distribution/xfer/download.go - third_party/github.com/moby/moby - Git at Google

 package xfer // import "github.com/docker/docker/distribution/xfer"

 import (
 	"context"
 	"errors"
 	"fmt"
 	"io"
 	"runtime"
 	"time"

 	"github.com/docker/distribution"
 	"github.com/docker/docker/image"
 	"github.com/docker/docker/layer"
 	"github.com/docker/docker/pkg/archive"
 	"github.com/docker/docker/pkg/ioutils"
 	"github.com/docker/docker/pkg/progress"
 	"github.com/docker/docker/pkg/system"
 	"github.com/sirupsen/logrus"
 )

 const maxDownloadAttempts = 5

 // LayerDownloadManager figures out which layers need to be downloaded, then
 // registers and downloads those, taking into account dependencies between
 // layers.
 type LayerDownloadManager struct {
 	layerStores  map[string]layer.Store
 	tm           TransferManager
 	waitDuration time.Duration
 }

 // SetConcurrency sets the max concurrent downloads for each pull
 func (ldm *LayerDownloadManager) SetConcurrency(concurrency int) {
 	ldm.tm.SetConcurrency(concurrency)
 }

 // NewLayerDownloadManager returns a new LayerDownloadManager.
 func NewLayerDownloadManager(layerStores map[string]layer.Store, concurrencyLimit int, options ...func(*LayerDownloadManager)) *LayerDownloadManager {
 	manager := LayerDownloadManager{
 		layerStores:  layerStores,
 		tm:           NewTransferManager(concurrencyLimit),
 		waitDuration: time.Second,
 	}
 	for _, option := range options {
 		option(&manager)
 	}
 	return &manager
 }

 type downloadTransfer struct {
 	Transfer

 	layerStore layer.Store
 	layer      layer.Layer
 	err        error
 }

 // result returns the layer resulting from the download, if the download
 // and registration were successful.
 func (d *downloadTransfer) result() (layer.Layer, error) {
 	return d.layer, d.err
 }

 // A DownloadDescriptor references a layer that may need to be downloaded.
 type DownloadDescriptor interface {
 	// Key returns the key used to deduplicate downloads.
 	Key() string
 	// ID returns the ID for display purposes.
 	ID() string
 	// DiffID should return the DiffID for this layer, or an error
 	// if it is unknown (for example, if it has not been downloaded
 	// before).
 	DiffID() (layer.DiffID, error)
 	// Download is called to perform the download.
 	Download(ctx context.Context, progressOutput progress.Output) (io.ReadCloser, int64, error)
 	// Close is called when the download manager is finished with this
 	// descriptor and will not call Download again or read from the reader
 	// that Download returned.
 	Close()
 }

 // DownloadDescriptorWithRegistered is a DownloadDescriptor that has an
 // additional Registered method which gets called after a downloaded layer is
 // registered. This allows the user of the download manager to know the DiffID
 // of each registered layer. This method is called if a cast to
 // DownloadDescriptorWithRegistered is successful.
 type DownloadDescriptorWithRegistered interface {
 	DownloadDescriptor
 	Registered(diffID layer.DiffID)
 }

 // Download is a blocking function which ensures the requested layers are
 // present in the layer store. It uses the string returned by the Key method to
 // deduplicate downloads. If a given layer is not already known to present in
 // the layer store, and the key is not used by an in-progress download, the
 // Download method is called to get the layer tar data. Layers are then
 // registered in the appropriate order.  The caller must call the returned
 // release function once it is done with the returned RootFS object.
 func (ldm *LayerDownloadManager) Download(ctx context.Context, initialRootFS image.RootFS, os string, layers []DownloadDescriptor, progressOutput progress.Output) (image.RootFS, func(), error) {
 	var (
 		topLayer       layer.Layer
 		topDownload    *downloadTransfer
 		watcher        *Watcher
 		missingLayer   bool
 		transferKey    = ""
 		downloadsByKey = make(map[string]*downloadTransfer)
 	)

