/* Copyright 2016 GitHub Inc. See https://github.com/github/gh-ost/blob/master/LICENSE */ package logic import ( "fmt" "io" "math" "os" "strings" "sync/atomic" "time" "github.com/github/gh-ost/go/base" "github.com/github/gh-ost/go/binlog" "github.com/github/gh-ost/go/mysql" "github.com/github/gh-ost/go/sql" "github.com/outbrain/golib/log" ) type ChangelogState string const ( GhostTableMigrated ChangelogState = "GhostTableMigrated" AllEventsUpToLockProcessed = "AllEventsUpToLockProcessed" ) func ReadChangelogState(s string) ChangelogState { return ChangelogState(strings.Split(s, ":")[0]) } type tableWriteFunc func() error type applyEventStruct struct { writeFunc *tableWriteFunc dmlEvent *binlog.BinlogDMLEvent } func newApplyEventStructByFunc(writeFunc *tableWriteFunc) *applyEventStruct { result := &applyEventStruct{writeFunc: writeFunc} return result } func newApplyEventStructByDML(dmlEvent *binlog.BinlogDMLEvent) *applyEventStruct { result := &applyEventStruct{dmlEvent: dmlEvent} return result } type PrintStatusRule int const ( NoPrintStatusRule PrintStatusRule = iota HeuristicPrintStatusRule = iota ForcePrintStatusRule = iota ForcePrintStatusOnlyRule = iota ForcePrintStatusAndHintRule = iota ) // Migrator is the main schema migration flow manager. type Migrator struct { parser *sql.Parser inspector *Inspector applier *Applier eventsStreamer *EventsStreamer server *Server throttler *Throttler hooksExecutor *HooksExecutor migrationContext *base.MigrationContext firstThrottlingCollected chan bool ghostTableMigrated chan bool rowCopyComplete chan error allEventsUpToLockProcessed chan string rowCopyCompleteFlag int64 // copyRowsQueue should not be buffered; if buffered some non-damaging but // excessive work happens at the end of the iteration as new copy-jobs arrive befroe realizing the copy is complete copyRowsQueue chan tableWriteFunc applyEventsQueue chan *applyEventStruct handledChangelogStates map[string]bool finishedMigrating int64 } func NewMigrator(context *base.MigrationContext) *Migrator { migrator := &Migrator{ migrationContext: context, parser: sql.NewParser(), ghostTableMigrated: make(chan bool), firstThrottlingCollected: make(chan bool, 3), rowCopyComplete: make(chan error), allEventsUpToLockProcessed: make(chan string), copyRowsQueue: make(chan tableWriteFunc), applyEventsQueue: make(chan *applyEventStruct, base.MaxEventsBatchSize), handledChangelogStates: make(map[string]bool), finishedMigrating: 0, } return migrator } // initiateHooksExecutor func (this *Migrator) initiateHooksExecutor() (err error) { this.hooksExecutor = NewHooksExecutor(this.migrationContext) if err := this.hooksExecutor.initHooks(); err != nil { return err } return nil } // sleepWhileTrue sleeps indefinitely until the given function returns 'false' // (or fails with error) func (this *Migrator) sleepWhileTrue(operation func() (bool, error)) error { for { shouldSleep, err := operation() if err != nil { return err } if !shouldSleep { return nil } time.Sleep(time.Second) } } // retryOperation attempts up to `count` attempts at running given function, // exiting as soon as it returns with non-error. func (this *Migrator) retryOperation(operation func() error, notFatalHint ...bool) (err error) { maxRetries := int(this.migrationContext.MaxRetries()) for i := 0; i < maxRetries; i++ { if i != 0 { // sleep after previous iteration time.Sleep(1 * time.Second) } err = operation() if err == nil { return nil } // there's an error. Let's try again. } if len(notFatalHint) == 0 { this.migrationContext.PanicAbort <- err } return err } // executeAndThrottleOnError executes a given function. If it errors, it // throttles. func (this *Migrator) executeAndThrottleOnError(operation func() error) (err error) { if err := operation(); err != nil { this.throttler.throttle(nil) return err } return nil } // consumeRowCopyComplete blocks on the rowCopyComplete channel once, and then // consumes and drops any further incoming events that may be left hanging. func (this *Migrator) consumeRowCopyComplete() { if err := <-this.rowCopyComplete; err != nil { this.migrationContext.PanicAbort <- err } atomic.StoreInt64(&this.rowCopyCompleteFlag, 1) this.migrationContext.MarkRowCopyEndTime() go func() { for err := range this.rowCopyComplete { if err != nil { this.migrationContext.PanicAbort <- err } } }() } func (this *Migrator) canStopStreaming() bool { return atomic.LoadInt64(&this.migrationContext.CutOverCompleteFlag) != 0 } // onChangelogStateEvent is called when a binlog event operation on the changelog table is intercepted. func (this *Migrator) onChangelogStateEvent(dmlEvent *binlog.BinlogDMLEvent) (err error) { // Hey, I created the changelog table, I know the type of columns it has! if hint := dmlEvent.NewColumnValues.StringColumn(2); hint != "state" { return nil } changelogStateString := dmlEvent.NewColumnValues.StringColumn(3) changelogState := ReadChangelogState(changelogStateString) log.Infof("Intercepted changelog state %s", changelogState) switch changelogState { case GhostTableMigrated: { this.ghostTableMigrated <- true } case AllEventsUpToLockProcessed: { var applyEventFunc tableWriteFunc = func() error { this.allEventsUpToLockProcessed <- changelogStateString return nil } // at this point we know all events up to lock have been read from the streamer, // because