src/runtime/sema.go - go - Git at Google

 // Copyright 2009 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.

 // Semaphore implementation exposed to Go.
 // Intended use is provide a sleep and wakeup
 // primitive that can be used in the contended case
 // of other synchronization primitives.
 // Thus it targets the same goal as Linux's futex,
 // but it has much simpler semantics.
 //
 // That is, don't think of these as semaphores.
 // Think of them as a way to implement sleep and wakeup
 // such that every sleep is paired with a single wakeup,
 // even if, due to races, the wakeup happens before the sleep.
 //
 // See Mullender and Cox, ``Semaphores in Plan 9,''
 // http://swtch.com/semaphore.pdf

 package runtime

 import (
 	"runtime/internal/atomic"
 	"runtime/internal/sys"
 	"unsafe"
 )

 // Asynchronous semaphore for sync.Mutex.

 type semaRoot struct {
 	lock  mutex
 	head  *sudog
 	tail  *sudog
 	nwait uint32 // Number of waiters. Read w/o the lock.
 }

 // Prime to not correlate with any user patterns.
 const semTabSize = 251

 var semtable [semTabSize]struct {
 	root semaRoot
 	pad  [sys.CacheLineSize - unsafe.Sizeof(semaRoot{})]byte
 }

 //go:linkname sync_runtime_Semacquire sync.runtime_Semacquire
 func sync_runtime_Semacquire(addr *uint32) {
 	semacquire(addr, true)
 }

 //go:linkname net_runtime_Semacquire net.runtime_Semacquire
 func net_runtime_Semacquire(addr *uint32) {
 	semacquire(addr, true)
 }

 //go:linkname sync_runtime_Semrelease sync.runtime_Semrelease
 func sync_runtime_Semrelease(addr *uint32) {
 	semrelease(addr)
 }

 //go:linkname net_runtime_Semrelease net.runtime_Semrelease
 func net_runtime_Semrelease(addr *uint32) {
 	semrelease(addr)
 }

 // Called from runtime.
 func semacquire(addr *uint32, profile bool) {
 	gp := getg()
 	if gp != gp.m.curg {
 		throw("semacquire not on the G stack")
 	}

 	// Easy case.
 	if cansemacquire(addr) {
 		return
 	}

 	// Harder case:
 	//	increment waiter count
 	//	try cansemacquire one more time, return if succeeded
 	//	enqueue itself as a waiter
 	//	sleep
 	//	(waiter descriptor is dequeued by signaler)
 	s := acquireSudog()
 	root := semroot(addr)
 	t0 := int64(0)
 	s.releasetime = 0
 	if profile && blockprofilerate > 0 {
 		t0 = cputicks()
 		s.releasetime = -1
 	}
 	for {
 		lock(&root.lock)
 		// Add ourselves to nwait to disable "easy case" in semrelease.
 		atomic.Xadd(&root.nwait, 1)
 		// Check cansemacquire to avoid missed wakeup.
 		if cansemacquire(addr) {
 			atomic.Xadd(&root.nwait, -1)
 			unlock(&root.lock)
 			break
 		}
 		// Any semrelease after the cansemacquire knows we're waiting
 		// (we set nwait above), so go to sleep.
 		root.queue(addr, s)
 		goparkunlock(&root.lock, "semacquire", traceEvGoBlockSync, 4)
 		if cansemacquire(addr) {
 			break
 		}
 	}
 	if s.releasetime > 0 {
 		blockevent(int64(s.releasetime)-t0, 3)
 	}
 	releaseSudog(s)
 }

 func semrelease(addr *uint32) {
 	root := semroot(addr)
 	atomic.Xadd(addr, 1)

 	// Easy case: no waiters?
 	// This check must happen after the xadd, to avoid a missed wakeup
 	// (see loop in semacquire).
 	if atomic.Load(&root.nwait) == 0 {
 		return
 	}

