src/runtime/select.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.

 package runtime

 // This file contains the implementation of Go select statements.

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

 const (
 	debugSelect = false

 	// scase.kind
 	caseRecv = iota
 	caseSend
 	caseDefault
 )

 // Select statement header.
 // Known to compiler.
 // Changes here must also be made in src/cmd/internal/gc/select.go's selecttype.
 type hselect struct {
 	tcase     uint16   // total count of scase[]
 	ncase     uint16   // currently filled scase[]
 	pollorder *uint16  // case poll order
 	lockorder *uint16  // channel lock order
 	scase     [1]scase // one per case (in order of appearance)
 }

 // Select case descriptor.
 // Known to compiler.
 // Changes here must also be made in src/cmd/internal/gc/select.go's selecttype.
 type scase struct {
 	elem        unsafe.Pointer // data element
 	c           *hchan         // chan
 	pc          uintptr        // return pc
 	kind        uint16
 	so          uint16 // vararg of selected bool
 	receivedp   *bool  // pointer to received bool (recv2)
 	releasetime int64
 }

 var (
 	chansendpc = funcPC(chansend)
 	chanrecvpc = funcPC(chanrecv)
 )

 func selectsize(size uintptr) uintptr {
 	selsize := unsafe.Sizeof(hselect{}) +
 		(size-1)*unsafe.Sizeof(hselect{}.scase[0]) +
 		size*unsafe.Sizeof(*hselect{}.lockorder) +
 		size*unsafe.Sizeof(*hselect{}.pollorder)
 	return round(selsize, sys.Int64Align)
 }

 func newselect(sel *hselect, selsize int64, size int32) {
 	if selsize != int64(selectsize(uintptr(size))) {
 		print("runtime: bad select size ", selsize, ", want ", selectsize(uintptr(size)), "\n")
 		throw("bad select size")
 	}
 	sel.tcase = uint16(size)
 	sel.ncase = 0
 	sel.lockorder = (*uint16)(add(unsafe.Pointer(&sel.scase), uintptr(size)*unsafe.Sizeof(hselect{}.scase[0])))
 	sel.pollorder = (*uint16)(add(unsafe.Pointer(sel.lockorder), uintptr(size)*unsafe.Sizeof(*hselect{}.lockorder)))

 	if debugSelect {
 		print("newselect s=", sel, " size=", size, "\n")
 	}
 }

 //go:nosplit
 func selectsend(sel *hselect, c *hchan, elem unsafe.Pointer) (selected bool) {
 	// nil cases do not compete
 	if c != nil {
 		selectsendImpl(sel, c, getcallerpc(unsafe.Pointer(&sel)), elem, uintptr(unsafe.Pointer(&selected))-uintptr(unsafe.Pointer(&sel)))
 	}
 	return
 }

 // cut in half to give stack a chance to split
 func selectsendImpl(sel *hselect, c *hchan, pc uintptr, elem unsafe.Pointer, so uintptr) {
 	i := sel.ncase
 	if i >= sel.tcase {
 		throw("selectsend: too many cases")
 	}
 	sel.ncase = i + 1
 	cas := (*scase)(add(unsafe.Pointer(&sel.scase), uintptr(i)*unsafe.Sizeof(sel.scase[0])))

 	cas.pc = pc
 	cas.c = c
 	cas.so = uint16(so)
 	cas.kind = caseSend
 	cas.elem = elem

 	if debugSelect {
 		print("selectsend s=", sel, " pc=", hex(cas.pc), " chan=", cas.c, " so=", cas.so, "\n")
 	}
 }

 //go:nosplit
 func selectrecv(sel *hselect, c *hchan, elem unsafe.Pointer) (selected bool) {
 	// nil cases do not compete
 	if c != nil {
 		selectrecvImpl(sel, c, getcallerpc(unsafe.Pointer(&sel)), elem, nil, uintptr(unsafe.Pointer(&selected))-uintptr(unsafe.Pointer(&sel)))
 	}
 	return
 }

 //go:nosplit
 func selectrecv2(sel *hselect, c *hchan, elem unsafe.Pointer, received *bool) (selected bool) {
 	// nil cases do not compete
 	if c != nil {
 		selectrecvImpl(sel, c, getcallerpc(unsafe.Pointer(&sel)), elem, received, uintptr(unsafe.Pointer(&selected))-uintptr(unsafe.Pointer(&sel)))
 	}
 	return
 }

 func selectrecvImpl(sel *hselect, c *hchan, pc uintptr, elem unsafe.Pointer, received *bool, so uintptr) {
 	i := sel.ncase
 	if i >= sel.tcase {
 		throw("selectrecv: too many cases")
 	}
 	sel.ncase = i + 1
 	cas := (*scase)(add(unsafe.Pointer(&sel.scase), uintptr(i)*unsafe.Sizeof(sel.scase[0])))
 	cas.pc = pc
 	cas.c = c
 	cas.so = uint16(so)
 	cas.kind = caseRecv
 	cas.elem = elem
 	cas.receivedp = received

 	if debugSelect {
 		print("selectrecv s=", sel, " pc=", hex(cas.pc), " chan=", cas.c, " so=", cas.so, "\n")
 	}
 }

