#include #include "syncTest.h" void logTest() { sTrace("--- sync log test: trace"); sDebug("--- sync log test: debug"); sInfo("--- sync log test: info"); sWarn("--- sync log test: warn"); sError("--- sync log test: error"); sFatal("--- sync log test: fatal"); } uint16_t gPorts[] = {7010, 7110, 7210, 7310, 7410}; const char* gDir = "./syncReplicateTest"; int32_t gVgId = 1234; SyncIndex gSnapshotLastApplyIndex; void init() { int code = walInit(); assert(code == 0); code = syncInit(); assert(code == 0); sprintf(tsTempDir, "%s", "."); } void cleanup() { walCleanUp(); } void CommitCb(const struct SSyncFSM* pFsm, const SRpcMsg* pMsg, const SFsmCbMeta cbMeta) { SyncIndex beginIndex = SYNC_INDEX_INVALID; if (pFsm->FpGetSnapshotInfo != NULL) { SSnapshot snapshot; pFsm->FpGetSnapshotInfo(pFsm, &snapshot); beginIndex = snapshot.lastApplyIndex; } if (cbMeta.index > beginIndex) { char logBuf[256] = {0}; snprintf(logBuf, sizeof(logBuf), "==callback== ==CommitCb== pFsm:%p, index:%" PRId64 ", isWeak:%d, code:%d, state:%d %s flag:%" PRIu64 "\n", pFsm, cbMeta.index, cbMeta.isWeak, cbMeta.code, cbMeta.state, syncStr(cbMeta.state), cbMeta.flag); syncRpcMsgLog2(logBuf, (SRpcMsg*)pMsg); } else { sTrace("==callback== ==CommitCb== do not apply again %" PRId64, cbMeta.index); } } void PreCommitCb(const struct SSyncFSM* pFsm, const SRpcMsg* pMsg, SFsmCbMeta cbMeta) { char logBuf[256] = {0}; snprintf(logBuf, sizeof(logBuf), "==callback== ==PreCommitCb== pFsm:%p, index:%" PRId64 ", isWeak:%d, code:%d, state:%d %s flag:%" PRIu64 "\n", pFsm, cbMeta.index, cbMeta.isWeak, cbMeta.code, cbMeta.state, syncStr(cbMeta.state), cbMeta.flag); syncRpcMsgLog2(logBuf, (SRpcMsg*)pMsg); } void RollBackCb(const struct SSyncFSM* pFsm, const SRpcMsg* pMsg, SFsmCbMeta cbMeta) { char logBuf[256]; snprintf(logBuf, sizeof(logBuf), "==callback== ==RollBackCb== pFsm:%p, index:%" PRId64 ", isWeak:%d, code:%d, state:%d %s flag:%" PRIu64 "\n", pFsm, cbMeta.index, cbMeta.isWeak, cbMeta.code, cbMeta.state, syncStr(cbMeta.state), cbMeta.flag); syncRpcMsgLog2(logBuf, (SRpcMsg*)pMsg); } int32_t GetSnapshotCb(const struct SSyncFSM* pFsm, SSnapshot* pSnapshot) { pSnapshot->data = NULL; pSnapshot->lastApplyIndex = gSnapshotLastApplyIndex; pSnapshot->lastApplyTerm = 100; return 0; } void RestoreFinishCb(struct SSyncFSM* pFsm) { sTrace("==callback== ==RestoreFinishCb=="); } void ReConfigCb(struct SSyncFSM* pFsm, const SRpcMsg* pMsg, SReConfigCbMeta* cbMeta) { sTrace("==callback== ==ReConfigCb== flag:%" PRIx64 ", index:%" PRId64 ", code:%d, currentTerm:%" PRIu64 ", term:%" PRIu64, cbMeta->flag, cbMeta->index, cbMeta->code, cbMeta->currentTerm, cbMeta->term); } SSyncFSM* createFsm() { SSyncFSM* pFsm = (SSyncFSM*)taosMemoryMalloc(sizeof(SSyncFSM)); memset(pFsm, 0, sizeof(*pFsm)); #if 0 pFsm->FpCommitCb = CommitCb; pFsm->FpPreCommitCb = PreCommitCb; pFsm->FpRollBackCb = RollBackCb; pFsm->FpGetSnapshotInfo = GetSnapshotCb; pFsm->FpRestoreFinishCb = RestoreFinishCb; pFsm->FpReConfigCb = ReConfigCb; #endif return pFsm; } SWal* createWal(char* path, int32_t vgId) { SWalCfg walCfg; memset(&walCfg, 0, sizeof(SWalCfg)); walCfg.vgId = vgId; walCfg.fsyncPeriod = 1000; walCfg.retentionPeriod = 1000; walCfg.rollPeriod = 1000; walCfg.retentionSize = 1000; walCfg.segSize = 1000; walCfg.level = TAOS_WAL_FSYNC; SWal* pWal = walOpen(path, &walCfg); assert(pWal != NULL); return pWal; } int64_t createSyncNode(int32_t replicaNum, int32_t myIndex, int32_t vgId, SWal* pWal, char* path, bool isStandBy) { SSyncInfo syncInfo; syncInfo.vgId = vgId; syncInfo.msgcb = &gSyncIO->msgcb; syncInfo.syncSendMSg = syncIOSendMsg; syncInfo.syncEqMsg = syncIOEqMsg; syncInfo.pFsm = createFsm(); snprintf(syncInfo.path, sizeof(syncInfo.path), "%s_sync_replica%d_index%d", path, replicaNum, myIndex); syncInfo.pWal = pWal; syncInfo.isStandBy = isStandBy; SSyncCfg* pCfg = &syncInfo.syncCfg; if (isStandBy) { pCfg->myIndex = 