go-ethereum/vendor/github.com/syndtr/goleveldb/leveldb/db_compaction.go
Péter Szilágyi 289b30715d Godeps, vendor: convert dependency management to trash (#3198)
This commit converts the dependency management from Godeps to the vendor
folder, also switching the tool from godep to trash. Since the upstream tool
lacks a few features proposed via a few PRs, until those PRs are merged in
(if), use github.com/karalabe/trash.

You can update dependencies via trash --update.

All dependencies have been updated to their latest version.

Parts of the build system are reworked to drop old notions of Godeps and
invocation of the go vet command so that it doesn't run against the vendor
folder, as that will just blow up during vetting.

The conversion drops OpenCL (and hence GPU mining support) from ethash and our
codebase. The short reasoning is that there's noone to maintain and having
opencl libs in our deps messes up builds as go install ./... tries to build
them, failing with unsatisfied link errors for the C OpenCL deps.

golang.org/x/net/context is not vendored in. We expect it to be fetched by the
user (i.e. using go get). To keep ci.go builds reproducible the package is
"vendored" in build/_vendor.
2016-10-28 19:05:01 +02:00

827 lines
17 KiB
Go

// Copyright (c) 2012, Suryandaru Triandana <syndtr@gmail.com>
// All rights reserved.
//
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
package leveldb
import (
"sync"
"time"
"github.com/syndtr/goleveldb/leveldb/errors"
"github.com/syndtr/goleveldb/leveldb/opt"
"github.com/syndtr/goleveldb/leveldb/storage"
)
var (
errCompactionTransactExiting = errors.New("leveldb: compaction transact exiting")
)
type cStat struct {
duration time.Duration
read int64
write int64
}
func (p *cStat) add(n *cStatStaging) {
p.duration += n.duration
p.read += n.read
p.write += n.write
}
func (p *cStat) get() (duration time.Duration, read, write int64) {
return p.duration, p.read, p.write
}
type cStatStaging struct {
start time.Time
duration time.Duration
on bool
read int64
write int64
}
func (p *cStatStaging) startTimer() {
if !p.on {
p.start = time.Now()
p.on = true
}
}
func (p *cStatStaging) stopTimer() {
if p.on {
p.duration += time.Since(p.start)
p.on = false
}
}
type cStats struct {
lk sync.Mutex
stats []cStat
}
func (p *cStats) addStat(level int, n *cStatStaging) {
p.lk.Lock()
if level >= len(p.stats) {
newStats := make([]cStat, level+1)
copy(newStats, p.stats)
p.stats = newStats
}
p.stats[level].add(n)
p.lk.Unlock()
}
func (p *cStats) getStat(level int) (duration time.Duration, read, write int64) {
p.lk.Lock()
defer p.lk.Unlock()
if level < len(p.stats) {
return p.stats[level].get()
}
return
}
func (db *DB) compactionError() {
var err error
noerr:
// No error.
for {
select {
case err = <-db.compErrSetC:
switch {
case err == nil:
case err == ErrReadOnly, errors.IsCorrupted(err):
goto hasperr
default:
goto haserr
}
case <-db.closeC:
return
}
}
haserr:
// Transient error.
for {
select {
case db.compErrC <- err:
case err = <-db.compErrSetC:
switch {
case err == nil:
goto noerr
case err == ErrReadOnly, errors.IsCorrupted(err):
goto hasperr
default:
}
case <-db.closeC:
return
}
}
hasperr:
// Persistent error.
for {
select {
case db.compErrC <- err:
case db.compPerErrC <- err:
case db.writeLockC <- struct{}{}:
// Hold write lock, so that write won't pass-through.
db.compWriteLocking = true
case <-db.closeC:
if db.compWriteLocking {
// We should release the lock or Close will hang.
