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sync: yield to the waiter when unlocking a starving mutex
When we have already assigned the semaphore ticket to a specific waiter, we want to get the waiter running as fast as possible since no other G waiting on the semaphore can acquire it optimistically. The net effect is that, when a sync.Mutex is contented, the code in the critical section guarded by the Mutex gets a priority boost. Fixes #33747 Change-Id: I9967f0f763c25504010651bdd7f944ee0189cd45 Reviewed-on: https://go-review.googlesource.com/c/go/+/200577 Reviewed-by: Rhys Hiltner <rhys@justin.tv> Reviewed-by: Ian Lance Taylor <iant@golang.org> Run-TryBot: Emmanuel Odeke <emm.odeke@gmail.com> TryBot-Result: Gobot Gobot <gobot@golang.org>
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@ -730,3 +730,11 @@ func RunGetgThreadSwitchTest() {
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panic("g1 != g3")
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}
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}
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var Semacquire = semacquire
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var Semrelease1 = semrelease1
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func SemNwait(addr *uint32) uint32 {
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root := semroot(addr)
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return atomic.Load(&root.nwait)
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}
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@ -2753,7 +2753,22 @@ func preemptPark(gp *g) {
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casGToPreemptScan(gp, _Grunning, _Gscan|_Gpreempted)
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dropg()
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casfrom_Gscanstatus(gp, _Gscan|_Gpreempted, _Gpreempted)
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schedule()
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}
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// goyield is like Gosched, but it:
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// - does not emit a GoSched trace event
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// - puts the current G on the runq of the current P instead of the globrunq
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func goyield() {
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checkTimeouts()
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mcall(goyield_m)
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}
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func goyield_m(gp *g) {
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pp := gp.m.p.ptr()
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casgstatus(gp, _Grunning, _Grunnable)
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dropg()
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runqput(pp, gp, false)
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schedule()
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}
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@ -180,7 +180,7 @@ func semrelease1(addr *uint32, handoff bool, skipframes int) {
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atomic.Xadd(&root.nwait, -1)
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}
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unlock(&root.lock)
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if s != nil { // May be slow, so unlock first
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if s != nil { // May be slow or even yield, so unlock first
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acquiretime := s.acquiretime
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if acquiretime != 0 {
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mutexevent(t0-acquiretime, 3+skipframes)
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@ -192,6 +192,25 @@ func semrelease1(addr *uint32, handoff bool, skipframes int) {
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s.ticket = 1
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}
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readyWithTime(s, 5+skipframes)
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if s.ticket == 1 {
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// Direct G handoff
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// readyWithTime has added the waiter G as runnext in the
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// current P; we now call the scheduler so that we start running
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// the waiter G immediately.
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// Note that waiter inherits our time slice: this is desirable
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// to avoid having a highly contended semaphore hog the P
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// indefinitely. goyield is like Gosched, but it does not emit a
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// GoSched trace event and, more importantly, puts the current G
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// on the local runq instead of the global one.
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// We only do this in the starving regime (handoff=true), as in
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// the non-starving case it is possible for a different waiter
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// to acquire the semaphore while we are yielding/scheduling,
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// and this would be wasteful. We wait instead to enter starving
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// regime, and then we start to do direct handoffs of ticket and
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// P.
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// See issue 33747 for discussion.
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goyield()
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}
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}
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}
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80
src/runtime/sema_test.go
Normal file
80
src/runtime/sema_test.go
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@ -0,0 +1,80 @@
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// Copyright 2019 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package runtime_test
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import (
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. "runtime"
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"sync/atomic"
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"testing"
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)
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// TestSemaHandoff checks that when semrelease+handoff is
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// requested, the G that releases the semaphore yields its
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// P directly to the first waiter in line.
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// See issue 33747 for discussion.
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func TestSemaHandoff(t *testing.T) {
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const iter = 10000
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ok := 0
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for i := 0; i < iter; i++ {
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if testSemaHandoff() {
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ok++
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}
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}
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// As long as two thirds of handoffs are direct, we
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// consider the test successful. The scheduler is
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// nondeterministic, so this test checks that we get the
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// desired outcome in a significant majority of cases.
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// The actual ratio of direct handoffs is much higher
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// (>90%) but we use a lower threshold to minimize the
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// chances that unrelated changes in the runtime will
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// cause the test to fail or become flaky.
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if ok < iter*2/3 {
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t.Fatal("direct handoff < 2/3:", ok, iter)
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}
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}
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func TestSemaHandoff1(t *testing.T) {
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if GOMAXPROCS(-1) <= 1 {
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t.Skip("GOMAXPROCS <= 1")
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}
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defer GOMAXPROCS(GOMAXPROCS(-1))
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GOMAXPROCS(1)
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TestSemaHandoff(t)
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}
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func TestSemaHandoff2(t *testing.T) {
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if GOMAXPROCS(-1) <= 2 {
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t.Skip("GOMAXPROCS <= 2")
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}
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defer GOMAXPROCS(GOMAXPROCS(-1))
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GOMAXPROCS(2)
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TestSemaHandoff(t)
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}
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func testSemaHandoff() bool {
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var sema, res uint32
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done := make(chan struct{})
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go func() {
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Semacquire(&sema)
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atomic.CompareAndSwapUint32(&res, 0, 1)
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Semrelease1(&sema, true, 0)
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close(done)
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}()
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for SemNwait(&sema) == 0 {
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Gosched() // wait for goroutine to block in Semacquire
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}
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// The crux of the test: we release the semaphore with handoff
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// and immediately perform a CAS both here and in the waiter; we
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// want the CAS in the waiter to execute first.
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Semrelease1(&sema, true, 0)
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atomic.CompareAndSwapUint32(&res, 0, 2)
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<-done // wait for goroutines to finish to avoid data races
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return res == 1 // did the waiter run first?
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}
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@ -216,7 +216,8 @@ func (m *Mutex) unlockSlow(new int32) {
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old = m.state
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}
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} else {
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// Starving mode: handoff mutex ownership to the next waiter.
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// Starving mode: handoff mutex ownership to the next waiter, and yield
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// our time slice so that the next waiter can start to run immediately.
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// Note: mutexLocked is not set, the waiter will set it after wakeup.
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// But mutex is still considered locked if mutexStarving is set,
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// so new coming goroutines won't acquire it.
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