0; pCfg->replicaNum = 1; pCfg->nodeInfo[0].nodePort = gPorts[myIndex]; taosGetFqdn(pCfg->nodeInfo[0].nodeFqdn); } else { pCfg->myIndex = myIndex; pCfg->replicaNum = replicaNum; for (int i = 0; i < replicaNum; ++i) { pCfg->nodeInfo[i].nodePort = gPorts[i]; taosGetFqdn(pCfg->nodeInfo[i].nodeFqdn); // snprintf(pCfg->nodeInfo[i].nodeFqdn, sizeof(pCfg->nodeInfo[i].nodeFqdn), "%s", "127.0.0.1"); } } int64_t rid = syncOpen(&syncInfo); assert(rid > 0); SSyncNode* pSyncNode = (SSyncNode*)syncNodeAcquire(rid); assert(pSyncNode != NULL); // gSyncIO->FpOnSyncPing = pSyncNode->FpOnPing; // gSyncIO->FpOnSyncPingReply = pSyncNode->FpOnPingReply; // gSyncIO->FpOnSyncRequestVote = pSyncNode->FpOnRequestVote; // gSyncIO->FpOnSyncRequestVoteReply = pSyncNode->FpOnRequestVoteReply; // gSyncIO->FpOnSyncAppendEntries = pSyncNode->FpOnAppendEntries; // gSyncIO->FpOnSyncAppendEntriesReply = pSyncNode->FpOnAppendEntriesReply; // gSyncIO->FpOnSyncPing = pSyncNode->FpOnPing; // gSyncIO->FpOnSyncPingReply = pSyncNode->FpOnPingReply; // gSyncIO->FpOnSyncTimeout = pSyncNode->FpOnTimeout; // gSyncIO->FpOnSyncClientRequest = pSyncNode->FpOnClientRequest; gSyncIO->pSyncNode = pSyncNode; syncNodeRelease(pSyncNode); return rid; } void configChange(int64_t rid, int32_t replicaNum, int32_t myIndex) { SSyncCfg syncCfg; syncCfg.myIndex = myIndex; syncCfg.replicaNum = replicaNum; for (int i = 0; i < replicaNum; ++i) { syncCfg.nodeInfo[i].nodePort = gPorts[i]; taosGetFqdn(syncCfg.nodeInfo[i].nodeFqdn); } syncReconfig(rid, &syncCfg); } void usage(char* exe) { printf("usage: %s replicaNum myIndex lastApplyIndex writeRecordNum isStandBy isConfigChange \n", exe); } SRpcMsg* createRpcMsg(int i, int count, int myIndex) { SRpcMsg* pMsg = (SRpcMsg*)taosMemoryMalloc(sizeof(SRpcMsg)); memset(pMsg, 0, sizeof(SRpcMsg)); pMsg->msgType = 9999; pMsg->contLen = 256; pMsg->pCont = rpcMallocCont(pMsg->contLen); snprintf((char*)(pMsg->pCont), pMsg->contLen, "value-myIndex:%u-%d-%d-%" PRId64, myIndex, i, count, taosGetTimestampMs()); return pMsg; } int main(int argc, char** argv) { tsAsyncLog = 0; sDebugFlag = DEBUG_TRACE + DEBUG_SCREEN + DEBUG_FILE + DEBUG_INFO; if (argc != 7) { usage(argv[0]); exit(-1); } int32_t replicaNum = atoi(argv[1]); int32_t myIndex = atoi(argv[2]); int32_t lastApplyIndex = atoi(argv[3]); int32_t writeRecordNum = atoi(argv[4]); bool isStandBy = atoi(argv[5]); bool isConfigChange = atoi(argv[6]); gSnapshotLastApplyIndex = lastApplyIndex; if (!isStandBy) { assert(replicaNum >= 1 && replicaNum <= 5); assert(myIndex >= 0 && myIndex < replicaNum); assert(lastApplyIndex >= -1); assert(writeRecordNum >= 0); } init(); int32_t ret = syncIOStart((char*)"127.0.0.1", gPorts[myIndex]); assert(ret == 0); char walPath[128]; snprintf(walPath, sizeof(walPath), "%s_wal_replica%d_index%d", gDir, replicaNum, myIndex); SWal* pWal = createWal(walPath, gVgId); int64_t rid = createSyncNode(replicaNum, myIndex, gVgId, pWal, (char*)gDir, isStandBy); assert(rid > 0); syncStart(rid); /* if (isStandBy) { syncStartStandBy(rid); } else { syncStart(rid); } */ SSyncNode* pSyncNode = (SSyncNode*)syncNodeAcquire(rid); assert(pSyncNode != NULL); if (isConfigChange) { configChange(rid, 2, myIndex); } //--------------------------- int32_t alreadySend = 0; while (1) { char* s = syncNode2SimpleStr(pSyncNode); if (alreadySend < writeRecordNum) { SRpcMsg* pRpcMsg = createRpcMsg(alreadySend, writeRecordNum, myIndex); int32_t ret = syncPropose(rid, pRpcMsg, false); if (ret == -1 && terrno == TSDB_CODE_SYN_NOT_LEADER) { sTrace("%s value%d write not leader", s, alreadySend); } else { assert(ret == 0); sTrace("%s value%d write ok", s, alreadySend); } alreadySend++; rpcFreeCont(pRpcMsg->pCont); taosMemoryFree(pRpcMsg); } else { sTrace("%s", s); } taosMsleep(1000); taosMemoryFree(s); taosMsleep(1000); } syncNodeRelease(pSyncNode); syncStop(rid); walClose(pWal); syncIOStop(); cleanup(); return 0; }