<-db.writeLockC
}
return
}
}
}
type compactionTransactCounter int
func (cnt *compactionTransactCounter) incr() {
*cnt++
}
type compactionTransactInterface interface {
run(cnt *compactionTransactCounter) error
revert() error
}
func (db *DB) compactionTransact(name string, t compactionTransactInterface) {
defer func() {
if x := recover(); x != nil {
if x == errCompactionTransactExiting {
if err := t.revert(); err != nil {
db.logf("%s revert error %q", name, err)
}
}
panic(x)
}
}()
const (
backoffMin = 1 * time.Second
backoffMax = 8 * time.Second
backoffMul = 2 * time.Second
)
var (
backoff = backoffMin
backoffT = time.NewTimer(backoff)
lastCnt = compactionTransactCounter(0)
disableBackoff = db.s.o.GetDisableCompactionBackoff()
)
for n := 0; ; n++ {
// Check whether the DB is closed.
if db.isClosed() {
db.logf("%s exiting", name)
db.compactionExitTransact()
} else if n > 0 {
db.logf("%s retrying N·%d", name, n)
}
// Execute.
cnt := compactionTransactCounter(0)
err := t.run(&cnt)
if err != nil {
db.logf("%s error I·%d %q", name, cnt, err)
}
// Set compaction error status.
select {
case db.compErrSetC <- err:
case perr := <-db.compPerErrC:
if err != nil {
db.logf("%s exiting (persistent error %q)", name, perr)
db.compactionExitTransact()
}
case <-db.closeC:
db.logf("%s exiting", name)
db.compactionExitTransact()
}
if err == nil {
return
}
if errors.IsCorrupted(err) {
db.logf("%s exiting (corruption detected)", name)
db.compactionExitTransact()
}
if !disableBackoff {
// Reset backoff duration if counter is advancing.
if cnt > lastCnt {
backoff = backoffMin
lastCnt = cnt
}
// Backoff.
backoffT.Reset(backoff)
if backoff < backoffMax {
backoff *= backoffMul
if backoff > backoffMax {
backoff = backoffMax
}
}
select {
case <-backoffT.C:
case <-db.closeC:
db.logf("%s exiting", name)
db.compactionExitTransact()
}
}
}
}
type compactionTransactFunc struct {
runFunc func(cnt *compactionTransactCounter) error
revertFunc func() error
}
func (t *compactionTransactFunc) run(cnt *compactionTransactCounter) error {
return t.runFunc(cnt)
}
func (t *compactionTransactFunc) revert() error {
if t.revertFunc != nil {
return t.revertFunc()
}
return nil
}
func (db *DB) compactionTransactFunc(name string, run func(cnt *compactionTransactCounter) error, revert func() error) {
db.compactionTransact(name, &compactionTransactFunc{run, revert})
}
func (db *DB) compactionExitTransact() {
panic(errCompactionTransactExiting)
}
func (db *DB) compactionCommit(name string, rec *sessionRecord) {
db.compCommitLk.Lock()
defer db.compCommitLk.Unlock() // Defer is necessary.
db.compactionTransactFunc(name+"@commit", func(cnt *compactionTransactCounter) error {
return db.s.commit(rec)
}, nil)
}
func (db *DB) memCompaction() {
mdb := db.getFrozenMem()
if mdb == nil {
return
}
defer mdb.decref()
db.logf("memdb@flush N·%d S·%s", mdb.Len(), shortenb(mdb.Size()))
// Don't compact empty memdb.
if mdb.Len() == 0 {
db.logf("memdb@flush skipping")
// drop frozen memdb
db.dropFrozenMem()
return
}
// Pause table compaction.
resumeC := make(chan struct{})
select {
case db.tcompPauseC <- (chan<- struct{})(resumeC):
case <-db.compPerErrC:
close(resumeC)
resumeC = nil
case <-db.closeC:
return
}
var (
rec = &sessionRecord{}
stats = &cStatStaging{}
flushLevel int
)
// Generate tables.
db.compactionTransactFunc("memdb@flush", func(cnt *compactionTransactCounter) (err error) {
stats.startTimer()
flushLevel, err = db.s.flushMemdb(rec, mdb.DB, db.memdbMaxLevel)
stats.stopTimer()
return
}, func() error {
for _, r := range rec.addedTables {
db.logf("memdb@flush revert @%d", r.num)
if err := db.s.stor.Remove(storage.FileDesc{Type: storage.TypeTable, Num: r.num}); err != nil {
return err
}
}
return nil
})
rec.setJournalNum(db.journalFd.Num)
rec.setSeqNum(db.frozenSeq)
// Commit.
