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

 // Copyright 2023 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 runtime

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

 // A Pinner is a set of Go objects each pinned to a fixed location in memory. The
 // [Pinner.Pin] method pins one object, while [Pinner.Unpin] unpins all pinned
 // objects. See their comments for more information.
 type Pinner struct {
 	*pinner
 }

 // Pin pins a Go object, preventing it from being moved or freed by the garbage
 // collector until the [Pinner.Unpin] method has been called.
 //
 // A pointer to a pinned object can be directly stored in C memory or can be
 // contained in Go memory passed to C functions. If the pinned object itself
 // contains pointers to Go objects, these objects must be pinned separately if they
 // are going to be accessed from C code.
 //
 // The argument must be a pointer of any type or an [unsafe.Pointer].
 // It's safe to call Pin on non-Go pointers, in which case Pin will do nothing.
 func (p *Pinner) Pin(pointer any) {
 	if p.pinner == nil {
 		// Check the pinner cache first.
 		mp := acquirem()
 		if pp := mp.p.ptr(); pp != nil {
 			p.pinner = pp.pinnerCache
 			pp.pinnerCache = nil
 		}
 		releasem(mp)

 		if p.pinner == nil {
 			// Didn't get anything from the pinner cache.
 			p.pinner = new(pinner)
 			p.refs = p.refStore[:0]

 			// We set this finalizer once and never clear it. Thus, if the
 			// pinner gets cached, we'll reuse it, along with its finalizer.
 			// This lets us avoid the relatively expensive SetFinalizer call
 			// when reusing from the cache. The finalizer however has to be
 			// resilient to an empty pinner being finalized, which is done
 			// by checking p.refs' length.
 			SetFinalizer(p.pinner, func(i *pinner) {
 				if len(i.refs) != 0 {
 					i.unpin() // only required to make the test idempotent
 					pinnerLeakPanic()
 				}
 			})
 		}
 	}
 	ptr := pinnerGetPtr(&pointer)
 	if setPinned(ptr, true) {
 		p.refs = append(p.refs, ptr)
 	}
 }

 // Unpin unpins all pinned objects of the [Pinner].
 func (p *Pinner) Unpin() {
 	p.pinner.unpin()

 	mp := acquirem()
 	if pp := mp.p.ptr(); pp != nil && pp.pinnerCache == nil {
 		// Put the pinner back in the cache, but only if the
 		// cache is empty. If application code is reusing Pinners
 		// on its own, we want to leave the backing store in place
 		// so reuse is more efficient.
 		pp.pinnerCache = p.pinner
 		p.pinner = nil
 	}
 	releasem(mp)
 }

 const (
 	pinnerSize         = 64
 	pinnerRefStoreSize = (pinnerSize - unsafe.Sizeof([]unsafe.Pointer{})) / unsafe.Sizeof(unsafe.Pointer(nil))
 )

 type pinner struct {
 	refs     []unsafe.Pointer
 	refStore [pinnerRefStoreSize]unsafe.Pointer
 }

 func (p *pinner) unpin() {
 	if p == nil || p.refs == nil {
 		return
 	}
 	for i := range p.refs {
 		setPinned(p.refs[i], false)
 	}
 	// The following two lines make all pointers to references
 	// in p.refs unreachable, either by deleting them or dropping
 	// p.refs' backing store (if it was not backed by refStore).
 	p.refStore = [pinnerRefStoreSize]unsafe.Pointer{}
 	p.refs = p.refStore[:0]
 }

 func pinnerGetPtr(i *any) unsafe.Pointer {
 	e := efaceOf(i)
 	etyp := e._type
 	if etyp == nil {
 		panic(errorString("runtime.Pinner: argument is nil"))
 	}
 	if kind := etyp.Kind_ & abi.KindMask; kind != abi.Pointer && kind != abi.UnsafePointer {
 		panic(errorString("runtime.Pinner: argument is not a pointer: " + toRType(etyp).string()))
 	}
 	if inUserArenaChunk(uintptr(e.data)) {
 		// Arena-allocated objects are not eligible for pinning.
 		panic(errorString("runtime.Pinner: object was allocated into an arena"))
 	}
 	return e.data
 }

