gh-ost/go/logic/applier.go

869 lines
30 KiB
Go

/*
Copyright 2016 GitHub Inc.
See https://github.com/github/gh-ost/blob/master/LICENSE
*/
package logic
import (
gosql "database/sql"
"fmt"
"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"
"github.com/outbrain/golib/sqlutils"
)
const (
atomicCutOverMagicHint = "ghost-cut-over-sentry"
)
// Applier connects and writes the the applier-server, which is the server where migration
// happens. This is typically the master, but could be a replica when `--test-on-replica` or
// `--execute-on-replica` are given.
// Applier is the one to actually write row data and apply binlog events onto the ghost table.
// It is where the ghost & changelog tables get created. It is where the cut-over phase happens.
type Applier struct {
connectionConfig *mysql.ConnectionConfig
db *gosql.DB
singletonDB *gosql.DB
migrationContext *base.MigrationContext
}
func NewApplier() *Applier {
return &Applier{
connectionConfig: base.GetMigrationContext().ApplierConnectionConfig,
migrationContext: base.GetMigrationContext(),
}
}
func (this *Applier) InitDBConnections() (err error) {
applierUri := this.connectionConfig.GetDBUri(this.migrationContext.DatabaseName)
if this.db, _, err = sqlutils.GetDB(applierUri); err != nil {
return err
}
singletonApplierUri := fmt.Sprintf("%s?timeout=0", applierUri)
if this.singletonDB, _, err = sqlutils.GetDB(singletonApplierUri); err != nil {
return err
}
this.singletonDB.SetMaxOpenConns(1)
if err := this.validateConnection(this.db); err != nil {
return err
}
if err := this.validateConnection(this.singletonDB); err != nil {
return err
}
if impliedKey, err := mysql.GetInstanceKey(this.db); err != nil {
return err
} else {
this.connectionConfig.ImpliedKey = impliedKey
}
return nil
}
// validateConnection issues a simple can-connect to MySQL
func (this *Applier) validateConnection(db *gosql.DB) error {
query := `select @@global.port`
var port int
if err := db.QueryRow(query).Scan(&port); err != nil {
return err
}
if port != this.connectionConfig.Key.Port {
return fmt.Errorf("Unexpected database port reported: %+v", port)
}
log.Infof("connection validated on %+v", this.connectionConfig.Key)
return nil
}
// showTableStatus returns the output of `show table status like '...'` command
func (this *Applier) showTableStatus(tableName string) (rowMap sqlutils.RowMap) {
rowMap = nil
query := fmt.Sprintf(`show /* gh-ost */ table status from %s like '%s'`, sql.EscapeName(this.migrationContext.DatabaseName), tableName)
sqlutils.QueryRowsMap(this.db, query, func(m sqlutils.RowMap) error {
rowMap = m
return nil
})
return rowMap
}
// tableExists checks if a given table exists in database
func (this *Applier) tableExists(tableName string) (tableFound bool) {
m := this.showTableStatus(tableName)
return (m != nil)
}
// ValidateOrDropExistingTables verifies ghost and changelog tables do not exist,
// or attempts to drop them if instructed to.