 //go:nosplit
 func selectdefault(sel *hselect) (selected bool) {
 	selectdefaultImpl(sel, getcallerpc(unsafe.Pointer(&sel)), uintptr(unsafe.Pointer(&selected))-uintptr(unsafe.Pointer(&sel)))
 	return
 }

 func selectdefaultImpl(sel *hselect, callerpc uintptr, so uintptr) {
 	i := sel.ncase
 	if i >= sel.tcase {
 		throw("selectdefault: too many cases")
 	}
 	sel.ncase = i + 1
 	cas := (*scase)(add(unsafe.Pointer(&sel.scase), uintptr(i)*unsafe.Sizeof(sel.scase[0])))
 	cas.pc = callerpc
 	cas.c = nil
 	cas.so = uint16(so)
 	cas.kind = caseDefault

 	if debugSelect {
 		print("selectdefault s=", sel, " pc=", hex(cas.pc), " so=", cas.so, "\n")
 	}
 }

 func sellock(scases []scase, lockorder []uint16) {
 	var c *hchan
 	for _, o := range lockorder {
 		c0 := scases[o].c
 		if c0 != nil && c0 != c {
 			c = c0
 			lock(&c.lock)
 		}
 	}
 }

 func selunlock(scases []scase, lockorder []uint16) {
 	// We must be very careful here to not touch sel after we have unlocked
 	// the last lock, because sel can be freed right after the last unlock.
 	// Consider the following situation.
 	// First M calls runtime·park() in runtime·selectgo() passing the sel.
 	// Once runtime·park() has unlocked the last lock, another M makes
 	// the G that calls select runnable again and schedules it for execution.
 	// When the G runs on another M, it locks all the locks and frees sel.
 	// Now if the first M touches sel, it will access freed memory.
 	n := len(scases)
 	r := 0
 	// skip the default case
 	if n > 0 && scases[lockorder[0]].c == nil {
 		r = 1
 	}
 	for i := n - 1; i >= r; i-- {
 		c := scases[lockorder[i]].c
 		if i > 0 && c == scases[lockorder[i-1]].c {
 			continue // will unlock it on the next iteration
 		}
 		unlock(&c.lock)
 	}
 }

 func selparkcommit(gp *g, _ unsafe.Pointer) bool {
 	// This must not access gp's stack (see gopark). In
 	// particular, it must not access the *hselect. That's okay,
 	// because by the time this is called, gp.waiting has all
 	// channels in lock order.
 	var lastc *hchan
 	for sg := gp.waiting; sg != nil; sg = sg.waitlink {
 		if sg.c != lastc && lastc != nil {
 			// As soon as we unlock the channel, fields in
 			// any sudog with that channel may change,
 			// including c and waitlink. Since multiple
 			// sudogs may have the same channel, we unlock
 			// only after we've passed the last instance
 			// of a channel.
 			unlock(&lastc.lock)
 		}
 		lastc = sg.c
 	}
 	if lastc != nil {
 		unlock(&lastc.lock)
 	}
 	return true
 }

 func block() {
 	gopark(nil, nil, "select (no cases)", traceEvGoStop, 1) // forever
 }

 // selectgo implements the select statement.
 //
 // *sel is on the current goroutine's stack (regardless of any
 // escaping in selectgo).
 //
 // selectgo does not return. Instead, it overwrites its return PC and
 // returns directly to the triggered select case. Because of this, it
 // cannot appear at the top of a split stack.
 //
 //go:nosplit
 func selectgo(sel *hselect) {
 	pc, offset := selectgoImpl(sel)
 	*(*bool)(add(unsafe.Pointer(&sel), uintptr(offset))) = true
 	setcallerpc(unsafe.Pointer(&sel), pc)
 }

 // selectgoImpl returns scase.pc and scase.so for the select
 // case which fired.
 func selectgoImpl(sel *hselect) (uintptr, uint16) {
 	if debugSelect {
 		print("select: sel=", sel, "\n")
 	}

 	scaseslice := slice{unsafe.Pointer(&sel.scase), int(sel.ncase), int(sel.ncase)}
 	scases := *(*[]scase)(unsafe.Pointer(&scaseslice))

 	var t0 int64
 	if blockprofilerate > 0 {
 		t0 = cputicks()
 		for i := 0; i < int(sel.ncase); i++ {
 			scases[i].releasetime = -1
 		}
 	}

 	// The compiler rewrites selects that statically have
 	// only 0 or 1 cases plus default into simpler constructs.
 	// The only way we can end up with such small sel.ncase
 	// values here is for a larger select in which most channels
 	// have been nilled out. The general code handles those
 	// cases correctly, and they are rare enough not to bother
 	// optimizing (and needing to test).

