http2/testsync.go - net - Git at Google

 // Copyright 2024 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.
 package http2

 import (
 	"context"
 	"sync"
 	"time"
 )

 // testSyncHooks coordinates goroutines in tests.
 //
 // For example, a call to ClientConn.RoundTrip involves several goroutines, including:
 //   - the goroutine running RoundTrip;
 //   - the clientStream.doRequest goroutine, which writes the request; and
 //   - the clientStream.readLoop goroutine, which reads the response.
 //
 // Using testSyncHooks, a test can start a RoundTrip and identify when all these goroutines
 // are blocked waiting for some condition such as reading the Request.Body or waiting for
 // flow control to become available.
 //
 // The testSyncHooks also manage timers and synthetic time in tests.
 // This permits us to, for example, start a request and cause it to time out waiting for
 // response headers without resorting to time.Sleep calls.
 type testSyncHooks struct {
 	// active/inactive act as a mutex and condition variable.
 	//
 	//  - neither chan contains a value: testSyncHooks is locked.
 	//  - active contains a value: unlocked, and at least one goroutine is not blocked
 	//  - inactive contains a value: unlocked, and all goroutines are blocked
 	active   chan struct{}
 	inactive chan struct{}

 	// goroutine counts
 	total    int                     // total goroutines
 	condwait map[*sync.Cond]int      // blocked in sync.Cond.Wait
 	blocked  []*testBlockedGoroutine // otherwise blocked

 	// fake time
 	now    time.Time
 	timers []*fakeTimer

 	// Transport testing: Report various events.
 	newclientconn func(*ClientConn)
 	newstream     func(*clientStream)
 }

 // testBlockedGoroutine is a blocked goroutine.
 type testBlockedGoroutine struct {
 	f  func() bool   // blocked until f returns true
 	ch chan struct{} // closed when unblocked
 }

 func newTestSyncHooks() *testSyncHooks {
 	h := &testSyncHooks{
 		active:   make(chan struct{}, 1),
 		inactive: make(chan struct{}, 1),
 		condwait: map[*sync.Cond]int{},
 	}
 	h.inactive <- struct{}{}
 	h.now = time.Date(2000, 1, 1, 0, 0, 0, 0, time.UTC)
 	return h
 }

 // lock acquires the testSyncHooks mutex.
 func (h *testSyncHooks) lock() {
 	select {
 	case <-h.active:
 	case <-h.inactive:
 	}
 }

 // waitInactive waits for all goroutines to become inactive.
 func (h *testSyncHooks) waitInactive() {
 	for {
 		<-h.inactive
 		if !h.unlock() {
 			break
 		}
 	}
 }

 // unlock releases the testSyncHooks mutex.
 // It reports whether any goroutines are active.
 func (h *testSyncHooks) unlock() (active bool) {
 	// Look for a blocked goroutine which can be unblocked.
 	blocked := h.blocked[:0]
 	unblocked := false
 	for _, b := range h.blocked {
 		if !unblocked && b.f() {
 			unblocked = true
 			close(b.ch)
 		} else {
 			blocked = append(blocked, b)
 		}
 	}
 	h.blocked = blocked

 	// Count goroutines blocked on condition variables.
 	condwait := 0
 	for _, count := range h.condwait {
 		condwait += count
 	}

 	if h.total > condwait+len(blocked) {
 		h.active <- struct{}{}
 		return true
 	} else {
 		h.inactive <- struct{}{}
 		return false
 	}
 }

 // goRun starts a new goroutine.
 func (h *testSyncHooks) goRun(f func()) {
 	h.lock()
 	h.total++
 	h.unlock()
 	go func() {
 		defer func() {
 			h.lock()
 			h.total--
 			h.unlock()
 		}()
 		f()
 	}()
 }

 // blockUntil indicates that a goroutine is blocked waiting for some condition to become true.
 // It waits until f returns true before proceeding.
 //
 // Example usage:
 //
 //	h.blockUntil(func() bool {
 //		// Is the context done yet?
 //		select {
 //		case <-ctx.Done():
 //		default:
 //			return false
 //		}
 //		return true
 //	})
 //	// Wait for the context to become done.
 //	<-ctx.Done()
 //
 // The function f passed to blockUntil must be non-blocking and idempotent.
 func (h *testSyncHooks) blockUntil(f func() bool) {
 	if f() {
 		return
 	}
 	ch := make(chan struct{})
 	h.lock()
 	h.blocked = append(h.blocked, &testBlockedGoroutine{
 		f:  f,
 		ch: ch,
 	})
 	h.unlock()
 	<-ch
 }