 	// Assume that the operating system is the host OS if blank, and validate it
 	// to ensure we don't cause a panic by an invalid index into the layerstores.
 	if os == "" {
 		os = runtime.GOOS
 	}
 	if !system.IsOSSupported(os) {
 		return image.RootFS{}, nil, system.ErrNotSupportedOperatingSystem
 	}

 	rootFS := initialRootFS
 	for _, descriptor := range layers {
 		key := descriptor.Key()
 		transferKey += key

 		if !missingLayer {
 			missingLayer = true
 			diffID, err := descriptor.DiffID()
 			if err == nil {
 				getRootFS := rootFS
 				getRootFS.Append(diffID)
 				l, err := ldm.layerStores[os].Get(getRootFS.ChainID())
 				if err == nil {
 					// Layer already exists.
 					logrus.Debugf("Layer already exists: %s", descriptor.ID())
 					progress.Update(progressOutput, descriptor.ID(), "Already exists")
 					if topLayer != nil {
 						layer.ReleaseAndLog(ldm.layerStores[os], topLayer)
 					}
 					topLayer = l
 					missingLayer = false
 					rootFS.Append(diffID)
 					// Register this repository as a source of this layer.
 					withRegistered, hasRegistered := descriptor.(DownloadDescriptorWithRegistered)
 					if hasRegistered { // As layerstore may set the driver
 						withRegistered.Registered(diffID)
 					}
 					continue
 				}
 			}
 		}

 		// Does this layer have the same data as a previous layer in
 		// the stack? If so, avoid downloading it more than once.
 		var topDownloadUncasted Transfer
 		if existingDownload, ok := downloadsByKey[key]; ok {
 			xferFunc := ldm.makeDownloadFuncFromDownload(descriptor, existingDownload, topDownload, os)
 			defer topDownload.Transfer.Release(watcher)
 			topDownloadUncasted, watcher = ldm.tm.Transfer(transferKey, xferFunc, progressOutput)
 			topDownload = topDownloadUncasted.(*downloadTransfer)
 			continue
 		}

 		// Layer is not known to exist - download and register it.
 		progress.Update(progressOutput, descriptor.ID(), "Pulling fs layer")

 		var xferFunc DoFunc
 		if topDownload != nil {
 			xferFunc = ldm.makeDownloadFunc(descriptor, "", topDownload, os)
 			defer topDownload.Transfer.Release(watcher)
 		} else {
 			xferFunc = ldm.makeDownloadFunc(descriptor, rootFS.ChainID(), nil, os)
 		}
 		topDownloadUncasted, watcher = ldm.tm.Transfer(transferKey, xferFunc, progressOutput)
 		topDownload = topDownloadUncasted.(*downloadTransfer)
 		downloadsByKey[key] = topDownload
 	}

 	if topDownload == nil {
 		return rootFS, func() {
 			if topLayer != nil {
 				layer.ReleaseAndLog(ldm.layerStores[os], topLayer)
 			}
 		}, nil
 	}

 	// Won't be using the list built up so far - will generate it
 	// from downloaded layers instead.
 	rootFS.DiffIDs = []layer.DiffID{}

 	defer func() {
 		if topLayer != nil {
 			layer.ReleaseAndLog(ldm.layerStores[os], topLayer)
 		}
 	}()

 	select {
 	case <-ctx.Done():
 		topDownload.Transfer.Release(watcher)
 		return rootFS, func() {}, ctx.Err()
 	case <-topDownload.Done():
 		break
 	}

 	l, err := topDownload.result()
 	if err != nil {
 		topDownload.Transfer.Release(watcher)
 		return rootFS, func() {}, err
 	}

 	// Must do this exactly len(layers) times, so we don't include the
 	// base layer on Windows.
 	for range layers {
 		if l == nil {
 			topDownload.Transfer.Release(watcher)
 			return rootFS, func() {}, errors.New("internal error: too few parent layers")
 		}
 		rootFS.DiffIDs = append([]layer.DiffID{l.DiffID()}, rootFS.DiffIDs...)
 		l = l.Parent()
 	}
 	return rootFS, func() { topDownload.Transfer.Release(watcher) }, err
 }