 	// generate permuted order
 	pollslice := slice{unsafe.Pointer(sel.pollorder), int(sel.ncase), int(sel.ncase)}
 	pollorder := *(*[]uint16)(unsafe.Pointer(&pollslice))
 	for i := 1; i < int(sel.ncase); i++ {
 		j := int(fastrand()) % (i + 1)
 		pollorder[i] = pollorder[j]
 		pollorder[j] = uint16(i)
 	}

 	// sort the cases by Hchan address to get the locking order.
 	// simple heap sort, to guarantee n log n time and constant stack footprint.
 	lockslice := slice{unsafe.Pointer(sel.lockorder), int(sel.ncase), int(sel.ncase)}
 	lockorder := *(*[]uint16)(unsafe.Pointer(&lockslice))
 	for i := 0; i < int(sel.ncase); i++ {
 		j := i
 		// Start with the pollorder to permute cases on the same channel.
 		c := scases[pollorder[i]].c
 		for j > 0 && scases[lockorder[(j-1)/2]].c.sortkey() < c.sortkey() {
 			k := (j - 1) / 2
 			lockorder[j] = lockorder[k]
 			j = k
 		}
 		lockorder[j] = pollorder[i]
 	}
 	for i := int(sel.ncase) - 1; i >= 0; i-- {
 		o := lockorder[i]
 		c := scases[o].c
 		lockorder[i] = lockorder[0]
 		j := 0
 		for {
 			k := j*2 + 1
 			if k >= i {
 				break
 			}
 			if k+1 < i && scases[lockorder[k]].c.sortkey() < scases[lockorder[k+1]].c.sortkey() {
 				k++
 			}
 			if c.sortkey() < scases[lockorder[k]].c.sortkey() {
 				lockorder[j] = lockorder[k]
 				j = k
 				continue
 			}
 			break
 		}
 		lockorder[j] = o
 	}
 	/*
 		for i := 0; i+1 < int(sel.ncase); i++ {
 			if scases[lockorder[i]].c.sortkey() > scases[lockorder[i+1]].c.sortkey() {
 				print("i=", i, " x=", lockorder[i], " y=", lockorder[i+1], "\n")
 				throw("select: broken sort")
 			}
 		}
 	*/

 	// lock all the channels involved in the select
 	sellock(scases, lockorder)

 	var (
 		gp     *g
 		done   uint32
 		sg     *sudog
 		c      *hchan
 		k      *scase
 		sglist *sudog
 		sgnext *sudog
 		qp     unsafe.Pointer
 		nextp  **sudog
 	)

 loop:
 	// pass 1 - look for something already waiting
 	var dfl *scase
 	var cas *scase
 	for i := 0; i < int(sel.ncase); i++ {
 		cas = &scases[pollorder[i]]
 		c = cas.c

 		switch cas.kind {
 		case caseRecv:
 			sg = c.sendq.dequeue()
 			if sg != nil {
 				goto recv
 			}
 			if c.qcount > 0 {
 				goto bufrecv
 			}
 			if c.closed != 0 {
 				goto rclose
 			}

 		case caseSend:
 			if raceenabled {
 				racereadpc(unsafe.Pointer(c), cas.pc, chansendpc)
 			}
 			if c.closed != 0 {
 				goto sclose
 			}
 			sg = c.recvq.dequeue()
 			if sg != nil {
 				goto send
 			}
 			if c.qcount < c.dataqsiz {
 				goto bufsend
 			}

 		case caseDefault:
 			dfl = cas
 		}
 	}

 	if dfl != nil {
 		selunlock(scases, lockorder)
 		cas = dfl
 		goto retc
 	}

 	// pass 2 - enqueue on all chans
 	gp = getg()
 	done = 0
 	if gp.waiting != nil {
 		throw("gp.waiting != nil")
 	}
 	nextp = &gp.waiting
 	for _, casei := range lockorder {
 		cas = &scases[casei]
 		c = cas.c
 		sg := acquireSudog()
 		sg.g = gp
 		// Note: selectdone is adjusted for stack copies in stack1.go:adjustsudogs
 		sg.selectdone = (*uint32)(noescape(unsafe.Pointer(&done)))
 		// No stack splits between assigning elem and enqueuing
 		// sg on gp.waiting where copystack can find it.
 		sg.elem = cas.elem
 		sg.releasetime = 0
 		if t0 != 0 {
 			sg.releasetime = -1
 		}
 		sg.c = c
 		// Construct waiting list in lock order.
 		*nextp = sg
 		nextp = &sg.waitlink

 		switch cas.kind {
 		case caseRecv:
 			c.recvq.enqueue(sg)

 		case caseSend:
 			c.sendq.enqueue(sg)
 		}
 	}

 	// wait for someone to wake us up
 	gp.param = nil
 	gopark(selparkcommit, nil, "select", traceEvGoBlockSelect, 2)

