/* * 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 "parInsertData.h" #include "parInt.h" #include "parUtil.h" #include "parToken.h" #include "tglobal.h" #include "ttime.h" #include "ttypes.h" #define NEXT_TOKEN(pSql, sToken) \ do { \ int32_t index = 0; \ sToken = tStrGetToken(pSql, &index, false); \ pSql += index; \ } while (0) #define NEXT_TOKEN_WITH_PREV(pSql, sToken) \ do { \ int32_t index = 0; \ sToken = tStrGetToken(pSql, &index, true); \ pSql += index; \ } while (0) #define NEXT_TOKEN_KEEP_SQL(pSql, sToken, index) \ do { \ sToken = tStrGetToken(pSql, &index, false); \ } while (0) #define CHECK_CODE(expr) \ do { \ int32_t code = expr; \ if (TSDB_CODE_SUCCESS != code) { \ return code; \ } \ } while (0) typedef struct SInsertParseContext { SParseContext* pComCxt; // input char *pSql; // input SMsgBuf msg; // input STableMeta* pTableMeta; // each table SParsedDataColInfo tags; // each table SKVRowBuilder tagsBuilder; // each table SVCreateTbReq createTblReq; // each table SHashObj* pVgroupsHashObj; // global SHashObj* pTableBlockHashObj; // global SHashObj* pSubTableHashObj; // global SArray* pTableDataBlocks; // global SArray* pVgDataBlocks; // global int32_t totalNum; SVnodeModifOpStmt* pOutput; } SInsertParseContext; typedef int32_t (*_row_append_fn_t)(SMsgBuf* pMsgBuf, const void *value, int32_t len, void *param); static uint8_t TRUE_VALUE = (uint8_t)TSDB_TRUE; static uint8_t FALSE_VALUE = (uint8_t)TSDB_FALSE; static int32_t skipInsertInto(SInsertParseContext* pCxt) { SToken sToken; NEXT_TOKEN(pCxt->pSql, sToken); if (TK_INSERT != sToken.type) { return buildSyntaxErrMsg(&pCxt->msg, "keyword INSERT is expected", sToken.z); } NEXT_TOKEN(pCxt->pSql, sToken); if (TK_INTO != sToken.type) { return buildSyntaxErrMsg(&pCxt->msg, "keyword INTO is expected", sToken.z); } return TSDB_CODE_SUCCESS; } static int32_t parserValidateIdToken(SToken* pToken) { if (pToken == NULL || pToken->z == NULL || pToken->type != TK_NK_ID) { return TSDB_CODE_TSC_INVALID_OPERATION; } // it is a token quoted with escape char '`' if (pToken->z[0] == TS_ESCAPE_CHAR && pToken->z[pToken->n - 1] == TS_ESCAPE_CHAR) { return TSDB_CODE_SUCCESS; } char* sep = strnchr(pToken->z, TS_PATH_DELIMITER[0], pToken->n, true); if (sep == NULL) { // It is a single part token, not a complex type if (isNumber(pToken)) { return TSDB_CODE_TSC_INVALID_OPERATION; } strntolower(pToken->z, pToken->z, pToken->n); } else { // two part int32_t oldLen = pToken->n; char* pStr = pToken->z; if (pToken->type == TK_NK_SPACE) { pToken->n = (uint32_t)strtrim(pToken->z); } pToken->n = tGetToken(pToken->z, &pToken->type); if (pToken->z[pToken->n] != TS_PATH_DELIMITER[0]) { return TSDB_CODE_TSC_INVALID_OPERATION; } if (pToken->type != TK_NK_ID) { return TSDB_CODE_TSC_INVALID_OPERATION; } int32_t firstPartLen = pToken->n; pToken->z = sep + 1; pToken->n = (uint32_t)(oldLen - (sep - pStr) - 1); int32_t len = tGetToken(pToken->z, &pToken->type); if (len != pToken->n || pToken->type != TK_NK_ID) { return TSDB_CODE_TSC_INVALID_OPERATION; } // re-build the whole name string if (pStr[firstPartLen] == TS_PATH_DELIMITER[0]) { // first part do not have quote do nothing } else { pStr[firstPartLen] = TS_PATH_DELIMITER[0]; memmove(&pStr[firstPartLen + 1], pToken->z, pToken->n); uint32_t offset = (uint32_t)(pToken->z - (pStr + firstPartLen + 1)); memset(pToken->z + pToken->n - offset, ' ', offset); } pToken->n += (firstPartLen + sizeof(TS_PATH_DELIMITER[0])); pToken->z = pStr; strntolower(pToken->z, pToken->z, pToken->n); } return TSDB_CODE_SUCCESS; } static int32_t buildName(SInsertParseContext* pCxt, SToken* pStname, char* fullDbName, char* tableName) { if (parserValidateIdToken(pStname) != TSDB_CODE_SUCCESS) { return buildSyntaxErrMsg(&pCxt->msg, "invalid table name", pStname->z); } char* p = strnchr(pStname->z, TS_PATH_DELIMITER[0], pStname->n, false); if (NULL != p) { // db.table int32_t n = sprintf(fullDbName, "%d.", pCxt->pComCxt->acctId); strncpy(fullDbName + n, pStname->z, p - pStname->z); strncpy(tableName, p + 1, pStname->n - (p - pStname->z) - 1); } else { snprintf(fullDbName, TSDB_DB_FNAME_LEN, "%d.