func (this *Applier) ValidateOrDropExistingTables() error {
if this.migrationContext.InitiallyDropGhostTable {
if err := this.DropGhostTable(); err != nil {
return err
}
}
if this.tableExists(this.migrationContext.GetGhostTableName()) {
return fmt.Errorf("Table %s already exists. Panicking. Use --initially-drop-ghost-table to force dropping it", sql.EscapeName(this.migrationContext.GetGhostTableName()))
}
if this.migrationContext.InitiallyDropOldTable {
if err := this.DropOldTable(); err != nil {
return err
}
}
if this.tableExists(this.migrationContext.GetOldTableName()) {
return fmt.Errorf("Table %s already exists. Panicking. Use --initially-drop-old-table to force dropping it", sql.EscapeName(this.migrationContext.GetOldTableName()))
}
return nil
}
// CreateGhostTable creates the ghost table on the applier host
func (this *Applier) CreateGhostTable() error {
query := fmt.Sprintf(`create /* gh-ost */ table %s.%s like %s.%s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetGhostTableName()),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
)
log.Infof("Creating ghost table %s.%s",
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetGhostTableName()),
)
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
return err
}
log.Infof("Ghost table created")
return nil
}
// AlterGhost applies `alter` statement on ghost table
func (this *Applier) AlterGhost() error {
query := fmt.Sprintf(`alter /* gh-ost */ table %s.%s %s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetGhostTableName()),
this.migrationContext.AlterStatement,
)
log.Infof("Altering ghost table %s.%s",
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetGhostTableName()),
)
log.Debugf("ALTER statement: %s", query)
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
return err
}
log.Infof("Ghost table altered")
return nil
}
// CreateChangelogTable creates the changelog table on the applier host
func (this *Applier) CreateChangelogTable() error {
if err := this.DropChangelogTable(); err != nil {
return err
}
query := fmt.Sprintf(`create /* gh-ost */ table %s.%s (
id bigint auto_increment,
last_update timestamp not null DEFAULT CURRENT_TIMESTAMP ON UPDATE CURRENT_TIMESTAMP,
hint varchar(64) charset ascii not null,
value varchar(255) charset ascii not null,
primary key(id),
unique key hint_uidx(hint)
) auto_increment=256
`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetChangelogTableName()),
)
log.Infof("Creating changelog table %s.%s",
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetChangelogTableName()),
)
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
return err
}
log.Infof("Changelog table created")
return nil
}
// dropTable drops a given table on the applied host
func (this *Applier) dropTable(tableName string) error {
query := fmt.Sprintf(`drop /* gh-ost */ table if exists %s.%s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(tableName),
)
log.Infof("Droppping table %s.%s",
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(tableName),
)
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
return err
}
log.Infof("Table dropped")
return nil
}
// DropChangelogTable drops the changelog table on the applier host
func (this *Applier) DropChangelogTable() error {
return this.dropTable(this.migrationContext.GetChangelogTableName())
}
// DropOldTable drops the _Old table on the applier host
func (this *Applier) DropOldTable() error {
return this.dropTable(this.migrationContext.GetOldTableName())
}
// DropGhostTable drops the ghost table on the applier host
func (this *Applier) DropGhostTable() error {
return this.dropTable(this.migrationContext.GetGhostTableName())
}
// WriteChangelog writes a value to the changelog table.
// It returns the hint as given, for convenience
func (this *Applier) WriteChangelog(hint, value string) (string, error) {
explicitId := 0
switch hint {
case "heartbeat":
explicitId = 1
case "state":
explicitId = 2
case "throttle":
explicitId = 3
}
query := fmt.Sprintf(`
insert /* gh-ost */ into %s.%s
(id, hint, value)
values
(NULLIF(?, 0), ?, ?)
on duplicate key update
last_update=NOW(),
value=VALUES(value)
`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetChangelogTableName()),
)
_, err := sqlutils.Exec(this.db, query, explicitId, hint, value)
return hint, err
}
func (this *Applier) WriteAndLogChangelog(hint, value string) (string, error) {
this.WriteChangelog(hint, value)
return this.WriteChangelog(fmt.Sprintf("%s at %d", hint, time.Now().UnixNano()), value)
}
func (this *Applier) WriteChangelogState(value string) (string, error) {
return this.WriteAndLogChangelog("state", value)
}
// InitiateHeartbeat creates a heartbeat cycle, writing to the changelog table.
// This is done asynchronously
func (this *Applier) InitiateHeartbeat(heartbeatIntervalMilliseconds int64) {
var numSuccessiveFailures int64
injectHeartbeat := func() error {
if _, err := this.WriteChangelog("heartbeat", time.Now().Format(time.RFC3339Nano)); err != nil {
numSuccessiveFailures++
if numSuccessiveFailures > this.migrationContext.MaxRetries() {
return log.Errore(err)
}
} else {
numSuccessiveFailures = 0
}
return nil
}
injectHeartbeat()
heartbeatTick := time.Tick(time.Duration(heartbeatIntervalMilliseconds) * time.Millisecond)
for range heartbeatTick {
// Generally speaking, we would issue a goroutine, but I'd actually rather
// have this blocked rather than spam the master in the event something
// goes wrong
if err := injectHeartbeat(); err != nil {
return
}
}
}
// ExecuteThrottleQuery executes the `--throttle-query` and returns its results.
