TDengine/source/libs/function/src/tudf.c
2022-03-26 00:29:53 +08:00

925 lines
24 KiB
C

/*
* Copyright (c) 2019 TAOS Data, Inc. <jhtao@taosdata.com>
*
* 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 <http://www.gnu.org/licenses/>.
*/
#include "uv.h"
#include "os.h"
#include "tlog.h"
#include "tudf.h"
#include "tudfInt.h"
//TODO: when startup, set thread poll size. add it to cfg
//TODO: udfd restart when exist or aborts
//TODO: network error processing.
//TODO: add unit test
//TODO: add lua support
void onUdfcRead(uv_stream_t *client, ssize_t nread, const uv_buf_t *buf);
enum {
UV_TASK_CONNECT = 0,
UV_TASK_REQ_RSP = 1,
UV_TASK_DISCONNECT = 2
};
typedef struct SUdfUvSession {
int64_t severHandle;
uv_pipe_t *udfSvcPipe;
} SUdfUvSession;
typedef struct SClientUvTaskNode {
int8_t type;
int errCode;
uv_pipe_t *pipe;
int64_t seqNum;
uv_buf_t reqBuf;
uv_sem_t taskSem;
uv_buf_t rspBuf;
struct SClientUvTaskNode *prev;
struct SClientUvTaskNode *next;
} SClientUvTaskNode;
typedef struct SClientUdfTask {
int8_t type;
SUdfUvSession *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;
SClientUvTaskNode taskQueue;
SClientConnBuf readBuf;
} SClientUvConn;
uv_process_t gUdfdProcess;
uv_barrier_t gUdfInitBarrier;
uv_loop_t gUdfdLoop;
uv_thread_t gUdfLoopThread;
uv_async_t gUdfLoopTaskAync;
uv_async_t gUdfLoopStopAsync;
uv_mutex_t gUdfTaskQueueMutex;
int64_t gUdfTaskSeqNum = 0;
//double circular linked list
typedef SClientUvTaskNode *SClientUvTaskQueue;
SClientUvTaskNode gUdfQueueNode;
SClientUvTaskQueue gUdfTaskQueue = &gUdfQueueNode;
//add SClientUvTaskNode task that close conn
void udfTaskQueueInit(SClientUvTaskQueue q) {
q->next = q;
q->prev = q;
}
bool udfTaskQueueIsEmpty(SClientUvTaskQueue q) {
return q == q->next;
}
void udfTaskQueueInsertTail(SClientUvTaskQueue q, SClientUvTaskNode *e) {
e->next = q;
e->prev = q->prev;
e->prev->next = e;
q->prev = e;
}
void udfTaskQueueInsertTaskAtHead(SClientUvTaskQueue q, SClientUvTaskNode *e) {
e->next = q->next;
e->prev = q;
q->next->prev = e;
q->next = e;
}
void udfTaskQueueRemoveTask(SClientUvTaskNode *e) {
e->prev->next = e->next;
e->next->prev = e->prev;
}
void udfTaskQueueSplit(SClientUvTaskQueue q, SClientUvTaskNode *from, SClientUvTaskQueue n) {
n->prev = q->prev;
n->prev->next = n;
n->next = from;
q->prev = from->prev;
q->prev->next = q;
from->prev = n;
}
SClientUvTaskNode *udfTaskQueueHeadTask(SClientUvTaskQueue q) {
return q->next;
}
SClientUvTaskNode *udfTaskQueueTailTask(SClientUvTaskQueue q) {
return q->prev;
}
SClientUvTaskNode *udfTaskQueueNext(SClientUvTaskNode *e) {
return e->next;
}
void udfTaskQueueMove(SClientUvTaskQueue q, SClientUvTaskQueue n) {
if (udfTaskQueueIsEmpty(q)) {
udfTaskQueueInit(n);
} else {
SClientUvTaskNode *h = udfTaskQueueHeadTask(q);
udfTaskQueueSplit(q, h, n);
}
}
int32_t encodeRequest(char **pBuf, int32_t *pBufLen, SUdfRequest *request) {
debugPrint("%s", "encoding request");
int len = sizeof(SUdfRequest) - sizeof(void *);
switch (request->type) {
case UDF_TASK_SETUP: {
SUdfSetupRequest *setup = (SUdfSetupRequest *) (request->subReq);
len += sizeof(SUdfSetupRequest) - 1 * sizeof(char *) + setup->pathSize;
break;
}
case UDF_TASK_CALL: {
SUdfCallRequest *call = (SUdfCallRequest *) (request->subReq);
len += sizeof(SUdfCallRequest) - 2 * sizeof(char *) + call->inputBytes + call->stateBytes;
