未验证 提交 b0bdd7c2 编写于 作者: sangshuduo's avatar sangshuduo 提交者: GitHub

Hotfix/sangshuduo/td 5300 taosdemo stmt print (#6918)

* [TD-5300]<fix>: taosdemo stmt debug print.

* fix default iface is unknown.
上级 0953a606
......@@ -5225,63 +5225,69 @@ static int32_t generateStbDataTail(
int64_t remainderBufLen, int64_t insertRows,
uint64_t recordFrom, int64_t startTime,
int64_t *pSamplePos, int64_t *dataLen) {
uint64_t len = 0;
uint64_t len = 0;
char *pstr = buffer;
char *pstr = buffer;
bool tsRand;
if (0 == strncasecmp(superTblInfo->dataSource, "rand", strlen("rand"))) {
tsRand = true;
} else {
tsRand = false;
}
verbosePrint("%s() LN%d batch=%u buflen=%"PRId64"\n",
__func__, __LINE__, batch, remainderBufLen);
bool tsRand;
if (0 == strncasecmp(superTblInfo->dataSource, "rand", strlen("rand"))) {
tsRand = true;
} else {
tsRand = false;
}
verbosePrint("%s() LN%d batch=%u buflen=%"PRId64"\n",
__func__, __LINE__, batch, remainderBufLen);
int32_t k;
for (k = 0; k < batch;) {
char data[MAX_DATA_SIZE];
memset(data, 0, MAX_DATA_SIZE);
int32_t k;
for (k = 0; k < batch;) {
char data[MAX_DATA_SIZE];
memset(data, 0, MAX_DATA_SIZE);
int64_t lenOfRow = 0;
int64_t lenOfRow = 0;
if (tsRand) {
lenOfRow = generateStbRowData(superTblInfo, data,
startTime + getTSRandTail(
superTblInfo->timeStampStep, k,
superTblInfo->disorderRatio,
superTblInfo->disorderRange)
);
} else {
lenOfRow = getRowDataFromSample(
data,
(remainderBufLen < MAX_DATA_SIZE)?remainderBufLen:MAX_DATA_SIZE,
startTime + superTblInfo->timeStampStep * k,
superTblInfo,
pSamplePos);
}
if (tsRand) {
if (superTblInfo->disorderRatio > 0) {
lenOfRow = generateStbRowData(superTblInfo, data,
startTime + getTSRandTail(
superTblInfo->timeStampStep, k,
superTblInfo->disorderRatio,
superTblInfo->disorderRange)
);
} else {
lenOfRow = generateStbRowData(superTblInfo, data,
startTime + superTblInfo->timeStampStep * k
);
}
} else {
lenOfRow = getRowDataFromSample(
data,
(remainderBufLen < MAX_DATA_SIZE)?remainderBufLen:MAX_DATA_SIZE,
startTime + superTblInfo->timeStampStep * k,
superTblInfo,
pSamplePos);
}
if ((lenOfRow + 1) > remainderBufLen) {
break;
}
if ((lenOfRow + 1) > remainderBufLen) {
break;
}
pstr += snprintf(pstr , lenOfRow + 1, "%s", data);
k++;
len += lenOfRow;
remainderBufLen -= lenOfRow;
pstr += snprintf(pstr , lenOfRow + 1, "%s", data);
k++;
len += lenOfRow;
remainderBufLen -= lenOfRow;
verbosePrint("%s() LN%d len=%"PRIu64" k=%u \nbuffer=%s\n",
__func__, __LINE__, len, k, buffer);
verbosePrint("%s() LN%d len=%"PRIu64" k=%u \nbuffer=%s\n",
__func__, __LINE__, len, k, buffer);
recordFrom ++;
recordFrom ++;
if (recordFrom >= insertRows) {
break;
if (recordFrom >= insertRows) {
break;
}
}
}
*dataLen = len;
return k;
*dataLen = len;
return k;
}
......@@ -5378,52 +5384,52 @@ static int32_t generateStbInterlaceData(
int64_t startTime,
uint64_t *pRemainderBufLen)
{
assert(buffer);
char *pstr = buffer;
assert(buffer);
char *pstr = buffer;
int headLen = generateStbSQLHead(
superTblInfo,
tableName, tableSeq, pThreadInfo->db_name,
pstr, *pRemainderBufLen);
int headLen = generateStbSQLHead(
superTblInfo,
tableName, tableSeq, pThreadInfo->db_name,
pstr, *pRemainderBufLen);
