mirror of
https://github.com/octoleo/syncthing.git
synced 2024-11-13 00:36:28 +00:00
65aaa607ab
Change made by: - running "gvt fetch" on each of the packages mentioned in Godeps/Godeps.json - `rm -rf Godeps` - tweaking the build scripts to not mention Godeps - tweaking the build scripts to test `./lib/...`, `./cmd/...` explicitly (to avoid testing vendor) - tweaking the build scripts to not juggle GOPATH for Godeps and instead set GO15VENDOREXPERIMENT. This also results in some updated packages at the same time I bet. Building with Go 1.3 and 1.4 still *works* but won't use our vendored dependencies - the user needs to have the actual packages in their GOPATH then, which they'll get with a normal "go get". Building with Go 1.6+ will get our vendored dependencies by default even when not using our build script, which is nice. By doing this we gain some freedom in that we can pick and choose manually what to include in vendor, as it's not based on just dependency analysis of our own code. This is also a risk as we might pick up dependencies we are unaware of, as the build may work locally with those packages present in GOPATH. On the other hand the build server will detect this as it has no packages in it's GOPATH beyond what is included in the repo. Recommended tool to manage dependencies is github.com/FiloSottile/gvt.
359 lines
7.7 KiB
Go
359 lines
7.7 KiB
Go
// Copyright (c) 2012, Suryandaru Triandana <syndtr@gmail.com>
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// All rights reserved.
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//
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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package leveldb
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import (
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"time"
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"github.com/syndtr/goleveldb/leveldb/memdb"
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"github.com/syndtr/goleveldb/leveldb/opt"
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"github.com/syndtr/goleveldb/leveldb/util"
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)
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func (db *DB) writeJournal(b *Batch) error {
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w, err := db.journal.Next()
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if err != nil {
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return err
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}
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if _, err := w.Write(b.encode()); err != nil {
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return err
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}
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if err := db.journal.Flush(); err != nil {
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return err
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}
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if b.sync {
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return db.journalWriter.Sync()
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}
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return nil
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}
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func (db *DB) jWriter() {
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defer db.closeW.Done()
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for {
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select {
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case b := <-db.journalC:
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if b != nil {
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db.journalAckC <- db.writeJournal(b)
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}
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case _, _ = <-db.closeC:
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return
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}
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}
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}
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func (db *DB) rotateMem(n int, wait bool) (mem *memDB, err error) {
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// Wait for pending memdb compaction.
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err = db.compTriggerWait(db.mcompCmdC)
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if err != nil {
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return
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}
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// Create new memdb and journal.
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mem, err = db.newMem(n)
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if err != nil {
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return
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}
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// Schedule memdb compaction.
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if wait {
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err = db.compTriggerWait(db.mcompCmdC)
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} else {
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db.compTrigger(db.mcompCmdC)
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}
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return
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}
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func (db *DB) flush(n int) (mdb *memDB, mdbFree int, err error) {
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delayed := false
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flush := func() (retry bool) {
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v := db.s.version()
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defer v.release()
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mdb = db.getEffectiveMem()
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defer func() {
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if retry {
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mdb.decref()
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mdb = nil
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}
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}()
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mdbFree = mdb.Free()
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switch {
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case v.tLen(0) >= db.s.o.GetWriteL0SlowdownTrigger() && !delayed:
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delayed = true
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time.Sleep(time.Millisecond)
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case mdbFree >= n:
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return false
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case v.tLen(0) >= db.s.o.GetWriteL0PauseTrigger():
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delayed = true
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err = db.compTriggerWait(db.tcompCmdC)
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if err != nil {
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return false
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}
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default:
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// Allow memdb to grow if it has no entry.
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if mdb.Len() == 0 {
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mdbFree = n
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} else {
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mdb.decref()
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mdb, err = db.rotateMem(n, false)
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if err == nil {
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mdbFree = mdb.Free()
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} else {
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mdbFree = 0
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}
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}
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return false
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}
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return true
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}
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start := time.Now()
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for flush() {
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}
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if delayed {
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db.writeDelay += time.Since(start)
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db.writeDelayN++
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} else if db.writeDelayN > 0 {
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db.logf("db@write was delayed N·%d T·%v", db.writeDelayN, db.writeDelay)
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db.writeDelay = 0
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db.writeDelayN = 0
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}
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return
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}
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// Write apply the given batch to the DB. The batch will be applied
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// sequentially.
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//
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// It is safe to modify the contents of the arguments after Write returns.
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func (db *DB) Write(b *Batch, wo *opt.WriteOptions) (err error) {
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err = db.ok()
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if err != nil || b == nil || b.Len() == 0 {
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return
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}
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b.init(wo.GetSync() && !db.s.o.GetNoSync())
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if b.size() > db.s.o.GetWriteBuffer() && !db.s.o.GetDisableLargeBatchTransaction() {
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// Writes using transaction.
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tr, err1 := db.OpenTransaction()
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if err1 != nil {
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return err1
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}
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if err1 := tr.Write(b, wo); err1 != nil {
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tr.Discard()
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return err1
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}
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return tr.Commit()
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}
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// The write happen synchronously.
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select {
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case db.writeC <- b:
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if <-db.writeMergedC {
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return <-db.writeAckC
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}
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// Continue, the write lock already acquired by previous writer
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// and handed out to us.