break;
}
case UDF_TASK_TEARDOWN: {
SUdfTeardownRequest *teardown = (SUdfTeardownRequest *) (request->subReq);
len += sizeof(SUdfTeardownRequest);
break;
}
default:
break;
}
char *bufBegin = taosMemoryMalloc(len);
char *buf = bufBegin;
//skip msgLen first
buf += sizeof(int32_t);
*(int64_t *) buf = request->seqNum;
buf += sizeof(int64_t);
*(int8_t *) buf = request->type;
buf += sizeof(int8_t);
switch (request->type) {
case UDF_TASK_SETUP: {
SUdfSetupRequest *setup = (SUdfSetupRequest *) (request->subReq);
memcpy(buf, setup->udfName, 16);
buf += 16;
*(int8_t *) buf = setup->scriptType;
buf += sizeof(int8_t);
*(int8_t *) buf = setup->udfType;
buf += sizeof(int8_t);
*(int16_t *) buf = setup->pathSize;
buf += sizeof(int16_t);
memcpy(buf, setup->path, setup->pathSize);
buf += setup->pathSize;
break;
}
case UDF_TASK_CALL: {
SUdfCallRequest *call = (SUdfCallRequest *) (request->subReq);
*(int64_t *) buf = call->udfHandle;
buf += sizeof(int64_t);
*(int8_t *) buf = call->step;
buf += sizeof(int8_t);
*(int32_t *) buf = call->inputBytes;
buf += sizeof(int32_t);
memcpy(buf, call->input, call->inputBytes);
buf += call->inputBytes;
*(int32_t *) buf = call->stateBytes;
buf += sizeof(int32_t);
memcpy(buf, call->state, call->stateBytes);
buf += call->stateBytes;
break;
}
case UDF_TASK_TEARDOWN: {
SUdfTeardownRequest *teardown = (SUdfTeardownRequest *) (request->subReq);
*(int64_t *) buf = teardown->udfHandle;
buf += sizeof(int64_t);
break;
}
default:
break;
}
request->msgLen = buf - bufBegin;
*(int32_t *) bufBegin = request->msgLen;
*pBuf = bufBegin;
*pBufLen = request->msgLen;
return 0;
}
int32_t decodeRequest(char *bufMsg, int32_t bufLen, SUdfRequest **pRequest) {
debugPrint("%s", "decoding request");
if (*(int32_t *) bufMsg != bufLen) {
debugPrint("%s", "decoding request error");
return -1;
}
char *buf = bufMsg;
SUdfRequest *request = taosMemoryMalloc(sizeof(SUdfRequest));
request->subReq = NULL;
request->msgLen = *(int32_t *) (buf);
buf += sizeof(int32_t);
request->seqNum = *(int64_t *) (buf);
buf += sizeof(int64_t);
request->type = *(int8_t *) (buf);
buf += sizeof(int8_t);
switch (request->type) {
case UDF_TASK_SETUP: {
SUdfSetupRequest *setup = taosMemoryMalloc(sizeof(SUdfSetupRequest));
memcpy(setup->udfName, buf, 16);
buf += 16;
setup->scriptType = *(int8_t *) buf;
buf += sizeof(int8_t);
setup->udfType = *(int8_t *) buf;
buf += sizeof(int8_t);
setup->pathSize = *(int16_t *) buf;
buf += sizeof(int16_t);
setup->path = buf;
buf += setup->pathSize;
request->subReq = setup;
break;
}
case UDF_TASK_CALL: {
SUdfCallRequest *call = taosMemoryMalloc(sizeof(SUdfCallRequest));
call->udfHandle = *(int64_t *) buf;
buf += sizeof(int64_t);
call->step = *(int8_t *) buf;
buf += sizeof(int8_t);
call->inputBytes = *(int32_t *) buf;
buf += sizeof(int32_t);
call->input = buf;
buf += call->inputBytes;
call->stateBytes = *(int32_t *) buf;
buf += sizeof(int32_t);
call->state = buf;
buf += call->stateBytes;
request->subReq = call;
break;
}
case UDF_TASK_TEARDOWN: {
SUdfTeardownRequest *teardown = taosMemoryMalloc(sizeof(SUdfTeardownRequest));
teardown->udfHandle = *(int64_t *) buf;
buf += sizeof(int64_t);
request->subReq = teardown;
}
}
if (buf - bufMsg != bufLen) {
debugPrint("%s", "decode request error");
