vendor/github.com/docker/docker/distribution/xfer/transfer_test.go - cloudstack-kubernetes-provider - Git at Google

 package xfer

 import (
 	"sync/atomic"
 	"testing"
 	"time"

 	"github.com/docker/docker/pkg/progress"
 )

 func TestTransfer(t *testing.T) {
 	makeXferFunc := func(id string) DoFunc {
 		return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
 			select {
 			case <-start:
 			default:
 				t.Fatalf("transfer function not started even though concurrency limit not reached")
 			}

 			xfer := NewTransfer()
 			go func() {
 				for i := 0; i <= 10; i++ {
 					progressChan <- progress.Progress{ID: id, Action: "testing", Current: int64(i), Total: 10}
 					time.Sleep(10 * time.Millisecond)
 				}
 				close(progressChan)
 			}()
 			return xfer
 		}
 	}

 	tm := NewTransferManager(5)
 	progressChan := make(chan progress.Progress)
 	progressDone := make(chan struct{})
 	receivedProgress := make(map[string]int64)

 	go func() {
 		for p := range progressChan {
 			val, present := receivedProgress[p.ID]
 			if present && p.Current <= val {
 				t.Fatalf("got unexpected progress value: %d (expected %d)", p.Current, val+1)
 			}
 			receivedProgress[p.ID] = p.Current
 		}
 		close(progressDone)
 	}()

 	// Start a few transfers
 	ids := []string{"id1", "id2", "id3"}
 	xfers := make([]Transfer, len(ids))
 	watchers := make([]*Watcher, len(ids))
 	for i, id := range ids {
 		xfers[i], watchers[i] = tm.Transfer(id, makeXferFunc(id), progress.ChanOutput(progressChan))
 	}

 	for i, xfer := range xfers {
 		<-xfer.Done()
 		xfer.Release(watchers[i])
 	}
 	close(progressChan)
 	<-progressDone

 	for _, id := range ids {
 		if receivedProgress[id] != 10 {
 			t.Fatalf("final progress value %d instead of 10", receivedProgress[id])
 		}
 	}
 }

 func TestConcurrencyLimit(t *testing.T) {
 	concurrencyLimit := 3
 	var runningJobs int32

 	makeXferFunc := func(id string) DoFunc {
 		return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
 			xfer := NewTransfer()
 			go func() {
 				<-start
 				totalJobs := atomic.AddInt32(&runningJobs, 1)
 				if int(totalJobs) > concurrencyLimit {
 					t.Fatalf("too many jobs running")
 				}
 				for i := 0; i <= 10; i++ {
 					progressChan <- progress.Progress{ID: id, Action: "testing", Current: int64(i), Total: 10}
 					time.Sleep(10 * time.Millisecond)
 				}
 				atomic.AddInt32(&runningJobs, -1)
 				close(progressChan)
 			}()
 			return xfer
 		}
 	}

 	tm := NewTransferManager(concurrencyLimit)
 	progressChan := make(chan progress.Progress)
 	progressDone := make(chan struct{})
 	receivedProgress := make(map[string]int64)

 	go func() {
 		for p := range progressChan {
 			receivedProgress[p.ID] = p.Current
 		}
 		close(progressDone)
 	}()

 	// Start more transfers than the concurrency limit
 	ids := []string{"id1", "id2", "id3", "id4", "id5", "id6", "id7", "id8"}
 	xfers := make([]Transfer, len(ids))
 	watchers := make([]*Watcher, len(ids))
 	for i, id := range ids {
 		xfers[i], watchers[i] = tm.Transfer(id, makeXferFunc(id), progress.ChanOutput(progressChan))
 	}

 	for i, xfer := range xfers {
 		<-xfer.Done()
 		xfer.Release(watchers[i])
 	}
 	close(progressChan)
 	<-progressDone

 	for _, id := range ids {
 		if receivedProgress[id] != 10 {
 			t.Fatalf("final progress value %d instead of 10", receivedProgress[id])
 		}
 	}
 }