the streamer works sequentially. So those events are either already handled, // or have event functions in applyEventsQueue. // So as not to create a potential deadlock, we write this func to applyEventsQueue // asynchronously, understanding it doesn't really matter. go func() { this.applyEventsQueue <- newApplyEventStructByFunc(&applyEventFunc) }() } default: { return fmt.Errorf("Unknown changelog state: %+v", changelogState) } } log.Infof("Handled changelog state %s", changelogState) return nil } // listenOnPanicAbort aborts on abort request func (this *Migrator) listenOnPanicAbort() { err := <-this.migrationContext.PanicAbort log.Fatale(err) } // validateStatement validates the `alter` statement meets criteria. // At this time this means: // - column renames are approved func (this *Migrator) validateStatement() (err error) { if this.parser.HasNonTrivialRenames() && !this.migrationContext.SkipRenamedColumns { this.migrationContext.ColumnRenameMap = this.parser.GetNonTrivialRenames() if !this.migrationContext.ApproveRenamedColumns { return fmt.Errorf("gh-ost believes the ALTER statement renames columns, as follows: %v; as precaution, you are asked to confirm gh-ost is correct, and provide with `--approve-renamed-columns`, and we're all happy. Or you can skip renamed columns via `--skip-renamed-columns`, in which case column data may be lost", this.parser.GetNonTrivialRenames()) } log.Infof("Alter statement has column(s) renamed. gh-ost finds the following renames: %v; --approve-renamed-columns is given and so migration proceeds.", this.parser.GetNonTrivialRenames()) } this.migrationContext.DroppedColumnsMap = this.parser.DroppedColumnsMap() return nil } func (this *Migrator) countTableRows() (err error) { if !this.migrationContext.CountTableRows { // Not counting; we stay with an estimate return nil } if this.migrationContext.Noop { log.Debugf("Noop operation; not really counting table rows") return nil } countRowsFunc := func() error { if err := this.inspector.CountTableRows(); err != nil { return err } if err := this.hooksExecutor.onRowCountComplete(); err != nil { return err } return nil } if this.migrationContext.ConcurrentCountTableRows { log.Infof("As instructed, counting rows in the background; meanwhile I will use an estimated count, and will update it later on") go countRowsFunc() // and we ignore errors, because this turns to be a background job return nil } return countRowsFunc() } func (this *Migrator) createFlagFiles() (err error) { if this.migrationContext.PostponeCutOverFlagFile != "" { if !base.FileExists(this.migrationContext.PostponeCutOverFlagFile) { if err := base.TouchFile(this.migrationContext.PostponeCutOverFlagFile); err != nil { return log.Errorf("--postpone-cut-over-flag-file indicated by gh-ost is unable to create said file: %s", err.Error()) } log.Infof("Created postpone-cut-over-flag-file: %s", this.migrationContext.PostponeCutOverFlagFile) } } return nil } // Migrate executes the complete migration logic. This is *the* major gh-ost function. func (this *Migrator) Migrate() (err error) { log.Infof("Migrating %s.%s", sql.EscapeName(this.migrationContext.DatabaseName), sql.EscapeName(this.migrationContext.OriginalTableName)) this.migrationContext.StartTime = time.Now() if this.migrationContext.Hostname, err = os.Hostname(); err != nil { return err } go this.listenOnPanicAbort() if err := this.initiateHooksExecutor(); err != nil { return err } if err := this.hooksExecutor.onStartup(); err != nil { return err } if err := this.parser.ParseAlterStatement(this.migrationContext.AlterStatement); err != nil { return err } if err := this.validateStatement(); err != nil { return err } // After this point, we'll need to teardown anything that's been started // so we don't leave things hanging around defer this.teardown() if err := this.initiateInspector(); err != nil { return err } if err := this.initiateStreaming(); err != nil { return err } if err := this.initiateApplier(); err != nil { return err } if err := this.createFlagFiles(); err != nil { return err } initialLag, _ := this.inspector.getReplicationLag() log.Infof("Waiting for ghost table to be migrated. Current lag is %+v", initialLag) <-this.ghostTableMigrated log.Debugf("ghost table migrated") // Yay! We now know the Ghost and Changelog tables are good to examine! // When running on replica, this means the replica has those tables. When running // on master this is always true, of course, and yet it also implies this knowledge // is in the binlogs. if err := this.inspector.inspectOriginalAndGhostTables(); err != nil { return err } // Validation complete! We're good to execute this migration if err := this.hooksExecutor.onValidated(); err != nil { return err } if err := this.initiateServer(); err != nil { return err } defer this.server.RemoveSocketFile() if err := this.countTableRows(); err != nil { return err } if err := this.addDMLEventsListener(); err != nil { return err } if err := this.applier.ReadMigrationRangeValues(); err != nil { return err } if err := this.initiateThrottler(); err != nil { return err } if err := this.hooksExecutor.onBeforeRowCopy(); err != nil { return err } go this.executeWriteFuncs() go this.iterateChunks() this.migrationContext.MarkRowCopyStartTime() go this.initiateStatus() log.Debugf("Operating until row copy is complete") this.consumeRowCopyComplete() log.Infof("Row copy complete") if err := this.hooksExecutor.onRowCopyComplete(); err != nil { return err } this.printStatus(ForcePrintStatusRule) if err := this.hooksExecutor.onBeforeCutOver(); err != nil { return err } if err := this.retryOperation(this.cutOver); err != nil { return err } atomic.StoreInt64(&this.migrationContext.CutOverCompleteFlag, 1) if err := this.finalCleanup(); err != nil { return nil } if err := this.hooksExecutor.onSuccess(); err != nil { return err } log.Infof("Done migrating %s.