 // broadcast is sync.Cond.Broadcast.
 func (h *testSyncHooks) condBroadcast(cond *sync.Cond) {
 	h.lock()
 	delete(h.condwait, cond)
 	h.unlock()
 	cond.Broadcast()
 }

 // broadcast is sync.Cond.Wait.
 func (h *testSyncHooks) condWait(cond *sync.Cond) {
 	h.lock()
 	h.condwait[cond]++
 	h.unlock()
 }

 // newTimer creates a new fake timer.
 func (h *testSyncHooks) newTimer(d time.Duration) timer {
 	h.lock()
 	defer h.unlock()
 	t := &fakeTimer{
 		hooks: h,
 		when:  h.now.Add(d),
 		c:     make(chan time.Time),
 	}
 	h.timers = append(h.timers, t)
 	return t
 }

 // afterFunc creates a new fake AfterFunc timer.
 func (h *testSyncHooks) afterFunc(d time.Duration, f func()) timer {
 	h.lock()
 	defer h.unlock()
 	t := &fakeTimer{
 		hooks: h,
 		when:  h.now.Add(d),
 		f:     f,
 	}
 	h.timers = append(h.timers, t)
 	return t
 }

 func (h *testSyncHooks) contextWithTimeout(ctx context.Context, d time.Duration) (context.Context, context.CancelFunc) {
 	ctx, cancel := context.WithCancel(ctx)
 	t := h.afterFunc(d, cancel)
 	return ctx, func() {
 		t.Stop()
 		cancel()
 	}
 }

 func (h *testSyncHooks) timeUntilEvent() time.Duration {
 	h.lock()
 	defer h.unlock()
 	var next time.Time
 	for _, t := range h.timers {
 		if next.IsZero() || t.when.Before(next) {
 			next = t.when
 		}
 	}
 	if d := next.Sub(h.now); d > 0 {
 		return d
 	}
 	return 0
 }

 // advance advances time and causes synthetic timers to fire.
 func (h *testSyncHooks) advance(d time.Duration) {
 	h.lock()
 	defer h.unlock()
 	h.now = h.now.Add(d)
 	timers := h.timers[:0]
 	for _, t := range h.timers {
 		t := t // remove after go.mod depends on go1.22
 		t.mu.Lock()
 		switch {
 		case t.when.After(h.now):
 			timers = append(timers, t)
 		case t.when.IsZero():
 			// stopped timer
 		default:
 			t.when = time.Time{}
 			if t.c != nil {
 				close(t.c)
 			}
 			if t.f != nil {
 				h.total++
 				go func() {
 					defer func() {
 						h.lock()
 						h.total--
 						h.unlock()
 					}()
 					t.f()
 				}()
 			}
 		}
 		t.mu.Unlock()
 	}
 	h.timers = timers
 }

 // A timer wraps a time.Timer, or a synthetic equivalent in tests.
 // Unlike time.Timer, timer is single-use: The timer channel is closed when the timer expires.
 type timer interface {
 	C() <-chan time.Time
 	Stop() bool
 	Reset(d time.Duration) bool
 }

 // timeTimer implements timer using real time.
 type timeTimer struct {
 	t *time.Timer
 	c chan time.Time
 }

 // newTimeTimer creates a new timer using real time.
 func newTimeTimer(d time.Duration) timer {
 	ch := make(chan time.Time)
 	t := time.AfterFunc(d, func() {
 		close(ch)
 	})
 	return &timeTimer{t, ch}
 }

 // newTimeAfterFunc creates an AfterFunc timer using real time.
 func newTimeAfterFunc(d time.Duration, f func()) timer {
 	return &timeTimer{
 		t: time.AfterFunc(d, f),
 	}
 }

 func (t timeTimer) C() <-chan time.Time        { return t.c }
 func (t timeTimer) Stop() bool                 { return t.t.Stop() }
 func (t timeTimer) Reset(d time.Duration) bool { return t.t.Reset(d) }

 // fakeTimer implements timer using fake time.
 type fakeTimer struct {
 	hooks *testSyncHooks

 	mu   sync.Mutex
 	when time.Time      // when the timer will fire
 	c    chan time.Time // closed when the timer fires; mutually exclusive with f
 	f    func()         // called when the timer fires; mutually exclusive with c
 }

 func (t *fakeTimer) C() <-chan time.Time { return t.c }

 func (t *fakeTimer) Stop() bool {
 	t.mu.Lock()
 	defer t.mu.Unlock()
 	stopped := t.when.IsZero()
 	t.when = time.Time{}
 	return stopped
 }

 func (t *fakeTimer) Reset(d time.Duration) bool {
 	if t.c != nil || t.f == nil {
 		panic("fakeTimer only supports Reset on AfterFunc timers")
 	}
 	t.mu.Lock()
 	defer t.mu.Unlock()
 	t.hooks.lock()
 	defer t.hooks.unlock()
 	active := !t.when.IsZero()
 	t.when = t.hooks.now.Add(d)
 	if !active {
 		t.hooks.timers = append(t.hooks.timers, t)
 	}
 	return active
 }
	// Copyright 2024 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.
	package http2

	import (
	"context"
	"sync"
	"time"
	)

