pkg/ioutils/bytespipe.go - third_party/github.com/moby/moby - Git at Google

 package ioutils

 import (
 	"errors"
 	"io"
 	"sync"
 )

 // maxCap is the highest capacity to use in byte slices that buffer data.
 const maxCap = 1e6

 // minCap is the lowest capacity to use in byte slices that buffer data
 const minCap = 64

 // blockThreshold is the minimum number of bytes in the buffer which will cause
 // a write to BytesPipe to block when allocating a new slice.
 const blockThreshold = 1e6

 var (
 	// ErrClosed is returned when Write is called on a closed BytesPipe.
 	ErrClosed = errors.New("write to closed BytesPipe")

 	bufPools     = make(map[int]*sync.Pool)
 	bufPoolsLock sync.Mutex
 )

 // BytesPipe is io.ReadWriteCloser which works similarly to pipe(queue).
 // All written data may be read at most once. Also, BytesPipe allocates
 // and releases new byte slices to adjust to current needs, so the buffer
 // won't be overgrown after peak loads.
 type BytesPipe struct {
 	mu       sync.Mutex
 	wait     *sync.Cond
 	buf      []*fixedBuffer
 	bufLen   int
 	closeErr error // error to return from next Read. set to nil if not closed.
 }

 // NewBytesPipe creates new BytesPipe, initialized by specified slice.
 // If buf is nil, then it will be initialized with slice which cap is 64.
 // buf will be adjusted in a way that len(buf) == 0, cap(buf) == cap(buf).
 func NewBytesPipe() *BytesPipe {
 	bp := &BytesPipe{}
 	bp.buf = append(bp.buf, getBuffer(minCap))
 	bp.wait = sync.NewCond(&bp.mu)
 	return bp
 }

 // Write writes p to BytesPipe.
 // It can allocate new []byte slices in a process of writing.
 func (bp *BytesPipe) Write(p []byte) (int, error) {
 	bp.mu.Lock()

 	written := 0
 loop0:
 	for {
 		if bp.closeErr != nil {
 			bp.mu.Unlock()
 			return written, ErrClosed
 		}

 		if len(bp.buf) == 0 {
 			bp.buf = append(bp.buf, getBuffer(64))
 		}
 		// get the last buffer
 		b := bp.buf[len(bp.buf)-1]

 		n, err := b.Write(p)
 		written += n
 		bp.bufLen += n

 		// errBufferFull is an error we expect to get if the buffer is full
 		if err != nil && err != errBufferFull {
 			bp.wait.Broadcast()
 			bp.mu.Unlock()
 			return written, err
 		}

 		// if there was enough room to write all then break
 		if len(p) == n {
 			break
 		}

 		// more data: write to the next slice
 		p = p[n:]

 		// make sure the buffer doesn't grow too big from this write
 		for bp.bufLen >= blockThreshold {
 			bp.wait.Wait()
 			if bp.closeErr != nil {
 				continue loop0
 			}
 		}

 		// add new byte slice to the buffers slice and continue writing
 		nextCap := b.Cap() * 2
 		if nextCap > maxCap {
 			nextCap = maxCap
 		}
 		bp.buf = append(bp.buf, getBuffer(nextCap))
 	}
 	bp.wait.Broadcast()
 	bp.mu.Unlock()
 	return written, nil
 }

 // CloseWithError causes further reads from a BytesPipe to return immediately.
 func (bp *BytesPipe) CloseWithError(err error) error {
 	bp.mu.Lock()
 	if err != nil {
 		bp.closeErr = err
 	} else {
 		bp.closeErr = io.EOF
 	}
 	bp.wait.Broadcast()
 	bp.mu.Unlock()
 	return nil
 }

 // Close causes further reads from a BytesPipe to return immediately.
 func (bp *BytesPipe) Close() error {
 	return bp.CloseWithError(nil)
 }

 // Read reads bytes from BytesPipe.
 // Data could be read only once.
 func (bp *BytesPipe) Read(p []byte) (n int, err error) {
 	bp.mu.Lock()
 	if bp.bufLen == 0 {
 		if bp.closeErr != nil {
 			bp.mu.Unlock()
 			return 0, bp.closeErr
 		}
 		bp.wait.Wait()
 		if bp.bufLen == 0 && bp.closeErr != nil {
 			err := bp.closeErr
 			bp.mu.Unlock()
 			return 0, err
 		}
 	}

 	for bp.bufLen > 0 {
 		b := bp.buf[0]
 		read, _ := b.Read(p) // ignore error since fixedBuffer doesn't really return an error
 		n += read
 		bp.bufLen -= read

 		if b.Len() == 0 {
 			// it's empty so return it to the pool and move to the next one
 			returnBuffer(b)
 			bp.buf[0] = nil
 			bp.buf = bp.buf[1:]
 		}

 		if len(p) == read {
 			break
 		}

 		p = p[read:]
 	}

 	bp.wait.Broadcast()
 	bp.mu.Unlock()
 	return
 }

 func returnBuffer(b *fixedBuffer) {
 	b.Reset()
 	bufPoolsLock.Lock()
 	pool := bufPools[b.Cap()]
 	bufPoolsLock.Unlock()
 	if pool != nil {
 		pool.Put(b)
 	}
 }

 func getBuffer(size int) *fixedBuffer {
 	bufPoolsLock.Lock()
 	pool, ok := bufPools[size]
 	if !ok {
 		pool = &sync.Pool{New: func() interface{} { return &fixedBuffer{buf: make([]byte, 0, size)} }}
 		bufPools[size] = pool
 	}
 	bufPoolsLock.Unlock()
 	return pool.Get().(*fixedBuffer)
 }
	package ioutils

	import (
	"errors"
	"io"
	"sync"
	)