taosMemoryFree(request->subReq);
taosMemoryFree(request);
return -1;
}
*pRequest = request;
return 0;
}
int32_t encodeResponse(char **pBuf, int32_t *pBufLen, SUdfResponse *response) {
debugPrint("%s", "encoding response");
int32_t len = sizeof(SUdfResponse) - sizeof(void *);
switch (response->type) {
case UDF_TASK_SETUP: {
len += sizeof(SUdfSetupResponse);
break;
}
case UDF_TASK_CALL: {
SUdfCallResponse *callResp = (SUdfCallResponse *) (response->subRsp);
len += sizeof(SUdfCallResponse) - 2 * sizeof(char *) +
callResp->outputBytes + callResp->newStateBytes;
break;
}
case UDF_TASK_TEARDOWN: {
len += sizeof(SUdfTeardownResponse);
break;
}
}
char *bufBegin = taosMemoryMalloc(len);
char *buf = bufBegin;
//skip msgLen
buf += sizeof(int32_t);
*(int64_t *) buf = response->seqNum;
buf += sizeof(int64_t);
*(int8_t *) buf = response->type;
buf += sizeof(int8_t);
*(int32_t *) buf = response->code;
buf += sizeof(int32_t);
switch (response->type) {
case UDF_TASK_SETUP: {
SUdfSetupResponse *setupResp = (SUdfSetupResponse *) (response->subRsp);
*(int64_t *) buf = setupResp->udfHandle;
buf += sizeof(int64_t);
break;
}
case UDF_TASK_CALL: {
SUdfCallResponse *callResp = (SUdfCallResponse *) (response->subRsp);
*(int32_t *) buf = callResp->outputBytes;
buf += sizeof(int32_t);
memcpy(buf, callResp->output, callResp->outputBytes);
buf += callResp->outputBytes;
*(int32_t *) buf = callResp->newStateBytes;
buf += sizeof(int32_t);
memcpy(buf, callResp->newState, callResp->newStateBytes);
buf += callResp->newStateBytes;
break;
}
case UDF_TASK_TEARDOWN: {
SUdfTeardownResponse *teardownResp = (SUdfTeardownResponse *) (response->subRsp);
break;
}
default:
break;
}
response->msgLen = buf - bufBegin;
*(int32_t *) bufBegin = response->msgLen;
*pBuf = bufBegin;
*pBufLen = response->msgLen;
return 0;
}
int32_t decodeResponse(char *bufMsg, int32_t bufLen, SUdfResponse **pResponse) {
debugPrint("%s", "decoding response");
if (*(int32_t *) bufMsg != bufLen) {
debugPrint("%s", "can not decode response");
return -1;
}
char *buf = bufMsg;
SUdfResponse *rsp = taosMemoryMalloc(sizeof(SUdfResponse));
rsp->msgLen = *(int32_t *) buf;
buf += sizeof(int32_t);
rsp->seqNum = *(int64_t *) buf;
buf += sizeof(int64_t);
rsp->type = *(int8_t *) buf;
buf += sizeof(int8_t);
rsp->code = *(int32_t *) buf;
buf += sizeof(int32_t);
switch (rsp->type) {
case UDF_TASK_SETUP: {
SUdfSetupResponse *setupRsp = (SUdfSetupResponse *) taosMemoryMalloc(sizeof(SUdfSetupResponse));
setupRsp->udfHandle = *(int64_t *) buf;
buf += sizeof(int64_t);
rsp->subRsp = (char *) setupRsp;
break;
}
case UDF_TASK_CALL: {
SUdfCallResponse *callRsp = (SUdfCallResponse *) taosMemoryMalloc(sizeof(SUdfCallResponse));
callRsp->outputBytes = *(int32_t *) buf;
buf += sizeof(int32_t);
callRsp->output = buf;
buf += callRsp->outputBytes;
callRsp->newStateBytes = *(int32_t *) buf;
buf += sizeof(int32_t);
callRsp->newState = buf;
buf += callRsp->newStateBytes;
rsp->subRsp = callRsp;
break;
}
case UDF_TASK_TEARDOWN: {
SUdfTeardownResponse *teardownRsp = (SUdfTeardownResponse *) taosMemoryMalloc(sizeof(SUdfTeardownResponse));
rsp->subRsp = teardownRsp;
break;
}
default:
break;
}
if (buf - bufMsg != bufLen) {
debugPrint("%s", "can not decode response");
taosMemoryFree(rsp->subRsp);
taosMemoryFree(rsp);
return -1;
}
*pResponse = rsp;