stats.startTimer()
db.compactionCommit("memdb", rec)
stats.stopTimer()
db.logf("memdb@flush committed F·%d T·%v", len(rec.addedTables), stats.duration)
for _, r := range rec.addedTables {
stats.write += r.size
}
db.compStats.addStat(flushLevel, stats)
// Drop frozen memdb.
db.dropFrozenMem()
// Resume table compaction.
if resumeC != nil {
select {
case <-resumeC:
close(resumeC)
case <-db.closeC:
return
}
}
// Trigger table compaction.
db.compTrigger(db.tcompCmdC)
}
type tableCompactionBuilder struct {
db *DB
s *session
c *compaction
rec *sessionRecord
stat0, stat1 *cStatStaging
snapHasLastUkey bool
snapLastUkey []byte
snapLastSeq uint64
snapIter int
snapKerrCnt int
snapDropCnt int
kerrCnt int
dropCnt int
minSeq uint64
strict bool
tableSize int
tw *tWriter
}
func (b *tableCompactionBuilder) appendKV(key, value []byte) error {
// Create new table if not already.
if b.tw == nil {
// Check for pause event.
if b.db != nil {
select {
case ch := <-b.db.tcompPauseC:
b.db.pauseCompaction(ch)
case <-b.db.closeC:
b.db.compactionExitTransact()
default:
}
}
// Create new table.
var err error
b.tw, err = b.s.tops.create()
if err != nil {
return err
}
}
// Write key/value into table.
return b.tw.append(key, value)
}
func (b *tableCompactionBuilder) needFlush() bool {
return b.tw.tw.BytesLen() >= b.tableSize
}
func (b *tableCompactionBuilder) flush() error {
t, err := b.tw.finish()
if err != nil {
return err
}
b.rec.addTableFile(b.c.sourceLevel+1, t)
b.stat1.write += t.size
b.s.logf("table@build created L%d@%d N·%d S·%s %q:%q", b.c.sourceLevel+1, t.fd.Num, b.tw.tw.EntriesLen(), shortenb(int(t.size)), t.imin, t.imax)
b.tw = nil
return nil
}
func (b *tableCompactionBuilder) cleanup() {
if b.tw != nil {
b.tw.drop()
b.tw = nil
}
}
func (b *tableCompactionBuilder) run(cnt *compactionTransactCounter) error {
snapResumed := b.snapIter > 0
hasLastUkey := b.snapHasLastUkey // The key might has zero length, so this is necessary.
lastUkey := append([]byte{}, b.snapLastUkey...)
lastSeq := b.snapLastSeq
b.kerrCnt = b.snapKerrCnt
b.dropCnt = b.snapDropCnt
// Restore compaction state.
b.c.restore()
defer b.cleanup()
b.stat1.startTimer()
defer b.stat1.stopTimer()
iter := b.c.newIterator()
defer iter.Release()
for i := 0; iter.Next(); i++ {
// Incr transact counter.
cnt.incr()
// Skip until last state.
if i < b.snapIter {
continue
}
resumed := false
if snapResumed {
resumed = true
snapResumed = false
}
ikey := iter.Key()
ukey, seq, kt, kerr := parseInternalKey(ikey)
if kerr == nil {
shouldStop := !resumed && b.c.shouldStopBefore(ikey)
if !hasLastUkey || b.s.icmp.uCompare(lastUkey, ukey) != 0 {
// First occurrence of this user key.