 // isPinned checks if a Go pointer is pinned.
 // nosplit, because it's called from nosplit code in cgocheck.
 //
 //go:nosplit
 func isPinned(ptr unsafe.Pointer) bool {
 	span := spanOfHeap(uintptr(ptr))
 	if span == nil {
 		// this code is only called for Go pointer, so this must be a
 		// linker-allocated global object.
 		return true
 	}
 	pinnerBits := span.getPinnerBits()
 	// these pinnerBits might get unlinked by a concurrently running sweep, but
 	// that's OK because gcBits don't get cleared until the following GC cycle
 	// (nextMarkBitArenaEpoch)
 	if pinnerBits == nil {
 		return false
 	}
 	objIndex := span.objIndex(uintptr(ptr))
 	pinState := pinnerBits.ofObject(objIndex)
 	KeepAlive(ptr) // make sure ptr is alive until we are done so the span can't be freed
 	return pinState.isPinned()
 }

 // setPinned marks or unmarks a Go pointer as pinned, when the ptr is a Go pointer.
 // It will be ignored while try to pin a non-Go pointer,
 // and it will be panic while try to unpin a non-Go pointer,
 // which should not happen in normal usage.
 func setPinned(ptr unsafe.Pointer, pin bool) bool {
 	span := spanOfHeap(uintptr(ptr))
 	if span == nil {
 		if !pin {
 			panic(errorString("tried to unpin non-Go pointer"))
 		}
 		// This is a linker-allocated, zero size object or other object,
 		// nothing to do, silently ignore it.
 		return false
 	}

 	// ensure that the span is swept, b/c sweeping accesses the specials list
 	// w/o locks.
 	mp := acquirem()
 	span.ensureSwept()
 	KeepAlive(ptr) // make sure ptr is still alive after span is swept

 	objIndex := span.objIndex(uintptr(ptr))

 	lock(&span.speciallock) // guard against concurrent calls of setPinned on same span

 	pinnerBits := span.getPinnerBits()
 	if pinnerBits == nil {
 		pinnerBits = span.newPinnerBits()
 		span.setPinnerBits(pinnerBits)
 	}
 	pinState := pinnerBits.ofObject(objIndex)
 	if pin {
 		if pinState.isPinned() {
 			// multiple pins on same object, set multipin bit
 			pinState.setMultiPinned(true)
 			// and increase the pin counter
 			// TODO(mknyszek): investigate if systemstack is necessary here
 			systemstack(func() {
 				offset := objIndex * span.elemsize
 				span.incPinCounter(offset)
 			})
 		} else {
 			// set pin bit
 			pinState.setPinned(true)
 		}
 	} else {
 		// unpin
 		if pinState.isPinned() {
 			if pinState.isMultiPinned() {
 				var exists bool
 				// TODO(mknyszek): investigate if systemstack is necessary here
 				systemstack(func() {
 					offset := objIndex * span.elemsize
 					exists = span.decPinCounter(offset)
 				})
 				if !exists {
 					// counter is 0, clear multipin bit
 					pinState.setMultiPinned(false)
 				}
 			} else {
 				// no multipins recorded. unpin object.
 				pinState.setPinned(false)
 			}
 		} else {
 			// unpinning unpinned object, bail out
 			throw("runtime.Pinner: object already unpinned")
 		}
 	}
 	unlock(&span.speciallock)
 	releasem(mp)
 	return true
 }

 type pinState struct {
 	bytep   *uint8
 	byteVal uint8
 	mask    uint8
 }

 // nosplit, because it's called by isPinned, which is nosplit
 //
 //go:nosplit
 func (v *pinState) isPinned() bool {
 	return (v.byteVal & v.mask) != 0
 }

 func (v *pinState) isMultiPinned() bool {
 	return (v.byteVal & (v.mask << 1)) != 0
 }

 func (v *pinState) setPinned(val bool) {
 	v.set(val, false)
 }

 func (v *pinState) setMultiPinned(val bool) {
 	v.set(val, true)
 }

 // set sets the pin bit of the pinState to val. If multipin is true, it
 // sets/unsets the multipin bit instead.
 func (v *pinState) set(val bool, multipin bool) {
 	mask := v.mask
 	if multipin {
 		mask <<= 1
 	}
 	if val {
 		atomic.Or8(v.bytep, mask)
 	} else {
 		atomic.And8(v.bytep, ^mask)
 	}
 }

 // pinnerBits is the same type as gcBits but has different methods.
 type pinnerBits gcBits