 func TestInactiveJobs(t *testing.T) {
 	concurrencyLimit := 3
 	var runningJobs int32
 	testDone := make(chan struct{})

 	makeXferFunc := func(id string) DoFunc {
 		return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
 			xfer := NewTransfer()
 			go func() {
 				<-start
 				totalJobs := atomic.AddInt32(&runningJobs, 1)
 				if int(totalJobs) > concurrencyLimit {
 					t.Fatalf("too many jobs running")
 				}
 				for i := 0; i <= 10; i++ {
 					progressChan <- progress.Progress{ID: id, Action: "testing", Current: int64(i), Total: 10}
 					time.Sleep(10 * time.Millisecond)
 				}
 				atomic.AddInt32(&runningJobs, -1)
 				close(inactive)
 				<-testDone
 				close(progressChan)
 			}()
 			return xfer
 		}
 	}

 	tm := NewTransferManager(concurrencyLimit)
 	progressChan := make(chan progress.Progress)
 	progressDone := make(chan struct{})
 	receivedProgress := make(map[string]int64)

 	go func() {
 		for p := range progressChan {
 			receivedProgress[p.ID] = p.Current
 		}
 		close(progressDone)
 	}()

 	// Start more transfers than the concurrency limit
 	ids := []string{"id1", "id2", "id3", "id4", "id5", "id6", "id7", "id8"}
 	xfers := make([]Transfer, len(ids))
 	watchers := make([]*Watcher, len(ids))
 	for i, id := range ids {
 		xfers[i], watchers[i] = tm.Transfer(id, makeXferFunc(id), progress.ChanOutput(progressChan))
 	}

 	close(testDone)
 	for i, xfer := range xfers {
 		<-xfer.Done()
 		xfer.Release(watchers[i])
 	}
 	close(progressChan)
 	<-progressDone

 	for _, id := range ids {
 		if receivedProgress[id] != 10 {
 			t.Fatalf("final progress value %d instead of 10", receivedProgress[id])
 		}
 	}
 }

 func TestWatchRelease(t *testing.T) {
 	ready := make(chan struct{})

 	makeXferFunc := func(id string) DoFunc {
 		return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
 			xfer := NewTransfer()
 			go func() {
 				defer func() {
 					close(progressChan)
 				}()
 				<-ready
 				for i := int64(0); ; i++ {
 					select {
 					case <-time.After(10 * time.Millisecond):
 					case <-xfer.Context().Done():
 						return
 					}
 					progressChan <- progress.Progress{ID: id, Action: "testing", Current: i, Total: 10}
 				}
 			}()
 			return xfer
 		}
 	}

 	tm := NewTransferManager(5)

 	type watcherInfo struct {
 		watcher               *Watcher
 		progressChan          chan progress.Progress
 		progressDone          chan struct{}
 		receivedFirstProgress chan struct{}
 	}

 	progressConsumer := func(w watcherInfo) {
 		first := true
 		for range w.progressChan {
 			if first {
 				close(w.receivedFirstProgress)
 			}
 			first = false
 		}
 		close(w.progressDone)
 	}

 	// Start a transfer
 	watchers := make([]watcherInfo, 5)
 	var xfer Transfer
 	watchers[0].progressChan = make(chan progress.Progress)
 	watchers[0].progressDone = make(chan struct{})
 	watchers[0].receivedFirstProgress = make(chan struct{})
 	xfer, watchers[0].watcher = tm.Transfer("id1", makeXferFunc("id1"), progress.ChanOutput(watchers[0].progressChan))
 	go progressConsumer(watchers[0])

 	// Give it multiple watchers
 	for i := 1; i != len(watchers); i++ {
 		watchers[i].progressChan = make(chan progress.Progress)
 		watchers[i].progressDone = make(chan struct{})
 		watchers[i].receivedFirstProgress = make(chan struct{})
 		watchers[i].watcher = xfer.Watch(progress.ChanOutput(watchers[i].progressChan))
 		go progressConsumer(watchers[i])
 	}