if (headLen <= 0) {
return 0;
}
// generate data buffer
verbosePrint("[%d] %s() LN%d i=%"PRIu64" buffer:\n%s\n",
if (headLen <= 0) {
return 0;
}
// generate data buffer
verbosePrint("[%d] %s() LN%d i=%"PRIu64" buffer:\n%s\n",
pThreadInfo->threadID, __func__, __LINE__, i, buffer);
pstr += headLen;
*pRemainderBufLen -= headLen;
pstr += headLen;
*pRemainderBufLen -= headLen;
int64_t dataLen = 0;
int64_t dataLen = 0;
verbosePrint("[%d] %s() LN%d i=%"PRIu64" batchPerTblTimes=%u batchPerTbl = %u\n",
verbosePrint("[%d] %s() LN%d i=%"PRIu64" batchPerTblTimes=%u batchPerTbl = %u\n",
pThreadInfo->threadID, __func__, __LINE__,
i, batchPerTblTimes, batchPerTbl);
if (0 == strncasecmp(superTblInfo->startTimestamp, "now", 3)) {
startTime = taosGetTimestamp(pThreadInfo->time_precision);
}
if (0 == strncasecmp(superTblInfo->startTimestamp, "now", 3)) {
startTime = taosGetTimestamp(pThreadInfo->time_precision);
}
int32_t k = generateStbDataTail(
int32_t k = generateStbDataTail(
superTblInfo,
batchPerTbl, pstr, *pRemainderBufLen, insertRows, 0,
startTime,
&(pThreadInfo->samplePos), &dataLen);
if (k == batchPerTbl) {
pstr += dataLen;
*pRemainderBufLen -= dataLen;
} else {
debugPrint("%s() LN%d, generated data tail: %u, not equal batch per table: %u\n",
__func__, __LINE__, k, batchPerTbl);
pstr -= headLen;
pstr[0] = '\0';
k = 0;
}
if (k == batchPerTbl) {
pstr += dataLen;
*pRemainderBufLen -= dataLen;
} else {
debugPrint("%s() LN%d, generated data tail: %u, not equal batch per table: %u\n",
__func__, __LINE__, k, batchPerTbl);
pstr -= headLen;
pstr[0] = '\0';
k = 0;
}
return k;
return k;
}
static int64_t generateInterlaceDataWithoutStb(
......@@ -5871,7 +5877,7 @@ static int32_t prepareStbStmtInterlace(
stbInfo,
stmt,
tableName,
g_args.num_of_RPR,
batch,
insertRows, 0, startTime,
pSamplePos);
}
......@@ -5905,29 +5911,29 @@ static int32_t generateStbProgressiveData(
uint64_t recordFrom, int64_t startTime, int64_t *pSamplePos,
int64_t *pRemainderBufLen)
{
assert(buffer != NULL);
char *pstr = buffer;
assert(buffer != NULL);
char *pstr = buffer;
memset(buffer, 0, *pRemainderBufLen);
memset(buffer, 0, *pRemainderBufLen);
int64_t headLen = generateStbSQLHead(
superTblInfo,
tableName, tableSeq, dbName,
buffer, *pRemainderBufLen);
int64_t headLen = generateStbSQLHead(
superTblInfo,
tableName, tableSeq, dbName,
buffer, *pRemainderBufLen);
if (headLen <= 0) {
return 0;
}
pstr += headLen;
*pRemainderBufLen -= headLen;
if (headLen <= 0) {
return 0;
}
pstr += headLen;
*pRemainderBufLen -= headLen;
int64_t dataLen;
int64_t dataLen;
return generateStbDataTail(superTblInfo,
g_args.num_of_RPR, pstr, *pRemainderBufLen,
insertRows, recordFrom,
startTime,
pSamplePos, &dataLen);
return generateStbDataTail(superTblInfo,
g_args.num_of_RPR, pstr, *pRemainderBufLen,
insertRows, recordFrom,
startTime,
pSamplePos, &dataLen);
}
static int32_t generateProgressiveDataWithoutStb(
......@@ -5974,283 +5980,283 @@ static void printStatPerThread(threadInfo *pThreadInfo)
// sync write interlace data
static void* syncWriteInterlace(threadInfo *pThreadInfo) {
debugPrint("[%d] %s() LN%d: ### interlace write\n",
pThreadInfo->threadID, __func__, __LINE__);