 // ofObject returns the pinState of the n'th object.
 // nosplit, because it's called by isPinned, which is nosplit
 //
 //go:nosplit
 func (p *pinnerBits) ofObject(n uintptr) pinState {
 	bytep, mask := (*gcBits)(p).bitp(n * 2)
 	byteVal := atomic.Load8(bytep)
 	return pinState{bytep, byteVal, mask}
 }

 func (s *mspan) pinnerBitSize() uintptr {
 	return divRoundUp(uintptr(s.nelems)*2, 8)
 }

 // newPinnerBits returns a pointer to 8 byte aligned bytes to be used for this
 // span's pinner bits. newPinnerBits is used to mark objects that are pinned.
 // They are copied when the span is swept.
 func (s *mspan) newPinnerBits() *pinnerBits {
 	return (*pinnerBits)(newMarkBits(uintptr(s.nelems) * 2))
 }

 // nosplit, because it's called by isPinned, which is nosplit
 //
 //go:nosplit
 func (s *mspan) getPinnerBits() *pinnerBits {
 	return (*pinnerBits)(atomic.Loadp(unsafe.Pointer(&s.pinnerBits)))
 }

 func (s *mspan) setPinnerBits(p *pinnerBits) {
 	atomicstorep(unsafe.Pointer(&s.pinnerBits), unsafe.Pointer(p))
 }

 // refreshPinnerBits replaces pinnerBits with a fresh copy in the arenas for the
 // next GC cycle. If it does not contain any pinned objects, pinnerBits of the
 // span is set to nil.
 func (s *mspan) refreshPinnerBits() {
 	p := s.getPinnerBits()
 	if p == nil {
 		return
 	}

 	hasPins := false
 	bytes := alignUp(s.pinnerBitSize(), 8)

 	// Iterate over each 8-byte chunk and check for pins. Note that
 	// newPinnerBits guarantees that pinnerBits will be 8-byte aligned, so we
 	// don't have to worry about edge cases, irrelevant bits will simply be
 	// zero.
 	for _, x := range unsafe.Slice((*uint64)(unsafe.Pointer(&p.x)), bytes/8) {
 		if x != 0 {
 			hasPins = true
 			break
 		}
 	}

 	if hasPins {
 		newPinnerBits := s.newPinnerBits()
 		memmove(unsafe.Pointer(&newPinnerBits.x), unsafe.Pointer(&p.x), bytes)
 		s.setPinnerBits(newPinnerBits)
 	} else {
 		s.setPinnerBits(nil)
 	}
 }

 // incPinCounter is only called for multiple pins of the same object and records
 // the _additional_ pins.
 func (span *mspan) incPinCounter(offset uintptr) {
 	var rec *specialPinCounter
 	ref, exists := span.specialFindSplicePoint(offset, _KindSpecialPinCounter)
 	if !exists {
 		lock(&mheap_.speciallock)
 		rec = (*specialPinCounter)(mheap_.specialPinCounterAlloc.alloc())
 		unlock(&mheap_.speciallock)
 		// splice in record, fill in offset.
 		rec.special.offset = uint16(offset)
 		rec.special.kind = _KindSpecialPinCounter
 		rec.special.next = *ref
 		*ref = (*special)(unsafe.Pointer(rec))
 		spanHasSpecials(span)
 	} else {
 		rec = (*specialPinCounter)(unsafe.Pointer(*ref))
 	}
 	rec.counter++
 }

 // decPinCounter decreases the counter. If the counter reaches 0, the counter
 // special is deleted and false is returned. Otherwise true is returned.
 func (span *mspan) decPinCounter(offset uintptr) bool {
 	ref, exists := span.specialFindSplicePoint(offset, _KindSpecialPinCounter)
 	if !exists {
 		throw("runtime.Pinner: decreased non-existing pin counter")
 	}
 	counter := (*specialPinCounter)(unsafe.Pointer(*ref))
 	counter.counter--
 	if counter.counter == 0 {
 		*ref = counter.special.next
 		if span.specials == nil {
 			spanHasNoSpecials(span)
 		}
 		lock(&mheap_.speciallock)
 		mheap_.specialPinCounterAlloc.free(unsafe.Pointer(counter))
 		unlock(&mheap_.speciallock)
 		return false
 	}
 	return true
 }

 // only for tests
 func pinnerGetPinCounter(addr unsafe.Pointer) *uintptr {
 	_, span, objIndex := findObject(uintptr(addr), 0, 0)
 	offset := objIndex * span.elemsize
 	t, exists := span.specialFindSplicePoint(offset, _KindSpecialPinCounter)
 	if !exists {
 		return nil
 	}
 	counter := (*specialPinCounter)(unsafe.Pointer(*t))
 	return &counter.counter
 }

