8dc2499aa6
gotools/ * Makefile.am (go_cmd_cgo_files): Add ast_go118.go (check-go-tool): Copy golang.org/x/tools directories. * Makefile.in: Regenerate. Reviewed-on: https://go-review.googlesource.com/c/gofrontend/+/384695
251 lines
7.9 KiB
Go
251 lines
7.9 KiB
Go
// Copyright 2009 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 sync provides basic synchronization primitives such as mutual
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// exclusion locks. Other than the Once and WaitGroup types, most are intended
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// for use by low-level library routines. Higher-level synchronization is
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// better done via channels and communication.
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//
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// Values containing the types defined in this package should not be copied.
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package sync
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import (
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"internal/race"
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"sync/atomic"
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"unsafe"
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)
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func throw(string) // provided by runtime
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// A Mutex is a mutual exclusion lock.
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// The zero value for a Mutex is an unlocked mutex.
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//
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// A Mutex must not be copied after first use.
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type Mutex struct {
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state int32
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sema uint32
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}
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// A Locker represents an object that can be locked and unlocked.
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type Locker interface {
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Lock()
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Unlock()
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}
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const (
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mutexLocked = 1 << iota // mutex is locked
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mutexWoken
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mutexStarving
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mutexWaiterShift = iota
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// Mutex fairness.
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//
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// Mutex can be in 2 modes of operations: normal and starvation.
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// In normal mode waiters are queued in FIFO order, but a woken up waiter
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// does not own the mutex and competes with new arriving goroutines over
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// the ownership. New arriving goroutines have an advantage -- they are
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// already running on CPU and there can be lots of them, so a woken up
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// waiter has good chances of losing. In such case it is queued at front
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// of the wait queue. If a waiter fails to acquire the mutex for more than 1ms,
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// it switches mutex to the starvation mode.
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//
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// In starvation mode ownership of the mutex is directly handed off from
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// the unlocking goroutine to the waiter at the front of the queue.
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// New arriving goroutines don't try to acquire the mutex even if it appears
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// to be unlocked, and don't try to spin. Instead they queue themselves at
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// the tail of the wait queue.
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//
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// If a waiter receives ownership of the mutex and sees that either
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// (1) it is the last waiter in the queue, or (2) it waited for less than 1 ms,
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// it switches mutex back to normal operation mode.
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//
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// Normal mode has considerably better performance as a goroutine can acquire
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// a mutex several times in a row even if there are blocked waiters.
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// Starvation mode is important to prevent pathological cases of tail latency.
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starvationThresholdNs = 1e6
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)
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// Lock locks m.
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// If the lock is already in use, the calling goroutine
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// blocks until the mutex is available.
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func (m *Mutex) Lock() {
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// Fast path: grab unlocked mutex.
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if atomic.CompareAndSwapInt32(&m.state, 0, mutexLocked) {
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if race.Enabled {
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race.Acquire(unsafe.Pointer(m))
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}
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return
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}
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// Slow path (outlined so that the fast path can be inlined)
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m.lockSlow()
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}
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// TryLock tries to lock m and reports whether it succeeded.
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//
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// Note that while correct uses of TryLock do exist, they are rare,
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// and use of TryLock is often a sign of a deeper problem
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// in a particular use of mutexes.
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func (m *Mutex) TryLock() bool {
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old := m.state
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if old&(mutexLocked|mutexStarving) != 0 {
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return false
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}
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// There may be a goroutine waiting for the mutex, but we are
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// running now and can try to grab the mutex before that
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// goroutine wakes up.
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if !atomic.CompareAndSwapInt32(&m.state, old, old|mutexLocked) {
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return false
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}
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if race.Enabled {
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race.Acquire(unsafe.Pointer(m))
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}
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return true
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}
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func (m *Mutex) lockSlow() {
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var waitStartTime int64
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starving := false
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awoke := false
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iter := 0
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old := m.state
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for {
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// Don't spin in starvation mode, ownership is handed off to waiters
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// so we won't be able to acquire the mutex anyway.
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if old&(mutexLocked|mutexStarving) == mutexLocked && runtime_canSpin(iter) {
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// Active spinning makes sense.
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// Try to set mutexWoken flag to inform Unlock
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// to not wake other blocked goroutines.