%s", pCxt->pComCxt->acctId, pCxt->pComCxt->db); strncpy(tableName, pStname->z, pStname->n); } return TSDB_CODE_SUCCESS; } static int32_t createSName(SName* pName, SToken* pTableName, SParseContext* pParseCtx, SMsgBuf* pMsgBuf) { const char* msg1 = "name too long"; const char* msg2 = "invalid database name"; const char* msg3 = "db is not specified"; int32_t code = TSDB_CODE_SUCCESS; char* p = strnchr(pTableName->z, TS_PATH_DELIMITER[0], pTableName->n, true); if (p != NULL) { // db has been specified in sql string so we ignore current db path assert(*p == TS_PATH_DELIMITER[0]); int32_t dbLen = p - pTableName->z; char name[TSDB_DB_FNAME_LEN] = {0}; strncpy(name, pTableName->z, dbLen); dbLen = strdequote(name); code = tNameSetDbName(pName, pParseCtx->acctId, name, dbLen); if (code != TSDB_CODE_SUCCESS) { return buildInvalidOperationMsg(pMsgBuf, msg1); } int32_t tbLen = pTableName->n - dbLen - 1; char tbname[TSDB_TABLE_FNAME_LEN] = {0}; strncpy(tbname, p + 1, tbLen); /*tbLen = */strdequote(tbname); code = tNameFromString(pName, tbname, T_NAME_TABLE); if (code != 0) { return buildInvalidOperationMsg(pMsgBuf, msg1); } } else { // get current DB name first, and then set it into path if (pTableName->n >= TSDB_TABLE_NAME_LEN) { return buildInvalidOperationMsg(pMsgBuf, msg1); } assert(pTableName->n < TSDB_TABLE_FNAME_LEN); char name[TSDB_TABLE_FNAME_LEN] = {0}; strncpy(name, pTableName->z, pTableName->n); strdequote(name); if (pParseCtx->db == NULL) { return buildInvalidOperationMsg(pMsgBuf, msg3); } code = tNameSetDbName(pName, pParseCtx->acctId, pParseCtx->db, strlen(pParseCtx->db)); if (code != TSDB_CODE_SUCCESS) { code = buildInvalidOperationMsg(pMsgBuf, msg2); return code; } code = tNameFromString(pName, name, T_NAME_TABLE); if (code != 0) { code = buildInvalidOperationMsg(pMsgBuf, msg1); } } return code; } static int32_t getTableMetaImpl(SInsertParseContext* pCxt, SToken* pTname, bool isStb) { SParseContext* pBasicCtx = pCxt->pComCxt; SName name = {0}; createSName(&name, pTname, pBasicCtx, &pCxt->msg); if (isStb) { CHECK_CODE(catalogGetSTableMeta(pBasicCtx->pCatalog, pBasicCtx->pTransporter, &pBasicCtx->mgmtEpSet, &name, &pCxt->pTableMeta)); } else { CHECK_CODE(catalogGetTableMeta(pBasicCtx->pCatalog, pBasicCtx->pTransporter, &pBasicCtx->mgmtEpSet, &name, &pCxt->pTableMeta)); } SVgroupInfo vg; CHECK_CODE(catalogGetTableHashVgroup(pBasicCtx->pCatalog, pBasicCtx->pTransporter, &pBasicCtx->mgmtEpSet, &name, &vg)); CHECK_CODE(taosHashPut(pCxt->pVgroupsHashObj, (const char*)&vg.vgId, sizeof(vg.vgId), (char*)&vg, sizeof(vg))); return TSDB_CODE_SUCCESS; } static int32_t getTableMeta(SInsertParseContext* pCxt, SToken* pTname) { return getTableMetaImpl(pCxt, pTname, false); } static int32_t getSTableMeta(SInsertParseContext* pCxt, SToken* pTname) { return getTableMetaImpl(pCxt, pTname, true); } static int32_t findCol(SToken* pColname, int32_t start, int32_t end, SSchema* pSchema) { while (start < end) { if (strlen(pSchema[start].name) == pColname->n && strncmp(pColname->z, pSchema[start].name, pColname->n) == 0) { return start; } ++start; } return -1; } static void buildMsgHeader(STableDataBlocks* src, SVgDataBlocks* blocks) { SSubmitReq* submit = (SSubmitReq*)blocks->pData; submit->header.vgId = htonl(blocks->vg.vgId); submit->header.contLen = htonl(blocks->size); submit->length = submit->header.contLen; submit->numOfBlocks = htonl(blocks->numOfTables); SSubmitBlk* blk = (SSubmitBlk*)(submit + 1); int32_t numOfBlocks = blocks->numOfTables; while (numOfBlocks--) { int32_t dataLen = blk->dataLen; blk->uid = htobe64(blk->uid); blk->suid = htobe64(blk->suid); blk->padding = htonl(blk->padding); blk->sversion = htonl(blk->sversion); blk->dataLen = htonl(blk->dataLen); blk->schemaLen = htonl(blk->schemaLen); blk->numOfRows = htons(blk->numOfRows); blk = (SSubmitBlk*)(blk->data + dataLen); } } static int32_t buildOutput(SInsertParseContext* pCxt) { size_t numOfVg = taosArrayGetSize(pCxt->pVgDataBlocks); pCxt->pOutput->pDataBlocks = taosArrayInit(numOfVg, POINTER_BYTES); if (NULL == pCxt->pOutput->pDataBlocks) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } for (size_t i = 0; i < numOfVg; ++i) { STableDataBlocks* src = taosArrayGetP(pCxt->pVgDataBlocks, i); SVgDataBlocks* dst = taosMemoryCalloc(1, sizeof(SVgDataBlocks)); if (NULL == dst) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } taosHashGetDup(pCxt->pVgroupsHashObj, (const char*)&src->vgId, sizeof(src->vgId), &dst->vg); dst->numOfTables = src->numOfTables; dst->size = src->size; TSWAP(dst->pData, src->pData, char*); buildMsgHeader(src, dst); taosArrayPush(pCxt->pOutput->pDataBlocks, &dst); } return