 // to be able to test that the GC panics when a pinned pointer is leaking, this
 // panic function is a variable, that can be overwritten by a test.
 var pinnerLeakPanic = func() {
 	panic(errorString("runtime.Pinner: found leaking pinned pointer; forgot to call Unpin()?"))
 }
	// Copyright 2023 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 runtime

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

	// A Pinner is a set of Go objects each pinned to a fixed location in memory. The
	// [Pinner.Pin] method pins one object, while [Pinner.Unpin] unpins all pinned
	// objects. See their comments for more information.
	type Pinner struct {
	*pinner
	}

	// Pin pins a Go object, preventing it from being moved or freed by the garbage
	// collector until the [Pinner.Unpin] method has been called.
	//
	// A pointer to a pinned object can be directly stored in C memory or can be
	// contained in Go memory passed to C functions. If the pinned object itself
	// contains pointers to Go objects, these objects must be pinned separately if they
	// are going to be accessed from C code.
	//
	// The argument must be a pointer of any type or an [unsafe.Pointer].
	// It's safe to call Pin on non-Go pointers, in which case Pin will do nothing.
	func (p *Pinner) Pin(pointer any) {
	if p.pinner == nil {
	// Check the pinner cache first.
	mp := acquirem()
	if pp := mp.p.ptr(); pp != nil {
	p.pinner = pp.pinnerCache
	pp.pinnerCache = nil
	}
	releasem(mp)

	if p.pinner == nil {
	// Didn't get anything from the pinner cache.
	p.pinner = new(pinner)
	p.refs = p.refStore[:0]

	// We set this finalizer once and never clear it. Thus, if the
	// pinner gets cached, we'll reuse it, along with its finalizer.
	// This lets us avoid the relatively expensive SetFinalizer call
	// when reusing from the cache. The finalizer however has to be
	// resilient to an empty pinner being finalized, which is done
	// by checking p.refs' length.
	SetFinalizer(p.pinner, func(i *pinner) {
	if len(i.refs) != 0 {
	i.unpin() // only required to make the test idempotent
	pinnerLeakPanic()
	}
	})
	}
	}
	ptr := pinnerGetPtr(&pointer)
	if setPinned(ptr, true) {
	p.refs = append(p.refs, ptr)
	}
	}

	// Unpin unpins all pinned objects of the [Pinner].
	func (p *Pinner) Unpin() {
	p.pinner.unpin()

	mp := acquirem()
	if pp := mp.p.ptr(); pp != nil && pp.pinnerCache == nil {
	// Put the pinner back in the cache, but only if the
	// cache is empty. If application code is reusing Pinners
	// on its own, we want to leave the backing store in place
	// so reuse is more efficient.
	pp.pinnerCache = p.pinner
	p.pinner = nil
	}
	releasem(mp)
	}

	const (
	pinnerSize = 64
	pinnerRefStoreSize = (pinnerSize - unsafe.Sizeof([]unsafe.Pointer{})) / unsafe.Sizeof(unsafe.Pointer(nil))
	)

	type pinner struct {
	refs []unsafe.Pointer
	refStore [pinnerRefStoreSize]unsafe.Pointer
	}

	func (p *pinner) unpin() {
	if p == nil \|\| p.refs == nil {
	return
	}
	for i := range p.refs {
	setPinned(p.refs[i], false)
	}
	// The following two lines make all pointers to references
	// in p.refs unreachable, either by deleting them or dropping
	// p.refs' backing store (if it was not backed by refStore).
	p.refStore = [pinnerRefStoreSize]unsafe.Pointer{}
	p.refs = p.refStore[:0]
	}

	func pinnerGetPtr(i *any) unsafe.Pointer {
	e := efaceOf(i)
	etyp := e._type
	if etyp == nil {
	panic(errorString("runtime.Pinner: argument is nil"))
	}
	if kind := etyp.Kind_ & abi.KindMask; kind != abi.Pointer && kind != abi.UnsafePointer {
	panic(errorString("runtime.Pinner: argument is not a pointer: " + toRType(etyp).string()))
	}
	if inUserArenaChunk(uintptr(e.data)) {
	// Arena-allocated objects are not eligible for pinning.
	panic(errorString("runtime.Pinner: object was allocated into an arena"))
	}
	return e.data
	}

