// Write apply the given batch to the DB. The batch records will be applied // sequentially. Write might be used concurrently, when used concurrently and // batch is small enough, write will try to merge the batches. Set NoWriteMerge // option to true to disable write merge. // // It is safe to modify the contents of the arguments after Write returns but // not before. Write will not modify content of the batch. func (db *DB) Write(batch *Batch, wo *opt.WriteOptions) error { if err := db.ok(); err != nil || batch == nil || batch.Len() == 0 { return err } // If the batch size is larger than write buffer, it may justified to write // using transaction instead. Using transaction the batch will be written // into tables directly, skipping the journaling. if batch.internalLen > db.s.o.GetWriteBuffer() && !db.s.o.GetDisableLargeBatchTransaction() { tr, err := db.OpenTransaction() if err != nil { return err } if err := tr.Write(batch, wo); err != nil { tr.Discard() return err } return tr.Commit() } merge := !wo.GetNoWriteMerge() && !db.s.o.GetNoWriteMerge() sync := wo.GetSync() && !db.s.o.GetNoSync() // Acquire write lock. if merge { select { case db.writeMergeC <- writeMerge{sync: sync, batch: batch}: if <-db.writeMergedC { // Write is merged. return <-db.writeAckC } // Write is not merged, the write lock is handed to us. Continue. case db.writeLockC <- struct{}{}: // Write lock acquired. case err := <-db.compPerErrC: // Compaction error. return err case <-db.closeC: // Closed return ErrClosed } } else { select { case db.writeLockC <- struct{}{}: // Write lock acquired. case err := <-db.compPerErrC: // Compaction error. return err case <-db.closeC: // Closed return ErrClosed } } return db.writeLocked(batch, nil, merge, sync) }
func (db *DB) putRec(kt keyType, key, value []byte, wo *opt.WriteOptions) error { if err := db.ok(); err != nil { return err } merge := !wo.GetNoWriteMerge() && !db.s.o.GetNoWriteMerge() sync := wo.GetSync() && !db.s.o.GetNoSync() // Acquire write lock. if merge { select { case db.writeMergeC <- writeMerge{sync: sync, keyType: kt, key: key, value: value}: if <-db.writeMergedC { // Write is merged. return <-db.writeAckC } // Write is not merged, the write lock is handed to us. Continue. case db.writeLockC <- struct{}{}: // Write lock acquired. case err := <-db.compPerErrC: // Compaction error. return err case <-db.closeC: // Closed return ErrClosed } } else { select { case db.writeLockC <- struct{}{}: // Write lock acquired. case err := <-db.compPerErrC: // Compaction error. return err case <-db.closeC: // Closed return ErrClosed } } batch := db.batchPool.Get().(*Batch) batch.Reset() batch.appendRec(kt, key, value) return db.writeLocked(batch, batch, merge, sync) }
// Write apply the given batch to the DB. The batch will be applied // sequentially. // // It is safe to modify the contents of the arguments after Write returns. func (db *DB) Write(b *Batch, wo *opt.WriteOptions) (err error) { err = db.ok() if err != nil || b == nil || b.Len() == 0 { return } b.init(wo.GetSync() && !db.s.o.GetNoSync()) if b.size() > db.s.o.GetWriteBuffer() && !db.s.o.GetDisableLargeBatchTransaction() { // Writes using transaction. tr, err1 := db.OpenTransaction() if err1 != nil { return err1 } if err1 := tr.Write(b, wo); err1 != nil { tr.Discard() return err1 } return tr.Commit() } // The write happen synchronously. select { case db.writeC <- b: if <-db.writeMergedC { return <-db.writeAckC } // Continue, the write lock already acquired by previous writer // and handed out to us. case db.writeLockC <- struct{}{}: case err = <-db.compPerErrC: return case _, _ = <-db.closeC: return ErrClosed } merged := 0 danglingMerge := false defer func() { for i := 0; i < merged; i++ { db.writeAckC <- err } if danglingMerge { // Only one dangling merge at most, so this is safe. db.writeMergedC <- false } else { <-db.writeLockC } }() mdb, mdbFree, err := db.flush(b.size()) if err != nil { return } defer mdb.decref() // Calculate maximum size of the batch. m := 1 << 20 if x := b.size(); x <= 128<<10 { m = x + (128 << 10) } m = minInt(m, mdbFree) // Merge with other batch. drain: for b.size() < m && !b.sync { select { case nb := <-db.writeC: if b.size()+nb.size() <= m { b.append(nb) db.writeMergedC <- true merged++ } else { danglingMerge = true break drain } default: break drain } } // Set batch first seq number relative from last