TSDB_CODE_SUCCESS; } static int32_t checkTimestamp(STableDataBlocks *pDataBlocks, const char *start) { // once the data block is disordered, we do NOT keep previous timestamp any more if (!pDataBlocks->ordered) { return TSDB_CODE_SUCCESS; } TSKEY k = *(TSKEY *)start; if (k <= pDataBlocks->prevTS) { pDataBlocks->ordered = false; } pDataBlocks->prevTS = k; return TSDB_CODE_SUCCESS; } static int parseTime(char **end, SToken *pToken, int16_t timePrec, int64_t *time, SMsgBuf* pMsgBuf) { int32_t index = 0; SToken sToken; int64_t interval; int64_t ts = 0; char* pTokenEnd = *end; if (pToken->type == TK_NOW) { ts = taosGetTimestamp(timePrec); } else if (pToken->type == TK_TODAY) { ts = taosGetTimestampToday(timePrec); } else if (pToken->type == TK_NK_INTEGER) { bool isSigned = false; toInteger(pToken->z, pToken->n, 10, &ts, &isSigned); } else { // parse the RFC-3339/ISO-8601 timestamp format string if (taosParseTime(pToken->z, time, pToken->n, timePrec, tsDaylight) != TSDB_CODE_SUCCESS) { return buildSyntaxErrMsg(pMsgBuf, "invalid timestamp format", pToken->z); } return TSDB_CODE_SUCCESS; } for (int k = pToken->n; pToken->z[k] != '\0'; k++) { if (pToken->z[k] == ' ' || pToken->z[k] == '\t') continue; if (pToken->z[k] == '(' && pToken->z[k + 1] == ')') { //for insert NOW()/TODAY() *end = pTokenEnd = &pToken->z[k + 2]; k++; continue; } if (pToken->z[k] == ',') { *end = pTokenEnd; *time = ts; return 0; } break; } /* * time expression: * e.g., now+12a, now-5h */ SToken valueToken; index = 0; sToken = tStrGetToken(pTokenEnd, &index, false); pTokenEnd += index; if (sToken.type == TK_NK_MINUS || sToken.type == TK_NK_PLUS) { index = 0; valueToken = tStrGetToken(pTokenEnd, &index, false); pTokenEnd += index; if (valueToken.n < 2) { return buildSyntaxErrMsg(pMsgBuf, "value expected in timestamp", sToken.z); } char unit = 0; if (parseAbsoluteDuration(valueToken.z, valueToken.n, &interval, &unit, timePrec) != TSDB_CODE_SUCCESS) { return TSDB_CODE_TSC_INVALID_OPERATION; } if (sToken.type == TK_NK_PLUS) { ts += interval; } else { ts = ts - interval; } *end = pTokenEnd; } *time = ts; return TSDB_CODE_SUCCESS; } static FORCE_INLINE int32_t checkAndTrimValue(SToken* pToken, uint32_t type, char* tmpTokenBuf, SMsgBuf* pMsgBuf) { if ((pToken->type != TK_NOW && pToken->type != TK_TODAY && pToken->type != TK_NK_INTEGER && pToken->type != TK_NK_STRING && pToken->type != TK_NK_FLOAT && pToken->type != TK_NK_BOOL && pToken->type != TK_NULL && pToken->type != TK_NK_HEX && pToken->type != TK_NK_OCT && pToken->type != TK_NK_BIN) || (pToken->n == 0) || (pToken->type == TK_NK_RP)) { return buildSyntaxErrMsg(pMsgBuf, "invalid data or symbol", pToken->z); } if (IS_NUMERIC_TYPE(type) && pToken->n == 0) { return buildSyntaxErrMsg(pMsgBuf, "invalid numeric data", pToken->z); } // Remove quotation marks if (TK_NK_STRING == pToken->type) { if (pToken->n >= TSDB_MAX_BYTES_PER_ROW) { return buildSyntaxErrMsg(pMsgBuf, "too long string", pToken->z); } // delete escape character: \\, \', \" char delim = pToken->z[0]; int32_t cnt = 0; int32_t j = 0; for (uint32_t k = 1; k < pToken->n - 1; ++k) { if (pToken->z[k] == '\\' || (pToken->z[k] == delim && pToken->z[k + 1] == delim)) { tmpTokenBuf[j] = pToken->z[k + 1]; cnt++; j++; k++; continue; } tmpTokenBuf[j] = pToken->z[k]; j++; } tmpTokenBuf[j] = 0; pToken->z = tmpTokenBuf; pToken->n -= 2 + cnt; } return TSDB_CODE_SUCCESS; } static bool isNullStr(SToken *pToken) { return (pToken->type == TK_NULL) || ((pToken->type == TK_NK_STRING) && (pToken->n != 0) && (strncasecmp(TSDB_DATA_NULL_STR_L, pToken->z, pToken->n) == 0)); } static FORCE_INLINE int32_t toDouble(SToken *pToken, double *value, char **endPtr) { errno = 0; *value = strtold(pToken->z, endPtr); // not a valid integer number, return error if ((*endPtr - pToken->z) != pToken->n) { return TK_NK_ILLEGAL; } return pToken->type; } static int32_t parseValueToken(char** end, SToken* pToken, SSchema* pSchema, int16_t timePrec, char* tmpTokenBuf, _row_append_fn_t func, void* param, SMsgBuf* pMsgBuf) { int64_t iv; char *endptr = NULL; bool isSigned = false; int32_t code = checkAndTrimValue(pToken, pSchema->type, tmpTokenBuf, pMsgBuf); if (code != TSDB_CODE_SUCCESS) { return code; } if (isNullStr(pToken)) { if (TSDB_DATA_TYPE_TIMESTAMP == pSchema->type && PRIMARYKEY_TIMESTAMP_COL_ID == pSchema->colId) { int64_t