func (this *Applier) ExecuteThrottleQuery() (int64, error) {
throttleQuery := this.migrationContext.GetThrottleQuery()
if throttleQuery == "" {
return 0, nil
}
var result int64
if err := this.db.QueryRow(throttleQuery).Scan(&result); err != nil {
return 0, log.Errore(err)
}
return result, nil
}
// ReadMigrationMinValues returns the minimum values to be iterated on rowcopy
func (this *Applier) ReadMigrationMinValues(uniqueKey *sql.UniqueKey) error {
log.Debugf("Reading migration range according to key: %s", uniqueKey.Name)
query, err := sql.BuildUniqueKeyMinValuesPreparedQuery(this.migrationContext.DatabaseName, this.migrationContext.OriginalTableName, uniqueKey.Columns.Names)
if err != nil {
return err
}
rows, err := this.db.Query(query)
if err != nil {
return err
}
for rows.Next() {
this.migrationContext.MigrationRangeMinValues = sql.NewColumnValues(uniqueKey.Len())
if err = rows.Scan(this.migrationContext.MigrationRangeMinValues.ValuesPointers...); err != nil {
return err
}
}
log.Infof("Migration min values: [%s]", this.migrationContext.MigrationRangeMinValues)
return err
}
// ReadMigrationMaxValues returns the maximum values to be iterated on rowcopy
func (this *Applier) ReadMigrationMaxValues(uniqueKey *sql.UniqueKey) error {
log.Debugf("Reading migration range according to key: %s", uniqueKey.Name)
query, err := sql.BuildUniqueKeyMaxValuesPreparedQuery(this.migrationContext.DatabaseName, this.migrationContext.OriginalTableName, uniqueKey.Columns.Names)
if err != nil {
return err
}
rows, err := this.db.Query(query)
if err != nil {
return err
}
for rows.Next() {
this.migrationContext.MigrationRangeMaxValues = sql.NewColumnValues(uniqueKey.Len())
if err = rows.Scan(this.migrationContext.MigrationRangeMaxValues.ValuesPointers...); err != nil {
return err
}
}
log.Infof("Migration max values: [%s]", this.migrationContext.MigrationRangeMaxValues)
return err
}
// ReadMigrationRangeValues reads min/max values that will be used for rowcopy
func (this *Applier) ReadMigrationRangeValues() error {
if err := this.ReadMigrationMinValues(this.migrationContext.UniqueKey); err != nil {
return err
}
if err := this.ReadMigrationMaxValues(this.migrationContext.UniqueKey); err != nil {
return err
}
return nil
}
// CalculateNextIterationRangeEndValues reads the next-iteration-range-end unique key values,
// which will be used for copying the next chunk of rows. Ir returns "false" if there is
// no further chunk to work through, i.e. we're past the last chunk and are done with
// itrating the range (and this done with copying row chunks)
func (this *Applier) CalculateNextIterationRangeEndValues() (hasFurtherRange bool, err error) {
this.migrationContext.MigrationIterationRangeMinValues = this.migrationContext.MigrationIterationRangeMaxValues
if this.migrationContext.MigrationIterationRangeMinValues == nil {
this.migrationContext.MigrationIterationRangeMinValues = this.migrationContext.MigrationRangeMinValues
}
query, explodedArgs, err := sql.BuildUniqueKeyRangeEndPreparedQuery(
this.migrationContext.DatabaseName,
this.migrationContext.OriginalTableName,
this.migrationContext.UniqueKey.Columns.Names,
this.migrationContext.MigrationIterationRangeMinValues.AbstractValues(),
this.migrationContext.MigrationRangeMaxValues.AbstractValues(),
atomic.LoadInt64(&this.migrationContext.ChunkSize),
this.migrationContext.GetIteration() == 0,
fmt.Sprintf("iteration:%d", this.migrationContext.GetIteration()),
)
if err != nil {
return hasFurtherRange, err
}
rows, err := this.db.Query(query, explodedArgs...)