 // makeDownloadFunc returns a function that performs the layer download and
 // registration. If parentDownload is non-nil, it waits for that download to
 // complete before the registration step, and registers the downloaded data
 // on top of parentDownload's resulting layer. Otherwise, it registers the
 // layer on top of the ChainID given by parentLayer.
 func (ldm *LayerDownloadManager) makeDownloadFunc(descriptor DownloadDescriptor, parentLayer layer.ChainID, parentDownload *downloadTransfer, os string) DoFunc {
 	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
 		d := &downloadTransfer{
 			Transfer:   NewTransfer(),
 			layerStore: ldm.layerStores[os],
 		}

 		go func() {
 			defer func() {
 				close(progressChan)
 			}()

 			progressOutput := progress.ChanOutput(progressChan)

 			select {
 			case <-start:
 			default:
 				progress.Update(progressOutput, descriptor.ID(), "Waiting")
 				<-start
 			}

 			if parentDownload != nil {
 				// Did the parent download already fail or get
 				// cancelled?
 				select {
 				case <-parentDownload.Done():
 					_, err := parentDownload.result()
 					if err != nil {
 						d.err = err
 						return
 					}
 				default:
 				}
 			}

 			var (
 				downloadReader io.ReadCloser
 				size           int64
 				err            error
 				retries        int
 			)

 			defer descriptor.Close()

 			for {
 				downloadReader, size, err = descriptor.Download(d.Transfer.Context(), progressOutput)
 				if err == nil {
 					break
 				}

 				// If an error was returned because the context
 				// was cancelled, we shouldn't retry.
 				select {
 				case <-d.Transfer.Context().Done():
 					d.err = err
 					return
 				default:
 				}

 				retries++
 				if _, isDNR := err.(DoNotRetry); isDNR || retries == maxDownloadAttempts {
 					logrus.Errorf("Download failed: %v", err)
 					d.err = err
 					return
 				}

 				logrus.Errorf("Download failed, retrying: %v", err)
 				delay := retries * 5
 				ticker := time.NewTicker(ldm.waitDuration)

 			selectLoop:
 				for {
 					progress.Updatef(progressOutput, descriptor.ID(), "Retrying in %d second%s", delay, (map[bool]string{true: "s"})[delay != 1])
 					select {
 					case <-ticker.C:
 						delay--
 						if delay == 0 {
 							ticker.Stop()
 							break selectLoop
 						}
 					case <-d.Transfer.Context().Done():
 						ticker.Stop()
 						d.err = errors.New("download cancelled during retry delay")
 						return
 					}

 				}
 			}

 			close(inactive)

 			if parentDownload != nil {
 				select {
 				case <-d.Transfer.Context().Done():
 					d.err = errors.New("layer registration cancelled")
 					downloadReader.Close()
 					return
 				case <-parentDownload.Done():
 				}

 				l, err := parentDownload.result()
 				if err != nil {
 					d.err = err
 					downloadReader.Close()
 					return
 				}
 				parentLayer = l.ChainID()
 			}

 			reader := progress.NewProgressReader(ioutils.NewCancelReadCloser(d.Transfer.Context(), downloadReader), progressOutput, size, descriptor.ID(), "Extracting")
 			defer reader.Close()

 			inflatedLayerData, err := archive.DecompressStream(reader)
 			if err != nil {
 				d.err = fmt.Errorf("could not get decompression stream: %v", err)
 				return
 			}

 			var src distribution.Descriptor
 			if fs, ok := descriptor.(distribution.Describable); ok {
 				src = fs.Descriptor()
 			}
 			if ds, ok := d.layerStore.(layer.DescribableStore); ok {
 				d.layer, err = ds.RegisterWithDescriptor(inflatedLayerData, parentLayer, src)
 			} else {
 				d.layer, err = d.layerStore.Register(inflatedLayerData, parentLayer)
 			}
 			if err != nil {
 				select {
 				case <-d.Transfer.Context().Done():
 					d.err = errors.New("layer registration cancelled")
 				default:
 					d.err = fmt.Errorf("failed to register layer: %v", err)
 				}
 				return
 			}

 			progress.Update(progressOutput, descriptor.ID(), "Pull complete")
 			withRegistered, hasRegistered := descriptor.(DownloadDescriptorWithRegistered)
 			if hasRegistered {
 				withRegistered.Registered(d.layer.DiffID())
 			}