	// isPinned checks if a Go pointer is pinned.
	// nosplit, because it's called from nosplit code in cgocheck.
	//
	//go:nosplit
	func isPinned(ptr unsafe.Pointer) bool {
	span := spanOfHeap(uintptr(ptr))
	if span == nil {
	// this code is only called for Go pointer, so this must be a
	// linker-allocated global object.
	return true
	}
	pinnerBits := span.getPinnerBits()
	// these pinnerBits might get unlinked by a concurrently running sweep, but
	// that's OK because gcBits don't get cleared until the following GC cycle
	// (nextMarkBitArenaEpoch)
	if pinnerBits == nil {
	return false
	}
	objIndex := span.objIndex(uintptr(ptr))
	pinState := pinnerBits.ofObject(objIndex)
	KeepAlive(ptr) // make sure ptr is alive until we are done so the span can't be freed
	return pinState.isPinned()
	}

	// setPinned marks or unmarks a Go pointer as pinned, when the ptr is a Go pointer.
	// It will be ignored while try to pin a non-Go pointer,
	// and it will be panic while try to unpin a non-Go pointer,
	// which should not happen in normal usage.
	func setPinned(ptr unsafe.Pointer, pin bool) bool {
	span := spanOfHeap(uintptr(ptr))
	if span == nil {
	if !pin {
	panic(errorString("tried to unpin non-Go pointer"))
	}
	// This is a linker-allocated, zero size object or other object,
	// nothing to do, silently ignore it.
	return false
	}

	// ensure that the span is swept, b/c sweeping accesses the specials list
	// w/o locks.
	mp := acquirem()
	span.ensureSwept()
	KeepAlive(ptr) // make sure ptr is still alive after span is swept

	objIndex := span.objIndex(uintptr(ptr))

	lock(&span.speciallock) // guard against concurrent calls of setPinned on same span

	pinnerBits := span.getPinnerBits()
	if pinnerBits == nil {
	pinnerBits = span.newPinnerBits()
	span.setPinnerBits(pinnerBits)
	}
	pinState := pinnerBits.ofObject(objIndex)
	if pin {
	if pinState.isPinned() {
	// multiple pins on same object, set multipin bit
	pinState.setMultiPinned(true)
	// and increase the pin counter
	// TODO(mknyszek): investigate if systemstack is necessary here
	systemstack(func() {
	offset := objIndex * span.elemsize
	span.incPinCounter(offset)
	})
	} else {
	// set pin bit
	pinState.setPinned(true)
	}
	} else {
	// unpin
	if pinState.isPinned() {
	if pinState.isMultiPinned() {
	var exists bool
	// TODO(mknyszek): investigate if systemstack is necessary here
	systemstack(func() {
	offset := objIndex * span.elemsize
	exists = span.decPinCounter(offset)
	})
	if !exists {
	// counter is 0, clear multipin bit
	pinState.setMultiPinned(false)
	}
	} else {
	// no multipins recorded. unpin object.
	pinState.setPinned(false)
	}
	} else {
	// unpinning unpinned object, bail out
	throw("runtime.Pinner: object already unpinned")
	}
	}
	unlock(&span.speciallock)
	releasem(mp)
	return true
	}

	type pinState struct {
	bytep *uint8
	byteVal uint8
	mask uint8
	}

	// nosplit, because it's called by isPinned, which is nosplit
	//
	//go:nosplit
	func (v *pinState) isPinned() bool {
	return (v.byteVal & v.mask) != 0
	}

	func (v *pinState) isMultiPinned() bool {
	return (v.byteVal & (v.mask << 1)) != 0
	}

	func (v *pinState) setPinned(val bool) {
	v.set(val, false)
	}

	func (v *pinState) setMultiPinned(val bool) {
	v.set(val, true)
	}

	// set sets the pin bit of the pinState to val. If multipin is true, it
	// sets/unsets the multipin bit instead.
	func (v *pinState) set(val bool, multipin bool) {
	mask := v.mask
	if multipin {
	mask <<= 1
	}
	if val {
	atomic.Or8(v.bytep, mask)
	} else {
	atomic.And8(v.bytep, ^mask)
	}
	}

	// pinnerBits is the same type as gcBits but has different methods.
	type pinnerBits gcBits

	// ofObject returns the pinState of the n'th object.
	// nosplit, because it's called by isPinned, which is nosplit
	//
	//go:nosplit
	func (p *pinnerBits) ofObject(n uintptr) pinState {
	bytep, mask := (gcBits)(p).bitp(n 2)
	byteVal := atomic.Load8(bytep)
	return pinState{bytep, byteVal, mask}
	}

	func (s *mspan) pinnerBitSize() uintptr {
	return divRoundUp(uintptr(s.nelems)*2, 8)
	}