 	// While we were asleep, some goroutine came along and completed
 	// one of the cases in the select and woke us up (called ready).
 	// As part of that process, the goroutine did a cas on done above
 	// (aka *sg.selectdone for all queued sg) to win the right to
 	// complete the select. Now done = 1.
 	//
 	// If we copy (grow) our own stack, we will update the
 	// selectdone pointers inside the gp.waiting sudog list to point
 	// at the new stack. Another goroutine attempting to
 	// complete one of our (still linked in) select cases might
 	// see the new selectdone pointer (pointing at the new stack)
 	// before the new stack has real data; if the new stack has done = 0
 	// (before the old values are copied over), the goroutine might
 	// do a cas via sg.selectdone and incorrectly believe that it has
 	// won the right to complete the select, executing a second
 	// communication and attempting to wake us (call ready) again.
 	//
 	// Then things break.
 	//
 	// The best break is that the goroutine doing ready sees the
 	// _Gcopystack status and throws, as in #17007.
 	// A worse break would be for us to continue on, start running real code,
 	// block in a semaphore acquisition (sema.go), and have the other
 	// goroutine wake us up without having really acquired the semaphore.
 	// That would result in the goroutine spuriously running and then
 	// queue up another spurious wakeup when the semaphore really is ready.
 	// In general the situation can cascade until something notices the
 	// problem and causes a crash.
 	//
 	// A stack shrink does not have this problem, because it locks
 	// all the channels that are involved first, blocking out the
 	// possibility of a cas on selectdone.
 	//
 	// A stack growth before gopark above does not have this
 	// problem, because we hold those channel locks (released by
 	// selparkcommit).
 	//
 	// A stack growth after sellock below does not have this
 	// problem, because again we hold those channel locks.
 	//
 	// The only problem is a stack growth during sellock.
 	// To keep that from happening, run sellock on the system stack.
 	//
 	// It might be that we could avoid this if copystack copied the
 	// stack before calling adjustsudogs. In that case,
 	// syncadjustsudogs would need to recopy the tiny part that
 	// it copies today, resulting in a little bit of extra copying.
 	//
 	// An even better fix, not for the week before a release candidate,
 	// would be to put space in every sudog and make selectdone
 	// point at (say) the space in the first sudog.

 	systemstack(func() {
 		sellock(scases, lockorder)
 	})

 	sg = (*sudog)(gp.param)
 	gp.param = nil

 	// pass 3 - dequeue from unsuccessful chans
 	// otherwise they stack up on quiet channels
 	// record the successful case, if any.
 	// We singly-linked up the SudoGs in lock order.
 	cas = nil
 	sglist = gp.waiting
 	// Clear all elem before unlinking from gp.waiting.
 	for sg1 := gp.waiting; sg1 != nil; sg1 = sg1.waitlink {
 		sg1.selectdone = nil
 		sg1.elem = nil
 		sg1.c = nil
 	}
 	gp.waiting = nil

 	for _, casei := range lockorder {
 		k = &scases[casei]
 		if sglist.releasetime > 0 {
 			k.releasetime = sglist.releasetime
 		}
 		if sg == sglist {
 			// sg has already been dequeued by the G that woke us up.
 			cas = k
 		} else {
 			c = k.c
 			if k.kind == caseSend {
 				c.sendq.dequeueSudoG(sglist)
 			} else {
 				c.recvq.dequeueSudoG(sglist)
 			}
 		}
 		sgnext = sglist.waitlink
 		sglist.waitlink = nil
 		releaseSudog(sglist)
 		sglist = sgnext
 	}

 	if cas == nil {
 		// We can wake up with gp.param == nil (so cas == nil)
 		// when a channel involved in the select has been closed.
 		// It is easiest to loop and re-run the operation;
 		// we'll see that it's now closed.
 		// Maybe some day we can signal the close explicitly,
 		// but we'd have to distinguish close-on-reader from close-on-writer.
 		// It's easiest not to duplicate the code and just recheck above.
 		// We know that something closed, and things never un-close,
 		// so we won't block again.
 		goto loop
 	}

 	c = cas.c

 	if debugSelect {
 		print("wait-return: sel=", sel, " c=", c, " cas=", cas, " kind=", cas.kind, "\n")
 	}

 	if cas.kind == caseRecv {
 		if cas.receivedp != nil {
 			*cas.receivedp = true
 		}
 	}

 	if raceenabled {
 		if cas.kind == caseRecv && cas.elem != nil {
 			raceWriteObjectPC(c.elemtype, cas.elem, cas.pc, chanrecvpc)
 		} else if cas.kind == caseSend {
 			raceReadObjectPC(c.elemtype, cas.elem, cas.pc, chansendpc)
 		}
 	}
 	if msanenabled {
 		if cas.kind == caseRecv && cas.elem != nil {
 			msanwrite(cas.elem, c.elemtype.size)
 		} else if cas.kind == caseSend {
 			msanread(cas.elem, c.elemtype.size)
 		}
 	}