	// testSyncHooks coordinates goroutines in tests.
	//
	// For example, a call to ClientConn.RoundTrip involves several goroutines, including:
	// - the goroutine running RoundTrip;
	// - the clientStream.doRequest goroutine, which writes the request; and
	// - the clientStream.readLoop goroutine, which reads the response.
	//
	// Using testSyncHooks, a test can start a RoundTrip and identify when all these goroutines
	// are blocked waiting for some condition such as reading the Request.Body or waiting for
	// flow control to become available.
	//
	// The testSyncHooks also manage timers and synthetic time in tests.
	// This permits us to, for example, start a request and cause it to time out waiting for
	// response headers without resorting to time.Sleep calls.
	type testSyncHooks struct {
	// active/inactive act as a mutex and condition variable.
	//
	// - neither chan contains a value: testSyncHooks is locked.
	// - active contains a value: unlocked, and at least one goroutine is not blocked
	// - inactive contains a value: unlocked, and all goroutines are blocked
	active chan struct{}
	inactive chan struct{}

	// goroutine counts
	total int // total goroutines
	condwait map[*sync.Cond]int // blocked in sync.Cond.Wait
	blocked []*testBlockedGoroutine // otherwise blocked

	// fake time
	now time.Time
	timers []*fakeTimer

	// Transport testing: Report various events.
	newclientconn func(*ClientConn)
	newstream func(*clientStream)
	}

	// testBlockedGoroutine is a blocked goroutine.
	type testBlockedGoroutine struct {
	f func() bool // blocked until f returns true
	ch chan struct{} // closed when unblocked
	}

	func newTestSyncHooks() *testSyncHooks {
	h := &testSyncHooks{
	active: make(chan struct{}, 1),
	inactive: make(chan struct{}, 1),
	condwait: map[*sync.Cond]int{},
	}
	h.inactive <- struct{}{}
	h.now = time.Date(2000, 1, 1, 0, 0, 0, 0, time.UTC)
	return h
	}

	// lock acquires the testSyncHooks mutex.
	func (h *testSyncHooks) lock() {
	select {
	case <-h.active:
	case <-h.inactive:
	}
	}

	// waitInactive waits for all goroutines to become inactive.
	func (h *testSyncHooks) waitInactive() {
	for {
	<-h.inactive
	if !h.unlock() {
	break
	}
	}
	}

	// unlock releases the testSyncHooks mutex.
	// It reports whether any goroutines are active.
	func (h *testSyncHooks) unlock() (active bool) {
	// Look for a blocked goroutine which can be unblocked.
	blocked := h.blocked[:0]
	unblocked := false
	for _, b := range h.blocked {
	if !unblocked && b.f() {
	unblocked = true
	close(b.ch)
	} else {
	blocked = append(blocked, b)
	}
	}
	h.blocked = blocked

	// Count goroutines blocked on condition variables.
	condwait := 0
	for _, count := range h.condwait {
	condwait += count
	}

	if h.total > condwait+len(blocked) {
	h.active <- struct{}{}
	return true
	} else {
	h.inactive <- struct{}{}
	return false
	}
	}

	// goRun starts a new goroutine.
	func (h *testSyncHooks) goRun(f func()) {
	h.lock()
	h.total++
	h.unlock()
	go func() {
	defer func() {
	h.lock()
	h.total--
	h.unlock()
	}()
	f()
	}()
	}

	// blockUntil indicates that a goroutine is blocked waiting for some condition to become true.
	// It waits until f returns true before proceeding.
	//
	// Example usage:
	//
	// h.blockUntil(func() bool {
	// // Is the context done yet?
	// select {
	// case <-ctx.Done():
	// default:
	// return false
	// }
	// return true
	// })
	// // Wait for the context to become done.
	// <-ctx.Done()
	//
	// The function f passed to blockUntil must be non-blocking and idempotent.
	func (h *testSyncHooks) blockUntil(f func() bool) {
	if f() {
	return
	}
	ch := make(chan struct{})
	h.lock()
	h.blocked = append(h.blocked, &testBlockedGoroutine{
	f: f,
	ch: ch,
	})
	h.unlock()
	<-ch
	}