debugPrint("[%d] %s() LN%d: ### interlace write\n",
pThreadInfo->threadID, __func__, __LINE__);
int64_t insertRows;
uint32_t interlaceRows;
uint64_t maxSqlLen;
int64_t nTimeStampStep;
uint64_t insert_interval;
int64_t insertRows;
uint32_t interlaceRows;
uint64_t maxSqlLen;
int64_t nTimeStampStep;
uint64_t insert_interval;
SSuperTable* superTblInfo = pThreadInfo->superTblInfo;
SSuperTable* superTblInfo = pThreadInfo->superTblInfo;
if (superTblInfo) {
insertRows = superTblInfo->insertRows;
if (superTblInfo) {
insertRows = superTblInfo->insertRows;
if ((superTblInfo->interlaceRows == 0)
&& (g_args.interlace_rows > 0)) {
interlaceRows = g_args.interlace_rows;
if ((superTblInfo->interlaceRows == 0)
&& (g_args.interlace_rows > 0)) {
interlaceRows = g_args.interlace_rows;
} else {
interlaceRows = superTblInfo->interlaceRows;
}
maxSqlLen = superTblInfo->maxSqlLen;
nTimeStampStep = superTblInfo->timeStampStep;
insert_interval = superTblInfo->insertInterval;
} else {
interlaceRows = superTblInfo->interlaceRows;
insertRows = g_args.num_of_DPT;
interlaceRows = g_args.interlace_rows;
maxSqlLen = g_args.max_sql_len;
nTimeStampStep = DEFAULT_TIMESTAMP_STEP;
insert_interval = g_args.insert_interval;
}
maxSqlLen = superTblInfo->maxSqlLen;
nTimeStampStep = superTblInfo->timeStampStep;
insert_interval = superTblInfo->insertInterval;
} else {
insertRows = g_args.num_of_DPT;
interlaceRows = g_args.interlace_rows;
maxSqlLen = g_args.max_sql_len;
nTimeStampStep = DEFAULT_TIMESTAMP_STEP;
insert_interval = g_args.insert_interval;
}
debugPrint("[%d] %s() LN%d: start_table_from=%"PRIu64" ntables=%"PRId64" insertRows=%"PRIu64"\n",
pThreadInfo->threadID, __func__, __LINE__,
pThreadInfo->start_table_from,
pThreadInfo->ntables, insertRows);
debugPrint("[%d] %s() LN%d: start_table_from=%"PRIu64" ntables=%"PRId64" insertRows=%"PRIu64"\n",
pThreadInfo->threadID, __func__, __LINE__,
pThreadInfo->start_table_from,
pThreadInfo->ntables, insertRows);
if (interlaceRows > insertRows)
interlaceRows = insertRows;
if (interlaceRows > insertRows)
interlaceRows = insertRows;
if (interlaceRows > g_args.num_of_RPR)
interlaceRows = g_args.num_of_RPR;
if (interlaceRows > g_args.num_of_RPR)
interlaceRows = g_args.num_of_RPR;
uint32_t batchPerTbl = interlaceRows;
uint32_t batchPerTblTimes;
uint32_t batchPerTbl = interlaceRows;
uint32_t batchPerTblTimes;
if ((interlaceRows > 0) && (pThreadInfo->ntables > 1)) {
batchPerTblTimes =
g_args.num_of_RPR / interlaceRows;
} else {
batchPerTblTimes = 1;
}
if ((interlaceRows > 0) && (pThreadInfo->ntables > 1)) {
batchPerTblTimes =
g_args.num_of_RPR / interlaceRows;
} else {
batchPerTblTimes = 1;
}
pThreadInfo->buffer = calloc(maxSqlLen, 1);
if (NULL == pThreadInfo->buffer) {
errorPrint( "%s() LN%d, Failed to alloc %"PRIu64" Bytes, reason:%s\n",
__func__, __LINE__, maxSqlLen, strerror(errno));
return NULL;
}
pThreadInfo->buffer = calloc(maxSqlLen, 1);
if (NULL == pThreadInfo->buffer) {
errorPrint( "%s() LN%d, Failed to alloc %"PRIu64" Bytes, reason:%s\n",
__func__, __LINE__, maxSqlLen, strerror(errno));
return NULL;
}
pThreadInfo->totalInsertRows = 0;
pThreadInfo->totalAffectedRows = 0;