 			// Doesn't actually need to be its own goroutine, but
 			// done like this so we can defer close(c).
 			go func() {
 				<-d.Transfer.Released()
 				if d.layer != nil {
 					layer.ReleaseAndLog(d.layerStore, d.layer)
 				}
 			}()
 		}()

 		return d
 	}
 }

 // makeDownloadFuncFromDownload returns a function that performs the layer
 // registration when the layer data is coming from an existing download. It
 // waits for sourceDownload and parentDownload to complete, and then
 // reregisters the data from sourceDownload's top layer on top of
 // parentDownload. This function does not log progress output because it would
 // interfere with the progress reporting for sourceDownload, which has the same
 // Key.
 func (ldm *LayerDownloadManager) makeDownloadFuncFromDownload(descriptor DownloadDescriptor, sourceDownload *downloadTransfer, parentDownload *downloadTransfer, os string) DoFunc {
 	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
 		d := &downloadTransfer{
 			Transfer:   NewTransfer(),
 			layerStore: ldm.layerStores[os],
 		}

 		go func() {
 			defer func() {
 				close(progressChan)
 			}()

 			<-start

 			close(inactive)

 			select {
 			case <-d.Transfer.Context().Done():
 				d.err = errors.New("layer registration cancelled")
 				return
 			case <-parentDownload.Done():
 			}

 			l, err := parentDownload.result()
 			if err != nil {
 				d.err = err
 				return
 			}
 			parentLayer := l.ChainID()

 			// sourceDownload should have already finished if
 			// parentDownload finished, but wait for it explicitly
 			// to be sure.
 			select {
 			case <-d.Transfer.Context().Done():
 				d.err = errors.New("layer registration cancelled")
 				return
 			case <-sourceDownload.Done():
 			}

 			l, err = sourceDownload.result()
 			if err != nil {
 				d.err = err
 				return
 			}

 			layerReader, err := l.TarStream()
 			if err != nil {
 				d.err = err
 				return
 			}
 			defer layerReader.Close()

 			var src distribution.Descriptor
 			if fs, ok := l.(distribution.Describable); ok {
 				src = fs.Descriptor()
 			}
 			if ds, ok := d.layerStore.(layer.DescribableStore); ok {
 				d.layer, err = ds.RegisterWithDescriptor(layerReader, parentLayer, src)
 			} else {
 				d.layer, err = d.layerStore.Register(layerReader, parentLayer)
 			}
 			if err != nil {
 				d.err = fmt.Errorf("failed to register layer: %v", err)
 				return
 			}

 			withRegistered, hasRegistered := descriptor.(DownloadDescriptorWithRegistered)
 			if hasRegistered {
 				withRegistered.Registered(d.layer.DiffID())
 			}

 			// Doesn't actually need to be its own goroutine, but
 			// done like this so we can defer close(c).
 			go func() {
 				<-d.Transfer.Released()
 				if d.layer != nil {
 					layer.ReleaseAndLog(d.layerStore, d.layer)
 				}
 			}()
 		}()

 		return d
 	}
 }
	package xfer // import "github.com/docker/docker/distribution/xfer"

	import (
	"context"
	"errors"
	"fmt"
	"io"
	"runtime"
	"time"

	"github.com/docker/distribution"
	"github.com/docker/docker/image"
	"github.com/docker/docker/layer"
	"github.com/docker/docker/pkg/archive"
	"github.com/docker/docker/pkg/ioutils"
	"github.com/docker/docker/pkg/progress"
	"github.com/docker/docker/pkg/system"
	"github.com/sirupsen/logrus"
	)

	const maxDownloadAttempts = 5

	// LayerDownloadManager figures out which layers need to be downloaded, then
	// registers and downloads those, taking into account dependencies between
	// layers.
	type LayerDownloadManager struct {
	layerStores map[string]layer.Store
	tm TransferManager
	waitDuration time.Duration
	}

	// SetConcurrency sets the max concurrent downloads for each pull
	func (ldm *LayerDownloadManager) SetConcurrency(concurrency int) {
	ldm.tm.SetConcurrency(concurrency)
	}

	// NewLayerDownloadManager returns a new LayerDownloadManager.
	func NewLayerDownloadManager(layerStores map[string]layer.Store, concurrencyLimit int, options ...func(LayerDownloadManager)) LayerDownloadManager {
	manager := LayerDownloadManager{
	layerStores: layerStores,
	tm: NewTransferManager(concurrencyLimit),
	waitDuration: time.Second,
	}
	for _, option := range options {
	option(&manager)
	}
	return &manager
	}

	type downloadTransfer struct {
	Transfer

	layerStore layer.Store
	layer layer.Layer
	err error
	}

	// result returns the layer resulting from the download, if the download
	// and registration were successful.
	func (d *downloadTransfer) result() (layer.Layer, error) {
	return d.layer, d.err
	}