tmpVal = 0; return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } return func(pMsgBuf, NULL, 0, param); } switch (pSchema->type) { case TSDB_DATA_TYPE_BOOL: { if ((pToken->type == TK_NK_BOOL || pToken->type == TK_NK_STRING) && (pToken->n != 0)) { if (strncmp(pToken->z, "true", pToken->n) == 0) { return func(pMsgBuf, &TRUE_VALUE, pSchema->bytes, param); } else if (strncmp(pToken->z, "false", pToken->n) == 0) { return func(pMsgBuf, &FALSE_VALUE, pSchema->bytes, param); } else { return buildSyntaxErrMsg(pMsgBuf, "invalid bool data", pToken->z); } } else if (pToken->type == TK_NK_INTEGER) { return func(pMsgBuf, ((strtoll(pToken->z, NULL, 10) == 0) ? &FALSE_VALUE : &TRUE_VALUE), pSchema->bytes, param); } else if (pToken->type == TK_NK_FLOAT) { return func(pMsgBuf, ((strtod(pToken->z, NULL) == 0) ? &FALSE_VALUE : &TRUE_VALUE), pSchema->bytes, param); } else { return buildSyntaxErrMsg(pMsgBuf, "invalid bool data", pToken->z); } } case TSDB_DATA_TYPE_TINYINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid tinyint data", pToken->z); } else if (!IS_VALID_TINYINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "tinyint data overflow", pToken->z); } uint8_t tmpVal = (uint8_t)iv; return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_UTINYINT:{ if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid unsigned tinyint data", pToken->z); } else if (!IS_VALID_UTINYINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "unsigned tinyint data overflow", pToken->z); } uint8_t tmpVal = (uint8_t)iv; return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_SMALLINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid smallint data", pToken->z); } else if (!IS_VALID_SMALLINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "smallint data overflow", pToken->z); } int16_t tmpVal = (int16_t)iv; return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_USMALLINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid unsigned smallint data", pToken->z); } else if (!IS_VALID_USMALLINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "unsigned smallint data overflow", pToken->z); } uint16_t tmpVal = (uint16_t)iv; return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_INT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid int data", pToken->z); } else if (!IS_VALID_INT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "int data overflow", pToken->z); } int32_t tmpVal = (int32_t)iv; return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_UINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid unsigned int data", pToken->z); } else if (!IS_VALID_UINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "unsigned int data overflow", pToken->z); } uint32_t tmpVal = (uint32_t)iv; return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_BIGINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid bigint data", pToken->z); } else if (!IS_VALID_BIGINT(iv)) { return buildSyntaxErrMsg(pMsgBuf, "bigint data overflow", pToken->z); } return func(pMsgBuf, &iv, pSchema->bytes, param); } case TSDB_DATA_TYPE_UBIGINT: { if (TSDB_CODE_SUCCESS != toInteger(pToken->z, pToken->n, 10, &iv, &isSigned)) { return buildSyntaxErrMsg(pMsgBuf, "invalid unsigned bigint data", pToken->z); } else if (!IS_VALID_UBIGINT((uint64_t)iv)) { return buildSyntaxErrMsg(pMsgBuf, "unsigned bigint data overflow", pToken->z); } uint64_t tmpVal = (uint64_t)iv; return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_FLOAT: { double dv; if (TK_NK_ILLEGAL == toDouble(pToken, &dv, &endptr)) { return buildSyntaxErrMsg(pMsgBuf, "illegal float data", pToken->z); } if (((dv == HUGE_VAL || dv == -HUGE_VAL) && errno == ERANGE) || dv > FLT_MAX || dv < -FLT_MAX || isinf(dv) || isnan(dv)) { return buildSyntaxErrMsg(pMsgBuf, "illegal float data", pToken->z); } float tmpVal = (float)dv; return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } case TSDB_DATA_TYPE_DOUBLE: { double dv; if (TK_NK_ILLEGAL == toDouble(pToken, &dv, &endptr)) { return buildSyntaxErrMsg(pMsgBuf, "illegal double data", pToken->z); } if (((dv == HUGE_VAL || dv == -HUGE_VAL) && errno == ERANGE) || isinf(dv) || isnan(dv)) { return buildSyntaxErrMsg(pMsgBuf, "illegal double data", pToken->z); } return func(pMsgBuf, &dv, pSchema->bytes, param); } case TSDB_DATA_TYPE_BINARY: { // Too long values will raise the invalid sql error message