 	// Now that the watchers are set up, allow the transfer goroutine to
 	// proceed.
 	close(ready)

 	// Confirm that each watcher gets progress output.
 	for _, w := range watchers {
 		<-w.receivedFirstProgress
 	}

 	// Release one watcher every 5ms
 	for _, w := range watchers {
 		xfer.Release(w.watcher)
 		<-time.After(5 * time.Millisecond)
 	}

 	// Now that all watchers have been released, Released() should
 	// return a closed channel.
 	<-xfer.Released()

 	// Done() should return a closed channel because the xfer func returned
 	// due to cancellation.
 	<-xfer.Done()

 	for _, w := range watchers {
 		close(w.progressChan)
 		<-w.progressDone
 	}
 }

 func TestWatchFinishedTransfer(t *testing.T) {
 	makeXferFunc := func(id string) DoFunc {
 		return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
 			xfer := NewTransfer()
 			go func() {
 				// Finish immediately
 				close(progressChan)
 			}()
 			return xfer
 		}
 	}

 	tm := NewTransferManager(5)

 	// Start a transfer
 	watchers := make([]*Watcher, 3)
 	var xfer Transfer
 	xfer, watchers[0] = tm.Transfer("id1", makeXferFunc("id1"), progress.ChanOutput(make(chan progress.Progress)))

 	// Give it a watcher immediately
 	watchers[1] = xfer.Watch(progress.ChanOutput(make(chan progress.Progress)))

 	// Wait for the transfer to complete
 	<-xfer.Done()

 	// Set up another watcher
 	watchers[2] = xfer.Watch(progress.ChanOutput(make(chan progress.Progress)))

 	// Release the watchers
 	for _, w := range watchers {
 		xfer.Release(w)
 	}

 	// Now that all watchers have been released, Released() should
 	// return a closed channel.
 	<-xfer.Released()
 }

 func TestDuplicateTransfer(t *testing.T) {
 	ready := make(chan struct{})

 	var xferFuncCalls int32

 	makeXferFunc := func(id string) DoFunc {
 		return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
 			atomic.AddInt32(&xferFuncCalls, 1)
 			xfer := NewTransfer()
 			go func() {
 				defer func() {
 					close(progressChan)
 				}()
 				<-ready
 				for i := int64(0); ; i++ {
 					select {
 					case <-time.After(10 * time.Millisecond):
 					case <-xfer.Context().Done():
 						return
 					}
 					progressChan <- progress.Progress{ID: id, Action: "testing", Current: i, Total: 10}
 				}
 			}()
 			return xfer
 		}
 	}

 	tm := NewTransferManager(5)

 	type transferInfo struct {
 		xfer                  Transfer
 		watcher               *Watcher
 		progressChan          chan progress.Progress
 		progressDone          chan struct{}
 		receivedFirstProgress chan struct{}
 	}

 	progressConsumer := func(t transferInfo) {
 		first := true
 		for range t.progressChan {
 			if first {
 				close(t.receivedFirstProgress)
 			}
 			first = false
 		}
 		close(t.progressDone)
 	}

 	// Try to start multiple transfers with the same ID
 	transfers := make([]transferInfo, 5)
 	for i := range transfers {
 		t := &transfers[i]
 		t.progressChan = make(chan progress.Progress)
 		t.progressDone = make(chan struct{})
 		t.receivedFirstProgress = make(chan struct{})
 		t.xfer, t.watcher = tm.Transfer("id1", makeXferFunc("id1"), progress.ChanOutput(t.progressChan))
 		go progressConsumer(*t)
 	}

 	// Allow the transfer goroutine to proceed.
 	close(ready)

 	// Confirm that each watcher gets progress output.
 	for _, t := range transfers {
 		<-t.receivedFirstProgress
 	}

 	// Confirm that the transfer function was called exactly once.
 	if xferFuncCalls != 1 {
 		t.Fatal("transfer function wasn't called exactly once")
 	}