%s", sql.EscapeName(this.migrationContext.DatabaseName), sql.EscapeName(this.migrationContext.OriginalTableName)) return nil } // ExecOnFailureHook executes the onFailure hook, and this method is provided as the only external // hook access point func (this *Migrator) ExecOnFailureHook() (err error) { return this.hooksExecutor.onFailure() } func (this *Migrator) handleCutOverResult(cutOverError error) (err error) { if this.migrationContext.TestOnReplica { // We're merely testing, we don't want to keep this state. Rollback the renames as possible this.applier.RenameTablesRollback() } if cutOverError == nil { return nil } // Only on error: if this.migrationContext.TestOnReplica { // With `--test-on-replica` we stop replication thread, and then proceed to use // the same cut-over phase as the master would use. That means we take locks // and swap the tables. // The difference is that we will later swap the tables back. if err := this.hooksExecutor.onStartReplication(); err != nil { return log.Errore(err) } if this.migrationContext.TestOnReplicaSkipReplicaStop { log.Warningf("--test-on-replica-skip-replica-stop enabled, we are not starting replication.") } else { log.Debugf("testing on replica. Starting replication IO thread after cut-over failure") if err := this.retryOperation(this.applier.StartReplication); err != nil { return log.Errore(err) } } } return nil } // cutOver performs the final step of migration, based on migration // type (on replica? atomic? safe?) func (this *Migrator) cutOver() (err error) { if this.migrationContext.Noop { log.Debugf("Noop operation; not really swapping tables") return nil } this.migrationContext.MarkPointOfInterest() this.throttler.throttle(func() { log.Debugf("throttling before swapping tables") }) this.migrationContext.MarkPointOfInterest() log.Debugf("checking for cut-over postpone") this.sleepWhileTrue( func() (bool, error) { if this.migrationContext.PostponeCutOverFlagFile == "" { return false, nil } if atomic.LoadInt64(&this.migrationContext.UserCommandedUnpostponeFlag) > 0 { atomic.StoreInt64(&this.migrationContext.UserCommandedUnpostponeFlag, 0) return false, nil } if base.FileExists(this.migrationContext.PostponeCutOverFlagFile) { // Postpone file defined and exists! if atomic.LoadInt64(&this.migrationContext.IsPostponingCutOver) == 0 { if err := this.hooksExecutor.onBeginPostponed(); err != nil { return true, err } } atomic.StoreInt64(&this.migrationContext.IsPostponingCutOver, 1) return true, nil } return false, nil }, ) atomic.StoreInt64(&this.migrationContext.IsPostponingCutOver, 0) this.migrationContext.MarkPointOfInterest() log.Debugf("checking for cut-over postpone: complete") if this.migrationContext.TestOnReplica { // With `--test-on-replica` we stop replication thread, and then proceed to use // the same cut-over phase as the master would use. That means we take locks // and swap the tables. // The difference is that we will later swap the tables back. if err := this.hooksExecutor.onStopReplication(); err != nil { return err } if this.migrationContext.TestOnReplicaSkipReplicaStop { log.Warningf("--test-on-replica-skip-replica-stop enabled, we are not stopping replication.") } else { log.Debugf("testing on replica. Stopping replication IO thread") if err := this.retryOperation(this.applier.StopReplication); err != nil { return err } } } if this.migrationContext.CutOverType == base.CutOverAtomic { // Atomic solution: we use low timeout and multiple attempts. But for // each failed attempt, we throttle until replication lag is back to normal err := this.atomicCutOver() this.handleCutOverResult(err) return err } if this.migrationContext.CutOverType == base.CutOverTwoStep { err := this.cutOverTwoStep() this.handleCutOverResult(err) return err } return log.Fatalf("Unknown cut-over type: %d; should never get here!", this.migrationContext.CutOverType) } // Inject the "AllEventsUpToLockProcessed" state hint, wait for it to appear in the binary logs, // make sure the queue is drained. func (this *Migrator) waitForEventsUpToLock() (err error) { timeout := time.NewTimer(time.Second * time.Duration(this.migrationContext.CutOverLockTimeoutSeconds)) this.migrationContext.MarkPointOfInterest() waitForEventsUpToLockStartTime := time.Now() allEventsUpToLockProcessedChallenge := fmt.Sprintf("%s:%d", string(AllEventsUpToLockProcessed), waitForEventsUpToLockStartTime.UnixNano()) log.Infof("Writing changelog state: %+v", allEventsUpToLockProcessedChallenge) if _, err := this.applier.WriteChangelogState(allEventsUpToLockProcessedChallenge); err != nil { return err } log.Infof("Waiting for events up to lock") atomic.StoreInt64(&this.migrationContext.AllEventsUpToLockProcessedInjectedFlag, 1) for found := false; !found; { select { case <-timeout.C: { return log.Errorf("Timeout while waiting for events up to lock") } case state := <-this.allEventsUpToLockProcessed: { if state == allEventsUpToLockProcessedChallenge { log.Infof("Waiting for events up to lock: got %s", state) found = true } else { log.Infof("Waiting for events up to lock: skipping %s", state) } } } } waitForEventsUpToLockDuration := time.Since(waitForEventsUpToLockStartTime) log.Infof("Done waiting for events up to lock; duration=%+v", waitForEventsUpToLockDuration) this.printStatus(ForcePrintStatusAndHintRule) return nil } // cutOverTwoStep will lock down the original table, execute // what's left of last DML entries, and **non-atomically** swap original->old, then new->original. // There is a point in time where the "original" table does not exist and queries are non-blocked // and failing. func (this *Migrator) cutOverTwoStep() (err error) { atomic.StoreInt64(&this.migrationContext.InCutOverCriticalSectionFlag, 1) defer atomic.StoreInt64(&this.migrationContext.InCutOverCriticalSectionFlag, 0) atomic.StoreInt64(&this.migrationContext.AllEventsUpToLockProcessedInjectedFlag, 0) if err := this.retryOperation(this.applier.LockOriginalTable); err != nil { return err } if err := this.retryOperation(this.waitForEventsUpToLock); err != nil { return err } if err := this.retryOperation(this.applier.SwapTablesQuickAndBumpy); err != nil { return err } if err := this.retryOperation(this.applier.UnlockTables); err != nil { return err } lockAndRenameDuration := this.migrationContext.RenameTablesEndTime.Sub(this.migrationContext.LockTablesStartTime) renameDuration := this.migrationContext.RenameTablesEndTime.Sub(this.migrationContext.RenameTablesStartTime) log.Debugf("Lock & rename duration: %s (rename only: %s). During this time, queries on %s were locked or failing", lockAndRenameDuration, renameDuration, sql.EscapeName(this.migrationContext.OriginalTableName)) return nil } // atomicCutOver func (this *Migrator) atomicCutOver() (err error) { atomic.StoreInt64(&this.migrationContext.InCutOverCriticalSectionFlag, 1) defer atomic.StoreInt64(&this.migrationContext.InCutOverCriticalSectionFlag, 0) okToUnlockTable := make(chan bool, 4) defer func() { okToUnlockTable <- true this.applier.DropAtomicCutOverSentryTableIfExists() }() atomic.StoreInt64(&this.migrationContext.AllEventsUpToLockProcessedInjectedFlag, 0) lockOriginalSessionIdChan := make(chan int64, 2) tableLocked := make(chan error, 2) tableUnlocked := make(chan error, 2) go func() { if err := this.applier.AtomicCutOverMagicLock(lockOriginalSessionIdChan, tableLocked, okToUnlockTable, tableUnlocked); err != nil { log.Errore(err) } }() if err := <-tableLocked; err != nil { return log.Errore(err) } lockOriginalSessionId := <-lockOriginalSessionIdChan log.Infof("Session locking original & magic tables is %+v", lockOriginalSessionId) // At this point we know the original table is locked. // We know any newly incoming DML on original table is blocked. if err := this.waitForEventsUpToLock(); err != nil { return log.Errore(err) } // Step 2 // We now attempt an atomic RENAME on original & ghost tables, and expect it to block. this.migrationContext.RenameTablesStartTime = time.Now() var tableRenameKnownToHaveFailed int64 renameSessionIdChan := make(chan int64, 2) tablesRenamed := make(chan error, 2) go func() { if err := this.applier.AtomicCutoverRename(renameSessionIdChan, tablesRenamed); err != nil { // Abort! Release the lock atomic.StoreInt64(&tableRenameKnownToHaveFailed, 1) okToUnlockTable <- true } }() renameSessionId := <-renameSessionIdChan log.Infof("Session renaming tables is %+v", renameSessionId) waitForRename := func() error { if atomic.LoadInt64(&tableRenameKnownToHaveFailed) == 1 { // We return `nil` here so as to avoid the `retry`. The RENAME has failed, // it won't show up in PROCESSLIST, no point in waiting return nil } return this.applier.ExpectProcess(renameSessionId, "metadata lock", "rename") } // Wait for the RENAME to appear in PROCESSLIST if err := this.retryOperation(waitForRename, true); err != nil { // Abort! Release the lock okToUnlockTable <- true return err } if atomic.LoadInt64(&tableRenameKnownToHaveFailed) == 0 { log.Infof("Found atomic RENAME to be blocking, as expected. Double checking the lock is still in place (though I don't strictly have to)") } if err := this.applier.ExpectUsedLock(lockOriginalSessionId); err != nil { // Abort operation. Just make sure to drop the magic table. return log.Errore(err) } log.Infof("Connection holding lock on original table still exists") // Now that we've found the RENAME blocking, AND the locking connection still alive, // we know it is safe to proceed to release the lock okToUnlockTable <- true // BAM! magic table dropped, original table lock is released // -> RENAME released -> queries on original are unblocked. if err := <-tableUnlocked; err != nil { return log.Errore(err) } if err := <-tablesRenamed; err != nil { return log.Errore(err) } this.migrationContext.RenameTablesEndTime = time.Now() // ooh nice! We're actually truly and thankfully done lockAndRenameDuration := this.migrationContext.RenameTablesEndTime.Sub(this.migrationContext.LockTablesStartTime) log.Infof("Lock & rename duration: %s. During this time, queries on %s were blocked", lockAndRenameDuration, sql.EscapeName(this.migrationContext.OriginalTableName)) return