if (pToken->n + VARSTR_HEADER_SIZE > pSchema->bytes) { return buildSyntaxErrMsg(pMsgBuf, "string data overflow", pToken->z); } return func(pMsgBuf, pToken->z, pToken->n, param); } case TSDB_DATA_TYPE_NCHAR: { return func(pMsgBuf, pToken->z, pToken->n, param); } case TSDB_DATA_TYPE_TIMESTAMP: { int64_t tmpVal; if (parseTime(end, pToken, timePrec, &tmpVal, pMsgBuf) != TSDB_CODE_SUCCESS) { return buildSyntaxErrMsg(pMsgBuf, "invalid timestamp", pToken->z); } return func(pMsgBuf, &tmpVal, pSchema->bytes, param); } } return TSDB_CODE_FAILED; } typedef struct SMemParam { SRowBuilder* rb; SSchema* schema; int32_t toffset; col_id_t colIdx; } SMemParam; static FORCE_INLINE int32_t MemRowAppend(SMsgBuf* pMsgBuf, const void* value, int32_t len, void* param) { SMemParam* pa = (SMemParam*)param; SRowBuilder* rb = pa->rb; if (value == NULL) { // it is a null data tdAppendColValToRow(rb, pa->schema->colId, pa->schema->type, TD_VTYPE_NULL, value, false, pa->toffset, pa->colIdx); return TSDB_CODE_SUCCESS; } if (TSDB_DATA_TYPE_BINARY == pa->schema->type) { const char* rowEnd = tdRowEnd(rb->pBuf); STR_WITH_SIZE_TO_VARSTR(rowEnd, value, len); tdAppendColValToRow(rb, pa->schema->colId, pa->schema->type, TD_VTYPE_NORM, rowEnd, true, pa->toffset, pa->colIdx); } else if (TSDB_DATA_TYPE_NCHAR == pa->schema->type) { // if the converted output len is over than pColumnModel->bytes, return error: 'Argument list too long' int32_t output = 0; const char* rowEnd = tdRowEnd(rb->pBuf); if (!taosMbsToUcs4(value, len, (TdUcs4*)varDataVal(rowEnd), pa->schema->bytes - VARSTR_HEADER_SIZE, &output)) { char buf[512] = {0}; snprintf(buf, tListLen(buf), "%s", strerror(errno)); return buildSyntaxErrMsg(pMsgBuf, buf, value); } varDataSetLen(rowEnd, output); tdAppendColValToRow(rb, pa->schema->colId, pa->schema->type, TD_VTYPE_NORM, rowEnd, false, pa->toffset, pa->colIdx); } else { tdAppendColValToRow(rb, pa->schema->colId, pa->schema->type, TD_VTYPE_NORM, value, false, pa->toffset, pa->colIdx); } return TSDB_CODE_SUCCESS; } // pSql -> tag1_name, ...) static int32_t parseBoundColumns(SInsertParseContext* pCxt, SParsedDataColInfo* pColList, SSchema* pSchema) { col_id_t nCols = pColList->numOfCols; pColList->numOfBound = 0; pColList->boundNullLen = 0; memset(pColList->boundColumns, 0, sizeof(col_id_t) * nCols); for (col_id_t i = 0; i < nCols; ++i) { pColList->cols[i].valStat = VAL_STAT_NONE; } SToken sToken; bool isOrdered = true; col_id_t lastColIdx = -1; // last column found while (1) { NEXT_TOKEN(pCxt->pSql, sToken); if (TK_NK_RP == sToken.type) { break; } col_id_t t = lastColIdx + 1; col_id_t index = findCol(&sToken, t, nCols, pSchema); if (index < 0 && t > 0) { index = findCol(&sToken, 0, t, pSchema); isOrdered = false; } if (index < 0) { return buildSyntaxErrMsg(&pCxt->msg, "invalid column/tag name", sToken.z); } if (pColList->cols[index].valStat == VAL_STAT_HAS) { return buildSyntaxErrMsg(&pCxt->msg, "duplicated column name", sToken.z); } lastColIdx = index; pColList->cols[index].valStat = VAL_STAT_HAS; pColList->boundColumns[pColList->numOfBound] = index + PRIMARYKEY_TIMESTAMP_COL_ID; ++pColList->numOfBound; switch (pSchema[t].type) { case TSDB_DATA_TYPE_BINARY: pColList->boundNullLen += (sizeof(VarDataOffsetT) + VARSTR_HEADER_SIZE + CHAR_BYTES); break; case TSDB_DATA_TYPE_NCHAR: pColList->boundNullLen += (sizeof(VarDataOffsetT) + VARSTR_HEADER_SIZE + TSDB_NCHAR_SIZE); break; default: pColList->boundNullLen += TYPE_BYTES[pSchema[t].type]; break; } } pColList->orderStatus = isOrdered ? ORDER_STATUS_ORDERED : ORDER_STATUS_DISORDERED; if (!isOrdered) { pColList->colIdxInfo = taosMemoryCalloc(pColList->numOfBound, sizeof(SBoundIdxInfo)); if (NULL == pColList->colIdxInfo) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } SBoundIdxInfo* pColIdx = pColList->colIdxInfo; for (col_id_t i = 0; i < pColList->numOfBound; ++i) { pColIdx[i].schemaColIdx = pColList->boundColumns[i]; pColIdx[i].boundIdx = i; } qsort(pColIdx, pColList->numOfBound, sizeof(SBoundIdxInfo), schemaIdxCompar); for (col_id_t i = 0; i < pColList->numOfBound; ++i) { pColIdx[i].finalIdx = i; } qsort(pColIdx, pColList->numOfBound, sizeof(SBoundIdxInfo), boundIdxCompar); } memset(&pColList->boundColumns[pColList->numOfBound], 0, sizeof(col_id_t) * (pColList->numOfCols - pColList->numOfBound)); return TSDB_CODE_SUCCESS; } typedef struct SKvParam { SKVRowBuilder *builder; SSchema *schema; char buf[TSDB_MAX_TAGS_LEN]; } SKvParam; static int32_t KvRowAppend(SMsgBuf* pMsgBuf, const void *value, int32_t len, void *param) { SKvParam* pa = (SKvParam*) param; int8_t type = pa->schema->type; int16_t colId = pa->schema->colId; if (TSDB_DATA_TYPE_BINARY == type) { STR_WITH_SIZE_TO_VARSTR(pa->buf, value, len); tdAddColToKVRow(pa->builder, colId, type, pa->buf); } else if (TSDB_DATA_TYPE_NCHAR == type) { // if the converted output len is over than pColumnModel->bytes, return error: 'Argument list too long' int32_t output = 0; if (!taosMbsToUcs4(value, len, (TdUcs4*)varDataVal(pa->buf), pa->schema->bytes - VARSTR_HEADER_SIZE, &output)) { char buf[512] = {0}; snprintf(buf, tListLen(buf), "%s", strerror(errno)); return buildSyntaxErrMsg(pMsgBuf, buf, value);; } varDataSetLen(pa->buf, output); tdAddColToKVRow(pa->builder, colId, type, pa->buf); } else { tdAddColToKVRow(pa->builder, colId, type, value); } return TSDB_CODE_SUCCESS; } static int32_t buildCreateTbReq(SInsertParseContext* pCxt, const SName* pName, SKVRow row) { char dbFName[TSDB_DB_FNAME_LEN] = {0}; tNameGetFullDbName(pName, dbFName); pCxt->createTblReq.type = TD_CHILD_TABLE; pCxt->createTblReq.dbFName = strdup(dbFName); pCxt->createTblReq.name = strdup(pName->tname); pCxt->createTblReq.ctbCfg.suid = pCxt->pTableMeta->suid; pCxt->createTblReq.ctbCfg.pTag = row; return TSDB_CODE_SUCCESS; } // pSql -> tag1_value, ...) static int32_t parseTagsClause(SInsertParseContext* pCxt, SSchema* pSchema, uint8_t precision, const SName* pName) { if (tdInitKVRowBuilder(&pCxt->tagsBuilder) < 0) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } SKvParam param = {.builder = &pCxt->tagsBuilder}; SToken sToken; char tmpTokenBuf[TSDB_MAX_BYTES_PER_ROW] = {0}; // used for deleting Escape character: \\, \', \" for (int i = 0; i < pCxt->tags.numOfBound; ++i) { NEXT_TOKEN_WITH_PREV(pCxt->pSql, sToken); SSchema* pTagSchema = &pSchema[pCxt->tags.boundColumns[i] - 1]; // colId starts with 1 param.schema = pTagSchema; CHECK_CODE(parseValueToken(&pCxt->pSql, &sToken, pTagSchema, precision, tmpTokenBuf, KvRowAppend, ¶m, &pCxt->msg)); } SKVRow row = tdGetKVRowFromBuilder(&pCxt->tagsBuilder); if (NULL == row) { return buildInvalidOperationMsg(&pCxt->msg, "tag value expected"); } tdSortKVRowByColIdx(row); return buildCreateTbReq(pCxt, pName, row); } static int32_t cloneTableMeta(STableMeta* pSrc, STableMeta** pDst) { *pDst = taosMemoryMalloc(TABLE_META_SIZE(pSrc)); if (NULL == *pDst) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } memcpy(*pDst, pSrc, TABLE_META_SIZE(pSrc)); return TSDB_CODE_SUCCESS; } static int32_t storeTableMeta(SHashObj* pHash, const char* pName, int32_t len, STableMeta* pMeta) { STableMeta* pBackup = NULL; if (TSDB_CODE_SUCCESS != cloneTableMeta(pMeta, &pBackup)) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } pBackup->uid = tGenIdPI64(); return taosHashPut(pHash, pName, len, &pBackup, POINTER_BYTES); } // pSql -> stb_name [(tag1_name, ...)] TAGS (tag1_value, ...) static int32_t parseUsingClause(SInsertParseContext* pCxt, SToken* pTbnameToken) { SName name; createSName(&name, pTbnameToken, pCxt->pComCxt, &pCxt->msg); char tbFName[TSDB_TABLE_FNAME_LEN]; tNameExtractFullName(&name, tbFName); int32_t len = strlen(tbFName); STableMeta** pMeta = taosHashGet(pCxt->pSubTableHashObj, tbFName, len); if (NULL != pMeta) { return cloneTableMeta(*pMeta, &pCxt->pTableMeta); } SToken sToken; // pSql -> stb_name [(tag1_name, ...)] TAGS (tag1_value, ...) NEXT_TOKEN(pCxt->pSql, sToken); CHECK_CODE(getSTableMeta(pCxt, &sToken)); if (TSDB_SUPER_TABLE != pCxt->pTableMeta->tableType) { return buildInvalidOperationMsg(&pCxt->msg, "create table only from super table is allowed"); } CHECK_CODE(storeTableMeta(pCxt->pSubTableHashObj, tbFName, len, pCxt->pTableMeta)); SSchema* pTagsSchema = getTableTagSchema(pCxt->pTableMeta); setBoundColumnInfo(&pCxt->tags, pTagsSchema, getNumOfTags(pCxt->pTableMeta)); // pSql -> [(tag1_name, ...)] TAGS (tag1_value, ...) NEXT_TOKEN(pCxt->pSql, sToken); if (TK_NK_LP == sToken.type) { CHECK_CODE(parseBoundColumns(pCxt, &pCxt->tags, pTagsSchema)); NEXT_TOKEN(pCxt->pSql, sToken); } if (TK_TAGS != sToken.type) { return buildSyntaxErrMsg(&pCxt->msg, "TAGS is expected", sToken.z); } // pSql -> (tag1_value, ...) NEXT_TOKEN(pCxt->pSql, sToken); if (TK_NK_LP != sToken.type) { return