	// maxCap is the highest capacity to use in byte slices that buffer data.
	const maxCap = 1e6

	// minCap is the lowest capacity to use in byte slices that buffer data
	const minCap = 64

	// blockThreshold is the minimum number of bytes in the buffer which will cause
	// a write to BytesPipe to block when allocating a new slice.
	const blockThreshold = 1e6

	var (
	// ErrClosed is returned when Write is called on a closed BytesPipe.
	ErrClosed = errors.New("write to closed BytesPipe")

	bufPools = make(map[int]*sync.Pool)
	bufPoolsLock sync.Mutex
	)

	// BytesPipe is io.ReadWriteCloser which works similarly to pipe(queue).
	// All written data may be read at most once. Also, BytesPipe allocates
	// and releases new byte slices to adjust to current needs, so the buffer
	// won't be overgrown after peak loads.
	type BytesPipe struct {
	mu sync.Mutex
	wait *sync.Cond
	buf []*fixedBuffer
	bufLen int
	closeErr error // error to return from next Read. set to nil if not closed.
	}

	// NewBytesPipe creates new BytesPipe, initialized by specified slice.
	// If buf is nil, then it will be initialized with slice which cap is 64.
	// buf will be adjusted in a way that len(buf) == 0, cap(buf) == cap(buf).
	func NewBytesPipe() *BytesPipe {
	bp := &BytesPipe{}
	bp.buf = append(bp.buf, getBuffer(minCap))
	bp.wait = sync.NewCond(&bp.mu)
	return bp
	}

	// Write writes p to BytesPipe.
	// It can allocate new []byte slices in a process of writing.
	func (bp *BytesPipe) Write(p []byte) (int, error) {
	bp.mu.Lock()

	written := 0
	loop0:
	for {
	if bp.closeErr != nil {
	bp.mu.Unlock()
	return written, ErrClosed
	}

	if len(bp.buf) == 0 {
	bp.buf = append(bp.buf, getBuffer(64))
	}
	// get the last buffer
	b := bp.buf[len(bp.buf)-1]

	n, err := b.Write(p)
	written += n
	bp.bufLen += n

	// errBufferFull is an error we expect to get if the buffer is full
	if err != nil && err != errBufferFull {
	bp.wait.Broadcast()
	bp.mu.Unlock()
	return written, err
	}

	// if there was enough room to write all then break
	if len(p) == n {
	break
	}

	// more data: write to the next slice
	p = p[n:]

	// make sure the buffer doesn't grow too big from this write
	for bp.bufLen >= blockThreshold {
	bp.wait.Wait()
	if bp.closeErr != nil {
	continue loop0
	}
	}

	// add new byte slice to the buffers slice and continue writing
	nextCap := b.Cap() * 2
	if nextCap > maxCap {
	nextCap = maxCap
	}
	bp.buf = append(bp.buf, getBuffer(nextCap))
	}
	bp.wait.Broadcast()
	bp.mu.Unlock()
	return written, nil
	}

	// CloseWithError causes further reads from a BytesPipe to return immediately.
	func (bp *BytesPipe) CloseWithError(err error) error {
	bp.mu.Lock()
	if err != nil {
	bp.closeErr = err
	} else {
	bp.closeErr = io.EOF
	}
	bp.wait.Broadcast()
	bp.mu.Unlock()
	return nil
	}

	// Close causes further reads from a BytesPipe to return immediately.
	func (bp *BytesPipe) Close() error {
	return bp.CloseWithError(nil)
	}

	// Read reads bytes from BytesPipe.
	// Data could be read only once.
	func (bp *BytesPipe) Read(p []byte) (n int, err error) {
	bp.mu.Lock()
	if bp.bufLen == 0 {
	if bp.closeErr != nil {
	bp.mu.Unlock()
	return 0, bp.closeErr
	}
	bp.wait.Wait()
	if bp.bufLen == 0 && bp.closeErr != nil {
	err := bp.closeErr
	bp.mu.Unlock()
	return 0, err
	}
	}

	for bp.bufLen > 0 {
	b := bp.buf[0]
	read, _ := b.Read(p) // ignore error since fixedBuffer doesn't really return an error
	n += read
	bp.bufLen -= read

	if b.Len() == 0 {
	// it's empty so return it to the pool and move to the next one
	returnBuffer(b)
	bp.buf[0] = nil
	bp.buf = bp.buf[1:]
	}

	if len(p) == read {
	break
	}

	p = p[read:]
	}

	bp.wait.Broadcast()
	bp.mu.Unlock()
	return
	}

	func returnBuffer(b *fixedBuffer) {
	b.Reset()
	bufPoolsLock.Lock()
	pool := bufPools[b.Cap()]
	bufPoolsLock.Unlock()
	if pool != nil {
	pool.Put(b)
	}
	}

	func getBuffer(size int) *fixedBuffer {
	bufPoolsLock.Lock()
	pool, ok := bufPools[size]
	if !ok {
	pool = &sync.Pool{New: func() interface{} { return &fixedBuffer{buf: make([]byte, 0, size)} }}
	bufPools[size] = pool
	}
	bufPoolsLock.Unlock()
	return pool.Get().(*fixedBuffer)
	}