// Only rotate tables if ukey doesn't hop across.
if b.tw != nil && (shouldStop || b.needFlush()) {
if err := b.flush(); err != nil {
return err
}
// Creates snapshot of the state.
b.c.save()
b.snapHasLastUkey = hasLastUkey
b.snapLastUkey = append(b.snapLastUkey[:0], lastUkey...)
b.snapLastSeq = lastSeq
b.snapIter = i
b.snapKerrCnt = b.kerrCnt
b.snapDropCnt = b.dropCnt
}
hasLastUkey = true
lastUkey = append(lastUkey[:0], ukey...)
lastSeq = keyMaxSeq
}
switch {
case lastSeq <= b.minSeq:
// Dropped because newer entry for same user key exist
fallthrough // (A)
case kt == keyTypeDel && seq <= b.minSeq && b.c.baseLevelForKey(lastUkey):
// For this user key:
// (1) there is no data in higher levels
// (2) data in lower levels will have larger seq numbers
// (3) data in layers that are being compacted here and have
// smaller seq numbers will be dropped in the next
// few iterations of this loop (by rule (A) above).
// Therefore this deletion marker is obsolete and can be dropped.
lastSeq = seq
b.dropCnt++
continue
default:
lastSeq = seq
}
} else {
if b.strict {
return kerr
}
// Don't drop corrupted keys.
hasLastUkey = false
lastUkey = lastUkey[:0]
lastSeq = keyMaxSeq
b.kerrCnt++
}
if err := b.appendKV(ikey, iter.Value()); err != nil {
return err
}
}
if err := iter.Error(); err != nil {
return err
}
// Finish last table.
if b.tw != nil && !b.tw.empty() {
return b.flush()
}
return nil
}
func (b *tableCompactionBuilder) revert() error {
for _, at := range b.rec.addedTables {
b.s.logf("table@build revert @%d", at.num)
if err := b.s.stor.Remove(storage.FileDesc{Type: storage.TypeTable, Num: at.num}); err != nil {
return err
}
}
return nil
}
func (db *DB) tableCompaction(c *compaction, noTrivial bool) {
defer c.release()
rec := &sessionRecord{}
rec.addCompPtr(c.sourceLevel, c.imax)
if !noTrivial && c.trivial() {
t := c.levels[0][0]
db.logf("table@move L%d@%d -> L%d", c.sourceLevel, t.fd.Num, c.sourceLevel+1)
rec.delTable(c.sourceLevel, t.fd.Num)
rec.addTableFile(c.sourceLevel+1, t)
db.compactionCommit("table-move", rec)
return
}
var stats [2]cStatStaging
for i, tables := range c.levels {
for _, t := range tables {
stats[i].read += t.size
// Insert deleted tables into record
rec.delTable(c.sourceLevel+i, t.fd.Num)
}
}
sourceSize := int(stats[0].read + stats[1].read)
minSeq := db.minSeq()
db.logf("table@compaction L%d·%d -> L%d·%d S·%s Q·%d", c.sourceLevel, len(c.levels[0]), c.sourceLevel+1, len(c.levels[1]), shortenb(sourceSize), minSeq)
b := &tableCompactionBuilder{
db: db,
s: db.s,
c: c,
rec: rec,
stat1: &stats[1],
minSeq: minSeq,
strict: db.s.o.GetStrict(opt.StrictCompaction),
tableSize: db.s.o.GetCompactionTableSize(c.sourceLevel + 1),
}
db.compactionTransact("table@build", b)
// Commit.
stats[1].startTimer()
db.compactionCommit("table", rec)
stats[1].stopTimer()
resultSize := int(stats[1].write)
db.logf("table@compaction committed F%s S%s Ke·%d D·%d T·%v", sint(len(rec.addedTables)-len(rec.deletedTables)), sshortenb(resultSize-sourceSize), b.kerrCnt, b.dropCnt, stats[1].duration)
// Save compaction stats
for i := range stats {
db.compStats.addStat(c.sourceLevel+1, &stats[i])
}
}
func (db *DB) tableRangeCompaction(level int, umin, umax []byte) error {
db.logf("table@compaction range L%d %q:%q", level, umin, umax)
if level >= 0 {
if c := db.s.getCompactionRange(level, umin, umax, true); c != nil {
db.tableCompaction(c, true)
}
} else {
// Retry until nothing to compact.
for {
compacted := false
// Scan for maximum level with overlapped tables.