pThreadInfo->totalInsertRows = 0;
pThreadInfo->totalAffectedRows = 0;
uint64_t st = 0;
uint64_t et = UINT64_MAX;
uint64_t st = 0;
uint64_t et = UINT64_MAX;
uint64_t lastPrintTime = taosGetTimestampMs();
uint64_t startTs = taosGetTimestampMs();
uint64_t endTs;
uint64_t lastPrintTime = taosGetTimestampMs();
uint64_t startTs = taosGetTimestampMs();
uint64_t endTs;
uint64_t tableSeq = pThreadInfo->start_table_from;
int64_t startTime = pThreadInfo->start_time;
uint64_t tableSeq = pThreadInfo->start_table_from;
int64_t startTime = pThreadInfo->start_time;
uint64_t generatedRecPerTbl = 0;
bool flagSleep = true;
uint64_t sleepTimeTotal = 0;
uint64_t generatedRecPerTbl = 0;
bool flagSleep = true;
uint64_t sleepTimeTotal = 0;
while(pThreadInfo->totalInsertRows < pThreadInfo->ntables * insertRows) {
if ((flagSleep) && (insert_interval)) {
st = taosGetTimestampMs();
flagSleep = false;
}
// generate data
memset(pThreadInfo->buffer, 0, maxSqlLen);
uint64_t remainderBufLen = maxSqlLen;
while(pThreadInfo->totalInsertRows < pThreadInfo->ntables * insertRows) {
if ((flagSleep) && (insert_interval)) {
st = taosGetTimestampMs();
flagSleep = false;
}
// generate data
memset(pThreadInfo->buffer, 0, maxSqlLen);
uint64_t remainderBufLen = maxSqlLen;
char *pstr = pThreadInfo->buffer;
char *pstr = pThreadInfo->buffer;
int len = snprintf(pstr,
strlen(STR_INSERT_INTO) + 1, "%s", STR_INSERT_INTO);
pstr += len;
remainderBufLen -= len;
int len = snprintf(pstr,
strlen(STR_INSERT_INTO) + 1, "%s", STR_INSERT_INTO);
pstr += len;
remainderBufLen -= len;
uint32_t recOfBatch = 0;
uint32_t recOfBatch = 0;
for (uint64_t i = 0; i < batchPerTblTimes; i ++) {
char tableName[TSDB_TABLE_NAME_LEN];
for (uint64_t i = 0; i < batchPerTblTimes; i ++) {
char tableName[TSDB_TABLE_NAME_LEN];
getTableName(tableName, pThreadInfo, tableSeq);
if (0 == strlen(tableName)) {
errorPrint("[%d] %s() LN%d, getTableName return null\n",
pThreadInfo->threadID, __func__, __LINE__);
free(pThreadInfo->buffer);
return NULL;
}
getTableName(tableName, pThreadInfo, tableSeq);
if (0 == strlen(tableName)) {
errorPrint("[%d] %s() LN%d, getTableName return null\n",
pThreadInfo->threadID, __func__, __LINE__);
free(pThreadInfo->buffer);
return NULL;
}
uint64_t oldRemainderLen = remainderBufLen;
uint64_t oldRemainderLen = remainderBufLen;
int32_t generated;
if (superTblInfo) {
if (superTblInfo->iface == STMT_IFACE) {
int32_t generated;
if (superTblInfo) {
if (superTblInfo->iface == STMT_IFACE) {
#if STMT_IFACE_ENABLED == 1
generated = prepareStbStmtInterlace(
superTblInfo,
pThreadInfo->stmt,
tableName,
batchPerTbl,
insertRows, i,
startTime,
&(pThreadInfo->samplePos));
generated = prepareStbStmtInterlace(
superTblInfo,
pThreadInfo->stmt,
tableName,
batchPerTbl,
insertRows, i,
startTime,
&(pThreadInfo->samplePos));
#else
generated = -1;
generated = -1;
#endif
} else {
generated = generateStbInterlaceData(
superTblInfo,
tableName, batchPerTbl, i,
batchPerTblTimes,
tableSeq,
pThreadInfo, pstr,
insertRows,
startTime,
&remainderBufLen);
}
} else {
if (g_args.iface == STMT_IFACE) {
debugPrint("[%d] %s() LN%d, tableName:%s, batch:%d startTime:%"PRId64"\n",