buildSyntaxErrMsg(&pCxt->msg, "( is expected", sToken.z); } CHECK_CODE(parseTagsClause(pCxt, pCxt->pTableMeta->schema, getTableInfo(pCxt->pTableMeta).precision, &name)); NEXT_TOKEN(pCxt->pSql, sToken); if (TK_NK_RP != sToken.type) { return buildSyntaxErrMsg(&pCxt->msg, ") is expected", sToken.z); } return TSDB_CODE_SUCCESS; } static int parseOneRow(SInsertParseContext* pCxt, STableDataBlocks* pDataBlocks, int16_t timePrec, int32_t* len, char* tmpTokenBuf) { SParsedDataColInfo* spd = &pDataBlocks->boundColumnInfo; SRowBuilder* pBuilder = &pDataBlocks->rowBuilder; STSRow* row = (STSRow*)(pDataBlocks->pData + pDataBlocks->size); // skip the SSubmitBlk header tdSRowResetBuf(pBuilder, row); bool isParseBindParam = false; SSchema* schema = getTableColumnSchema(pDataBlocks->pTableMeta); SMemParam param = {.rb = pBuilder}; SToken sToken = {0}; // 1. set the parsed value from sql string for (int i = 0; i < spd->numOfBound; ++i) { NEXT_TOKEN_WITH_PREV(pCxt->pSql, sToken); SSchema* pSchema = &schema[spd->boundColumns[i] - 1]; param.schema = pSchema; getSTSRowAppendInfo(schema, pBuilder->rowType, spd, i, ¶m.toffset, ¶m.colIdx); CHECK_CODE(parseValueToken(&pCxt->pSql, &sToken, pSchema, timePrec, tmpTokenBuf, MemRowAppend, ¶m, &pCxt->msg)); if (PRIMARYKEY_TIMESTAMP_COL_ID == pSchema->colId) { TSKEY tsKey = TD_ROW_KEY(row); if (checkTimestamp(pDataBlocks, (const char *)&tsKey) != TSDB_CODE_SUCCESS) { buildSyntaxErrMsg(&pCxt->msg, "client time/server time can not be mixed up", sToken.z); return TSDB_CODE_TSC_INVALID_TIME_STAMP; } } } if (!isParseBindParam) { // set the null value for the columns that do not assign values if ((spd->numOfBound < spd->numOfCols) && TD_IS_TP_ROW(row)) { for (int32_t i = 0; i < spd->numOfCols; ++i) { if (spd->cols[i].valStat == VAL_STAT_NONE) { // the primary TS key is not VAL_STAT_NONE tdAppendColValToTpRow(pBuilder, TD_VTYPE_NONE, getNullValue(schema[i].type), true, schema[i].type, i, spd->cols[i].toffset); } } } } // *len = pBuilder->extendedRowSize; return TSDB_CODE_SUCCESS; } // pSql -> (field1_value, ...) [(field1_value2, ...) ...] static int32_t parseValues(SInsertParseContext* pCxt, STableDataBlocks* pDataBlock, int maxRows, int32_t* numOfRows) { STableComInfo tinfo = getTableInfo(pDataBlock->pTableMeta); int32_t extendedRowSize = getExtendedRowSize(pDataBlock); CHECK_CODE(initRowBuilder(&pDataBlock->rowBuilder, pDataBlock->pTableMeta->sversion, &pDataBlock->boundColumnInfo)); (*numOfRows) = 0; char tmpTokenBuf[TSDB_MAX_BYTES_PER_ROW] = {0}; // used for deleting Escape character: \\, \', \" SToken sToken; while (1) { int32_t index = 0; NEXT_TOKEN_KEEP_SQL(pCxt->pSql, sToken, index); if (TK_NK_LP != sToken.type) { break; } pCxt->pSql += index; if ((*numOfRows) >= maxRows || pDataBlock->size + extendedRowSize >= pDataBlock->nAllocSize) { int32_t tSize; CHECK_CODE(allocateMemIfNeed(pDataBlock, extendedRowSize, &tSize)); ASSERT(tSize >= maxRows); maxRows = tSize; } int32_t len = 0; CHECK_CODE(parseOneRow(pCxt, pDataBlock, tinfo.precision, &len, tmpTokenBuf)); pDataBlock->size += extendedRowSize; //len; NEXT_TOKEN(pCxt->pSql, sToken); if (TK_NK_RP != sToken.type) { return buildSyntaxErrMsg(&pCxt->msg, ") expected", sToken.z); } (*numOfRows)++; } if (0 == (*numOfRows)) { return buildSyntaxErrMsg(&pCxt->msg, "no any data points", NULL); } return TSDB_CODE_SUCCESS; } static int32_t parseValuesClause(SInsertParseContext* pCxt, STableDataBlocks* dataBuf) { int32_t maxNumOfRows; CHECK_CODE(allocateMemIfNeed(dataBuf, getExtendedRowSize(dataBuf), &maxNumOfRows)); int32_t numOfRows = 0; CHECK_CODE(parseValues(pCxt, dataBuf, maxNumOfRows, &numOfRows)); SSubmitBlk *pBlocks = (SSubmitBlk *)(dataBuf->pData); if (TSDB_CODE_SUCCESS != setBlockInfo(pBlocks, dataBuf, numOfRows)) { return buildInvalidOperationMsg(&pCxt->msg, "too many rows in sql, total number of rows should be less than 32767"); } dataBuf->numOfTables = 1; pCxt->totalNum += numOfRows; return TSDB_CODE_SUCCESS; } static void destroyCreateSubTbReq(SVCreateTbReq* pReq) { taosMemoryFreeClear(pReq->dbFName); taosMemoryFreeClear(pReq->name); taosMemoryFreeClear(pReq->ctbCfg.pTag); } static void destroyInsertParseContextForTable(SInsertParseContext* pCxt) { taosMemoryFreeClear(pCxt->pTableMeta); destroyBoundColumnInfo(&pCxt->tags); tdDestroyKVRowBuilder(&pCxt->tagsBuilder); destroyCreateSubTbReq(&pCxt->createTblReq); } static