	// A DownloadDescriptor references a layer that may need to be downloaded.
	type DownloadDescriptor interface {
	// Key returns the key used to deduplicate downloads.
	Key() string
	// ID returns the ID for display purposes.
	ID() string
	// DiffID should return the DiffID for this layer, or an error
	// if it is unknown (for example, if it has not been downloaded
	// before).
	DiffID() (layer.DiffID, error)
	// Download is called to perform the download.
	Download(ctx context.Context, progressOutput progress.Output) (io.ReadCloser, int64, error)
	// Close is called when the download manager is finished with this
	// descriptor and will not call Download again or read from the reader
	// that Download returned.
	Close()
	}

	// DownloadDescriptorWithRegistered is a DownloadDescriptor that has an
	// additional Registered method which gets called after a downloaded layer is
	// registered. This allows the user of the download manager to know the DiffID
	// of each registered layer. This method is called if a cast to
	// DownloadDescriptorWithRegistered is successful.
	type DownloadDescriptorWithRegistered interface {
	DownloadDescriptor
	Registered(diffID layer.DiffID)
	}

	// Download is a blocking function which ensures the requested layers are
	// present in the layer store. It uses the string returned by the Key method to
	// deduplicate downloads. If a given layer is not already known to present in
	// the layer store, and the key is not used by an in-progress download, the
	// Download method is called to get the layer tar data. Layers are then
	// registered in the appropriate order. The caller must call the returned
	// release function once it is done with the returned RootFS object.
	func (ldm *LayerDownloadManager) Download(ctx context.Context, initialRootFS image.RootFS, os string, layers []DownloadDescriptor, progressOutput progress.Output) (image.RootFS, func(), error) {
	var (
	topLayer layer.Layer
	topDownload *downloadTransfer
	watcher *Watcher
	missingLayer bool
	transferKey = ""
	downloadsByKey = make(map[string]*downloadTransfer)
	)

	// Assume that the operating system is the host OS if blank, and validate it
	// to ensure we don't cause a panic by an invalid index into the layerstores.
	if os == "" {
	os = runtime.GOOS
	}
	if !system.IsOSSupported(os) {
	return image.RootFS{}, nil, system.ErrNotSupportedOperatingSystem
	}

	rootFS := initialRootFS
	for _, descriptor := range layers {
	key := descriptor.Key()
	transferKey += key

	if !missingLayer {
	missingLayer = true
	diffID, err := descriptor.DiffID()
	if err == nil {
	getRootFS := rootFS
	getRootFS.Append(diffID)
	l, err := ldm.layerStores[os].Get(getRootFS.ChainID())
	if err == nil {
	// Layer already exists.
	logrus.Debugf("Layer already exists: %s", descriptor.ID())
	progress.Update(progressOutput, descriptor.ID(), "Already exists")
	if topLayer != nil {
	layer.ReleaseAndLog(ldm.layerStores[os], topLayer)
	}
	topLayer = l
	missingLayer = false
	rootFS.Append(diffID)
	// Register this repository as a source of this layer.
	withRegistered, hasRegistered := descriptor.(DownloadDescriptorWithRegistered)
	if hasRegistered { // As layerstore may set the driver
	withRegistered.Registered(diffID)
	}
	continue
	}
	}
	}

	// Does this layer have the same data as a previous layer in
	// the stack? If so, avoid downloading it more than once.
	var topDownloadUncasted Transfer
	if existingDownload, ok := downloadsByKey[key]; ok {
	xferFunc := ldm.makeDownloadFuncFromDownload(descriptor, existingDownload, topDownload, os)
	defer topDownload.Transfer.Release(watcher)
	topDownloadUncasted, watcher = ldm.tm.Transfer(transferKey, xferFunc, progressOutput)
	topDownload = topDownloadUncasted.(*downloadTransfer)
	continue
	}