 	// Harder case: search for a waiter and wake it.
 	lock(&root.lock)
 	if atomic.Load(&root.nwait) == 0 {
 		// The count is already consumed by another goroutine,
 		// so no need to wake up another goroutine.
 		unlock(&root.lock)
 		return
 	}
 	s := root.head
 	for ; s != nil; s = s.next {
 		if s.elem == unsafe.Pointer(addr) {
 			atomic.Xadd(&root.nwait, -1)
 			root.dequeue(s)
 			break
 		}
 	}
 	unlock(&root.lock)
 	if s != nil {
 		if s.releasetime != 0 {
 			s.releasetime = cputicks()
 		}
 		goready(s.g, 4)
 	}
 }

 func semroot(addr *uint32) *semaRoot {
 	return &semtable[(uintptr(unsafe.Pointer(addr))>>3)%semTabSize].root
 }

 func cansemacquire(addr *uint32) bool {
 	for {
 		v := atomic.Load(addr)
 		if v == 0 {
 			return false
 		}
 		if atomic.Cas(addr, v, v-1) {
 			return true
 		}
 	}
 }

 func (root *semaRoot) queue(addr *uint32, s *sudog) {
 	s.g = getg()
 	s.elem = unsafe.Pointer(addr)
 	s.next = nil
 	s.prev = root.tail
 	if root.tail != nil {
 		root.tail.next = s
 	} else {
 		root.head = s
 	}
 	root.tail = s
 }

 func (root *semaRoot) dequeue(s *sudog) {
 	if s.next != nil {
 		s.next.prev = s.prev
 	} else {
 		root.tail = s.prev
 	}
 	if s.prev != nil {
 		s.prev.next = s.next
 	} else {
 		root.head = s.next
 	}
 	s.elem = nil
 	s.next = nil
 	s.prev = nil
 }

 // Synchronous semaphore for sync.Cond.
 type syncSema struct {
 	lock mutex
 	head *sudog
 	tail *sudog
 }

 // syncsemacquire waits for a pairing syncsemrelease on the same semaphore s.
 //go:linkname syncsemacquire sync.runtime_Syncsemacquire
 func syncsemacquire(s *syncSema) {
 	lock(&s.lock)
 	if s.head != nil && s.head.nrelease > 0 {
 		// Have pending release, consume it.
 		var wake *sudog
 		s.head.nrelease--
 		if s.head.nrelease == 0 {
 			wake = s.head
 			s.head = wake.next
 			if s.head == nil {
 				s.tail = nil
 			}
 		}
 		unlock(&s.lock)
 		if wake != nil {
 			wake.next = nil
 			goready(wake.g, 4)
 		}
 	} else {
 		// Enqueue itself.
 		w := acquireSudog()
 		w.g = getg()
 		w.nrelease = -1
 		w.next = nil
 		w.releasetime = 0
 		t0 := int64(0)
 		if blockprofilerate > 0 {
 			t0 = cputicks()
 			w.releasetime = -1
 		}
 		if s.tail == nil {
 			s.head = w
 		} else {
 			s.tail.next = w
 		}
 		s.tail = w
 		goparkunlock(&s.lock, "semacquire", traceEvGoBlockCond, 3)
 		if t0 != 0 {
 			blockevent(int64(w.releasetime)-t0, 2)
 		}
 		releaseSudog(w)
 	}
 }

 // syncsemrelease waits for n pairing syncsemacquire on the same semaphore s.
 //go:linkname syncsemrelease sync.runtime_Syncsemrelease
 func syncsemrelease(s *syncSema, n uint32) {
 	lock(&s.lock)
 	for n > 0 && s.head != nil && s.head.nrelease < 0 {
 		// Have pending acquire, satisfy it.
 		wake := s.head
 		s.head = wake.next
 		if s.head == nil {
 			s.tail = nil
 		}
 		if wake.releasetime != 0 {
 			wake.releasetime = cputicks()
 		}
 		wake.next = nil
 		goready(wake.g, 4)
 		n--
 	}
 	if n > 0 {
 		// enqueue itself
 		w := acquireSudog()
 		w.g = getg()
 		w.nrelease = int32(n)
 		w.next = nil
 		w.releasetime = 0
 		if s.tail == nil {
 			s.head = w
 		} else {
 			s.tail.next = w
 		}
 		s.tail = w
 		goparkunlock(&s.lock, "semarelease", traceEvGoBlockCond, 3)
 		releaseSudog(w)
 	} else {
 		unlock(&s.lock)
 	}
 }

 //go:linkname syncsemcheck sync.runtime_Syncsemcheck
 func syncsemcheck(sz uintptr) {
 	if sz != unsafe.Sizeof(syncSema{}) {
 		print("runtime: bad syncSema size - sync=", sz, " runtime=", unsafe.Sizeof(syncSema{}), "\n")
 		throw("bad syncSema size")
 	}
 }
	// Copyright 2009 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.