void destroyDataBlock(STableDataBlocks* pDataBlock) { if (pDataBlock == NULL) { return; } taosMemoryFreeClear(pDataBlock->pData); if (!pDataBlock->cloned) { // free the refcount for metermeta if (pDataBlock->pTableMeta != NULL) { taosMemoryFreeClear(pDataBlock->pTableMeta); } destroyBoundColumnInfo(&pDataBlock->boundColumnInfo); } taosMemoryFreeClear(pDataBlock); } static void destroyInsertParseContext(SInsertParseContext* pCxt) { destroyInsertParseContextForTable(pCxt); taosHashCleanup(pCxt->pVgroupsHashObj); destroyBlockHashmap(pCxt->pTableBlockHashObj); destroyBlockArrayList(pCxt->pTableDataBlocks); destroyBlockArrayList(pCxt->pVgDataBlocks); } // tb_name // [USING stb_name [(tag1_name, ...)] TAGS (tag1_value, ...)] // [(field1_name, ...)] // VALUES (field1_value, ...) [(field1_value2, ...) ...] | FILE csv_file_path // [...]; static int32_t parseInsertBody(SInsertParseContext* pCxt) { // for each table while (1) { destroyInsertParseContextForTable(pCxt); SToken sToken; // pSql -> tb_name ... NEXT_TOKEN(pCxt->pSql, sToken); // no data in the sql string anymore. if (sToken.n == 0) { if (0 == pCxt->totalNum) { return buildInvalidOperationMsg(&pCxt->msg, "no data in sql");; } break; } SToken tbnameToken = sToken; NEXT_TOKEN(pCxt->pSql, sToken); // USING cluase if (TK_USING == sToken.type) { CHECK_CODE(parseUsingClause(pCxt, &tbnameToken)); NEXT_TOKEN(pCxt->pSql, sToken); } else { CHECK_CODE(getTableMeta(pCxt, &tbnameToken)); } STableDataBlocks *dataBuf = NULL; CHECK_CODE(getDataBlockFromList(pCxt->pTableBlockHashObj, pCxt->pTableMeta->uid, TSDB_DEFAULT_PAYLOAD_SIZE, sizeof(SSubmitBlk), getTableInfo(pCxt->pTableMeta).rowSize, pCxt->pTableMeta, &dataBuf, NULL, &pCxt->createTblReq)); if (TK_NK_LP == sToken.type) { // pSql -> field1_name, ...) CHECK_CODE(parseBoundColumns(pCxt, &dataBuf->boundColumnInfo, getTableColumnSchema(pCxt->pTableMeta))); NEXT_TOKEN(pCxt->pSql, sToken); } if (TK_VALUES == sToken.type) { // pSql -> (field1_value, ...) [(field1_value2, ...) ...] CHECK_CODE(parseValuesClause(pCxt, dataBuf)); pCxt->pOutput->insertType = TSDB_QUERY_TYPE_INSERT; continue; } // FILE csv_file_path if (TK_NK_FILE == sToken.type) { // pSql -> csv_file_path NEXT_TOKEN(pCxt->pSql, sToken); if (0 == sToken.n || (TK_NK_STRING != sToken.type && TK_NK_ID != sToken.type)) { return buildSyntaxErrMsg(&pCxt->msg, "file path is required following keyword FILE", sToken.z); } // todo pCxt->pOutput->insertType = TSDB_QUERY_TYPE_FILE_INSERT; continue; } return buildSyntaxErrMsg(&pCxt->msg, "keyword VALUES or FILE is expected", sToken.z); } // merge according to vgId if (!TSDB_QUERY_HAS_TYPE(pCxt->pOutput->insertType, TSDB_QUERY_TYPE_STMT_INSERT) && taosHashGetSize(pCxt->pTableBlockHashObj) > 0) { CHECK_CODE(mergeTableDataBlocks(pCxt->pTableBlockHashObj, pCxt->pOutput->payloadType, &pCxt->pVgDataBlocks)); } return buildOutput(pCxt); } // INSERT INTO // tb_name // [USING stb_name [(tag1_name, ...)] TAGS (tag1_value, ...)] // [(field1_name, ...)] // VALUES (field1_value, ...) [(field1_value2, ...) ...] | FILE csv_file_path // [...]; int32_t parseInsertSql(SParseContext* pContext, SQuery** pQuery) { SInsertParseContext context = { .pComCxt = pContext, .pSql = (char*) pContext->pSql, .msg = {.buf = pContext->pMsg, .len = pContext->msgLen}, .pTableMeta = NULL, .pVgroupsHashObj = taosHashInit(128, taosGetDefaultHashFunction(TSDB_DATA_TYPE_INT), true, false), .pTableBlockHashObj = taosHashInit(128, taosGetDefaultHashFunction(TSDB_DATA_TYPE_BIGINT), true, false), .pSubTableHashObj = taosHashInit(128, taosGetDefaultHashFunction(TSDB_DATA_TYPE_VARCHAR), true, false), .totalNum = 0, .pOutput = (SVnodeModifOpStmt*)nodesMakeNode(QUERY_NODE_VNODE_MODIF_STMT) }; if (NULL == context.pVgroupsHashObj || NULL == context.pTableBlockHashObj || NULL == context.pSubTableHashObj || NULL == context.pOutput) { return TSDB_CODE_TSC_OUT_OF_MEMORY; } *pQuery = taosMemoryCalloc(1, sizeof(SQuery)); if (NULL == *pQuery) { return TSDB_CODE_OUT_OF_MEMORY; } (*pQuery)->execMode = QUERY_EXEC_MODE_SCHEDULE; (*pQuery)->haveResultSet = false; (*pQuery)->msgType = TDMT_VND_SUBMIT; (*pQuery)->pRoot = (SNode*)context.pOutput; context.pOutput->payloadType = PAYLOAD_TYPE_KV; int32_t code = skipInsertInto(&context); if (TSDB_CODE_SUCCESS == code) { code = parseInsertBody(&context); } destroyInsertParseContext(&context); return code; }