/* * 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 #include #include "cmdnodes.h" #include "parser.h" #include "planInt.h" using namespace std; using namespace testing; class PlannerTest : public Test { protected: void setDatabase(const string& acctId, const string& db) { acctId_ = acctId; db_ = db; } void bind(const char* sql) { reset(); cxt_.acctId = atoi(acctId_.c_str()); cxt_.db = db_.c_str(); sqlBuf_ = string(sql); transform(sqlBuf_.begin(), sqlBuf_.end(), sqlBuf_.begin(), ::tolower); cxt_.sqlLen = strlen(sql); cxt_.pSql = sqlBuf_.c_str(); } bool run(bool streamQuery = false) { int32_t code = qParseQuerySql(&cxt_, &query_); if (code != TSDB_CODE_SUCCESS) { cout << "sql:[" << cxt_.pSql << "] qParseQuerySql code:" << code << ", strerror:" << tstrerror(code) << ", msg:" << errMagBuf_ << endl; return false; } const string syntaxTreeStr = toString(query_->pRoot, false); SLogicNode* pLogicNode = nullptr; SPlanContext cxt = {0}; cxt.queryId = 1; cxt.acctId = 0; cxt.streamQuery = streamQuery; setPlanContext(query_, &cxt); code = createLogicPlan(&cxt, &pLogicNode); if (code != TSDB_CODE_SUCCESS) { cout << "sql:[" << cxt_.pSql << "] createLogicPlan code:" << code << ", strerror:" << tstrerror(code) << endl; return false; } cout << "====================sql : [" << cxt_.pSql << "]" << endl; cout << "syntax tree : " << endl; cout << syntaxTreeStr << endl; cout << "unformatted logic plan : " << endl; cout << toString((const SNode*)pLogicNode, false) << endl; code = optimizeLogicPlan(&cxt, pLogicNode); if (code != TSDB_CODE_SUCCESS) { cout << "sql:[" << cxt_.pSql << "] optimizeLogicPlan code:" << code << ", strerror:" << tstrerror(code) << endl; return false; } SLogicSubplan* pLogicSubplan = nullptr; code = splitLogicPlan(&cxt, pLogicNode, &pLogicSubplan); if (code != TSDB_CODE_SUCCESS) { cout << "sql:[" << cxt_.pSql << "] splitLogicPlan code:" << code << ", strerror:" << tstrerror(code) << endl; return false; } SQueryLogicPlan* pLogicPlan = NULL; code = scaleOutLogicPlan(&cxt, pLogicSubplan, &pLogicPlan); if (code != TSDB_CODE_SUCCESS) { cout << "sql:[" << cxt_.pSql << "] createPhysiPlan code:" << code << ", strerror:" << tstrerror(code) << endl; return false; } SQueryPlan* pPlan = nullptr; code = createPhysiPlan(&cxt, pLogicPlan, &pPlan, NULL); if (code != TSDB_CODE_SUCCESS) { cout << "sql:[" << cxt_.pSql << "] createPhysiPlan code:" << code << ", strerror:" << tstrerror(code) << endl; return false; } cout << "unformatted physical plan : " << endl; cout << toString((const SNode*)pPlan, false) << endl; SNode* pNode; FOREACH(pNode, pPlan->pSubplans) { SNode* pSubplan; FOREACH(pSubplan, ((SNodeListNode*)pNode)->pNodeList) { cout << "unformatted physical subplan : " << endl; cout << toString(pSubplan, false) << endl; } } return true; } private: static const int max_err_len = 1024; void setPlanContext(SQuery* pQuery, SPlanContext* pCxt) { if (QUERY_NODE_CREATE_TOPIC_STMT == nodeType(pQuery->pRoot)) { pCxt->pAstRoot = ((SCreateTopicStmt*)pQuery->pRoot)->pQuery; pCxt->topicQuery = true; } else if (QUERY_NODE_CREATE_INDEX_STMT == nodeType(pQuery->pRoot)) { SMCreateSmaReq req = {0}; tDeserializeSMCreateSmaReq(pQuery->pCmdMsg->pMsg, pQuery->pCmdMsg->msgLen, &req); nodesStringToNode(req.ast, &pCxt->pAstRoot); pCxt->streamQuery = true; } else if (QUERY_NODE_CREATE_STREAM_STMT == nodeType(pQuery->pRoot)) { SCreateStreamStmt* pStmt = (SCreateStreamStmt*)pQuery->pRoot; pCxt->pAstRoot = pStmt->pQuery; pCxt->streamQuery = true; pCxt->triggerType = pStmt->pOptions->triggerType; pCxt->watermark = (NULL != pStmt->pOptions->pWatermark ? ((SValueNode*)pStmt->pOptions->pWatermark)->datum.i : 0); } else { pCxt->pAstRoot = pQuery->pRoot; } } void reset() { memset(&cxt_, 0, sizeof(cxt_)); memset(errMagBuf_, 0, max_err_len); cxt_.pMsg = errMagBuf_; cxt_.msgLen = max_err_len; } string toString(const SNode* pRoot, bool format = true) { char* pStr = NULL; int32_t len = 0; int32_t code = nodesNodeToString(pRoot, format, &pStr, &len); if (code != TSDB_CODE_SUCCESS) { cout << "sql:[" << cxt_.pSql << "] toString code:" << code << ", strerror:" << tstrerror(code) << endl; return string(); } string str(pStr); taosMemoryFreeClear(pStr); return str; } string acctId_; string db_; char errMagBuf_[max_err_len]; string sqlBuf_; SParseContext cxt_; SQuery* query_; }; TEST_F(PlannerTest, selectBasic) { setDatabase("root", "test"); bind("SELECT * FROM t1"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectConstant) { setDatabase("root", "test"); bind("SELECT 2-1 FROM t1"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectStableBasic) { setDatabase("root", "test"); bind("SELECT * FROM st1"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectJoin) { setDatabase("root", "test"); bind("SELECT t1.c1, t2.c2 FROM st1s1 t1, st1s2 t2 where t1.ts = t2.ts"); ASSERT_TRUE(run()); bind("SELECT t1.