	// broadcast is sync.Cond.Broadcast.
	func (h testSyncHooks) condBroadcast(cond sync.Cond) {
	h.lock()
	delete(h.condwait, cond)
	h.unlock()
	cond.Broadcast()
	}

	// broadcast is sync.Cond.Wait.
	func (h testSyncHooks) condWait(cond sync.Cond) {
	h.lock()
	h.condwait[cond]++
	h.unlock()
	}

	// newTimer creates a new fake timer.
	func (h *testSyncHooks) newTimer(d time.Duration) timer {
	h.lock()
	defer h.unlock()
	t := &fakeTimer{
	hooks: h,
	when: h.now.Add(d),
	c: make(chan time.Time),
	}
	h.timers = append(h.timers, t)
	return t
	}

	// afterFunc creates a new fake AfterFunc timer.
	func (h *testSyncHooks) afterFunc(d time.Duration, f func()) timer {
	h.lock()
	defer h.unlock()
	t := &fakeTimer{
	hooks: h,
	when: h.now.Add(d),
	f: f,
	}
	h.timers = append(h.timers, t)
	return t
	}

	func (h *testSyncHooks) contextWithTimeout(ctx context.Context, d time.Duration) (context.Context, context.CancelFunc) {
	ctx, cancel := context.WithCancel(ctx)
	t := h.afterFunc(d, cancel)
	return ctx, func() {
	t.Stop()
	cancel()
	}
	}

	func (h *testSyncHooks) timeUntilEvent() time.Duration {
	h.lock()
	defer h.unlock()
	var next time.Time
	for _, t := range h.timers {
	if next.IsZero() \|\| t.when.Before(next) {
	next = t.when
	}
	}
	if d := next.Sub(h.now); d > 0 {
	return d
	}
	return 0
	}

	// advance advances time and causes synthetic timers to fire.
	func (h *testSyncHooks) advance(d time.Duration) {
	h.lock()
	defer h.unlock()
	h.now = h.now.Add(d)
	timers := h.timers[:0]
	for _, t := range h.timers {
	t := t // remove after go.mod depends on go1.22
	t.mu.Lock()
	switch {
	case t.when.After(h.now):
	timers = append(timers, t)
	case t.when.IsZero():
	// stopped timer
	default:
	t.when = time.Time{}
	if t.c != nil {
	close(t.c)
	}
	if t.f != nil {
	h.total++
	go func() {
	defer func() {
	h.lock()
	h.total--
	h.unlock()
	}()
	t.f()
	}()
	}
	}
	t.mu.Unlock()
	}
	h.timers = timers
	}

	// A timer wraps a time.Timer, or a synthetic equivalent in tests.
	// Unlike time.Timer, timer is single-use: The timer channel is closed when the timer expires.
	type timer interface {
	C() <-chan time.Time
	Stop() bool
	Reset(d time.Duration) bool
	}

	// timeTimer implements timer using real time.
	type timeTimer struct {
	t *time.Timer
	c chan time.Time
	}

	// newTimeTimer creates a new timer using real time.
	func newTimeTimer(d time.Duration) timer {
	ch := make(chan time.Time)
	t := time.AfterFunc(d, func() {
	close(ch)
	})
	return &timeTimer{t, ch}
	}

	// newTimeAfterFunc creates an AfterFunc timer using real time.
	func newTimeAfterFunc(d time.Duration, f func()) timer {
	return &timeTimer{
	t: time.AfterFunc(d, f),
	}
	}

	func (t timeTimer) C() <-chan time.Time { return t.c }
	func (t timeTimer) Stop() bool { return t.t.Stop() }
	func (t timeTimer) Reset(d time.Duration) bool { return t.t.Reset(d) }

	// fakeTimer implements timer using fake time.
	type fakeTimer struct {
	hooks *testSyncHooks

	mu sync.Mutex
	when time.Time // when the timer will fire
	c chan time.Time // closed when the timer fires; mutually exclusive with f
	f func() // called when the timer fires; mutually exclusive with c
	}

	func (t *fakeTimer) C() <-chan time.Time { return t.c }

	func (t *fakeTimer) Stop() bool {
	t.mu.Lock()
	defer t.mu.Unlock()
	stopped := t.when.IsZero()
	t.when = time.Time{}
	return stopped
	}

	func (t *fakeTimer) Reset(d time.Duration) bool {
	if t.c != nil \|\| t.f == nil {
	panic("fakeTimer only supports Reset on AfterFunc timers")
	}
	t.mu.Lock()
	defer t.mu.Unlock()
	t.hooks.lock()
	defer t.hooks.unlock()
	active := !t.when.IsZero()
	t.when = t.hooks.now.Add(d)
	if !active {
	t.hooks.timers = append(t.hooks.timers, t)
	}
	return active
	}