nil } // initiateServer begins listening on unix socket/tcp for incoming interactive commands func (this *Migrator) initiateServer() (err error) { var f printStatusFunc = func(rule PrintStatusRule, writer io.Writer) { this.printStatus(rule, writer) } this.server = NewServer(this.migrationContext, this.hooksExecutor, f) if err := this.server.BindSocketFile(); err != nil { return err } if err := this.server.BindTCPPort(); err != nil { return err } go this.server.Serve() return nil } // initiateInspector connects, validates and inspects the "inspector" server. // The "inspector" server is typically a replica; it is where we issue some // queries such as: // - table row count // - schema validation // - heartbeat // When `--allow-on-master` is supplied, the inspector is actually the master. func (this *Migrator) initiateInspector() (err error) { this.inspector = NewInspector(this.migrationContext) if err := this.inspector.InitDBConnections(); err != nil { return err } if err := this.inspector.ValidateOriginalTable(); err != nil { return err } if err := this.inspector.InspectOriginalTable(); err != nil { return err } // So far so good, table is accessible and valid. // Let's get master connection config if this.migrationContext.AssumeMasterHostname == "" { // No forced master host; detect master if this.migrationContext.ApplierConnectionConfig, err = this.inspector.getMasterConnectionConfig(); err != nil { return err } log.Infof("Master found to be %+v", *this.migrationContext.ApplierConnectionConfig.ImpliedKey) } else { // Forced master host. key, err := mysql.ParseRawInstanceKeyLoose(this.migrationContext.AssumeMasterHostname) if err != nil { return err } this.migrationContext.ApplierConnectionConfig = this.migrationContext.InspectorConnectionConfig.DuplicateCredentials(*key) if this.migrationContext.CliMasterUser != "" { this.migrationContext.ApplierConnectionConfig.User = this.migrationContext.CliMasterUser } if this.migrationContext.CliMasterPassword != "" { this.migrationContext.ApplierConnectionConfig.Password = this.migrationContext.CliMasterPassword } log.Infof("Master forced to be %+v", *this.migrationContext.ApplierConnectionConfig.ImpliedKey) } // validate configs if this.migrationContext.TestOnReplica || this.migrationContext.MigrateOnReplica { if this.migrationContext.InspectorIsAlsoApplier() { return fmt.Errorf("Instructed to --test-on-replica or --migrate-on-replica, but the server we connect to doesn't seem to be a replica") } log.Infof("--test-on-replica or --migrate-on-replica given. Will not execute on master %+v but rather on replica %+v itself", *this.migrationContext.ApplierConnectionConfig.ImpliedKey, *this.migrationContext.InspectorConnectionConfig.ImpliedKey, ) this.migrationContext.ApplierConnectionConfig = this.migrationContext.InspectorConnectionConfig.Duplicate() if this.migrationContext.GetThrottleControlReplicaKeys().Len() == 0 { this.migrationContext.AddThrottleControlReplicaKey(this.migrationContext.InspectorConnectionConfig.Key) } } else if this.migrationContext.InspectorIsAlsoApplier() && !this.migrationContext.AllowedRunningOnMaster { return fmt.Errorf("It seems like this migration attempt to run directly on master. Preferably it would be executed on a replica (and this reduces load from the master). To proceed please provide --allow-on-master. Inspector config=%+v, applier config=%+v", this.migrationContext.InspectorConnectionConfig, this.migrationContext.ApplierConnectionConfig) } if err := this.inspector.validateLogSlaveUpdates(); err != nil { return err } return nil } // initiateStatus sets and activates the printStatus() ticker func (this *Migrator) initiateStatus() error { this.printStatus(ForcePrintStatusAndHintRule) statusTick := time.Tick(1 * time.Second) for range statusTick { if atomic.LoadInt64(&this.finishedMigrating) > 0 { return nil } go this.printStatus(HeuristicPrintStatusRule) } return nil } // printMigrationStatusHint prints a detailed configuration dump, that is useful // to keep in mind; such as the name of migrated table, throttle params etc. // This gets printed at beginning and end of migration, every 10 minutes throughout // migration, and as response to the "status" interactive command. func (this *Migrator) printMigrationStatusHint(writers ...io.Writer) { w := io.MultiWriter(writers...) fmt.Fprintln(w, fmt.Sprintf("# Migrating %s.%s; Ghost table is %s.%s", sql.EscapeName(this.migrationContext.DatabaseName), sql.EscapeName(this.migrationContext.OriginalTableName), sql.EscapeName(this.migrationContext.DatabaseName), sql.EscapeName(this.migrationContext.GetGhostTableName()), )) fmt.Fprintln(w, fmt.Sprintf("# Migrating %+v; inspecting %+v; executing on %+v", *this.applier.connectionConfig.ImpliedKey, *this.inspector.connectionConfig.ImpliedKey, this.migrationContext.Hostname, )) fmt.Fprintln(w, fmt.Sprintf("# Migration started at %+v", this.migrationContext.StartTime.Format(time.RubyDate), )) maxLoad := this.migrationContext.GetMaxLoad() criticalLoad := this.migrationContext.GetCriticalLoad() fmt.Fprintln(w, fmt.Sprintf("# chunk-size: %+v; max-lag-millis: %+vms; dml-batch-size: %+v; max-load: %s; critical-load: %s; nice-ratio: %f", atomic.LoadInt64(&this.migrationContext.ChunkSize), atomic.LoadInt64(&this.migrationContext.MaxLagMillisecondsThrottleThreshold), atomic.LoadInt64(&this.migrationContext.DMLBatchSize), maxLoad.String(), criticalLoad.String(), this.migrationContext.GetNiceRatio(), )) if this.migrationContext.ThrottleFlagFile != "" { setIndicator := "" if base.FileExists(this.migrationContext.ThrottleFlagFile) { setIndicator = "[set]" } fmt.Fprintln(w, fmt.Sprintf("# throttle-flag-file: %+v %+v", this.migrationContext.ThrottleFlagFile, setIndicator, )) } if this.migrationContext.ThrottleAdditionalFlagFile != "" { setIndicator := "" if base.FileExists(this.migrationContext.ThrottleAdditionalFlagFile) { setIndicator = "[set]" } fmt.Fprintln(w, fmt.Sprintf("# throttle-additional-flag-file: %+v %+v", this.migrationContext.ThrottleAdditionalFlagFile, setIndicator, )) } if throttleQuery := this.migrationContext.GetThrottleQuery(); throttleQuery != "" { fmt.Fprintln(w, fmt.Sprintf("# throttle-query: %+v", throttleQuery, )) } if throttleControlReplicaKeys := this.migrationContext.GetThrottleControlReplicaKeys(); throttleControlReplicaKeys.Len() > 0 { fmt.Fprintln(w, fmt.Sprintf("# throttle-control-replicas count: %+v", throttleControlReplicaKeys.Len(), )) } if this.migrationContext.PostponeCutOverFlagFile != "" { setIndicator := "" if base.FileExists(this.migrationContext.PostponeCutOverFlagFile) { setIndicator = "[set]" } fmt.Fprintln(w, fmt.Sprintf("# postpone-cut-over-flag-file: %+v %+v", this.migrationContext.PostponeCutOverFlagFile, setIndicator, )) } if this.migrationContext.PanicFlagFile != "" { fmt.Fprintln(w, fmt.Sprintf("# panic-flag-file: %+v", this.migrationContext.PanicFlagFile, )) } fmt.Fprintln(w, fmt.Sprintf("# Serving on unix socket: %+v", this.migrationContext.ServeSocketFile, )) if this.migrationContext.ServeTCPPort != 0 { fmt.Fprintln(w, fmt.Sprintf("# Serving on TCP port: %+v", this.migrationContext.ServeTCPPort)) } } // printStatus prints the progress status, and optionally additionally detailed // dump of configuration. // `rule` indicates the type of output expected. // By default the status is written to standard output, but other writers can // be used as well. func (this *Migrator) printStatus(rule PrintStatusRule, writers ...io.Writer) { if rule == NoPrintStatusRule { return } writers = append(writers, os.Stdout) elapsedTime := this.migrationContext.ElapsedTime() elapsedSeconds := int64(elapsedTime.Seconds()) totalRowsCopied := this.migrationContext.GetTotalRowsCopied() rowsEstimate := atomic.LoadInt64(&this.migrationContext.RowsEstimate) + atomic.LoadInt64(&this.migrationContext.RowsDeltaEstimate) if atomic.LoadInt64(&this.rowCopyCompleteFlag) == 1 { // Done copying rows. The totalRowsCopied value is the de-facto number of rows, // and there is no further need to keep updating the value. rowsEstimate = totalRowsCopied } var progressPct float64 if rowsEstimate == 0 { progressPct = 100.0 } else { progressPct = 100.0 * float64(totalRowsCopied) / float64(rowsEstimate) } // Before status, let's see if we should print a nice reminder for what exactly we're doing here. shouldPrintMigrationStatusHint := (elapsedSeconds%600 == 0) if rule == ForcePrintStatusAndHintRule { shouldPrintMigrationStatusHint = true } if rule == ForcePrintStatusOnlyRule { shouldPrintMigrationStatusHint = false } if shouldPrintMigrationStatusHint { this.printMigrationStatusHint(writers...) } var etaSeconds float64 = math.MaxFloat64 eta := "N/A" if progressPct >= 100.0 { eta = "due" } else if progressPct >= 1.0 { elapsedRowCopySeconds := this.migrationContext.ElapsedRowCopyTime().Seconds() totalExpectedSeconds := elapsedRowCopySeconds * float64(rowsEstimate) / float64(totalRowsCopied) etaSeconds = totalExpectedSeconds - elapsedRowCopySeconds if etaSeconds >= 0 { etaDuration := time.Duration(etaSeconds) * time.Second eta = base.PrettifyDurationOutput(etaDuration) } else { eta = "due" } } state := "migrating" if atomic.LoadInt64(&this.migrationContext.CountingRowsFlag) > 0 && !this.migrationContext.ConcurrentCountTableRows { state = "counting rows" } else if atomic.LoadInt64(&this.migrationContext.IsPostponingCutOver) > 0 { eta = "due" state = "postponing cut-over" } else if isThrottled, throttleReason, _ := this.migrationContext.IsThrottled(); isThrottled { state = fmt.Sprintf("throttled, %s", throttleReason) } shouldPrintStatus := false if rule == HeuristicPrintStatusRule { if elapsedSeconds <= 60 { shouldPrintStatus = true } else if etaSeconds <= 60 { shouldPrintStatus = true } else if etaSeconds <= 180 { shouldPrintStatus = (elapsedSeconds%5 == 0) } else if elapsedSeconds <= 180 { shouldPrintStatus = (elapsedSeconds%5 == 0) } else if this.migrationContext.TimeSincePointOfInterest().Seconds() <= 60 { shouldPrintStatus = (elapsedSeconds%5 == 0) } else { shouldPrintStatus = (elapsedSeconds%30 == 0) } } else { // Not heuristic shouldPrintStatus = true } if !shouldPrintStatus { return } currentBinlogCoordinates := *this.eventsStreamer.GetCurrentBinlogCoordinates() status := fmt.Sprintf("Copy: %d/%d %.1f%%; Applied: %d; Backlog: %d/%d; Time: %+v(total), %+v(copy); streamer: %+v; State: %s; ETA: %s", totalRowsCopied, rowsEstimate, progressPct, atomic.LoadInt64(&this.migrationContext.TotalDMLEventsApplied), len(this.applyEventsQueue), cap(this.applyEventsQueue), base.PrettifyDurationOutput(elapsedTime), base.PrettifyDurationOutput(this.migrationContext.ElapsedRowCopyTime()), currentBinlogCoordinates, state, eta, ) this.applier.WriteChangelog( fmt.Sprintf("copy