return 0;
}
void onUdfdExit(uv_process_t *req, int64_t exit_status, int term_signal) {
debugPrint("Process exited with status %" PRId64 ", signal %d", exit_status, term_signal);
uv_close((uv_handle_t *) req, NULL);
//TODO: restart the udfd process
}
void onUdfcPipeClose(uv_handle_t *handle) {
SClientUvConn *conn = handle->data;
if (!udfTaskQueueIsEmpty(&conn->taskQueue)) {
SClientUvTaskNode *task = udfTaskQueueHeadTask(&conn->taskQueue);
task->errCode = 0;
uv_sem_post(&task->taskSem);
}
taosMemoryFree(conn->readBuf.buf);
taosMemoryFree(conn);
taosMemoryFree((uv_pipe_t *) handle);
}
int32_t udfcGetUvTaskResponseResult(SClientUdfTask *task, SClientUvTaskNode *uvTask) {
debugPrint("%s", "get uv task result");
if (uvTask->type == UV_TASK_REQ_RSP) {
if (uvTask->rspBuf.base != NULL) {
SUdfResponse *rsp;
decodeResponse(uvTask->rspBuf.base, uvTask->rspBuf.len, &rsp);
task->errCode = rsp->code;
switch (task->type) {
case UDF_TASK_SETUP: {
//TODO: copy or not
task->_setup.rsp = *(SUdfSetupResponse *) (rsp->subRsp);
break;
}
case UDF_TASK_CALL: {
task->_call.rsp = *(SUdfCallResponse *) (rsp->subRsp);
//TODO: copy or not
break;
}
case UDF_TASK_TEARDOWN: {
task->_teardown.rsp = *(SUdfTeardownResponse *) (rsp->subRsp);
//TODO: copy or not?
break;
}
default: {
break;
}
}
// TODO: the call buffer is setup and freed by udf invocation
taosMemoryFree(uvTask->rspBuf.base);
taosMemoryFree(rsp->subRsp);
taosMemoryFree(rsp);
} 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) {
debugPrint("%s", "client allocate buffer to receive from pipe");
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 {
//TODO: log error
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 {
//TODO: log error free connBuf->buf
buf->base = NULL;
buf->len = 0;
}
}
debugPrint("\tconn 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) {
return true;
}
return false;
}
void udfcUvHandleRsp(SClientUvConn *conn) {
SClientConnBuf *connBuf = &conn->readBuf;
int64_t seqNum = *(int64_t *) (connBuf->buf + sizeof(int32_t)); // msglen int32_t then seqnum
if (udfTaskQueueIsEmpty(&conn->taskQueue)) {
//LOG error
return;
}
bool found = false;
SClientUvTaskNode *taskFound = NULL;
SClientUvTaskNode *task = udfTaskQueueNext(&conn->taskQueue);
while (task != &conn->taskQueue) {
if (task->seqNum == seqNum) {
if (found == false) {
found = true;
taskFound = task;
} else {
//LOG error;
continue;
}
}
task = udfTaskQueueNext(task);
}
if (taskFound) {
taskFound->rspBuf = uv_buf_init(connBuf->buf, connBuf->len);
udfTaskQueueRemoveTask(taskFound);
uv_sem_post(&taskFound->taskSem);
} else {
//LOG error
}
connBuf->buf = NULL;
connBuf->total = -1;
connBuf->len = 0;
connBuf->cap = 0;
}
void udfcUvHandleError(SClientUvConn *conn) {
uv_close((uv_handle_t *) conn->pipe, onUdfcPipeClose);
}
void onUdfcRead(uv_stream_t *client, ssize_t nread, const uv_buf_t *buf) {
debugPrint("%s, nread: %zd", "client read from pipe", 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) {
debugPrint("\tclient read error: %s", uv_strerror(nread));
if (nread == UV_EOF) {
//TODO:
}
udfcUvHandleError(conn);
}
}
void onUdfClientWrite(uv_write_t *write, int status) {
debugPrint("%s", "after writing to pipe");
SClientUvTaskNode *uvTask = write->data;
if (status == 0) {
uv_pipe_t *pipe = uvTask->pipe;
SClientUvConn *conn = pipe->data;
