Retro68/gcc/libgo/go/sync/pool.go

// Copyright 2013 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 sync

import (
	"internal/race"
	"runtime"
	"sync/atomic"
	"unsafe"
)

// A Pool is a set of temporary objects that may be individually saved and
// retrieved.
//
// Any item stored in the Pool may be removed automatically at any time without
// notification. If the Pool holds the only reference when this happens, the
// item might be deallocated.
//
// A Pool is safe for use by multiple goroutines simultaneously.
//
// Pool's purpose is to cache allocated but unused items for later reuse,
// relieving pressure on the garbage collector. That is, it makes it easy to
// build efficient, thread-safe free lists. However, it is not suitable for all
// free lists.
//
// An appropriate use of a Pool is to manage a group of temporary items
// silently shared among and potentially reused by concurrent independent
// clients of a package. Pool provides a way to amortize allocation overhead
// across many clients.
//
// An example of good use of a Pool is in the fmt package, which maintains a
// dynamically-sized store of temporary output buffers. The store scales under
// load (when many goroutines are actively printing) and shrinks when
// quiescent.
//
// On the other hand, a free list maintained as part of a short-lived object is
// not a suitable use for a Pool, since the overhead does not amortize well in
// that scenario. It is more efficient to have such objects implement their own
// free list.
//
type Pool struct {
	local     unsafe.Pointer // local fixed-size per-P pool, actual type is [P]poolLocal
	localSize uintptr        // size of the local array

	// New optionally specifies a function to generate
	// a value when Get would otherwise return nil.
	// It may not be changed concurrently with calls to Get.
	New func() interface{}
}

// Local per-P Pool appendix.
type poolLocal struct {
	private interface{}   // Can be used only by the respective P.
	shared  []interface{} // Can be used by any P.
	Mutex                 // Protects shared.
	pad     [128]byte     // Prevents false sharing.
}

// Put adds x to the pool.
func (p *Pool) Put(x interface{}) {
	if race.Enabled {
		// Under race detector the Pool degenerates into no-op.
		// It's conforming, simple and does not introduce excessive
		// happens-before edges between unrelated goroutines.
		return
	}
	if x == nil {
		return
	}
	l := p.pin()
	if l.private == nil {
		l.private = x
		x = nil
	}
	runtime_procUnpin()
	if x == nil {
		return
	}
	l.Lock()
	l.shared = append(l.shared, x)
	l.Unlock()
}

// Get selects an arbitrary item from the Pool, removes it from the
// Pool, and returns it to the caller.
// Get may choose to ignore the pool and treat it as empty.
// Callers should not assume any relation between values passed to Put and
// the values returned by Get.
//
// If Get would otherwise return nil and p.New is non-nil, Get returns
// the result of calling p.New.
func (p *Pool) Get() interface{} {
	if race.Enabled {
		if p.New != nil {
			return p.New()
		}
		return nil
	}
	l := p.pin()
	x := l.private
	l.private = nil
	runtime_procUnpin()
	if x != nil {
		return x
	}
	l.Lock()
	last := len(l.shared) - 1
	if last >= 0 {
		x = l.shared[last]
		l.shared = l.shared[:last]
	}
	l.Unlock()
	if x != nil {
		return x
	}
	return p.getSlow()
}

func (p *Pool) getSlow() (x interface{}) {
	// See the comment in pin regarding ordering of the loads.
	size := atomic.LoadUintptr(&p.localSize) // load-acquire
	local := p.local                         // load-consume
	// Try to steal one element from other procs.
	pid := runtime_procPin()
	runtime_procUnpin()
	for i := 0; i < int(size); i++ {
		l := indexLocal(local, (pid+i+1)%int(size))
		l.Lock()
		last := len(l.shared) - 1
		if last >= 0 {
			x = l.shared[last]
			l.shared = l.shared[:last]
			l.Unlock()
			break
		}
		l.Unlock()
	}

	if x == nil && p.New != nil {
		x = p.New()
	}
	return x
}

// pin pins the current goroutine to P, disables preemption and returns poolLocal pool for the P.
// Caller must call runtime_procUnpin() when done with the pool.
func (p *Pool) pin() *poolLocal {
	pid := runtime_procPin()
	// In pinSlow we store to localSize and then to local, here we load in opposite order.
	// Since we've disabled preemption, GC can not happen in between.
	// Thus here we must observe local at least as large localSize.
	// We can observe a newer/larger local, it is fine (we must observe its zero-initialized-ness).
	s := atomic.LoadUintptr(&p.localSize) // load-acquire
	l := p.local                          // load-consume
	if uintptr(pid) < s {
		return indexLocal(l, pid)
	}
	return p.pinSlow()
}