pThreadInfo->threadID,
__func__, __LINE__,
tableName, batchPerTbl, startTime);
} else {
generated = generateStbInterlaceData(
superTblInfo,
tableName, batchPerTbl, i,
batchPerTblTimes,
tableSeq,
pThreadInfo, pstr,
insertRows,
startTime,
&remainderBufLen);
}
} else {
if (g_args.iface == STMT_IFACE) {
debugPrint("[%d] %s() LN%d, tableName:%s, batch:%d startTime:%"PRId64"\n",
pThreadInfo->threadID,
__func__, __LINE__,
tableName, batchPerTbl, startTime);
#if STMT_IFACE_ENABLED == 1
generated = prepareStmtWithoutStb(
pThreadInfo->stmt, tableName,
batchPerTbl,
insertRows, i,
startTime);
generated = prepareStmtWithoutStb(
pThreadInfo->stmt, tableName,
batchPerTbl,
insertRows, i,
startTime);
#else
generated = -1;
generated = -1;
#endif
} else {
generated = generateInterlaceDataWithoutStb(
tableName, batchPerTbl,
tableSeq,
pThreadInfo->db_name, pstr,
insertRows,
startTime,
&remainderBufLen);
}
}
} else {
generated = generateInterlaceDataWithoutStb(
tableName, batchPerTbl,
tableSeq,
pThreadInfo->db_name, pstr,
insertRows,
startTime,
&remainderBufLen);
}
}
debugPrint("[%d] %s() LN%d, generated records is %d\n",
pThreadInfo->threadID, __func__, __LINE__, generated);
if (generated < 0) {
errorPrint("[%d] %s() LN%d, generated records is %d\n",
pThreadInfo->threadID, __func__, __LINE__, generated);
goto free_of_interlace;
} else if (generated == 0) {
break;
}
debugPrint("[%d] %s() LN%d, generated records is %d\n",
pThreadInfo->threadID, __func__, __LINE__, generated);
if (generated < 0) {
errorPrint("[%d] %s() LN%d, generated records is %d\n",
pThreadInfo->threadID, __func__, __LINE__, generated);
goto free_of_interlace;
} else if (generated == 0) {
break;
}
tableSeq ++;
recOfBatch += batchPerTbl;
tableSeq ++;
recOfBatch += batchPerTbl;
pstr += (oldRemainderLen - remainderBufLen);
pThreadInfo->totalInsertRows += batchPerTbl;
pstr += (oldRemainderLen - remainderBufLen);
pThreadInfo->totalInsertRows += batchPerTbl;
verbosePrint("[%d] %s() LN%d batchPerTbl=%d recOfBatch=%d\n",
pThreadInfo->threadID, __func__, __LINE__,
batchPerTbl, recOfBatch);
verbosePrint("[%d] %s() LN%d batchPerTbl=%d recOfBatch=%d\n",
pThreadInfo->threadID, __func__, __LINE__,
batchPerTbl, recOfBatch);
if (tableSeq == pThreadInfo->start_table_from + pThreadInfo->ntables) {
// turn to first table
tableSeq = pThreadInfo->start_table_from;
generatedRecPerTbl += batchPerTbl;
if (tableSeq == pThreadInfo->start_table_from + pThreadInfo->ntables) {
// turn to first table
tableSeq = pThreadInfo->start_table_from;
generatedRecPerTbl += batchPerTbl;
startTime = pThreadInfo->start_time
+ generatedRecPerTbl * nTimeStampStep;
startTime = pThreadInfo->start_time
+ generatedRecPerTbl * nTimeStampStep;
flagSleep = true;
if (generatedRecPerTbl >= insertRows)
break;
flagSleep = true;
if (generatedRecPerTbl >= insertRows)
break;
int64_t remainRows = insertRows - generatedRecPerTbl;
if ((remainRows > 0) && (batchPerTbl > remainRows))
batchPerTbl = remainRows;
int64_t remainRows = insertRows - generatedRecPerTbl;
if ((remainRows > 0) && (batchPerTbl > remainRows))
batchPerTbl = remainRows;
if (pThreadInfo->ntables * batchPerTbl < g_args.num_of_RPR)
break;
}