	// Semaphore implementation exposed to Go.
	// Intended use is provide a sleep and wakeup
	// primitive that can be used in the contended case
	// of other synchronization primitives.
	// Thus it targets the same goal as Linux's futex,
	// but it has much simpler semantics.
	//
	// That is, don't think of these as semaphores.
	// Think of them as a way to implement sleep and wakeup
	// such that every sleep is paired with a single wakeup,
	// even if, due to races, the wakeup happens before the sleep.
	//
	// See Mullender and Cox, ``Semaphores in Plan 9,''
	// http://swtch.com/semaphore.pdf

	package runtime

	import (
	"runtime/internal/atomic"
	"runtime/internal/sys"
	"unsafe"
	)

	// Asynchronous semaphore for sync.Mutex.

	type semaRoot struct {
	lock mutex
	head *sudog
	tail *sudog
	nwait uint32 // Number of waiters. Read w/o the lock.
	}

	// Prime to not correlate with any user patterns.
	const semTabSize = 251

	var semtable [semTabSize]struct {
	root semaRoot
	pad [sys.CacheLineSize - unsafe.Sizeof(semaRoot{})]byte
	}

	//go:linkname sync_runtime_Semacquire sync.runtime_Semacquire
	func sync_runtime_Semacquire(addr *uint32) {
	semacquire(addr, true)
	}

	//go:linkname net_runtime_Semacquire net.runtime_Semacquire
	func net_runtime_Semacquire(addr *uint32) {
	semacquire(addr, true)
	}

	//go:linkname sync_runtime_Semrelease sync.runtime_Semrelease
	func sync_runtime_Semrelease(addr *uint32) {
	semrelease(addr)
	}

	//go:linkname net_runtime_Semrelease net.runtime_Semrelease
	func net_runtime_Semrelease(addr *uint32) {
	semrelease(addr)
	}

	// Called from runtime.
	func semacquire(addr *uint32, profile bool) {
	gp := getg()
	if gp != gp.m.curg {
	throw("semacquire not on the G stack")
	}

	// Easy case.
	if cansemacquire(addr) {
	return
	}

	// Harder case:
	// increment waiter count
	// try cansemacquire one more time, return if succeeded
	// enqueue itself as a waiter
	// sleep
	// (waiter descriptor is dequeued by signaler)
	s := acquireSudog()
	root := semroot(addr)
	t0 := int64(0)
	s.releasetime = 0
	if profile && blockprofilerate > 0 {
	t0 = cputicks()
	s.releasetime = -1
	}
	for {
	lock(&root.lock)
	// Add ourselves to nwait to disable "easy case" in semrelease.
	atomic.Xadd(&root.nwait, 1)
	// Check cansemacquire to avoid missed wakeup.
	if cansemacquire(addr) {
	atomic.Xadd(&root.nwait, -1)
	unlock(&root.lock)
	break
	}
	// Any semrelease after the cansemacquire knows we're waiting
	// (we set nwait above), so go to sleep.
	root.queue(addr, s)
	goparkunlock(&root.lock, "semacquire", traceEvGoBlockSync, 4)
	if cansemacquire(addr) {
	break
	}
	}
	if s.releasetime > 0 {
	blockevent(int64(s.releasetime)-t0, 3)
	}
	releaseSudog(s)
	}

	func semrelease(addr *uint32) {
	root := semroot(addr)
	atomic.Xadd(addr, 1)

	// Easy case: no waiters?
	// This check must happen after the xadd, to avoid a missed wakeup
	// (see loop in semacquire).
	if atomic.Load(&root.nwait) == 0 {
	return
	}