 	// Release one watcher every 5ms
 	for _, t := range transfers {
 		t.xfer.Release(t.watcher)
 		<-time.After(5 * time.Millisecond)
 	}

 	for _, t := range transfers {
 		// Now that all watchers have been released, Released() should
 		// return a closed channel.
 		<-t.xfer.Released()
 		// Done() should return a closed channel because the xfer func returned
 		// due to cancellation.
 		<-t.xfer.Done()
 	}

 	for _, t := range transfers {
 		close(t.progressChan)
 		<-t.progressDone
 	}
 }
	package xfer

	import (
	"sync/atomic"
	"testing"
	"time"

	"github.com/docker/docker/pkg/progress"
	)

	func TestTransfer(t *testing.T) {
	makeXferFunc := func(id string) DoFunc {
	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
	select {
	case <-start:
	default:
	t.Fatalf("transfer function not started even though concurrency limit not reached")
	}

	xfer := NewTransfer()
	go func() {
	for i := 0; i <= 10; i++ {
	progressChan <- progress.Progress{ID: id, Action: "testing", Current: int64(i), Total: 10}
	time.Sleep(10 * time.Millisecond)
	}
	close(progressChan)
	}()
	return xfer
	}
	}

	tm := NewTransferManager(5)
	progressChan := make(chan progress.Progress)
	progressDone := make(chan struct{})
	receivedProgress := make(map[string]int64)

	go func() {
	for p := range progressChan {
	val, present := receivedProgress[p.ID]
	if present && p.Current <= val {
	t.Fatalf("got unexpected progress value: %d (expected %d)", p.Current, val+1)
	}
	receivedProgress[p.ID] = p.Current
	}
	close(progressDone)
	}()

	// Start a few transfers
	ids := []string{"id1", "id2", "id3"}
	xfers := make([]Transfer, len(ids))
	watchers := make([]*Watcher, len(ids))
	for i, id := range ids {
	xfers[i], watchers[i] = tm.Transfer(id, makeXferFunc(id), progress.ChanOutput(progressChan))
	}

	for i, xfer := range xfers {
	<-xfer.Done()
	xfer.Release(watchers[i])
	}
	close(progressChan)
	<-progressDone

	for _, id := range ids {
	if receivedProgress[id] != 10 {
	t.Fatalf("final progress value %d instead of 10", receivedProgress[id])
	}
	}
	}

	func TestConcurrencyLimit(t *testing.T) {
	concurrencyLimit := 3
	var runningJobs int32

	makeXferFunc := func(id string) DoFunc {
	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
	xfer := NewTransfer()
	go func() {
	<-start
	totalJobs := atomic.AddInt32(&runningJobs, 1)
	if int(totalJobs) > concurrencyLimit {
	t.Fatalf("too many jobs running")
	}
	for i := 0; i <= 10; i++ {
	progressChan <- progress.Progress{ID: id, Action: "testing", Current: int64(i), Total: 10}
	time.Sleep(10 * time.Millisecond)
	}
	atomic.AddInt32(&runningJobs, -1)
	close(progressChan)
	}()
	return xfer
	}
	}

	tm := NewTransferManager(concurrencyLimit)
	progressChan := make(chan progress.Progress)
	progressDone := make(chan struct{})
	receivedProgress := make(map[string]int64)

	go func() {
	for p := range progressChan {
	receivedProgress[p.ID] = p.Current
	}
	close(progressDone)
	}()

	// Start more transfers than the concurrency limit
	ids := []string{"id1", "id2", "id3", "id4", "id5", "id6", "id7", "id8"}
	xfers := make([]Transfer, len(ids))
	watchers := make([]*Watcher, len(ids))
	for i, id := range ids {
	xfers[i], watchers[i] = tm.Transfer(id, makeXferFunc(id), progress.ChanOutput(progressChan))
	}

	for i, xfer := range xfers {
	<-xfer.Done()
	xfer.Release(watchers[i])
	}
	close(progressChan)
	<-progressDone

	for _, id := range ids {
	if receivedProgress[id] != 10 {
	t.Fatalf("final progress value %d instead of 10", receivedProgress[id])
	}
	}
	}