if (pThreadInfo->ntables * batchPerTbl < g_args.num_of_RPR)
break;
}
verbosePrint("[%d] %s() LN%d generatedRecPerTbl=%"PRId64" insertRows=%"PRId64"\n",
pThreadInfo->threadID, __func__, __LINE__,
generatedRecPerTbl, insertRows);
verbosePrint("[%d] %s() LN%d generatedRecPerTbl=%"PRId64" insertRows=%"PRId64"\n",
pThreadInfo->threadID, __func__, __LINE__,
generatedRecPerTbl, insertRows);
if ((g_args.num_of_RPR - recOfBatch) < batchPerTbl)
break;
}
if ((g_args.num_of_RPR - recOfBatch) < batchPerTbl)
break;
}
verbosePrint("[%d] %s() LN%d recOfBatch=%d totalInsertRows=%"PRIu64"\n",
pThreadInfo->threadID, __func__, __LINE__, recOfBatch,
pThreadInfo->totalInsertRows);
verbosePrint("[%d] %s() LN%d, buffer=%s\n",
pThreadInfo->threadID, __func__, __LINE__, pThreadInfo->buffer);
verbosePrint("[%d] %s() LN%d recOfBatch=%d totalInsertRows=%"PRIu64"\n",
pThreadInfo->threadID, __func__, __LINE__, recOfBatch,
pThreadInfo->totalInsertRows);
verbosePrint("[%d] %s() LN%d, buffer=%s\n",
pThreadInfo->threadID, __func__, __LINE__, pThreadInfo->buffer);
startTs = taosGetTimestampMs();
startTs = taosGetTimestampMs();
if (recOfBatch == 0) {
errorPrint("[%d] %s() LN%d Failed to insert records of batch %d\n",
pThreadInfo->threadID, __func__, __LINE__,
batchPerTbl);
if (batchPerTbl > 0) {
errorPrint("\tIf the batch is %d, the length of the SQL to insert a row must be less then %"PRId64"\n",
batchPerTbl, maxSqlLen / batchPerTbl);
if (recOfBatch == 0) {
errorPrint("[%d] %s() LN%d Failed to insert records of batch %d\n",
pThreadInfo->threadID, __func__, __LINE__,
batchPerTbl);
if (batchPerTbl > 0) {
errorPrint("\tIf the batch is %d, the length of the SQL to insert a row must be less then %"PRId64"\n",
batchPerTbl, maxSqlLen / batchPerTbl);
}
errorPrint("\tPlease check if the buffer length(%"PRId64") or batch(%d) is set with proper value!\n",
maxSqlLen, batchPerTbl);
goto free_of_interlace;
}
errorPrint("\tPlease check if the buffer length(%"PRId64") or batch(%d) is set with proper value!\n",
maxSqlLen, batchPerTbl);
goto free_of_interlace;
}
int64_t affectedRows = execInsert(pThreadInfo, recOfBatch);
int64_t affectedRows = execInsert(pThreadInfo, recOfBatch);
endTs = taosGetTimestampMs();
uint64_t delay = endTs - startTs;
performancePrint("%s() LN%d, insert execution time is %"PRIu64"ms\n",
__func__, __LINE__, delay);
verbosePrint("[%d] %s() LN%d affectedRows=%"PRId64"\n",
pThreadInfo->threadID,
__func__, __LINE__, affectedRows);
endTs = taosGetTimestampMs();
uint64_t delay = endTs - startTs;
performancePrint("%s() LN%d, insert execution time is %"PRIu64"ms\n",
__func__, __LINE__, delay);
verbosePrint("[%d] %s() LN%d affectedRows=%"PRId64"\n",
pThreadInfo->threadID,
__func__, __LINE__, affectedRows);
if (delay > pThreadInfo->maxDelay) pThreadInfo->maxDelay = delay;
if (delay < pThreadInfo->minDelay) pThreadInfo->minDelay = delay;
pThreadInfo->cntDelay++;
pThreadInfo->totalDelay += delay;
if (delay > pThreadInfo->maxDelay) pThreadInfo->maxDelay = delay;
if (delay < pThreadInfo->minDelay) pThreadInfo->minDelay = delay;
pThreadInfo->cntDelay++;
pThreadInfo->totalDelay += delay;
if (recOfBatch != affectedRows) {