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case db.writeLockC <- struct{}{}:
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case err = <-db.compPerErrC:
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return
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case _, _ = <-db.closeC:
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return ErrClosed
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}
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merged := 0
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danglingMerge := false
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defer func() {
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if danglingMerge {
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// Only one dangling merge at most, so this is safe.
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db.writeMergedC <- false
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} else {
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<-db.writeLockC
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}
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for i := 0; i < merged; i++ {
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db.writeAckC <- err
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}
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}()
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mdb, mdbFree, err := db.flush(b.size())
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if err != nil {
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return
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}
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defer mdb.decref()
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// Calculate maximum size of the batch.
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m := 1 << 20
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if x := b.size(); x <= 128<<10 {
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m = x + (128 << 10)
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}
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m = minInt(m, mdbFree)
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// Merge with other batch.
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drain:
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for b.size() < m && !b.sync {
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select {
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case nb := <-db.writeC:
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if b.size()+nb.size() <= m {
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b.append(nb)
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db.writeMergedC <- true
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merged++
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} else {
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danglingMerge = true
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break drain
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}
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default:
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break drain
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}
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}
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// Set batch first seq number relative from last seq.
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b.seq = db.seq + 1
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// Write journal concurrently if it is large enough.
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if b.size() >= (128 << 10) {
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// Push the write batch to the journal writer
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select {
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case db.journalC <- b:
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// Write into memdb
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if berr := b.memReplay(mdb.DB); berr != nil {
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panic(berr)
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}
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case err = <-db.compPerErrC:
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return
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case _, _ = <-db.closeC:
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err = ErrClosed
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return
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}
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// Wait for journal writer
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select {
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case err = <-db.journalAckC:
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if err != nil {
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// Revert memdb if error detected
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if berr := b.revertMemReplay(mdb.DB); berr != nil {
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panic(berr)
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}
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return
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}
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case _, _ = <-db.closeC:
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err = ErrClosed
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return
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}
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} else {
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err = db.writeJournal(b)
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if err != nil {
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return
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}
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if berr := b.memReplay(mdb.DB); berr != nil {
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panic(berr)
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}
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}
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// Set last seq number.
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db.addSeq(uint64(b.Len()))
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if b.size() >= mdbFree {
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db.rotateMem(0, false)
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}
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return
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}
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// Put sets the value for the given key. It overwrites any previous value
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// for that key; a DB is not a multi-map.
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//
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// It is safe to modify the contents of the arguments after Put returns.
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func (db *DB) Put(key, value []byte, wo *opt.WriteOptions) error {
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b := new(Batch)
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b.Put(key, value)
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return db.Write(b, wo)
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}
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// Delete deletes the value for the given key.
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//
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// It is safe to modify the contents of the arguments after Delete returns.
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func (db *DB) Delete(key []byte, wo *opt.WriteOptions) error {
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b := new(Batch)
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b.Delete(key)
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return db.Write(b, wo)
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}
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func isMemOverlaps(icmp *iComparer, mem *memdb.DB, min, max []byte) bool {
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iter := mem.NewIterator(nil)
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defer iter.Release()
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return (max == nil || (iter.First() && icmp.uCompare(max, internalKey(iter.Key()).ukey()) >= 0)) &&
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(min == nil || (iter.Last() && icmp.uCompare(min, internalKey(iter.Key()).ukey()) <= 0))
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}
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// CompactRange compacts the underlying DB for the given key range.
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// In particular, deleted and overwritten versions are discarded,
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// and the data is rearranged to reduce the cost of operations
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// needed to access the data. This operation should typically only
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// be invoked by users who understand the underlying implementation.
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//
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// A nil Range.Start is treated as a key before all keys in the DB.
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// And a nil Range.Limit is treated as a key after all keys in the DB.
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// Therefore if both is nil then it will compact entire DB.
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func (db *DB) CompactRange(r util.Range) error {
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if err := db.ok(); err != nil {
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return err
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}
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// Lock writer.
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select {
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case db.writeLockC <- struct{}{}:
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case err := <-db.compPerErrC:
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return err
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case _, _ = <-db.closeC:
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return ErrClosed
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}
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// Check for overlaps in memdb.
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mdb := db.getEffectiveMem()
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defer mdb.decref()
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if isMemOverlaps(db.s.icmp, mdb.DB, r.Start, r.Limit) {
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// Memdb compaction.
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if _, err := db.rotateMem(0, false); err != nil {
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<-db.writeLockC
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return err
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}
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<-db.writeLockC
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if err := db.compTriggerWait(db.mcompCmdC); err != nil {
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return err
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}
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} else {
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<-db.writeLockC
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}
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// Table compaction.
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return db.compTriggerRange(db.tcompCmdC, -1, r.Start, r.Limit)
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}
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// SetReadOnly makes DB read-only. It will stay read-only until reopened.
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func (db *DB) SetReadOnly() error {
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if err := db.ok(); err != nil {
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return err
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}
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// Lock writer.
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select {
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case db.writeLockC <- struct{}{}:
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db.compWriteLocking = true
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case err := <-db.compPerErrC:
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return err
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case _, _ = <-db.closeC:
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return ErrClosed
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}
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// Set compaction read-only.
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select {
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case db.compErrSetC <- ErrReadOnly:
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case perr := <-db.compPerErrC:
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return perr
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case _, _ = <-db.closeC:
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return ErrClosed
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}
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return nil
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}
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