 	selunlock(scases, lockorder)
 	goto retc

 bufrecv:
 	// can receive from buffer
 	if raceenabled {
 		if cas.elem != nil {
 			raceWriteObjectPC(c.elemtype, cas.elem, cas.pc, chanrecvpc)
 		}
 		raceacquire(chanbuf(c, c.recvx))
 		racerelease(chanbuf(c, c.recvx))
 	}
 	if msanenabled && cas.elem != nil {
 		msanwrite(cas.elem, c.elemtype.size)
 	}
 	if cas.receivedp != nil {
 		*cas.receivedp = true
 	}
 	qp = chanbuf(c, c.recvx)
 	if cas.elem != nil {
 		typedmemmove(c.elemtype, cas.elem, qp)
 	}
 	typedmemclr(c.elemtype, qp)
 	c.recvx++
 	if c.recvx == c.dataqsiz {
 		c.recvx = 0
 	}
 	c.qcount--
 	selunlock(scases, lockorder)
 	goto retc

 bufsend:
 	// can send to buffer
 	if raceenabled {
 		raceacquire(chanbuf(c, c.sendx))
 		racerelease(chanbuf(c, c.sendx))
 		raceReadObjectPC(c.elemtype, cas.elem, cas.pc, chansendpc)
 	}
 	if msanenabled {
 		msanread(cas.elem, c.elemtype.size)
 	}
 	typedmemmove(c.elemtype, chanbuf(c, c.sendx), cas.elem)
 	c.sendx++
 	if c.sendx == c.dataqsiz {
 		c.sendx = 0
 	}
 	c.qcount++
 	selunlock(scases, lockorder)
 	goto retc

 recv:
 	// can receive from sleeping sender (sg)
 	recv(c, sg, cas.elem, func() { selunlock(scases, lockorder) })
 	if debugSelect {
 		print("syncrecv: sel=", sel, " c=", c, "\n")
 	}
 	if cas.receivedp != nil {
 		*cas.receivedp = true
 	}
 	goto retc

 rclose:
 	// read at end of closed channel
 	selunlock(scases, lockorder)
 	if cas.receivedp != nil {
 		*cas.receivedp = false
 	}
 	if cas.elem != nil {
 		typedmemclr(c.elemtype, cas.elem)
 	}
 	if raceenabled {
 		raceacquire(unsafe.Pointer(c))
 	}
 	goto retc

 send:
 	// can send to a sleeping receiver (sg)
 	if raceenabled {
 		raceReadObjectPC(c.elemtype, cas.elem, cas.pc, chansendpc)
 	}
 	if msanenabled {
 		msanread(cas.elem, c.elemtype.size)
 	}
 	send(c, sg, cas.elem, func() { selunlock(scases, lockorder) })
 	if debugSelect {
 		print("syncsend: sel=", sel, " c=", c, "\n")
 	}
 	goto retc

 retc:
 	if cas.releasetime > 0 {
 		blockevent(cas.releasetime-t0, 2)
 	}
 	return cas.pc, cas.so

 sclose:
 	// send on closed channel
 	selunlock(scases, lockorder)
 	panic(plainError("send on closed channel"))
 }

 func (c *hchan) sortkey() uintptr {
 	// TODO(khr): if we have a moving garbage collector, we'll need to
 	// change this function.
 	return uintptr(unsafe.Pointer(c))
 }

 // A runtimeSelect is a single case passed to rselect.
 // This must match ../reflect/value.go:/runtimeSelect
 type runtimeSelect struct {
 	dir selectDir
 	typ unsafe.Pointer // channel type (not used here)
 	ch  *hchan         // channel
 	val unsafe.Pointer // ptr to data (SendDir) or ptr to receive buffer (RecvDir)
 }

 // These values must match ../reflect/value.go:/SelectDir.
 type selectDir int

 const (
 	_             selectDir = iota
 	selectSend              // case Chan <- Send
 	selectRecv              // case <-Chan:
 	selectDefault           // default
 )

 //go:linkname reflect_rselect reflect.rselect
 func reflect_rselect(cases []runtimeSelect) (chosen int, recvOK bool) {
 	// flagNoScan is safe here, because all objects are also referenced from cases.
 	size := selectsize(uintptr(len(cases)))
 	sel := (*hselect)(mallocgc(size, nil, true))
 	newselect(sel, int64(size), int32(len(cases)))
 	r := new(bool)
 	for i := range cases {
 		rc := &cases[i]
 		switch rc.dir {
 		case selectDefault:
 			selectdefaultImpl(sel, uintptr(i), 0)
 		case selectSend:
 			if rc.ch == nil {
 				break
 			}
 			selectsendImpl(sel, rc.ch, uintptr(i), rc.val, 0)
 		case selectRecv:
 			if rc.ch == nil {
 				break
 			}
 			selectrecvImpl(sel, rc.ch, uintptr(i), rc.val, r, 0)
 		}
 	}

 	pc, _ := selectgoImpl(sel)
 	chosen = int(pc)
 	recvOK = *r
 	return
 }

 func (q *waitq) dequeueSudoG(sgp *sudog) {
 	x := sgp.prev
 	y := sgp.next
 	if x != nil {
 		if y != nil {
 			// middle of queue
 			x.next = y
 			y.prev = x
 			sgp.next = nil
 			sgp.prev = nil
 			return
 		}
 		// end of queue
 		x.next = nil
 		q.last = x
 		sgp.prev = nil
 		return
 	}
 	if y != nil {
 		// start of queue
 		y.prev = nil
 		q.first = y
 		sgp.next = nil
 		return
 	}

 	// x==y==nil. Either sgp is the only element in the queue,
 	// or it has already been removed. Use q.first to disambiguate.
 	if q.first == sgp {
 		q.first = nil
 		q.last = nil
 	}
 }
	// 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.

	package runtime

	// This file contains the implementation of Go select statements.