if err != nil {
return hasFurtherRange, err
}
iterationRangeMaxValues := sql.NewColumnValues(this.migrationContext.UniqueKey.Len())
for rows.Next() {
if err = rows.Scan(iterationRangeMaxValues.ValuesPointers...); err != nil {
return hasFurtherRange, err
}
hasFurtherRange = true
}
if !hasFurtherRange {
log.Debugf("Iteration complete: no further range to iterate")
return hasFurtherRange, nil
}
this.migrationContext.MigrationIterationRangeMaxValues = iterationRangeMaxValues
return hasFurtherRange, nil
}
// ApplyIterationInsertQuery issues a chunk-INSERT query on the ghost table. It is where
// data actually gets copied from original table.
func (this *Applier) ApplyIterationInsertQuery() (chunkSize int64, rowsAffected int64, duration time.Duration, err error) {
startTime := time.Now()
chunkSize = atomic.LoadInt64(&this.migrationContext.ChunkSize)
query, explodedArgs, err := sql.BuildRangeInsertPreparedQuery(
this.migrationContext.DatabaseName,
this.migrationContext.OriginalTableName,
this.migrationContext.GetGhostTableName(),
this.migrationContext.SharedColumns.Names,
this.migrationContext.MappedSharedColumns.Names,
this.migrationContext.UniqueKey.Name,
this.migrationContext.UniqueKey.Columns.Names,
this.migrationContext.MigrationIterationRangeMinValues.AbstractValues(),
this.migrationContext.MigrationIterationRangeMaxValues.AbstractValues(),
this.migrationContext.GetIteration() == 0,
this.migrationContext.IsTransactionalTable(),
)
if err != nil {
return chunkSize, rowsAffected, duration, err
}
sqlResult, err := sqlutils.Exec(this.db, query, explodedArgs...)
if err != nil {
return chunkSize, rowsAffected, duration, err
}
rowsAffected, _ = sqlResult.RowsAffected()
duration = time.Since(startTime)
log.Debugf(
"Issued INSERT on range: [%s]..[%s]; iteration: %d; chunk-size: %d",
this.migrationContext.MigrationIterationRangeMinValues,
this.migrationContext.MigrationIterationRangeMaxValues,
this.migrationContext.GetIteration(),
chunkSize)
return chunkSize, rowsAffected, duration, nil
}
// LockOriginalTable places a write lock on the original table
func (this *Applier) LockOriginalTable() error {
query := fmt.Sprintf(`lock /* gh-ost */ tables %s.%s write`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
)
log.Infof("Locking %s.%s",
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
)
this.migrationContext.LockTablesStartTime = time.Now()
if _, err := sqlutils.ExecNoPrepare(this.singletonDB, query); err != nil {
return err
}
log.Infof("Table locked")
return nil
}
// UnlockTables makes tea. No wait, it unlocks tables.
func (this *Applier) UnlockTables() error {
query := `unlock /* gh-ost */ tables`
log.Infof("Unlocking tables")
if _, err := sqlutils.ExecNoPrepare(this.singletonDB, query); err != nil {
return err
}
log.Infof("Tables unlocked")
return nil
}
// SwapTablesQuickAndBumpy issues a two-step swap table operation:
// - rename original table to _old
// - rename ghost table to original
// There is a point in time in between where the table does not exist.
func (this *Applier) SwapTablesQuickAndBumpy() error {
query := fmt.Sprintf(`alter /* gh-ost */ table %s.%s rename %s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
sql.EscapeName(this.migrationContext.GetOldTableName()),
)
log.Infof("Renaming original table")
this.migrationContext.RenameTablesStartTime = time.Now()
if _, err := sqlutils.ExecNoPrepare(this.singletonDB, query); err != nil {
return err
}
query = fmt.Sprintf(`alter /* gh-ost */ table %s.%s rename %s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetGhostTableName()),
sql.EscapeName(this.migrationContext.OriginalTableName),
)
log.Infof("Renaming ghost table")
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
return err
}
this.migrationContext.RenameTablesEndTime = time.Now()
log.Infof("Tables renamed")
return nil
}
// RenameTablesRollback renames back both table: original back to ghost,
// _old back to original. This is used by `--test-on-replica`
func (this *Applier) RenameTablesRollback() (renameError error) {
// Restoring tables to original names.