	// newPinnerBits returns a pointer to 8 byte aligned bytes to be used for this
	// span's pinner bits. newPinnerBits is used to mark objects that are pinned.
	// They are copied when the span is swept.
	func (s mspan) newPinnerBits() pinnerBits {
	return (pinnerBits)(newMarkBits(uintptr(s.nelems) 2))
	}

	// nosplit, because it's called by isPinned, which is nosplit
	//
	//go:nosplit
	func (s mspan) getPinnerBits() pinnerBits {
	return (*pinnerBits)(atomic.Loadp(unsafe.Pointer(&s.pinnerBits)))
	}

	func (s mspan) setPinnerBits(p pinnerBits) {
	atomicstorep(unsafe.Pointer(&s.pinnerBits), unsafe.Pointer(p))
	}

	// refreshPinnerBits replaces pinnerBits with a fresh copy in the arenas for the
	// next GC cycle. If it does not contain any pinned objects, pinnerBits of the
	// span is set to nil.
	func (s *mspan) refreshPinnerBits() {
	p := s.getPinnerBits()
	if p == nil {
	return
	}

	hasPins := false
	bytes := alignUp(s.pinnerBitSize(), 8)

	// Iterate over each 8-byte chunk and check for pins. Note that
	// newPinnerBits guarantees that pinnerBits will be 8-byte aligned, so we
	// don't have to worry about edge cases, irrelevant bits will simply be
	// zero.
	for _, x := range unsafe.Slice((*uint64)(unsafe.Pointer(&p.x)), bytes/8) {
	if x != 0 {
	hasPins = true
	break
	}
	}

	if hasPins {
	newPinnerBits := s.newPinnerBits()
	memmove(unsafe.Pointer(&newPinnerBits.x), unsafe.Pointer(&p.x), bytes)
	s.setPinnerBits(newPinnerBits)
	} else {
	s.setPinnerBits(nil)
	}
	}

	// incPinCounter is only called for multiple pins of the same object and records
	// the _additional_ pins.
	func (span *mspan) incPinCounter(offset uintptr) {
	var rec *specialPinCounter
	ref, exists := span.specialFindSplicePoint(offset, _KindSpecialPinCounter)
	if !exists {
	lock(&mheap_.speciallock)
	rec = (*specialPinCounter)(mheap_.specialPinCounterAlloc.alloc())
	unlock(&mheap_.speciallock)
	// splice in record, fill in offset.
	rec.special.offset = uint16(offset)
	rec.special.kind = _KindSpecialPinCounter
	rec.special.next = *ref
	ref = (special)(unsafe.Pointer(rec))
	spanHasSpecials(span)
	} else {
	rec = (specialPinCounter)(unsafe.Pointer(ref))
	}
	rec.counter++
	}

	// decPinCounter decreases the counter. If the counter reaches 0, the counter
	// special is deleted and false is returned. Otherwise true is returned.
	func (span *mspan) decPinCounter(offset uintptr) bool {
	ref, exists := span.specialFindSplicePoint(offset, _KindSpecialPinCounter)
	if !exists {
	throw("runtime.Pinner: decreased non-existing pin counter")
	}
	counter := (specialPinCounter)(unsafe.Pointer(ref))
	counter.counter--
	if counter.counter == 0 {
	*ref = counter.special.next
	if span.specials == nil {
	spanHasNoSpecials(span)
	}
	lock(&mheap_.speciallock)
	mheap_.specialPinCounterAlloc.free(unsafe.Pointer(counter))
	unlock(&mheap_.speciallock)
	return false
	}
	return true
	}

	// only for tests
	func pinnerGetPinCounter(addr unsafe.Pointer) *uintptr {
	_, span, objIndex := findObject(uintptr(addr), 0, 0)
	offset := objIndex * span.elemsize
	t, exists := span.specialFindSplicePoint(offset, _KindSpecialPinCounter)
	if !exists {
	return nil
	}
	counter := (specialPinCounter)(unsafe.Pointer(t))
	return &counter.counter
	}

	// to be able to test that the GC panics when a pinned pointer is leaking, this
	// panic function is a variable, that can be overwritten by a test.
	var pinnerLeakPanic = func() {
	panic(errorString("runtime.Pinner: found leaking pinned pointer; forgot to call Unpin()?"))
	}