, recvTaskQueue); if (udfc->gUdfcState == UDFC_STATE_STOPPING) { task->errCode = UDFC_CODE_STOPPING; } uv_sem_post(&task->taskSem); } while (!QUEUE_EMPTY(&udfc->gUvProcTaskQueue)) { QUEUE* h = QUEUE_HEAD(&udfc->gUvProcTaskQueue); QUEUE_REMOVE(h); SClientUvTaskNode *task = QUEUE_DATA(h, SClientUvTaskNode, procTaskQueue); if (udfc->gUdfcState == UDFC_STATE_STOPPING) { task->errCode = UDFC_CODE_STOPPING; } uv_sem_post(&task->taskSem); } } void udfStopAsyncCb(uv_async_t *async) { SUdfdProxy *udfc = async->data; cleanUpUvTasks(udfc); if (udfc->gUdfcState == UDFC_STATE_STOPPING) { uv_stop(&udfc->gUdfdLoop); } } void constructUdfService(void *argsThread) { SUdfdProxy *udfc = (SUdfdProxy*)argsThread; uv_loop_init(&udfc->gUdfdLoop); uv_async_init(&udfc->gUdfdLoop, &udfc->gUdfLoopTaskAync, udfClientAsyncCb); udfc->gUdfLoopTaskAync.data = udfc; uv_async_init(&udfc->gUdfdLoop, &udfc->gUdfLoopStopAsync, udfStopAsyncCb); udfc->gUdfLoopStopAsync.data = udfc; uv_mutex_init(&udfc->gUdfTaskQueueMutex); QUEUE_INIT(&udfc->gUdfTaskQueue); QUEUE_INIT(&udfc->gUvProcTaskQueue); uv_barrier_wait(&udfc->gUdfInitBarrier); //TODO return value of uv_run uv_run(&udfc->gUdfdLoop, UV_RUN_DEFAULT); uv_loop_close(&udfc->gUdfdLoop); } int32_t udfcOpen() { int8_t old = atomic_val_compare_exchange_8(&gUdfdProxy.initialized, 0, 1); if (old == 1) { return 0; } SUdfdProxy *proxy = &gUdfdProxy; getUdfdPipeName(proxy->udfdPipeName, sizeof(proxy->udfdPipeName)); proxy->gUdfcState = UDFC_STATE_STARTNG; uv_barrier_init(&proxy->gUdfInitBarrier, 2); uv_thread_create(&proxy->gUdfLoopThread, constructUdfService, proxy); atomic_store_8(&proxy->gUdfcState, UDFC_STATE_READY); proxy->gUdfcState = UDFC_STATE_READY; uv_barrier_wait(&proxy->gUdfInitBarrier); fnInfo("udfc initialized") return 0; } int32_t udfcClose() { int8_t old = atomic_val_compare_exchange_8(&gUdfdProxy.initialized, 1, 0); if (old == 0) { return 0; } SUdfdProxy *udfc = &gUdfdProxy; udfc->gUdfcState = UDFC_STATE_STOPPING; uv_async_send(&udfc->gUdfLoopStopAsync); uv_thread_join(&udfc->gUdfLoopThread); uv_mutex_destroy(&udfc->gUdfTaskQueueMutex); uv_barrier_destroy(&udfc->gUdfInitBarrier); udfc->gUdfcState = UDFC_STATE_INITAL; fnInfo("udfc cleaned up"); return 0; } int32_t udfcRunUdfUvTask(SClientUdfTask *task, int8_t uvTaskType) { SClientUvTaskNode *uvTask = NULL; udfcCreateUvTask(task, uvTaskType, &uvTask); udfcQueueUvTask(uvTask); udfcGetUdfTaskResultFromUvTask(task, uvTask); if (uvTaskType == UV_TASK_CONNECT) { task->session->udfUvPipe = uvTask->pipe; SClientUvConn *conn = uvTask->pipe->data; conn->session = task->session; } taosMemoryFree(uvTask); uvTask = NULL; return task->errCode; } int32_t setupUdf(char udfName[], UdfcFuncHandle *funcHandle) { fnInfo("udfc setup udf. udfName: %s", udfName); if (gUdfdProxy.gUdfcState != UDFC_STATE_READY) { return UDFC_CODE_INVALID_STATE; } SClientUdfTask *task = taosMemoryCalloc(1,sizeof(SClientUdfTask)); task->errCode = 0; task->session = taosMemoryCalloc(1, sizeof(SClientUdfUvSession)); task->session->udfc = &gUdfdProxy; task->type = UDF_TASK_SETUP; SUdfSetupRequest *req = &task->_setup.req; memcpy(req->udfName, udfName, TSDB_FUNC_NAME_LEN); int32_t errCode = udfcRunUdfUvTask(task, UV_TASK_CONNECT); if (errCode != 0) { fnError("failed to connect to pipe. udfName: %s, pipe: %s", udfName, (&gUdfdProxy)->udfdPipeName); return UDFC_CODE_CONNECT_PIPE_ERR; } udfcRunUdfUvTask(task, UV_TASK_REQ_RSP); SUdfSetupResponse *rsp = &task->_setup.rsp; task->session->severHandle = rsp->udfHandle; task->session->outputType = rsp->outputType; task->session->outputLen = rsp->outputLen; task->session->bufSize = rsp->bufSize; if (task->errCode != 0) { fnError("failed to setup udf. err: %d", task->errCode) } else { fnInfo("sucessfully setup udf func handle. handle: %p", task->session); *funcHandle = task->session; } int32_t err = task->errCode; taosMemoryFree(task); return err; } int32_t callUdf(UdfcFuncHandle handle, int8_t callType, SSDataBlock *input, SUdfInterBuf *state, SUdfInterBuf *state2, SSDataBlock* output, SUdfInterBuf *newState) { fnTrace("udfc call udf. callType: %d, funcHandle: %p", callType, handle); SClientUdfUvSession *session = (SClientUdfUvSession *) handle; if (session->udfUvPipe == NULL) { fnError("No pipe to udfd"); return UDFC_CODE_NO_PIPE; } SClientUdfTask *task = taosMemoryCalloc(1, sizeof(SClientUdfTask)); task->errCode = 0; task->session = (SClientUdfUvSession *) handle; task->type = UDF_TASK_CALL; SUdfCallRequest *req = &task->_call.req; req->udfHandle = task->session->severHandle; req->callType = callType; switch (callType) { case TSDB_UDF_CALL_AGG_INIT: { req->initFirst = 1; break; } case TSDB_UDF_CALL_AGG_PROC: { req->block = *input; req->interBuf = *state; break; } case TSDB_UDF_CALL_AGG_MERGE: { req->interBuf = *state; req->interBuf2 = *state2; break; } case TSDB_UDF_CALL_AGG_FIN: { req->interBuf = *state; break; } case TSDB_UDF_CALL_SCALA_PROC: { req->block = *input; break; } } udfcRunUdfUvTask(task, UV_TASK_REQ_RSP); if (task->errCode != 0) { fnError("call udf failure. err: %d", task->errCode); } else { SUdfCallResponse *rsp = &task->_call.rsp; switch (callType) { case TSDB_UDF_CALL_AGG_INIT: { *newState = rsp->resultBuf; break; } case TSDB_UDF_CALL_AGG_PROC: { *newState = rsp->resultBuf; break; } case TSDB_UDF_CALL_AGG_MERGE: { *newState = rsp->resultBuf; break; } case TSDB_UDF_CALL_AGG_FIN: { *newState = rsp->resultBuf; break; } case TSDB_UDF_CALL_SCALA_PROC: { *output = rsp->resultData; break; } } }; int err = task->errCode; taosMemoryFree(task); return err; } int32_t callUdfAggInit(UdfcFuncHandle handle, SUdfInterBuf *interBuf) { int8_t callType = TSDB_UDF_CALL_AGG_INIT; int32_t err = callUdf(handle, callType, NULL, NULL, NULL, NULL, interBuf); return err; } // input: block, state // output: interbuf, int32_t callUdfAggProcess(UdfcFuncHandle handle, SSDataBlock *block, SUdfInterBuf *state, SUdfInterBuf *newState) { int8_t callType = TSDB_UDF_CALL_AGG_PROC; int32_t err = callUdf(handle, callType, block, state, NULL, NULL, newState); return err; } // input: interbuf1, interbuf2 // output: resultBuf int32_t callUdfAggMerge(UdfcFuncHandle handle, SUdfInterBuf *interBuf1, SUdfInterBuf *interBuf2, SUdfInterBuf *resultBuf) { int8_t callType = TSDB_UDF_CALL_AGG_MERGE; int32_t err = callUdf(handle, callType, NULL, interBuf1, interBuf2, NULL, resultBuf); return err; } // input: interBuf // output: resultData int32_t callUdfAggFinalize(UdfcFuncHandle handle, SUdfInterBuf *interBuf, SUdfInterBuf *resultData) { int8_t callType = TSDB_UDF_CALL_AGG_FIN; int32_t err = callUdf(handle, callType, NULL, interBuf, NULL, NULL, resultData); return err; } int32_t callUdfScalarFunc(UdfcFuncHandle handle, SScalarParam *input, int32_t numOfCols, SScalarParam* output) { int8_t callType = TSDB_UDF_CALL_SCALA_PROC; SSDataBlock inputBlock = {0}; convertScalarParamToDataBlock(input, numOfCols, &inputBlock); SSDataBlock resultBlock = {0}; int32_t err = callUdf(handle, callType, &inputBlock, NULL, NULL, &resultBlock, NULL); if (err == 0) { convertDataBlockToScalarParm(&resultBlock, output); } return err; } int32_t teardownUdf(UdfcFuncHandle handle) { fnInfo("tear down udf. udf func handle: %p", handle); SClientUdfUvSession *session = (SClientUdfUvSession *) handle; if (session->udfUvPipe == NULL) { fnError("pipe to udfd does not exist"); return UDFC_CODE_NO_PIPE; } SClientUdfTask *task = taosMemoryCalloc(1, sizeof(SClientUdfTask)); task->errCode = 0; task->session = session; task->type = UDF_TASK_TEARDOWN; SUdfTeardownRequest *req = &task->_teardown.req; req->udfHandle = task->session->severHandle; udfcRunUdfUvTask(task, UV_TASK_REQ_RSP); SUdfTeardownResponse *rsp = &task->_teardown.rsp; int32_t err = task->errCode; udfcRunUdfUvTask(task, UV_TASK_DISCONNECT); taosMemoryFree(task->session); taosMemoryFree(task); return err; } //memory layout |---SUdfAggRes----|-----final result-----|---inter result----| typedef struct SUdfAggRes { SClientUdfUvSession *session; int8_t finalResNum; int8_t interResNum; char* finalResBuf; char* interResBuf; } SUdfAggRes; bool udfAggGetEnv(struct SFunctionNode* pFunc, SFuncExecEnv* pEnv) { if (fmIsScalarFunc(pFunc->funcId)) { return false; } pEnv->calcMemSize = sizeof(SUdfAggRes) + pFunc->node.resType.bytes + pFunc->udfBufSize; return true; } bool udfAggInit(struct SqlFunctionCtx *pCtx, struct SResultRowEntryInfo* pResultCellInfo) { if (functionSetup(pCtx, pResultCellInfo) != true) { return false; } UdfcFuncHandle handle; int32_t udfCode = 0; if ((udfCode = setupUdf((char*)pCtx->udfName, &handle)) != 0) { fnError("udfAggInit error. step setupUdf. udf code: %d", udfCode); return false; } SClientUdfUvSession *session = (SClientUdfUvSession *)handle; SUdfAggRes *udfRes = (SUdfAggRes*)GET_ROWCELL_INTERBUF(pResultCellInfo); int32_t envSize = sizeof(SUdfAggRes) + session->outputLen + session->bufSize; memset(udfRes, 0, envSize); udfRes->finalResBuf = (char*)udfRes + sizeof(SUdfAggRes); udfRes->interResBuf = (char*)udfRes + sizeof(SUdfAggRes) + session->outputLen; udfRes->session = (SClientUdfUvSession *)handle; SUdfInterBuf buf = {0}; if ((udfCode = callUdfAggInit(handle, &buf)) != 0) { fnError("udfAggInit error. step callUdfAggInit. udf code: %d", udfCode); return false; } udfRes->interResNum = buf.numOfResult; memcpy(udfRes->interResBuf, buf.buf, buf.bufLen); return true; } int32_t udfAggProcess(struct SqlFunctionCtx *pCtx) { SInputColumnInfoData* pInput = &pCtx->input; int32_t numOfCols = pInput->numOfInputCols; SUdfAggRes* udfRes = (SUdfAggRes *)GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); SClientUdfUvSession *session = udfRes->session; udfRes->finalResBuf = (char*)udfRes + sizeof(SUdfAggRes); udfRes->interResBuf = (char*)udfRes + sizeof(SUdfAggRes) + session->outputLen; int32_t start = pInput->startRowIndex; int32_t numOfRows = pInput->numOfRows; SSDataBlock tempBlock = {0}; tempBlock.info.numOfCols = numOfCols; tempBlock.info.rows = numOfRows; tempBlock.info.uid = pInput->uid; bool hasVarCol = false; tempBlock.pDataBlock = taosArrayInit(numOfCols, sizeof(SColumnInfoData)); for (int32_t i = 0; i < numOfCols; ++i) { SColumnInfoData *col = pInput->pData[i]; if (IS_VAR_DATA_TYPE(col->info.type)) { hasVarCol = true; } taosArrayPush(tempBlock.pDataBlock, col); } tempBlock.info.hasVarCol = hasVarCol; SSDataBlock *inputBlock = blockDataExtractBlock(&tempBlock, start, numOfRows); SUdfInterBuf state = {.buf = udfRes->interResBuf, .bufLen = session->bufSize, .numOfResult = udfRes->interResNum}; SUdfInterBuf newState = {0}; int32_t udfCode = callUdfAggProcess(session, inputBlock, &state, &newState); if (udfCode != 0) { fnError("udfAggProcess error. code: %d", udfCode); newState.numOfResult = 0; } else { udfRes->interResNum = newState.numOfResult; memcpy(udfRes->interResBuf, newState.buf, newState.bufLen); } if (newState.numOfResult == 1 || state.numOfResult == 1) { GET_RES_INFO(pCtx)->numOfRes = 1; } blockDataDestroy(inputBlock); taosArrayDestroy(tempBlock.pDataBlock); taosMemoryFree(newState.buf); return TSDB_CODE_SUCCESS; } int32_t udfAggFinalize(struct SqlFunctionCtx *pCtx, SSDataBlock* pBlock) { SUdfAggRes* udfRes = (SUdfAggRes *)GET_ROWCELL_INTERBUF(GET_RES_INFO(pCtx)); SClientUdfUvSession *session = udfRes->session; udfRes->finalResBuf = (char*)udfRes + sizeof(SUdfAggRes); udfRes->interResBuf = (char*)udfRes + sizeof(SUdfAggRes) + session->outputLen; SUdfInterBuf resultBuf = {0}; SUdfInterBuf state = {.buf = udfRes->interResBuf, .bufLen = session->bufSize, .numOfResult = udfRes->interResNum}; int32_t udfCallCode= 0; udfCallCode= callUdfAggFinalize(session, &state, &resultBuf); if (udfCallCode!= 0) { fnError("udfAggFinalize error. callUdfAggFinalize step. udf code:%d", udfCallCode); GET_RES_INFO(pCtx)->numOfRes = 0; } else { memcpy(udfRes->finalResBuf, resultBuf.buf, session->outputLen); udfRes->finalResNum = resultBuf.numOfResult; GET_RES_INFO(pCtx)->numOfRes = udfRes->finalResNum; } int32_t code = teardownUdf(session); if (code != 0) { fnError("udfAggFinalize error. teardownUdf step. udf code: %d", code); } return functionFinalizeWithResultBuf(pCtx, pBlock, udfRes->finalResBuf); }