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if !awoke && old&mutexWoken == 0 && old>>mutexWaiterShift != 0 &&
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atomic.CompareAndSwapInt32(&m.state, old, old|mutexWoken) {
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awoke = true
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}
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runtime_doSpin()
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iter++
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old = m.state
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continue
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}
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new := old
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// Don't try to acquire starving mutex, new arriving goroutines must queue.
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if old&mutexStarving == 0 {
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new |= mutexLocked
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}
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if old&(mutexLocked|mutexStarving) != 0 {
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new += 1 << mutexWaiterShift
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}
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// The current goroutine switches mutex to starvation mode.
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// But if the mutex is currently unlocked, don't do the switch.
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// Unlock expects that starving mutex has waiters, which will not
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// be true in this case.
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if starving && old&mutexLocked != 0 {
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new |= mutexStarving
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}
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if awoke {
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// The goroutine has been woken from sleep,
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// so we need to reset the flag in either case.
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if new&mutexWoken == 0 {
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throw("sync: inconsistent mutex state")
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}
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new &^= mutexWoken
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}
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if atomic.CompareAndSwapInt32(&m.state, old, new) {
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if old&(mutexLocked|mutexStarving) == 0 {
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break // locked the mutex with CAS
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}
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// If we were already waiting before, queue at the front of the queue.
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queueLifo := waitStartTime != 0
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if waitStartTime == 0 {
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waitStartTime = runtime_nanotime()
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}
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runtime_SemacquireMutex(&m.sema, queueLifo, 1)
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starving = starving || runtime_nanotime()-waitStartTime > starvationThresholdNs
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old = m.state
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if old&mutexStarving != 0 {
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// If this goroutine was woken and mutex is in starvation mode,
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// ownership was handed off to us but mutex is in somewhat
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// inconsistent state: mutexLocked is not set and we are still
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// accounted as waiter. Fix that.
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if old&(mutexLocked|mutexWoken) != 0 || old>>mutexWaiterShift == 0 {
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throw("sync: inconsistent mutex state")
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}
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delta := int32(mutexLocked - 1<<mutexWaiterShift)
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if !starving || old>>mutexWaiterShift == 1 {
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// Exit starvation mode.
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// Critical to do it here and consider wait time.
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// Starvation mode is so inefficient, that two goroutines
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// can go lock-step infinitely once they switch mutex
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// to starvation mode.
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delta -= mutexStarving
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}
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atomic.AddInt32(&m.state, delta)
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break
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}
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awoke = true
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iter = 0
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} else {
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old = m.state
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}
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}
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if race.Enabled {
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race.Acquire(unsafe.Pointer(m))
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}
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}
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// Unlock unlocks m.
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// It is a run-time error if m is not locked on entry to Unlock.
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//
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// A locked Mutex is not associated with a particular goroutine.
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// It is allowed for one goroutine to lock a Mutex and then
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// arrange for another goroutine to unlock it.
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func (m *Mutex) Unlock() {
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if race.Enabled {
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_ = m.state
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race.Release(unsafe.Pointer(m))
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}
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// Fast path: drop lock bit.
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new := atomic.AddInt32(&m.state, -mutexLocked)
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if new != 0 {
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// Outlined slow path to allow inlining the fast path.
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// To hide unlockSlow during tracing we skip one extra frame when tracing GoUnblock.
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m.unlockSlow(new)
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}
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}
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func (m *Mutex) unlockSlow(new int32) {
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if (new+mutexLocked)&mutexLocked == 0 {
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throw("sync: unlock of unlocked mutex")
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}
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if new&mutexStarving == 0 {
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old := new
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for {
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// If there are no waiters or a goroutine has already
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// been woken or grabbed the lock, no need to wake anyone.
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// In starvation mode ownership is directly handed off from unlocking
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// goroutine to the next waiter. We are not part of this chain,
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// since we did not observe mutexStarving when we unlocked the mutex above.
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// So get off the way.
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if old>>mutexWaiterShift == 0 || old&(mutexLocked|mutexWoken|mutexStarving) != 0 {
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return
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}
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// Grab the right to wake someone.
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new = (old - 1<<mutexWaiterShift) | mutexWoken
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if atomic.CompareAndSwapInt32(&m.state, old, new) {
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runtime_Semrelease(&m.sema, false, 1)
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return
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}
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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, 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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runtime_Semrelease(&m.sema, true, 1)
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}
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}
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