	func TestInactiveJobs(t *testing.T) {
	concurrencyLimit := 3
	var runningJobs int32
	testDone := make(chan struct{})

	makeXferFunc := func(id string) DoFunc {
	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
	xfer := NewTransfer()
	go func() {
	<-start
	totalJobs := atomic.AddInt32(&runningJobs, 1)
	if int(totalJobs) > concurrencyLimit {
	t.Fatalf("too many jobs running")
	}
	for i := 0; i <= 10; i++ {
	progressChan <- progress.Progress{ID: id, Action: "testing", Current: int64(i), Total: 10}
	time.Sleep(10 * time.Millisecond)
	}
	atomic.AddInt32(&runningJobs, -1)
	close(inactive)
	<-testDone
	close(progressChan)
	}()
	return xfer
	}
	}

	tm := NewTransferManager(concurrencyLimit)
	progressChan := make(chan progress.Progress)
	progressDone := make(chan struct{})
	receivedProgress := make(map[string]int64)

	go func() {
	for p := range progressChan {
	receivedProgress[p.ID] = p.Current
	}
	close(progressDone)
	}()

	// Start more transfers than the concurrency limit
	ids := []string{"id1", "id2", "id3", "id4", "id5", "id6", "id7", "id8"}
	xfers := make([]Transfer, len(ids))
	watchers := make([]*Watcher, len(ids))
	for i, id := range ids {
	xfers[i], watchers[i] = tm.Transfer(id, makeXferFunc(id), progress.ChanOutput(progressChan))
	}

	close(testDone)
	for i, xfer := range xfers {
	<-xfer.Done()
	xfer.Release(watchers[i])
	}
	close(progressChan)
	<-progressDone

	for _, id := range ids {
	if receivedProgress[id] != 10 {
	t.Fatalf("final progress value %d instead of 10", receivedProgress[id])
	}
	}
	}

	func TestWatchRelease(t *testing.T) {
	ready := make(chan struct{})

	makeXferFunc := func(id string) DoFunc {
	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
	xfer := NewTransfer()
	go func() {
	defer func() {
	close(progressChan)
	}()
	<-ready
	for i := int64(0); ; i++ {
	select {
	case <-time.After(10 * time.Millisecond):
	case <-xfer.Context().Done():
	return
	}
	progressChan <- progress.Progress{ID: id, Action: "testing", Current: i, Total: 10}
	}
	}()
	return xfer
	}
	}

	tm := NewTransferManager(5)

	type watcherInfo struct {
	watcher *Watcher
	progressChan chan progress.Progress
	progressDone chan struct{}
	receivedFirstProgress chan struct{}
	}

	progressConsumer := func(w watcherInfo) {
	first := true
	for range w.progressChan {
	if first {
	close(w.receivedFirstProgress)
	}
	first = false
	}
	close(w.progressDone)
	}

	// Start a transfer
	watchers := make([]watcherInfo, 5)
	var xfer Transfer
	watchers[0].progressChan = make(chan progress.Progress)
	watchers[0].progressDone = make(chan struct{})
	watchers[0].receivedFirstProgress = make(chan struct{})
	xfer, watchers[0].watcher = tm.Transfer("id1", makeXferFunc("id1"), progress.ChanOutput(watchers[0].progressChan))
	go progressConsumer(watchers[0])

	// Give it multiple watchers
	for i := 1; i != len(watchers); i++ {
	watchers[i].progressChan = make(chan progress.Progress)
	watchers[i].progressDone = make(chan struct{})
	watchers[i].receivedFirstProgress = make(chan struct{})
	watchers[i].watcher = xfer.Watch(progress.ChanOutput(watchers[i].progressChan))
	go progressConsumer(watchers[i])
	}

	// Now that the watchers are set up, allow the transfer goroutine to
	// proceed.
	close(ready)

	// Confirm that each watcher gets progress output.
	for _, w := range watchers {
	<-w.receivedFirstProgress
	}