	// Layer is not known to exist - download and register it.
	progress.Update(progressOutput, descriptor.ID(), "Pulling fs layer")

	var xferFunc DoFunc
	if topDownload != nil {
	xferFunc = ldm.makeDownloadFunc(descriptor, "", topDownload, os)
	defer topDownload.Transfer.Release(watcher)
	} else {
	xferFunc = ldm.makeDownloadFunc(descriptor, rootFS.ChainID(), nil, os)
	}
	topDownloadUncasted, watcher = ldm.tm.Transfer(transferKey, xferFunc, progressOutput)
	topDownload = topDownloadUncasted.(*downloadTransfer)
	downloadsByKey[key] = topDownload
	}

	if topDownload == nil {
	return rootFS, func() {
	if topLayer != nil {
	layer.ReleaseAndLog(ldm.layerStores[os], topLayer)
	}
	}, nil
	}

	// Won't be using the list built up so far - will generate it
	// from downloaded layers instead.
	rootFS.DiffIDs = []layer.DiffID{}

	defer func() {
	if topLayer != nil {
	layer.ReleaseAndLog(ldm.layerStores[os], topLayer)
	}
	}()

	select {
	case <-ctx.Done():
	topDownload.Transfer.Release(watcher)
	return rootFS, func() {}, ctx.Err()
	case <-topDownload.Done():
	break
	}

	l, err := topDownload.result()
	if err != nil {
	topDownload.Transfer.Release(watcher)
	return rootFS, func() {}, err
	}

	// Must do this exactly len(layers) times, so we don't include the
	// base layer on Windows.
	for range layers {
	if l == nil {
	topDownload.Transfer.Release(watcher)
	return rootFS, func() {}, errors.New("internal error: too few parent layers")
	}
	rootFS.DiffIDs = append([]layer.DiffID{l.DiffID()}, rootFS.DiffIDs...)
	l = l.Parent()
	}
	return rootFS, func() { topDownload.Transfer.Release(watcher) }, err
	}

	// makeDownloadFunc returns a function that performs the layer download and
	// registration. If parentDownload is non-nil, it waits for that download to
	// complete before the registration step, and registers the downloaded data
	// on top of parentDownload's resulting layer. Otherwise, it registers the
	// layer on top of the ChainID given by parentLayer.
	func (ldm LayerDownloadManager) makeDownloadFunc(descriptor DownloadDescriptor, parentLayer layer.ChainID, parentDownload downloadTransfer, os string) DoFunc {
	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
	d := &downloadTransfer{
	Transfer: NewTransfer(),
	layerStore: ldm.layerStores[os],
	}

	go func() {
	defer func() {
	close(progressChan)
	}()

	progressOutput := progress.ChanOutput(progressChan)

	select {
	case <-start:
	default:
	progress.Update(progressOutput, descriptor.ID(), "Waiting")
	<-start
	}

	if parentDownload != nil {
	// Did the parent download already fail or get
	// cancelled?
	select {
	case <-parentDownload.Done():
	_, err := parentDownload.result()
	if err != nil {
	d.err = err
	return
	}
	default:
	}
	}

	var (
	downloadReader io.ReadCloser
	size int64
	err error
	retries int
	)

	defer descriptor.Close()

	for {
	downloadReader, size, err = descriptor.Download(d.Transfer.Context(), progressOutput)
	if err == nil {
	break
	}

	// If an error was returned because the context
	// was cancelled, we shouldn't retry.
	select {
	case <-d.Transfer.Context().Done():
	d.err = err
	return
	default:
	}

	retries++
	if _, isDNR := err.(DoNotRetry); isDNR \|\| retries == maxDownloadAttempts {
	logrus.Errorf("Download failed: %v", err)
	d.err = err
	return
	}

	logrus.Errorf("Download failed, retrying: %v", err)
	delay := retries * 5
	ticker := time.NewTicker(ldm.waitDuration)

	selectLoop:
	for {
	progress.Updatef(progressOutput, descriptor.ID(), "Retrying in %d second%s", delay, (map[bool]string{true: "s"})[delay != 1])
	select {
	case <-ticker.C:
	delay--
	if delay == 0 {
	ticker.Stop()
	break selectLoop
	}
	case <-d.Transfer.Context().Done():
	ticker.Stop()
	d.err = errors.New("download cancelled during retry delay")
	return
	}