// We prefer the single, atomic operation:
query := fmt.Sprintf(`rename /* gh-ost */ table %s.%s to %s.%s, %s.%s to %s.%s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetGhostTableName()),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetOldTableName()),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
)
log.Infof("Renaming back both tables")
if _, err := sqlutils.ExecNoPrepare(this.db, query); err == nil {
return nil
}
// But, if for some reason the above was impossible to do, we rename one by one.
query = fmt.Sprintf(`rename /* gh-ost */ table %s.%s to %s.%s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetGhostTableName()),
)
log.Infof("Renaming back to ghost table")
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
renameError = err
}
query = fmt.Sprintf(`rename /* gh-ost */ table %s.%s to %s.%s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetOldTableName()),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
)
log.Infof("Renaming back to original table")
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
renameError = err
}
return log.Errore(renameError)
}
// StopSlaveIOThread is applicable with --test-on-replica; it stops the IO thread, duh.
// We need to keep the SQL thread active so as to complete processing received events,
// and have them written to the binary log, so that we can then read them via streamer.
func (this *Applier) StopSlaveIOThread() error {
query := `stop /* gh-ost */ slave io_thread`
log.Infof("Stopping replication")
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
return err
}
log.Infof("Replication stopped")
return nil
}
// StartSlaveSQLThread is applicable with --test-on-replica
func (this *Applier) StopSlaveSQLThread() error {
query := `stop /* gh-ost */ slave sql_thread`
log.Infof("Verifying SQL thread is stopped")
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
return err
}
log.Infof("SQL thread stopped")
return nil
}
// StartSlaveSQLThread is applicable with --test-on-replica
func (this *Applier) StartSlaveSQLThread() error {
query := `start /* gh-ost */ slave sql_thread`
log.Infof("Verifying SQL thread is running")
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
return err
}
log.Infof("SQL thread started")
return nil
}
// StopReplication is used by `--test-on-replica` and stops replication.
func (this *Applier) StopReplication() error {
if err := this.StopSlaveIOThread(); err != nil {
return err
}
if err := this.StopSlaveSQLThread(); err != nil {
return err
}
readBinlogCoordinates, executeBinlogCoordinates, err := mysql.GetReplicationBinlogCoordinates(this.db)
if err != nil {
return err
}
log.Infof("Replication IO thread at %+v. SQL thread is at %+v", *readBinlogCoordinates, *executeBinlogCoordinates)
return nil
}
// GetSessionLockName returns a name for the special hint session voluntary lock
func (this *Applier) GetSessionLockName(sessionId int64) string {
return fmt.Sprintf("gh-ost.%d.lock", sessionId)
}
// ExpectUsedLock expects the special hint voluntary lock to exist on given session
func (this *Applier) ExpectUsedLock(sessionId int64) error {
var result int64
query := `select is_used_lock(?)`
lockName := this.GetSessionLockName(sessionId)
log.Infof("Checking session lock: %s", lockName)
if err := this.db.QueryRow(query, lockName).Scan(&result); err != nil || result != sessionId {
return fmt.Errorf("Session lock %s expected to be found but wasn't", lockName)
}
return nil
}
// ExpectProcess expects a process to show up in `SHOW PROCESSLIST` that has given characteristics
func (this *Applier) ExpectProcess(sessionId int64, stateHint, infoHint string) error {
found := false
query := `
select id
from information_schema.processlist
where
id != connection_id()
and ? in (0, id)
and state like concat('%', ?, '%')
and info like concat('%', ?, '%')
`
err := sqlutils.QueryRowsMap(this.db, query, func(m sqlutils.RowMap) error {
found = true
return nil
}, sessionId, stateHint, infoHint)
if err != nil {
return err
}
if !found {
return fmt.Errorf("Cannot find process. Hints: %s, %s", stateHint, infoHint)
}
return nil
}
// DropAtomicCutOverSentryTableIfExists checks if the "old" table name
// happens to be a cut-over magic table; if so, it drops it.
func (this *Applier) DropAtomicCutOverSentryTableIfExists() error {
log.Infof("Looking for magic cut-over table")
tableName := this.migrationContext.GetOldTableName()
rowMap := this.showTableStatus(tableName)
if rowMap == nil {
// Table does not exist
return nil
}
if rowMap["Comment"].String != atomicCutOverMagicHint {
return fmt.Errorf("Expected magic comment on %s, did not find it", tableName)
}
log.Infof("Dropping magic cut-over table")
return this.dropTable(tableName)
}
// DropAtomicCutOverSentryTableIfExists checks if the "old" table name
// happens to be a cut-over magic table; if so, it drops it.