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

	const (
	debugSelect = false

	// scase.kind
	caseRecv = iota
	caseSend
	caseDefault
	)

	// Select statement header.
	// Known to compiler.
	// Changes here must also be made in src/cmd/internal/gc/select.go's selecttype.
	type hselect struct {
	tcase uint16 // total count of scase[]
	ncase uint16 // currently filled scase[]
	pollorder *uint16 // case poll order
	lockorder *uint16 // channel lock order
	scase [1]scase // one per case (in order of appearance)
	}

	// Select case descriptor.
	// Known to compiler.
	// Changes here must also be made in src/cmd/internal/gc/select.go's selecttype.
	type scase struct {
	elem unsafe.Pointer // data element
	c *hchan // chan
	pc uintptr // return pc
	kind uint16
	so uint16 // vararg of selected bool
	receivedp *bool // pointer to received bool (recv2)
	releasetime int64
	}

	var (
	chansendpc = funcPC(chansend)
	chanrecvpc = funcPC(chanrecv)
	)

	func selectsize(size uintptr) uintptr {
	selsize := unsafe.Sizeof(hselect{}) +
	(size-1)*unsafe.Sizeof(hselect{}.scase[0]) +
	sizeunsafe.Sizeof(hselect{}.lockorder) +
	sizeunsafe.Sizeof(hselect{}.pollorder)
	return round(selsize, sys.Int64Align)
	}

	func newselect(sel *hselect, selsize int64, size int32) {
	if selsize != int64(selectsize(uintptr(size))) {
	print("runtime: bad select size ", selsize, ", want ", selectsize(uintptr(size)), "\n")
	throw("bad select size")
	}
	sel.tcase = uint16(size)
	sel.ncase = 0
	sel.lockorder = (uint16)(add(unsafe.Pointer(&sel.scase), uintptr(size)unsafe.Sizeof(hselect{}.scase[0])))
	sel.pollorder = (uint16)(add(unsafe.Pointer(sel.lockorder), uintptr(size)unsafe.Sizeof(*hselect{}.lockorder)))

	if debugSelect {
	print("newselect s=", sel, " size=", size, "\n")
	}
	}

	//go:nosplit
	func selectsend(sel hselect, c hchan, elem unsafe.Pointer) (selected bool) {
	// nil cases do not compete
	if c != nil {
	selectsendImpl(sel, c, getcallerpc(unsafe.Pointer(&sel)), elem, uintptr(unsafe.Pointer(&selected))-uintptr(unsafe.Pointer(&sel)))
	}
	return
	}

	// cut in half to give stack a chance to split
	func selectsendImpl(sel hselect, c hchan, pc uintptr, elem unsafe.Pointer, so uintptr) {
	i := sel.ncase
	if i >= sel.tcase {
	throw("selectsend: too many cases")
	}
	sel.ncase = i + 1
	cas := (scase)(add(unsafe.Pointer(&sel.scase), uintptr(i)unsafe.Sizeof(sel.scase[0])))

	cas.pc = pc
	cas.c = c
	cas.so = uint16(so)
	cas.kind = caseSend
	cas.elem = elem

	if debugSelect {
	print("selectsend s=", sel, " pc=", hex(cas.pc), " chan=", cas.c, " so=", cas.so, "\n")
	}
	}

	//go:nosplit
	func selectrecv(sel hselect, c hchan, elem unsafe.Pointer) (selected bool) {
	// nil cases do not compete
	if c != nil {
	selectrecvImpl(sel, c, getcallerpc(unsafe.Pointer(&sel)), elem, nil, uintptr(unsafe.Pointer(&selected))-uintptr(unsafe.Pointer(&sel)))
	}
	return
	}

	//go:nosplit
	func selectrecv2(sel hselect, c hchan, elem unsafe.Pointer, received *bool) (selected bool) {
	// nil cases do not compete
	if c != nil {
	selectrecvImpl(sel, c, getcallerpc(unsafe.Pointer(&sel)), elem, received, uintptr(unsafe.Pointer(&selected))-uintptr(unsafe.Pointer(&sel)))
	}
	return
	}

	func selectrecvImpl(sel hselect, c hchan, pc uintptr, elem unsafe.Pointer, received *bool, so uintptr) {
	i := sel.ncase
	if i >= sel.tcase {
	throw("selectrecv: too many cases")
	}
	sel.ncase = i + 1
	cas := (scase)(add(unsafe.Pointer(&sel.scase), uintptr(i)unsafe.Sizeof(sel.scase[0])))
	cas.pc = pc
	cas.c = c
	cas.so = uint16(so)
	cas.kind = caseRecv
	cas.elem = elem
	cas.receivedp = received

	if debugSelect {
	print("selectrecv s=", sel, " pc=", hex(cas.pc), " chan=", cas.c, " so=", cas.so, "\n")
	}
	}