*, t2.* FROM st1s1 t1, st1s2 t2 where t1.ts = t2.ts"); ASSERT_TRUE(run()); bind("SELECT t1.c1, t2.c1 FROM st1s1 t1 join st1s2 t2 on t1.ts = t2.ts where t1.c1 > t2.c1 and t1.c2 = 'abc' and t2.c2 = 'qwe'"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectGroupBy) { setDatabase("root", "test"); bind("SELECT count(*) FROM t1"); ASSERT_TRUE(run()); bind("SELECT c1, max(c3), min(c3), count(*) FROM t1 GROUP BY c1"); ASSERT_TRUE(run()); bind("SELECT c1 + c3, c1 + count(*) FROM t1 where c2 = 'abc' GROUP BY c1, c3"); ASSERT_TRUE(run()); bind("SELECT c1 + c3, sum(c4 * c5) FROM t1 where concat(c2, 'wwww') = 'abcwww' GROUP BY c1 + c3"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectSubquery) { setDatabase("root", "test"); bind("SELECT count(*) FROM (SELECT c1 + c3 a, c1 + count(*) b FROM t1 where c2 = 'abc' GROUP BY c1, c3) where a > 100 group by b"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectInterval) { setDatabase("root", "test"); bind("SELECT count(*) FROM t1 interval(10s)"); ASSERT_TRUE(run()); bind("SELECT _wstartts, _wduration, _wendts, count(*) FROM t1 interval(10s)"); ASSERT_TRUE(run()); bind("SELECT count(*) FROM t1 interval(10s) fill(linear)"); ASSERT_TRUE(run()); bind("SELECT count(*), sum(c1) FROM t1 interval(10s) fill(value, 10, 20)"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectSessionWindow) { setDatabase("root", "test"); bind("SELECT count(*) FROM t1 session(ts, 10s)"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectStateWindow) { setDatabase("root", "test"); bind("SELECT count(*) FROM t1 state_window(c1)"); ASSERT_TRUE(run()); bind("SELECT count(*) FROM t1 state_window(c1 + 10)"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectPartitionBy) { setDatabase("root", "test"); bind("SELECT * FROM t1 partition by c1"); ASSERT_TRUE(run()); bind("SELECT count(*) FROM t1 partition by c1"); ASSERT_TRUE(run()); bind("SELECT count(*) FROM t1 partition by c1 group by c2"); ASSERT_TRUE(run()); bind("SELECT count(*) FROM st1 partition by tag1, tag2 interval(10s)"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectOrderBy) { setDatabase("root", "test"); bind("SELECT c1 FROM t1 order by c1"); ASSERT_TRUE(run()); bind("SELECT c1 FROM t1 order by c2"); ASSERT_TRUE(run()); bind("SELECT * FROM t1 order by c1 + 10, c2"); ASSERT_TRUE(run()); bind("SELECT * FROM t1 order by c1 desc nulls first"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectGroupByOrderBy) { setDatabase("root", "test"); bind("select count(*), sum(c1) from t1 order by sum(c1)"); ASSERT_TRUE(run()); bind("select count(*), sum(c1) a from t1 order by a"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectDistinct) { setDatabase("root", "test"); bind("SELECT distinct c1 FROM t1"); ASSERT_TRUE(run()); bind("SELECT distinct c1, c2 + 10 FROM t1"); ASSERT_TRUE(run()); bind("SELECT distinct c1 + 10 a FROM t1 order by a"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectLimit) { setDatabase("root", "test"); bind("SELECT * FROM t1 limit 2"); ASSERT_TRUE(run()); bind("SELECT * FROM t1 limit 5 offset 2"); ASSERT_TRUE(run()); bind("SELECT * FROM t1 limit 2, 5"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, selectSlimit) { setDatabase("root", "test"); bind("SELECT * FROM t1 partition by c1 slimit 2"); ASSERT_TRUE(run()); bind("SELECT * FROM t1 partition by c1 slimit 5 soffset 2"); ASSERT_TRUE(run()); bind("SELECT * FROM t1 partition by c1 slimit 2, 5"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, showTables) { setDatabase("root", "test"); bind("show tables"); ASSERT_TRUE(run()); setDatabase("root", "information_schema"); bind("show tables"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, showStables) { setDatabase("root", "test"); bind("show stables"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, createTopic) { setDatabase("root", "test"); bind("create topic tp as SELECT * FROM st1"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, createStream) { setDatabase("root", "test"); bind("create stream if not exists s1 trigger window_close watermark 10s into st1 as select count(*) from t1 interval(10s)"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, createSmaIndex) { setDatabase("root", "test"); bind("create sma index index1 on t1 function(max(c1), min(c3 + 10), sum(c4)) INTERVAL(10s)"); ASSERT_TRUE(run()); } TEST_F(PlannerTest, explain) { setDatabase("root", "test"); bind("explain SELECT * FROM t1"); ASSERT_TRUE(run()); bind("explain analyze SELECT * FROM t1"); ASSERT_TRUE(run()); bind("explain analyze verbose true ratio 0.01 SELECT * FROM t1"); ASSERT_TRUE(run()); }