errorPrint("[%d] %s() LN%d execInsert insert %d, affected rows: %"PRId64"\n%s\n",
pThreadInfo->threadID, __func__, __LINE__,
recOfBatch, affectedRows, pThreadInfo->buffer);
goto free_of_interlace;
}
if (recOfBatch != affectedRows) {
errorPrint("[%d] %s() LN%d execInsert insert %d, affected rows: %"PRId64"\n%s\n",
pThreadInfo->threadID, __func__, __LINE__,
recOfBatch, affectedRows, pThreadInfo->buffer);
goto free_of_interlace;
}
pThreadInfo->totalAffectedRows += affectedRows;
pThreadInfo->totalAffectedRows += affectedRows;
int64_t currentPrintTime = taosGetTimestampMs();
if (currentPrintTime - lastPrintTime > 30*1000) {
printf("thread[%d] has currently inserted rows: %"PRIu64 ", affected rows: %"PRIu64 "\n",
int64_t currentPrintTime = taosGetTimestampMs();
if (currentPrintTime - lastPrintTime > 30*1000) {
printf("thread[%d] has currently inserted rows: %"PRIu64 ", affected rows: %"PRIu64 "\n",
pThreadInfo->threadID,
pThreadInfo->totalInsertRows,
pThreadInfo->totalAffectedRows);
lastPrintTime = currentPrintTime;
}
lastPrintTime = currentPrintTime;
}
if ((insert_interval) && flagSleep) {
et = taosGetTimestampMs();
if ((insert_interval) && flagSleep) {
et = taosGetTimestampMs();
if (insert_interval > (et - st) ) {
uint64_t sleepTime = insert_interval - (et -st);
performancePrint("%s() LN%d sleep: %"PRId64" ms for insert interval\n",
__func__, __LINE__, sleepTime);
taosMsleep(sleepTime); // ms
sleepTimeTotal += insert_interval;
}
if (insert_interval > (et - st) ) {
uint64_t sleepTime = insert_interval - (et -st);
performancePrint("%s() LN%d sleep: %"PRId64" ms for insert interval\n",
__func__, __LINE__, sleepTime);
taosMsleep(sleepTime); // ms
sleepTimeTotal += insert_interval;
}
}
}
}
free_of_interlace:
tmfree(pThreadInfo->buffer);
printStatPerThread(pThreadInfo);
return NULL;
tmfree(pThreadInfo->buffer);
printStatPerThread(pThreadInfo);
return NULL;
}
// sync insertion progressive data
......@@ -6417,29 +6423,29 @@ free_of_progressive:
static void* syncWrite(void *sarg) {
threadInfo *pThreadInfo = (threadInfo *)sarg;
SSuperTable* superTblInfo = pThreadInfo->superTblInfo;
threadInfo *pThreadInfo = (threadInfo *)sarg;
SSuperTable* superTblInfo = pThreadInfo->superTblInfo;
uint32_t interlaceRows;
uint32_t interlaceRows;
if (superTblInfo) {
if ((superTblInfo->interlaceRows == 0)
&& (g_args.interlace_rows > 0)) {
interlaceRows = g_args.interlace_rows;
if (superTblInfo) {
if ((superTblInfo->interlaceRows == 0)
&& (g_args.interlace_rows > 0)) {
interlaceRows = g_args.interlace_rows;
} else {
interlaceRows = superTblInfo->interlaceRows;
}
} else {
interlaceRows = superTblInfo->interlaceRows;
interlaceRows = g_args.interlace_rows;
}
} else {
interlaceRows = g_args.interlace_rows;
}
if (interlaceRows > 0) {
// interlace mode
return syncWriteInterlace(pThreadInfo);
} else {
// progressive mode
return syncWriteProgressive(pThreadInfo);
}
if (interlaceRows > 0) {
// interlace mode
return syncWriteInterlace(pThreadInfo);
} else {
// progressive mode
return syncWriteProgressive(pThreadInfo);
}
}
static void callBack(void *param, TAOS_RES *res, int code) {
......
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