	//go:nosplit
	func selectdefault(sel *hselect) (selected bool) {
	selectdefaultImpl(sel, getcallerpc(unsafe.Pointer(&sel)), uintptr(unsafe.Pointer(&selected))-uintptr(unsafe.Pointer(&sel)))
	return
	}

	func selectdefaultImpl(sel *hselect, callerpc uintptr, so uintptr) {
	i := sel.ncase
	if i >= sel.tcase {
	throw("selectdefault: too many cases")
	}
	sel.ncase = i + 1
	cas := (scase)(add(unsafe.Pointer(&sel.scase), uintptr(i)unsafe.Sizeof(sel.scase[0])))
	cas.pc = callerpc
	cas.c = nil
	cas.so = uint16(so)
	cas.kind = caseDefault

	if debugSelect {
	print("selectdefault s=", sel, " pc=", hex(cas.pc), " so=", cas.so, "\n")
	}
	}

	func sellock(scases []scase, lockorder []uint16) {
	var c *hchan
	for _, o := range lockorder {
	c0 := scases[o].c
	if c0 != nil && c0 != c {
	c = c0
	lock(&c.lock)
	}
	}
	}

	func selunlock(scases []scase, lockorder []uint16) {
	// We must be very careful here to not touch sel after we have unlocked
	// the last lock, because sel can be freed right after the last unlock.
	// Consider the following situation.
	// First M calls runtime·park() in runtime·selectgo() passing the sel.
	// Once runtime·park() has unlocked the last lock, another M makes
	// the G that calls select runnable again and schedules it for execution.
	// When the G runs on another M, it locks all the locks and frees sel.
	// Now if the first M touches sel, it will access freed memory.
	n := len(scases)
	r := 0
	// skip the default case
	if n > 0 && scases[lockorder[0]].c == nil {
	r = 1
	}
	for i := n - 1; i >= r; i-- {
	c := scases[lockorder[i]].c
	if i > 0 && c == scases[lockorder[i-1]].c {
	continue // will unlock it on the next iteration
	}
	unlock(&c.lock)
	}
	}

	func selparkcommit(gp *g, _ unsafe.Pointer) bool {
	// This must not access gp's stack (see gopark). In
	// particular, it must not access the *hselect. That's okay,
	// because by the time this is called, gp.waiting has all
	// channels in lock order.
	var lastc *hchan
	for sg := gp.waiting; sg != nil; sg = sg.waitlink {
	if sg.c != lastc && lastc != nil {
	// As soon as we unlock the channel, fields in
	// any sudog with that channel may change,
	// including c and waitlink. Since multiple
	// sudogs may have the same channel, we unlock
	// only after we've passed the last instance
	// of a channel.
	unlock(&lastc.lock)
	}
	lastc = sg.c
	}
	if lastc != nil {
	unlock(&lastc.lock)
	}
	return true
	}

	func block() {
	gopark(nil, nil, "select (no cases)", traceEvGoStop, 1) // forever
	}

	// selectgo implements the select statement.
	//
	// *sel is on the current goroutine's stack (regardless of any
	// escaping in selectgo).
	//
	// selectgo does not return. Instead, it overwrites its return PC and
	// returns directly to the triggered select case. Because of this, it
	// cannot appear at the top of a split stack.
	//
	//go:nosplit
	func selectgo(sel *hselect) {
	pc, offset := selectgoImpl(sel)
	(bool)(add(unsafe.Pointer(&sel), uintptr(offset))) = true
	setcallerpc(unsafe.Pointer(&sel), pc)
	}

	// selectgoImpl returns scase.pc and scase.so for the select
	// case which fired.
	func selectgoImpl(sel *hselect) (uintptr, uint16) {
	if debugSelect {
	print("select: sel=", sel, "\n")
	}

	scaseslice := slice{unsafe.Pointer(&sel.scase), int(sel.ncase), int(sel.ncase)}
	scases := ([]scase)(unsafe.Pointer(&scaseslice))

	var t0 int64
	if blockprofilerate > 0 {
	t0 = cputicks()
	for i := 0; i < int(sel.ncase); i++ {
	scases[i].releasetime = -1
	}
	}

	// The compiler rewrites selects that statically have
	// only 0 or 1 cases plus default into simpler constructs.
	// The only way we can end up with such small sel.ncase
	// values here is for a larger select in which most channels
	// have been nilled out. The general code handles those
	// cases correctly, and they are rare enough not to bother
	// optimizing (and needing to test).