iteration %d at %d", this.migrationContext.GetIteration(), time.Now().Unix()), status, ) w := io.MultiWriter(writers...) fmt.Fprintln(w, status) if elapsedSeconds%60 == 0 { this.hooksExecutor.onStatus(status) } } // initiateStreaming begins streaming of binary log events and registers listeners for such events func (this *Migrator) initiateStreaming() error { this.eventsStreamer = NewEventsStreamer(this.migrationContext) if err := this.eventsStreamer.InitDBConnections(); err != nil { return err } this.eventsStreamer.AddListener( false, this.migrationContext.DatabaseName, this.migrationContext.GetChangelogTableName(), func(dmlEvent *binlog.BinlogDMLEvent) error { return this.onChangelogStateEvent(dmlEvent) }, ) go func() { log.Debugf("Beginning streaming") err := this.eventsStreamer.StreamEvents(this.canStopStreaming) if err != nil { this.migrationContext.PanicAbort <- err } log.Debugf("Done streaming") }() go func() { ticker := time.Tick(1 * time.Second) for range ticker { if atomic.LoadInt64(&this.finishedMigrating) > 0 { return } this.migrationContext.SetRecentBinlogCoordinates(*this.eventsStreamer.GetCurrentBinlogCoordinates()) } }() return nil } // addDMLEventsListener begins listening for binlog events on the original table, // and creates & enqueues a write task per such event. func (this *Migrator) addDMLEventsListener() error { err := this.eventsStreamer.AddListener( false, this.migrationContext.DatabaseName, this.migrationContext.OriginalTableName, func(dmlEvent *binlog.BinlogDMLEvent) error { this.applyEventsQueue <- newApplyEventStructByDML(dmlEvent) return nil }, ) return err } // initiateThrottler kicks in the throttling collection and the throttling checks. func (this *Migrator) initiateThrottler() error { this.throttler = NewThrottler(this.migrationContext, this.applier, this.inspector) go this.throttler.initiateThrottlerCollection(this.firstThrottlingCollected) log.Infof("Waiting for first throttle metrics to be collected") <-this.firstThrottlingCollected // replication lag <-this.firstThrottlingCollected // HTTP status <-this.firstThrottlingCollected // other, general metrics log.Infof("First throttle metrics collected") go this.throttler.initiateThrottlerChecks() return nil } func (this *Migrator) initiateApplier() error { this.applier = NewApplier(this.migrationContext) if err := this.applier.InitDBConnections(); err != nil { return err } if err := this.applier.ValidateOrDropExistingTables(); err != nil { return err } if err := this.applier.CreateChangelogTable(); err != nil { log.Errorf("Unable to create changelog table, see further error details. Perhaps a previous migration failed without dropping the table? OR is there a running migration? Bailing out") return err } if err := this.applier.CreateGhostTable(); err != nil { log.Errorf("Unable to create ghost table, see further error details. Perhaps a previous migration failed without dropping the table? Bailing out") return err } if err := this.applier.AlterGhost(); err != nil { log.Errorf("Unable to ALTER ghost table, see further error details. Bailing out") return err } this.applier.WriteChangelogState(string(GhostTableMigrated)) go this.applier.InitiateHeartbeat() return nil } // iterateChunks iterates the existing table rows, and generates a copy task of // a chunk of rows onto the ghost table. func (this *Migrator) iterateChunks() error { terminateRowIteration := func(err error) error { this.rowCopyComplete <- err return log.Errore(err) } if this.migrationContext.Noop { log.Debugf("Noop operation; not really copying data") return terminateRowIteration(nil) } if this.migrationContext.MigrationRangeMinValues == nil { log.Debugf("No rows found in table. Rowcopy will be implicitly empty") return terminateRowIteration(nil) } // Iterate per chunk: for { if atomic.LoadInt64(&this.rowCopyCompleteFlag) == 1 { // Done // There's another such check down the line return nil } copyRowsFunc := func() error { if atomic.LoadInt64(&this.rowCopyCompleteFlag) == 1 { // Done. // There's another such check down the line return nil } hasFurtherRange, err := this.applier.CalculateNextIterationRangeEndValues() if err != nil { return terminateRowIteration(err) } if !hasFurtherRange { return terminateRowIteration(nil) } // Copy task: applyCopyRowsFunc := func() error { if atomic.LoadInt64(&this.rowCopyCompleteFlag) == 1 { // No need for more writes. // This is the de-facto place where we avoid writing in the event of completed cut-over. // There could _still_ be a race condition, but that's as close as we can get. // What about the race condition? Well, there's actually no data integrity issue. // when rowCopyCompleteFlag==1 that means **guaranteed** all necessary rows have been copied. // But some are still then collected at the binary log, and these are the ones we're trying to // not apply here. If the race condition wins over us, then we just attempt to apply onto the // _ghost_ table, which no longer exists. So, bothering error messages and all, but no damage. return nil } _, rowsAffected, _, err := this.applier.ApplyIterationInsertQuery() if err != nil { return terminateRowIteration(err) } atomic.AddInt64(&this.migrationContext.TotalRowsCopied, rowsAffected) atomic.AddInt64(&this.migrationContext.Iteration, 