udfTaskQueueInsertTail(&conn->taskQueue, uvTask);
} else {
//TODO Log error;
}
debugPrint("\tlength:%zu", 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);
}
int32_t createUdfcUvTask(SClientUdfTask *task, int8_t uvTaskType, SClientUvTaskNode **pUvTask) {
SClientUvTaskNode *uvTask = taosMemoryCalloc(1, sizeof(SClientUvTaskNode));
uvTask->type = uvTaskType;
if (uvTaskType == UV_TASK_CONNECT) {
} else if (uvTaskType == UV_TASK_REQ_RSP) {
uvTask->pipe = task->session->udfSvcPipe;
SUdfRequest request;
request.type = task->type;
request.seqNum = gUdfTaskSeqNum++;
if (task->type == UDF_TASK_SETUP) {
request.subReq = &task->_setup.req;
request.type = UDF_TASK_SETUP;
} else if (task->type == UDF_TASK_CALL) {
request.subReq = &task->_call.req;
request.type = UDF_TASK_CALL;
} else if (task->type == UDF_TASK_TEARDOWN) {
request.subReq = &task->_teardown.req;
request.type = UDF_TASK_TEARDOWN;
} else {
//TODO log and return error
}
char *buf = NULL;
int32_t bufLen = 0;
encodeRequest(&buf, &bufLen, &request);
uvTask->reqBuf = uv_buf_init(buf, bufLen);
uvTask->seqNum = request.seqNum;
} else if (uvTaskType == UV_TASK_DISCONNECT) {
uvTask->pipe = task->session->udfSvcPipe;
}
uv_sem_init(&uvTask->taskSem, 0);
*pUvTask = uvTask;
return 0;
}
int32_t queueUvUdfTask(SClientUvTaskNode *uvTask) {
debugPrint("%s, %d", "queue uv task", uvTask->type);
uv_mutex_lock(&gUdfTaskQueueMutex);
udfTaskQueueInsertTail(gUdfTaskQueue, uvTask);
uv_mutex_unlock(&gUdfTaskQueueMutex);
uv_async_send(&gUdfLoopTaskAync);
uv_sem_wait(&uvTask->taskSem);
uv_sem_destroy(&uvTask->taskSem);
return 0;
}
int32_t startUvUdfTask(SClientUvTaskNode *uvTask) {
debugPrint("%s, type %d", "start uv task ", uvTask->type);
switch (uvTask->type) {
case UV_TASK_CONNECT: {
uv_pipe_t *pipe = taosMemoryMalloc(sizeof(uv_pipe_t));
uv_pipe_init(&gUdfdLoop, pipe, 0);
uvTask->pipe = pipe;
SClientUvConn *conn = taosMemoryMalloc(sizeof(SClientUvConn));
conn->pipe = pipe;
conn->readBuf.len = 0;
conn->readBuf.cap = 0;
conn->readBuf.buf = 0;
conn->readBuf.total = -1;
udfTaskQueueInit(&conn->taskQueue);
pipe->data = conn;
uv_connect_t *connReq = taosMemoryMalloc(sizeof(uv_connect_t));
connReq->data = uvTask;
uv_pipe_connect(connReq, pipe, "udf.sock", 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;
udfTaskQueueInsertTail(&conn->taskQueue, uvTask);
uv_close((uv_handle_t *) uvTask->pipe, onUdfcPipeClose);
break;
}
default: {
break;
}
}
return 0;
}
void udfClientAsyncCb(uv_async_t *async) {
SClientUvTaskNode node;
SClientUvTaskQueue q = &node;
udfTaskQueueInit(q);
uv_mutex_lock(&gUdfTaskQueueMutex);
udfTaskQueueMove(gUdfTaskQueue, q);
uv_mutex_unlock(&gUdfTaskQueueMutex);
while (!udfTaskQueueIsEmpty(q)) {
SClientUvTaskNode *task = udfTaskQueueHeadTask(q);
udfTaskQueueRemoveTask(task);
startUvUdfTask(task);
}
}
void udfStopAsyncCb(uv_async_t *async) {
uv_stop(&gUdfdLoop);
uv_loop_close(&gUdfdLoop);
}
void startUdfd(void *argsThread) {
uv_loop_init(&gUdfdLoop);
//TODO: path
uv_process_options_t options;
static char path[256] = {0};
size_t cwdSize;
uv_cwd(path, &cwdSize);
strcat(path, "./udfd");
char* args[2] = {path, NULL};
options.args = args;
options.file = path;
options.exit_cb = onUdfdExit;
int err = uv_spawn(&gUdfdLoop, &gUdfdProcess, &options);
if (err != 0) {