v := db.s.version()
m := 1
for i := m; i < len(v.levels); i++ {
tables := v.levels[i]
if tables.overlaps(db.s.icmp, umin, umax, false) {
m = i
}
}
v.release()
for level := 0; level < m; level++ {
if c := db.s.getCompactionRange(level, umin, umax, false); c != nil {
db.tableCompaction(c, true)
compacted = true
}
}
if !compacted {
break
}
}
}
return nil
}
func (db *DB) tableAutoCompaction() {
if c := db.s.pickCompaction(); c != nil {
db.tableCompaction(c, false)
}
}
func (db *DB) tableNeedCompaction() bool {
v := db.s.version()
defer v.release()
return v.needCompaction()
}
func (db *DB) pauseCompaction(ch chan<- struct{}) {
select {
case ch <- struct{}{}:
case <-db.closeC:
db.compactionExitTransact()
}
}
type cCmd interface {
ack(err error)
}
type cAuto struct {
ackC chan<- error
}
func (r cAuto) ack(err error) {
if r.ackC != nil {
defer func() {
recover()
}()
r.ackC <- err
}
}
type cRange struct {
level int
min, max []byte
ackC chan<- error
}
func (r cRange) ack(err error) {
if r.ackC != nil {
defer func() {
recover()
}()
r.ackC <- err
}
}
// This will trigger auto compaction but will not wait for it.
func (db *DB) compTrigger(compC chan<- cCmd) {
select {
case compC <- cAuto{}:
default:
}
}
// This will trigger auto compaction and/or wait for all compaction to be done.
func (db *DB) compTriggerWait(compC chan<- cCmd) (err error) {
ch := make(chan error)
defer close(ch)
// Send cmd.
select {
case compC <- cAuto{ch}:
case err = <-db.compErrC:
return
case <-db.closeC:
return ErrClosed
}
// Wait cmd.
select {
case err = <-ch:
case err = <-db.compErrC:
case <-db.closeC:
return ErrClosed
}
return err
}
// Send range compaction request.
func (db *DB) compTriggerRange(compC chan<- cCmd, level int, min, max []byte) (err error) {
ch := make(chan error)
defer close(ch)
// Send cmd.
select {
case compC <- cRange{level, min, max, ch}:
case err := <-db.compErrC:
return err
case <-db.closeC:
return ErrClosed
}
// Wait cmd.
select {
case err = <-ch:
case err = <-db.compErrC:
case <-db.closeC:
return ErrClosed
}
return err
}
func (db *DB) mCompaction() {
var x cCmd
defer func() {
if x := recover(); x != nil {
if x != errCompactionTransactExiting {
panic(x)
}
}
if x != nil {
x.ack(ErrClosed)
}
db.closeW.Done()
}()
for {
select {
case x = <-db.mcompCmdC:
switch x.(type) {
case cAuto:
db.memCompaction()
x.ack(nil)
x = nil
default:
panic("leveldb: unknown command")
}
case <-db.closeC:
return
}
}
}
func (db *DB) tCompaction() {
var x cCmd
var ackQ []cCmd
defer func() {
if x := recover(); x != nil {
if x != errCompactionTransactExiting {
panic(x)
}
}
for i := range ackQ {
ackQ[i].ack(ErrClosed)
ackQ[i] = nil
}
if x != nil {
x.ack(ErrClosed)
}
db.closeW.Done()
}()
for {
if db.tableNeedCompaction() {
select {
case x = <-db.tcompCmdC:
case ch := <-db.tcompPauseC:
db.pauseCompaction(ch)
continue
case <-db.closeC:
return
default:
}
} else {
for i := range ackQ {
ackQ[i].ack(nil)
ackQ[i] = nil
}
ackQ = ackQ[:0]
select {
case x = <-db.tcompCmdC:
case ch := <-db.tcompPauseC:
db.pauseCompaction(ch)
continue
case <-db.closeC:
return
}
}
if x != nil {
switch cmd := x.(type) {
case cAuto:
ackQ = append(ackQ, x)
case cRange:
x.ack(db.tableRangeCompaction(cmd.level, cmd.min, cmd.max))
default:
panic("leveldb: unknown command")
}
x = nil
}
db.tableAutoCompaction()
}
}