func (this *Applier) CreateAtomicCutOverSentryTable() error {
if err := this.DropAtomicCutOverSentryTableIfExists(); err != nil {
return err
}
tableName := this.migrationContext.GetOldTableName()
query := fmt.Sprintf(`create /* gh-ost */ table %s.%s (
id int auto_increment primary key
) comment='%s'
`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(tableName),
atomicCutOverMagicHint,
)
log.Infof("Creating magic cut-over table %s.%s",
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(tableName),
)
if _, err := sqlutils.ExecNoPrepare(this.db, query); err != nil {
return err
}
log.Infof("Magic cut-over table created")
return nil
}
// AtomicCutOverMagicLock
func (this *Applier) AtomicCutOverMagicLock(sessionIdChan chan int64, tableLocked chan<- error, okToUnlockTable <-chan bool, tableUnlocked chan<- error) error {
tx, err := this.db.Begin()
if err != nil {
tableLocked <- err
return err
}
defer func() {
sessionIdChan <- -1
tableLocked <- fmt.Errorf("Unexpected error in AtomicCutOverMagicLock(), injected to release blocking channel reads")
tableUnlocked <- fmt.Errorf("Unexpected error in AtomicCutOverMagicLock(), injected to release blocking channel reads")
tx.Rollback()
}()
var sessionId int64
if err := tx.QueryRow(`select connection_id()`).Scan(&sessionId); err != nil {
tableLocked <- err
return err
}
sessionIdChan <- sessionId
lockResult := 0
query := `select get_lock(?, 0)`
lockName := this.GetSessionLockName(sessionId)
log.Infof("Grabbing voluntary lock: %s", lockName)
if err := tx.QueryRow(query, lockName).Scan(&lockResult); err != nil || lockResult != 1 {
err := fmt.Errorf("Unable to acquire lock %s", lockName)
tableLocked <- err
return err
}
tableLockTimeoutSeconds := this.migrationContext.CutOverLockTimeoutSeconds * 2
log.Infof("Setting LOCK timeout as %d seconds", tableLockTimeoutSeconds)
query = fmt.Sprintf(`set session lock_wait_timeout:=%d`, tableLockTimeoutSeconds)
if _, err := tx.Exec(query); err != nil {
tableLocked <- err
return err
}
if err := this.CreateAtomicCutOverSentryTable(); err != nil {
tableLocked <- err
return err
}
query = fmt.Sprintf(`lock /* gh-ost */ tables %s.%s write, %s.%s write`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetOldTableName()),
)
log.Infof("Locking %s.%s, %s.%s",
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetOldTableName()),
)
this.migrationContext.LockTablesStartTime = time.Now()
if _, err := tx.Exec(query); err != nil {
tableLocked <- err
return err
}
log.Infof("Tables locked")
tableLocked <- nil // No error.
// From this point on, we are committed to UNLOCK TABLES. No matter what happens,
// the UNLOCK must execute (or, alternatively, this connection dies, which gets the same impact)
// The cut-over phase will proceed to apply remaining backlog onto ghost table,
// and issue RENAME. We wait here until told to proceed.
<-okToUnlockTable
log.Infof("Will now proceed to drop magic table and unlock tables")
// The magic table is here because we locked it. And we are the only ones allowed to drop it.
// And in fact, we will:
log.Infof("Dropping magic cut-over table")
query = fmt.Sprintf(`drop /* gh-ost */ table if exists %s.%s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetOldTableName()),
)
if _, err := tx.Exec(query); err != nil {
log.Errore(err)
// We DO NOT return here because we must `UNLOCK TABLES`!