seq. b.seq = db.seq + 1 // Write journal concurrently if it is large enough. if b.size() >= (128 << 10) { // Push the write batch to the journal writer select { case db.journalC <- b: // Write into memdb if berr := b.memReplay(mdb.DB); berr != nil { panic(berr) } case err = <-db.compPerErrC: return case _, _ = <-db.closeC: err = ErrClosed return } // Wait for journal writer select { case err = <-db.journalAckC: if err != nil { // Revert memdb if error detected if berr := b.revertMemReplay(mdb.DB); berr != nil { panic(berr) } return } case _, _ = <-db.closeC: err = ErrClosed return } } else { err = db.writeJournal(b) if err != nil { return } if berr := b.memReplay(mdb.DB); berr != nil { panic(berr) } } // Set last seq number. db.addSeq(uint64(b.Len())) if b.size() >= mdbFree { db.rotateMem(0, false) } return }
// Write apply the given batch to the DB. The batch will be applied // sequentially. // // It is safe to modify the contents of the arguments after Write returns. func (d *DB) Write(b *Batch, wo *opt.WriteOptions) (err error) { err = d.ok() if err != nil || b == nil || b.len() == 0 { return } b.init(wo.GetSync()) // The write happen synchronously. select { case _, _ = <-d.closeCh: return ErrClosed case d.writeCh <- b: return <-d.writeAckCh case d.writeLockCh <- struct{}{}: } merged := 0 defer func() { <-d.writeLockCh for i := 0; i < merged; i++ { d.writeAckCh <- err } }() mem, err := d.flush() if err != nil { return } // Calculate maximum size of the batch. m := 1 << 20 if x := b.size(); x <= 128<<10 { m = x + (128 << 10) } // Merge with other batch. drain: for b.size() <= m && !b.sync { select { case nb := <-d.writeCh: b.append(nb) merged++ default: break drain } } // Set batch first seq number relative from last seq. b.seq = d.seq + 1 // Write journal concurrently if it is large enough. if b.size() >= (128 << 10) { // Push the write batch to the journal writer select { case _, _ = <-d.closeCh: err = ErrClosed return case d.journalCh <- b: // Write into memdb b.memReplay(mem) } // Wait for journal writer select { case _, _ = <-d.closeCh: err = ErrClosed return case err = <-d.journalAckCh: if err != nil { // Revert memdb if error detected b.revertMemReplay(mem) return } } } else { err = d.doWriteJournal(b) if err != nil { return } b.memReplay(mem) } // Set last seq number. d.addSeq(uint64(b.len())) return }
// Write apply the given batch to the DB. The batch will be applied // sequentially. // // It is safe to modify the contents of the arguments after Write returns. func (db *DB) Write(b *Batch, wo *opt.WriteOptions) (err error) { err = db.ok() if err != nil || b == nil || b.Len() == 0 { return } b.init(wo.GetSync()) // The write happen synchronously. select { case db.writeC <- b: if <-db.writeMergedC { return <-db.writeAckC } case db.writeLockC <- struct{}{}: case err = <-db.compPerErrC: return case _, _ = <-db.closeC: return ErrClosed } merged := 0 danglingMerge := false defer func() { if danglingMerge { db.writeMergedC <- false } else { <-db.writeLockC } for i := 0; i < merged; i++ { db.writeAckC <- err } }() mem, memFree, err := db.flush(b.size()) if err != nil { return } defer mem.decref() // Calculate maximum size of the batch. m := 1 << 20 if x := b.size(); x <= 128<<10 { m = x + (128 << 10) } m = minInt(m, memFree) // Merge with other batch. drain: for b.size() < m && !b.sync { select { case nb := <-db.writeC: if b.size()+nb.size() <= m { b.append(nb) db.writeMergedC <- true merged++ } else { danglingMerge = true break drain } default: break drain } } // Set batch first seq number relative from last seq. b.seq = db.seq + 1 // Write journal concurrently if it is large enough. if b.size() >= (128 << 10) { // Push the write batch to the journal writer select { case db.journalC <- b: // Write into memdb if berr := b.memReplay(mem.mdb); berr != nil { panic(berr) } case err = <-db.compPerErrC: return case _, _ = <-db.closeC: err = ErrClosed return } // Wait for journal writer select { case err = <-db.journalAckC: if err != nil { // Revert memdb if error detected if berr := b.revertMemReplay(mem.mdb); berr != nil { panic(berr) } return } case _, _ = <-db.closeC: err = ErrClosed return } } else { err = db.writeJournal(b) if err != nil { return } if berr := b.memReplay(mem.mdb); berr != nil { panic(berr) } } // Set last seq number. db.addSeq(uint64(b.Len())) if b.size() >= memFree { db.rotateMem(0) } return }