	// Harder case: search for a waiter and wake it.
	lock(&root.lock)
	if atomic.Load(&root.nwait) == 0 {
	// The count is already consumed by another goroutine,
	// so no need to wake up another goroutine.
	unlock(&root.lock)
	return
	}
	s := root.head
	for ; s != nil; s = s.next {
	if s.elem == unsafe.Pointer(addr) {
	atomic.Xadd(&root.nwait, -1)
	root.dequeue(s)
	break
	}
	}
	unlock(&root.lock)
	if s != nil {
	if s.releasetime != 0 {
	s.releasetime = cputicks()
	}
	goready(s.g, 4)
	}
	}

	func semroot(addr uint32) semaRoot {
	return &semtable[(uintptr(unsafe.Pointer(addr))>>3)%semTabSize].root
	}

	func cansemacquire(addr *uint32) bool {
	for {
	v := atomic.Load(addr)
	if v == 0 {
	return false
	}
	if atomic.Cas(addr, v, v-1) {
	return true
	}
	}
	}

	func (root semaRoot) queue(addr uint32, s *sudog) {
	s.g = getg()
	s.elem = unsafe.Pointer(addr)
	s.next = nil
	s.prev = root.tail
	if root.tail != nil {
	root.tail.next = s
	} else {
	root.head = s
	}
	root.tail = s
	}

	func (root semaRoot) dequeue(s sudog) {
	if s.next != nil {
	s.next.prev = s.prev
	} else {
	root.tail = s.prev
	}
	if s.prev != nil {
	s.prev.next = s.next
	} else {
	root.head = s.next
	}
	s.elem = nil
	s.next = nil
	s.prev = nil
	}

	// Synchronous semaphore for sync.Cond.
	type syncSema struct {
	lock mutex
	head *sudog
	tail *sudog
	}

	// syncsemacquire waits for a pairing syncsemrelease on the same semaphore s.
	//go:linkname syncsemacquire sync.runtime_Syncsemacquire
	func syncsemacquire(s *syncSema) {
	lock(&s.lock)
	if s.head != nil && s.head.nrelease > 0 {
	// Have pending release, consume it.
	var wake *sudog
	s.head.nrelease--
	if s.head.nrelease == 0 {
	wake = s.head
	s.head = wake.next
	if s.head == nil {
	s.tail = nil
	}
	}
	unlock(&s.lock)
	if wake != nil {
	wake.next = nil
	goready(wake.g, 4)
	}
	} else {
	// Enqueue itself.
	w := acquireSudog()
	w.g = getg()
	w.nrelease = -1
	w.next = nil
	w.releasetime = 0
	t0 := int64(0)
	if blockprofilerate > 0 {
	t0 = cputicks()
	w.releasetime = -1
	}
	if s.tail == nil {
	s.head = w
	} else {
	s.tail.next = w
	}
	s.tail = w
	goparkunlock(&s.lock, "semacquire", traceEvGoBlockCond, 3)
	if t0 != 0 {
	blockevent(int64(w.releasetime)-t0, 2)
	}
	releaseSudog(w)
	}
	}

	// syncsemrelease waits for n pairing syncsemacquire on the same semaphore s.
	//go:linkname syncsemrelease sync.runtime_Syncsemrelease
	func syncsemrelease(s *syncSema, n uint32) {
	lock(&s.lock)
	for n > 0 && s.head != nil && s.head.nrelease < 0 {
	// Have pending acquire, satisfy it.
	wake := s.head
	s.head = wake.next
	if s.head == nil {
	s.tail = nil
	}
	if wake.releasetime != 0 {
	wake.releasetime = cputicks()
	}
	wake.next = nil
	goready(wake.g, 4)
	n--
	}
	if n > 0 {
	// enqueue itself
	w := acquireSudog()
	w.g = getg()
	w.nrelease = int32(n)
	w.next = nil
	w.releasetime = 0
	if s.tail == nil {
	s.head = w
	} else {
	s.tail.next = w
	}
	s.tail = w
	goparkunlock(&s.lock, "semarelease", traceEvGoBlockCond, 3)
	releaseSudog(w)
	} else {
	unlock(&s.lock)
	}
	}

	//go:linkname syncsemcheck sync.runtime_Syncsemcheck
	func syncsemcheck(sz uintptr) {
	if sz != unsafe.Sizeof(syncSema{}) {
	print("runtime: bad syncSema size - sync=", sz, " runtime=", unsafe.Sizeof(syncSema{}), "\n")
	throw("bad syncSema size")
	}
	}