func (p *Pool) pinSlow() *poolLocal {
	// Retry under the mutex.
	// Can not lock the mutex while pinned.
	runtime_procUnpin()
	allPoolsMu.Lock()
	defer allPoolsMu.Unlock()
	pid := runtime_procPin()
	// poolCleanup won't be called while we are pinned.
	s := p.localSize
	l := p.local
	if uintptr(pid) < s {
		return indexLocal(l, pid)
	}
	if p.local == nil {
		allPools = append(allPools, p)
	}
	// If GOMAXPROCS changes between GCs, we re-allocate the array and lose the old one.
	size := runtime.GOMAXPROCS(0)
	local := make([]poolLocal, size)
	atomic.StorePointer((*unsafe.Pointer)(&p.local), unsafe.Pointer(&local[0])) // store-release
	atomic.StoreUintptr(&p.localSize, uintptr(size))                            // store-release
	return &local[pid]
}

func poolCleanup() {
	// This function is called with the world stopped, at the beginning of a garbage collection.
	// It must not allocate and probably should not call any runtime functions.
	// Defensively zero out everything, 2 reasons:
	// 1. To prevent false retention of whole Pools.
	// 2. If GC happens while a goroutine works with l.shared in Put/Get,
	//    it will retain whole Pool. So next cycle memory consumption would be doubled.
	for i, p := range allPools {
		allPools[i] = nil
		for i := 0; i < int(p.localSize); i++ {
			l := indexLocal(p.local, i)
			l.private = nil
			for j := range l.shared {
				l.shared[j] = nil
			}
			l.shared = nil
		}
		p.local = nil
		p.localSize = 0
	}
	allPools = []*Pool{}
}

var (
	allPoolsMu Mutex
	allPools   []*Pool
)

func init() {
	runtime_registerPoolCleanup(poolCleanup)
}

func indexLocal(l unsafe.Pointer, i int) *poolLocal {
	return &(*[1000000]poolLocal)(l)[i]
}

// Implemented in runtime.
func runtime_registerPoolCleanup(cleanup func())
func runtime_procPin() int
func runtime_procUnpin()
Update gcc to 5.2.0 2015-08-28 15:33:40 +00:00			`// Copyright 2013 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 sync`

			`import (`
upgrade gcc to 6.3.0, binutils to 2.28 2017-04-10 11:32:00 +00:00			`"internal/race"`
Update gcc to 5.2.0 2015-08-28 15:33:40 +00:00			`"runtime"`
			`"sync/atomic"`
			`"unsafe"`
			`)`

			`// A Pool is a set of temporary objects that may be individually saved and`
			`// retrieved.`
			`//`
			`// Any item stored in the Pool may be removed automatically at any time without`
			`// notification. If the Pool holds the only reference when this happens, the`
			`// item might be deallocated.`
			`//`
			`// A Pool is safe for use by multiple goroutines simultaneously.`
			`//`
			`// Pool's purpose is to cache allocated but unused items for later reuse,`
			`// relieving pressure on the garbage collector. That is, it makes it easy to`
			`// build efficient, thread-safe free lists. However, it is not suitable for all`
			`// free lists.`
			`//`
			`// An appropriate use of a Pool is to manage a group of temporary items`
			`// silently shared among and potentially reused by concurrent independent`
			`// clients of a package. Pool provides a way to amortize allocation overhead`
			`// across many clients.`
			`//`
			`// An example of good use of a Pool is in the fmt package, which maintains a`
			`// dynamically-sized store of temporary output buffers. The store scales under`
			`// load (when many goroutines are actively printing) and shrinks when`
			`// quiescent.`
			`//`
			`// On the other hand, a free list maintained as part of a short-lived object is`
			`// not a suitable use for a Pool, since the overhead does not amortize well in`
			`// that scenario. It is more efficient to have such objects implement their own`
			`// free list.`
			`//`
			`type Pool struct {`
			`local unsafe.Pointer // local fixed-size per-P pool, actual type is [P]poolLocal`
			`localSize uintptr // size of the local array`

			`// New optionally specifies a function to generate`
			`// a value when Get would otherwise return nil.`
			`// It may not be changed concurrently with calls to Get.`
			`New func() interface{}`
			`}`

			`// Local per-P Pool appendix.`
			`type poolLocal struct {`
			`private interface{} // Can be used only by the respective P.`
			`shared []interface{} // Can be used by any P.`
			`Mutex // Protects shared.`
			`pad [128]byte // Prevents false sharing.`
			`}`

			`// Put adds x to the pool.`
			`func (p *Pool) Put(x interface{}) {`
upgrade gcc to 6.3.0, binutils to 2.28 2017-04-10 11:32:00 +00:00			`if race.Enabled {`
Update gcc to 5.2.0 2015-08-28 15:33:40 +00:00			`// Under race detector the Pool degenerates into no-op.`
			`// It's conforming, simple and does not introduce excessive`
			`// happens-before edges between unrelated goroutines.`
			`return`
			`}`
			`if x == nil {`
			`return`
			`}`
			`l := p.pin()`
			`if l.private == nil {`
			`l.private = x`
			`x = nil`
			`}`
			`runtime_procUnpin()`
			`if x == nil {`
			`return`
			`}`
			`l.Lock()`
			`l.shared = append(l.shared, x)`
			`l.Unlock()`
			`}`