	}
	}

	close(inactive)

	if parentDownload != nil {
	select {
	case <-d.Transfer.Context().Done():
	d.err = errors.New("layer registration cancelled")
	downloadReader.Close()
	return
	case <-parentDownload.Done():
	}

	l, err := parentDownload.result()
	if err != nil {
	d.err = err
	downloadReader.Close()
	return
	}
	parentLayer = l.ChainID()
	}

	reader := progress.NewProgressReader(ioutils.NewCancelReadCloser(d.Transfer.Context(), downloadReader), progressOutput, size, descriptor.ID(), "Extracting")
	defer reader.Close()

	inflatedLayerData, err := archive.DecompressStream(reader)
	if err != nil {
	d.err = fmt.Errorf("could not get decompression stream: %v", err)
	return
	}

	var src distribution.Descriptor
	if fs, ok := descriptor.(distribution.Describable); ok {
	src = fs.Descriptor()
	}
	if ds, ok := d.layerStore.(layer.DescribableStore); ok {
	d.layer, err = ds.RegisterWithDescriptor(inflatedLayerData, parentLayer, src)
	} else {
	d.layer, err = d.layerStore.Register(inflatedLayerData, parentLayer)
	}
	if err != nil {
	select {
	case <-d.Transfer.Context().Done():
	d.err = errors.New("layer registration cancelled")
	default:
	d.err = fmt.Errorf("failed to register layer: %v", err)
	}
	return
	}

	progress.Update(progressOutput, descriptor.ID(), "Pull complete")
	withRegistered, hasRegistered := descriptor.(DownloadDescriptorWithRegistered)
	if hasRegistered {
	withRegistered.Registered(d.layer.DiffID())
	}

	// Doesn't actually need to be its own goroutine, but
	// done like this so we can defer close(c).
	go func() {
	<-d.Transfer.Released()
	if d.layer != nil {
	layer.ReleaseAndLog(d.layerStore, d.layer)
	}
	}()
	}()

	return d
	}
	}

	// makeDownloadFuncFromDownload returns a function that performs the layer
	// registration when the layer data is coming from an existing download. It
	// waits for sourceDownload and parentDownload to complete, and then
	// reregisters the data from sourceDownload's top layer on top of
	// parentDownload. This function does not log progress output because it would
	// interfere with the progress reporting for sourceDownload, which has the same
	// Key.
	func (ldm LayerDownloadManager) makeDownloadFuncFromDownload(descriptor DownloadDescriptor, sourceDownload downloadTransfer, parentDownload *downloadTransfer, os string) DoFunc {
	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
	d := &downloadTransfer{
	Transfer: NewTransfer(),
	layerStore: ldm.layerStores[os],
	}

	go func() {
	defer func() {
	close(progressChan)
	}()

	<-start

	close(inactive)

	select {
	case <-d.Transfer.Context().Done():
	d.err = errors.New("layer registration cancelled")
	return
	case <-parentDownload.Done():
	}

	l, err := parentDownload.result()
	if err != nil {
	d.err = err
	return
	}
	parentLayer := l.ChainID()

	// sourceDownload should have already finished if
	// parentDownload finished, but wait for it explicitly
	// to be sure.
	select {
	case <-d.Transfer.Context().Done():
	d.err = errors.New("layer registration cancelled")
	return
	case <-sourceDownload.Done():
	}

	l, err = sourceDownload.result()
	if err != nil {
	d.err = err
	return
	}

	layerReader, err := l.TarStream()
	if err != nil {
	d.err = err
	return
	}
	defer layerReader.Close()

	var src distribution.Descriptor
	if fs, ok := l.(distribution.Describable); ok {
	src = fs.Descriptor()
	}
	if ds, ok := d.layerStore.(layer.DescribableStore); ok {
	d.layer, err = ds.RegisterWithDescriptor(layerReader, parentLayer, src)
	} else {
	d.layer, err = d.layerStore.Register(layerReader, parentLayer)
	}
	if err != nil {
	d.err = fmt.Errorf("failed to register layer: %v", err)
	return
	}

	withRegistered, hasRegistered := descriptor.(DownloadDescriptorWithRegistered)
	if hasRegistered {
	withRegistered.Registered(d.layer.DiffID())
	}

	// Doesn't actually need to be its own goroutine, but
	// done like this so we can defer close(c).
	go func() {
	<-d.Transfer.Released()
	if d.layer != nil {
	layer.ReleaseAndLog(d.layerStore, d.layer)
	}
	}()
	}()

	return d
	}
	}