	// Release one watcher every 5ms
	for _, w := range watchers {
	xfer.Release(w.watcher)
	<-time.After(5 * time.Millisecond)
	}

	// Now that all watchers have been released, Released() should
	// return a closed channel.
	<-xfer.Released()

	// Done() should return a closed channel because the xfer func returned
	// due to cancellation.
	<-xfer.Done()

	for _, w := range watchers {
	close(w.progressChan)
	<-w.progressDone
	}
	}

	func TestWatchFinishedTransfer(t *testing.T) {
	makeXferFunc := func(id string) DoFunc {
	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
	xfer := NewTransfer()
	go func() {
	// Finish immediately
	close(progressChan)
	}()
	return xfer
	}
	}

	tm := NewTransferManager(5)

	// Start a transfer
	watchers := make([]*Watcher, 3)
	var xfer Transfer
	xfer, watchers[0] = tm.Transfer("id1", makeXferFunc("id1"), progress.ChanOutput(make(chan progress.Progress)))

	// Give it a watcher immediately
	watchers[1] = xfer.Watch(progress.ChanOutput(make(chan progress.Progress)))

	// Wait for the transfer to complete
	<-xfer.Done()

	// Set up another watcher
	watchers[2] = xfer.Watch(progress.ChanOutput(make(chan progress.Progress)))

	// Release the watchers
	for _, w := range watchers {
	xfer.Release(w)
	}

	// Now that all watchers have been released, Released() should
	// return a closed channel.
	<-xfer.Released()
	}

	func TestDuplicateTransfer(t *testing.T) {
	ready := make(chan struct{})

	var xferFuncCalls int32

	makeXferFunc := func(id string) DoFunc {
	return func(progressChan chan<- progress.Progress, start <-chan struct{}, inactive chan<- struct{}) Transfer {
	atomic.AddInt32(&xferFuncCalls, 1)
	xfer := NewTransfer()
	go func() {
	defer func() {
	close(progressChan)
	}()
	<-ready
	for i := int64(0); ; i++ {
	select {
	case <-time.After(10 * time.Millisecond):
	case <-xfer.Context().Done():
	return
	}
	progressChan <- progress.Progress{ID: id, Action: "testing", Current: i, Total: 10}
	}
	}()
	return xfer
	}
	}

	tm := NewTransferManager(5)

	type transferInfo struct {
	xfer Transfer
	watcher *Watcher
	progressChan chan progress.Progress
	progressDone chan struct{}
	receivedFirstProgress chan struct{}
	}

	progressConsumer := func(t transferInfo) {
	first := true
	for range t.progressChan {
	if first {
	close(t.receivedFirstProgress)
	}
	first = false
	}
	close(t.progressDone)
	}

	// Try to start multiple transfers with the same ID
	transfers := make([]transferInfo, 5)
	for i := range transfers {
	t := &transfers[i]
	t.progressChan = make(chan progress.Progress)
	t.progressDone = make(chan struct{})
	t.receivedFirstProgress = make(chan struct{})
	t.xfer, t.watcher = tm.Transfer("id1", makeXferFunc("id1"), progress.ChanOutput(t.progressChan))
	go progressConsumer(*t)
	}

	// Allow the transfer goroutine to proceed.
	close(ready)

	// Confirm that each watcher gets progress output.
	for _, t := range transfers {
	<-t.receivedFirstProgress
	}

	// Confirm that the transfer function was called exactly once.
	if xferFuncCalls != 1 {
	t.Fatal("transfer function wasn't called exactly once")
	}

	// Release one watcher every 5ms
	for _, t := range transfers {
	t.xfer.Release(t.watcher)
	<-time.After(5 * time.Millisecond)
	}

	for _, t := range transfers {
	// Now that all watchers have been released, Released() should
	// return a closed channel.
	<-t.xfer.Released()
	// Done() should return a closed channel because the xfer func returned
	// due to cancellation.
	<-t.xfer.Done()
	}

	for _, t := range transfers {
	close(t.progressChan)
	<-t.progressDone
	}
	}