}
// Tables still locked
log.Infof("Releasing lock from %s.%s, %s.%s",
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetOldTableName()),
)
query = `unlock tables`
if _, err := tx.Exec(query); err != nil {
tableUnlocked <- err
return log.Errore(err)
}
log.Infof("Tables unlocked")
tableUnlocked <- nil
return nil
}
// AtomicCutoverRename
func (this *Applier) AtomicCutoverRename(sessionIdChan chan int64, tablesRenamed chan<- error) error {
tx, err := this.db.Begin()
if err != nil {
return err
}
defer func() {
tx.Rollback()
sessionIdChan <- -1
tablesRenamed <- fmt.Errorf("Unexpected error in AtomicCutoverRename(), injected to release blocking channel reads")
}()
var sessionId int64
if err := tx.QueryRow(`select connection_id()`).Scan(&sessionId); err != nil {
return err
}
sessionIdChan <- sessionId
log.Infof("Setting RENAME timeout as %d seconds", this.migrationContext.CutOverLockTimeoutSeconds)
query := fmt.Sprintf(`set session lock_wait_timeout:=%d`, this.migrationContext.CutOverLockTimeoutSeconds)
if _, err := tx.Exec(query); err != nil {
return err
}
query = fmt.Sprintf(`rename /* gh-ost */ table %s.%s to %s.%s, %s.%s to %s.%s`,
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetOldTableName()),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.GetGhostTableName()),
sql.EscapeName(this.migrationContext.DatabaseName),
sql.EscapeName(this.migrationContext.OriginalTableName),
)
log.Infof("Issuing and expecting this to block: %s", query)
if _, err := tx.Exec(query); err != nil {
tablesRenamed <- err
return log.Errore(err)
}
tablesRenamed <- nil
log.Infof("Tables renamed")
return nil
}
func (this *Applier) ShowStatusVariable(variableName string) (result int64, err error) {
query := fmt.Sprintf(`show global status like '%s'`, variableName)
if err := this.db.QueryRow(query).Scan(&variableName, &result); err != nil {
return 0, err
}
return result, nil
}
// buildDMLEventQuery creates a query to operate on the ghost table, based on an intercepted binlog
// event entry on the original table.
func (this *Applier) buildDMLEventQuery(dmlEvent *binlog.BinlogDMLEvent) (query string, args []interface{}, rowsDelta int64, err error) {
switch dmlEvent.DML {
case binlog.DeleteDML:
{
query, uniqueKeyArgs, err := sql.BuildDMLDeleteQuery(dmlEvent.DatabaseName, this.migrationContext.GetGhostTableName(), this.migrationContext.OriginalTableColumns, &this.migrationContext.UniqueKey.Columns, dmlEvent.WhereColumnValues.AbstractValues())
return query, uniqueKeyArgs, -1, err
}
case binlog.InsertDML:
{
query, sharedArgs, err := sql.BuildDMLInsertQuery(dmlEvent.DatabaseName, this.migrationContext.GetGhostTableName(), this.migrationContext.OriginalTableColumns, this.migrationContext.MappedSharedColumns, dmlEvent.NewColumnValues.AbstractValues())
return query, sharedArgs, 1, err
}
case binlog.UpdateDML:
{
query, sharedArgs, uniqueKeyArgs, err := sql.BuildDMLUpdateQuery(dmlEvent.DatabaseName, this.migrationContext.GetGhostTableName(), this.migrationContext.OriginalTableColumns, this.migrationContext.MappedSharedColumns, &this.migrationContext.UniqueKey.Columns, dmlEvent.NewColumnValues.AbstractValues(), dmlEvent.WhereColumnValues.AbstractValues())
args = append(args, sharedArgs...)
args = append(args, uniqueKeyArgs...)
return query, args, 0, err
}
}
return "", args, 0, fmt.Errorf("Unknown dml event type: %+v", dmlEvent.DML)
}
// ApplyDMLEventQuery writes an entry to the ghost table, in response to an intercepted
// original-table binlog event
func (this *Applier) ApplyDMLEventQuery(dmlEvent *binlog.BinlogDMLEvent) error {
query, args, rowDelta, err := this.buildDMLEventQuery(dmlEvent)
if err != nil {
return err
}
_, err = sqlutils.Exec(this.db, query, args...)
if err == nil {
atomic.AddInt64(&this.migrationContext.TotalDMLEventsApplied, 1)
}
if this.migrationContext.CountTableRows {
atomic.AddInt64(&this.migrationContext.RowsEstimate, rowDelta)
}
if err != nil {
err = fmt.Errorf("%s; query=%s; args=%+v", err.Error(), query, args)
log.Errore(err)
}
return err
}