1) return nil } if err := this.retryOperation(applyCopyRowsFunc); err != nil { return terminateRowIteration(err) } return nil } // Enqueue copy operation; to be executed by executeWriteFuncs() this.copyRowsQueue <- copyRowsFunc } return nil } func (this *Migrator) onApplyEventStruct(eventStruct *applyEventStruct) error { handleNonDMLEventStruct := func(eventStruct *applyEventStruct) error { if eventStruct.writeFunc != nil { if err := this.retryOperation(*eventStruct.writeFunc); err != nil { return log.Errore(err) } } return nil } if eventStruct.dmlEvent == nil { return handleNonDMLEventStruct(eventStruct) } if eventStruct.dmlEvent != nil { dmlEvents := [](*binlog.BinlogDMLEvent){} dmlEvents = append(dmlEvents, eventStruct.dmlEvent) var nonDmlStructToApply *applyEventStruct availableEvents := len(this.applyEventsQueue) batchSize := int(atomic.LoadInt64(&this.migrationContext.DMLBatchSize)) if availableEvents > batchSize-1 { // The "- 1" is because we already consumed one event: the original event that led to this function getting called. // So, if DMLBatchSize==1 we wish to not process any further events availableEvents = batchSize - 1 } for i := 0; i < availableEvents; i++ { additionalStruct := <-this.applyEventsQueue if additionalStruct.dmlEvent == nil { // Not a DML. We don't group this, and we don't batch any further nonDmlStructToApply = additionalStruct break } dmlEvents = append(dmlEvents, additionalStruct.dmlEvent) } // Create a task to apply the DML event; this will be execute by executeWriteFuncs() var applyEventFunc tableWriteFunc = func() error { return this.applier.ApplyDMLEventQueries(dmlEvents) } if err := this.retryOperation(applyEventFunc); err != nil { return log.Errore(err) } if nonDmlStructToApply != nil { // We pulled DML events from the queue, and then we hit a non-DML event. Wait! // We need to handle it! if err := handleNonDMLEventStruct(nonDmlStructToApply); err != nil { return log.Errore(err) } } } return nil } // executeWriteFuncs writes data via applier: both the rowcopy and the events backlog. // This is where the ghost table gets the data. The function fills the data single-threaded. // Both event backlog and rowcopy events are polled; the backlog events have precedence. func (this *Migrator) executeWriteFuncs() error { if this.migrationContext.Noop { log.Debugf("Noop operation; not really executing write funcs") return nil } for { if atomic.LoadInt64(&this.finishedMigrating) > 0 { return nil } this.throttler.throttle(nil) // We give higher priority to event processing, then secondary priority to // rowcopy select { case eventStruct := <-this.applyEventsQueue: { if err := this.onApplyEventStruct(eventStruct); err != nil { return err } } default: { select { case copyRowsFunc := <-this.copyRowsQueue: { copyRowsStartTime := time.Now() // Retries are handled within the copyRowsFunc if err := copyRowsFunc(); err != nil { return log.Errore(err) } if niceRatio := this.migrationContext.GetNiceRatio(); niceRatio > 0 { copyRowsDuration := time.Since(copyRowsStartTime) sleepTimeNanosecondFloat64 := niceRatio * float64(copyRowsDuration.Nanoseconds()) sleepTime := time.Duration(time.Duration(int64(sleepTimeNanosecondFloat64)) * time.Nanosecond) time.Sleep(sleepTime) } } default: { // Hmmmmm... nothing in the queue; no events, but also no row copy. // This is possible upon load. Let's just sleep it over. log.Debugf("Getting nothing in the write queue. Sleeping...") time.Sleep(time.Second) } } } } } return nil } // finalCleanup takes actions at very end of migration, dropping tables etc. func (this *Migrator) finalCleanup() error { atomic.StoreInt64(&this.migrationContext.CleanupImminentFlag, 1) if this.migrationContext.Noop { if createTableStatement, err := this.inspector.showCreateTable(this.migrationContext.GetGhostTableName()); err == nil { log.Infof("New table structure follows") fmt.Println(createTableStatement) } else { log.Errore(err) } } if err := this.eventsStreamer.Close(); err != nil { log.Errore(err) } if err := this.retryOperation(this.applier.DropChangelogTable); err != nil { return err } if this.migrationContext.OkToDropTable && !this.migrationContext.TestOnReplica { if err := this.retryOperation(this.applier.DropOldTable); err != nil { return err } } else { if !this.migrationContext.Noop { log.Infof("Am not dropping old table because I want this operation to be as live as possible. If you insist I should do it, please add `--ok-to-drop-table` next time. But I prefer you do not. To drop the old table, issue:") log.Infof("-- drop table %s.%s", sql.EscapeName(this.migrationContext.DatabaseName), sql.EscapeName(this.migrationContext.GetOldTableName())) } } if this.migrationContext.Noop { if err := this.retryOperation(this.applier.DropGhostTable); err != nil { return err } } return nil } func (this *Migrator) teardown() { atomic.StoreInt64(&this.finishedMigrating, 1) if this.inspector != nil { log.Infof("Tearing down inspector") this.inspector.Teardown() } if this.applier != nil { log.Infof("Tearing down applier") this.applier.Teardown() } if this.eventsStreamer != nil { log.Infof("Tearing down streamer") this.eventsStreamer.Teardown() } if this.throttler != nil { log.Infof("Tearing down throttler") this.throttler.Teardown() } }