debugPrint("can not spawn udfd. path: %s, error: %s", path, uv_strerror(err));
}
uv_async_init(&gUdfdLoop, &gUdfLoopTaskAync, udfClientAsyncCb);
uv_async_init(&gUdfdLoop, &gUdfLoopStopAsync, udfStopAsyncCb);
uv_mutex_init(&gUdfTaskQueueMutex);
udfTaskQueueInit(gUdfTaskQueue);
uv_barrier_wait(&gUdfInitBarrier);
uv_run(&gUdfdLoop, UV_RUN_DEFAULT);
}
int32_t startUdfService() {
uv_barrier_init(&gUdfInitBarrier, 2);
uv_thread_create(&gUdfLoopThread, startUdfd, 0);
uv_barrier_wait(&gUdfInitBarrier);
return 0;
}
int32_t stopUdfService() {
uv_barrier_destroy(&gUdfInitBarrier);
uv_process_kill(&gUdfdProcess, SIGINT);
uv_async_send(&gUdfLoopStopAsync);
uv_mutex_destroy(&gUdfTaskQueueMutex);
uv_thread_join(&gUdfLoopThread);
return 0;
}
int32_t udfcRunUvTask(SClientUdfTask *task, int8_t uvTaskType) {
SClientUvTaskNode *uvTask = NULL;
createUdfcUvTask(task, uvTaskType, &uvTask);
queueUvUdfTask(uvTask);
udfcGetUvTaskResponseResult(task, uvTask);
if (uvTaskType == UV_TASK_CONNECT) {
task->session->udfSvcPipe = uvTask->pipe;
}
taosMemoryFree(uvTask);
uvTask = NULL;
return task->errCode;
}
int32_t setupUdf(SUdfInfo *udfInfo, UdfHandle *handle) {
debugPrint("%s", "client setup udf");
SClientUdfTask *task = taosMemoryMalloc(sizeof(SClientUdfTask));
task->errCode = 0;
task->session = taosMemoryMalloc(sizeof(SUdfUvSession));
task->type = UDF_TASK_SETUP;
SUdfSetupRequest *req = &task->_setup.req;
memcpy(req->udfName, udfInfo->udfName, 16);
req->path = udfInfo->path;
req->pathSize = strlen(req->path) + 1;
req->udfType = udfInfo->udfType;
req->scriptType = udfInfo->scriptType;
int32_t errCode = udfcRunUvTask(task, UV_TASK_CONNECT);
if (errCode != 0) {
//TODO: log error
return -1;
}
udfcRunUvTask(task, UV_TASK_REQ_RSP);
SUdfSetupResponse *rsp = &task->_setup.rsp;
task->session->severHandle = rsp->udfHandle;
*handle = task->session;
int32_t err = task->errCode;
taosMemoryFree(task);
return err;
}
int32_t callUdf(UdfHandle handle, int8_t step, char *state, int32_t stateSize, SUdfDataBlock input, char **newState,
int32_t *newStateSize, SUdfDataBlock *output) {
debugPrint("%s", "client call udf");
SClientUdfTask *task = taosMemoryMalloc(sizeof(SClientUdfTask));
task->errCode = 0;
task->session = (SUdfUvSession *) handle;
task->type = UDF_TASK_CALL;
SUdfCallRequest *req = &task->_call.req;
req->state = state;
req->stateBytes = stateSize;
req->inputBytes = input.size;
req->input = input.data;
req->udfHandle = task->session->severHandle;
req->step = step;
udfcRunUvTask(task, UV_TASK_REQ_RSP);
SUdfCallResponse *rsp = &task->_call.rsp;
*newState = rsp->newState;
*newStateSize = rsp->newStateBytes;
output->size = rsp->outputBytes;
output->data = rsp->output;
int32_t err = task->errCode;
taosMemoryFree(task);
return err;
}
int32_t teardownUdf(UdfHandle handle) {
debugPrint("%s", "client teardown udf");
SClientUdfTask *task = taosMemoryMalloc(sizeof(SClientUdfTask));
task->errCode = 0;
task->session = (SUdfUvSession *) handle;
task->type = UDF_TASK_TEARDOWN;
SUdfTeardownRequest *req = &task->_teardown.req;
req->udfHandle = task->session->severHandle;
udfcRunUvTask(task, UV_TASK_REQ_RSP);
SUdfTeardownResponse *rsp = &task->_teardown.rsp;
int32_t err = task->errCode;
udfcRunUvTask(task, UV_TASK_DISCONNECT);
taosMemoryFree(task->session);
taosMemoryFree(task);
return err;
}