			`// Get selects an arbitrary item from the Pool, removes it from the`
			`// Pool, and returns it to the caller.`
			`// Get may choose to ignore the pool and treat it as empty.`
			`// Callers should not assume any relation between values passed to Put and`
			`// the values returned by Get.`
			`//`
			`// If Get would otherwise return nil and p.New is non-nil, Get returns`
			`// the result of calling p.New.`
			`func (p *Pool) Get() interface{} {`
upgrade gcc to 6.3.0, binutils to 2.28 2017-04-10 11:32:00 +00:00			`if race.Enabled {`
Update gcc to 5.2.0 2015-08-28 15:33:40 +00:00			`if p.New != nil {`
			`return p.New()`
			`}`
			`return nil`
			`}`
			`l := p.pin()`
			`x := l.private`
			`l.private = nil`
			`runtime_procUnpin()`
			`if x != nil {`
			`return x`
			`}`
			`l.Lock()`
			`last := len(l.shared) - 1`
			`if last >= 0 {`
			`x = l.shared[last]`
			`l.shared = l.shared[:last]`
			`}`
			`l.Unlock()`
			`if x != nil {`
			`return x`
			`}`
			`return p.getSlow()`
			`}`

			`func (p *Pool) getSlow() (x interface{}) {`
			`// See the comment in pin regarding ordering of the loads.`
			`size := atomic.LoadUintptr(&p.localSize) // load-acquire`
			`local := p.local // load-consume`
			`// Try to steal one element from other procs.`
			`pid := runtime_procPin()`
			`runtime_procUnpin()`
			`for i := 0; i < int(size); i++ {`
			`l := indexLocal(local, (pid+i+1)%int(size))`
			`l.Lock()`
			`last := len(l.shared) - 1`
			`if last >= 0 {`
			`x = l.shared[last]`
			`l.shared = l.shared[:last]`
			`l.Unlock()`
			`break`
			`}`
			`l.Unlock()`
			`}`

			`if x == nil && p.New != nil {`
			`x = p.New()`
			`}`
			`return x`
			`}`

			`// pin pins the current goroutine to P, disables preemption and returns poolLocal pool for the P.`
			`// Caller must call runtime_procUnpin() when done with the pool.`
			`func (p Pool) pin() poolLocal {`
			`pid := runtime_procPin()`
			`// In pinSlow we store to localSize and then to local, here we load in opposite order.`
			`// Since we've disabled preemption, GC can not happen in between.`
			`// Thus here we must observe local at least as large localSize.`
			`// We can observe a newer/larger local, it is fine (we must observe its zero-initialized-ness).`
			`s := atomic.LoadUintptr(&p.localSize) // load-acquire`
			`l := p.local // load-consume`
			`if uintptr(pid) < s {`
			`return indexLocal(l, pid)`
			`}`
			`return p.pinSlow()`
			`}`

			`func (p Pool) pinSlow() poolLocal {`
			`// Retry under the mutex.`
			`// Can not lock the mutex while pinned.`
			`runtime_procUnpin()`
			`allPoolsMu.Lock()`
			`defer allPoolsMu.Unlock()`
			`pid := runtime_procPin()`
			`// poolCleanup won't be called while we are pinned.`
			`s := p.localSize`
			`l := p.local`
			`if uintptr(pid) < s {`
			`return indexLocal(l, pid)`
			`}`
			`if p.local == nil {`
			`allPools = append(allPools, p)`
			`}`
			`// If GOMAXPROCS changes between GCs, we re-allocate the array and lose the old one.`
			`size := runtime.GOMAXPROCS(0)`
			`local := make([]poolLocal, size)`
			`atomic.StorePointer((*unsafe.Pointer)(&p.local), unsafe.Pointer(&local[0])) // store-release`
			`atomic.StoreUintptr(&p.localSize, uintptr(size)) // store-release`
			`return &local[pid]`
			`}`

			`func poolCleanup() {`
			`// This function is called with the world stopped, at the beginning of a garbage collection.`
			`// It must not allocate and probably should not call any runtime functions.`
			`// Defensively zero out everything, 2 reasons:`
			`// 1. To prevent false retention of whole Pools.`
			`// 2. If GC happens while a goroutine works with l.shared in Put/Get,`
			`// it will retain whole Pool. So next cycle memory consumption would be doubled.`
			`for i, p := range allPools {`
			`allPools[i] = nil`
			`for i := 0; i < int(p.localSize); i++ {`
			`l := indexLocal(p.local, i)`
			`l.private = nil`
			`for j := range l.shared {`
			`l.shared[j] = nil`
			`}`
			`l.shared = nil`
			`}`
			`p.local = nil`
			`p.localSize = 0`
			`}`
			`allPools = []*Pool{}`
			`}`

			`var (`
			`allPoolsMu Mutex`
			`allPools []*Pool`
			`)`

			`func init() {`
			`runtime_registerPoolCleanup(poolCleanup)`
			`}`

			`func indexLocal(l unsafe.Pointer, i int) *poolLocal {`
			`return &(*[1000000]poolLocal)(l)[i]`
			`}`

			`// Implemented in runtime.`
			`func runtime_registerPoolCleanup(cleanup func())`
			`func runtime_procPin() int`
			`func runtime_procUnpin()`