	// generate permuted order
	pollslice := slice{unsafe.Pointer(sel.pollorder), int(sel.ncase), int(sel.ncase)}
	pollorder := ([]uint16)(unsafe.Pointer(&pollslice))
	for i := 1; i < int(sel.ncase); i++ {
	j := int(fastrand()) % (i + 1)
	pollorder[i] = pollorder[j]
	pollorder[j] = uint16(i)
	}

	// sort the cases by Hchan address to get the locking order.
	// simple heap sort, to guarantee n log n time and constant stack footprint.
	lockslice := slice{unsafe.Pointer(sel.lockorder), int(sel.ncase), int(sel.ncase)}
	lockorder := ([]uint16)(unsafe.Pointer(&lockslice))
	for i := 0; i < int(sel.ncase); i++ {
	j := i
	// Start with the pollorder to permute cases on the same channel.
	c := scases[pollorder[i]].c
	for j > 0 && scases[lockorder[(j-1)/2]].c.sortkey() < c.sortkey() {
	k := (j - 1) / 2
	lockorder[j] = lockorder[k]
	j = k
	}
	lockorder[j] = pollorder[i]
	}
	for i := int(sel.ncase) - 1; i >= 0; i-- {
	o := lockorder[i]
	c := scases[o].c
	lockorder[i] = lockorder[0]
	j := 0
	for {
	k := j*2 + 1
	if k >= i {
	break
	}
	if k+1 < i && scases[lockorder[k]].c.sortkey() < scases[lockorder[k+1]].c.sortkey() {
	k++
	}
	if c.sortkey() < scases[lockorder[k]].c.sortkey() {
	lockorder[j] = lockorder[k]
	j = k
	continue
	}
	break
	}
	lockorder[j] = o
	}
	/*
	for i := 0; i+1 < int(sel.ncase); i++ {
	if scases[lockorder[i]].c.sortkey() > scases[lockorder[i+1]].c.sortkey() {
	print("i=", i, " x=", lockorder[i], " y=", lockorder[i+1], "\n")
	throw("select: broken sort")
	}
	}
	*/

	// lock all the channels involved in the select
	sellock(scases, lockorder)

	var (
	gp *g
	done uint32
	sg *sudog
	c *hchan
	k *scase
	sglist *sudog
	sgnext *sudog
	qp unsafe.Pointer
	nextp **sudog
	)

	loop:
	// pass 1 - look for something already waiting
	var dfl *scase
	var cas *scase
	for i := 0; i < int(sel.ncase); i++ {
	cas = &scases[pollorder[i]]
	c = cas.c

	switch cas.kind {
	case caseRecv:
	sg = c.sendq.dequeue()
	if sg != nil {
	goto recv
	}
	if c.qcount > 0 {
	goto bufrecv
	}
	if c.closed != 0 {
	goto rclose
	}

	case caseSend:
	if raceenabled {
	racereadpc(unsafe.Pointer(c), cas.pc, chansendpc)
	}
	if c.closed != 0 {
	goto sclose
	}
	sg = c.recvq.dequeue()
	if sg != nil {
	goto send
	}
	if c.qcount < c.dataqsiz {
	goto bufsend
	}

	case caseDefault:
	dfl = cas
	}
	}

	if dfl != nil {
	selunlock(scases, lockorder)
	cas = dfl
	goto retc
	}

	// pass 2 - enqueue on all chans
	gp = getg()
	done = 0
	if gp.waiting != nil {
	throw("gp.waiting != nil")
	}
	nextp = &gp.waiting
	for _, casei := range lockorder {
	cas = &scases[casei]
	c = cas.c
	sg := acquireSudog()
	sg.g = gp
	// Note: selectdone is adjusted for stack copies in stack1.go:adjustsudogs
	sg.selectdone = (*uint32)(noescape(unsafe.Pointer(&done)))
	// No stack splits between assigning elem and enqueuing
	// sg on gp.waiting where copystack can find it.
	sg.elem = cas.elem
	sg.releasetime = 0
	if t0 != 0 {
	sg.releasetime = -1
	}
	sg.c = c
	// Construct waiting list in lock order.
	*nextp = sg
	nextp = &sg.waitlink

	switch cas.kind {
	case caseRecv:
	c.recvq.enqueue(sg)

	case caseSend:
	c.sendq.enqueue(sg)
	}
	}

	// wait for someone to wake us up
	gp.param = nil
	gopark(selparkcommit, nil, "select", traceEvGoBlockSelect, 2)

	// While we were asleep, some goroutine came along and completed
	// one of the cases in the select and woke us up (called ready).
	// As part of that process, the goroutine did a cas on done above
	// (aka *sg.selectdone for all queued sg) to win the right to
	// complete the select. Now done = 1.
	//
	// If we copy (grow) our own stack, we will update the
	// selectdone pointers inside the gp.waiting sudog list to point
	// at the new stack. Another goroutine attempting to
	// complete one of our (still linked in) select cases might
	// see the new selectdone pointer (pointing at the new stack)
	// before the new stack has real data; if the new stack has done = 0
	// (before the old values are copied over), the goroutine might
	// do a cas via sg.selectdone and incorrectly believe that it has
	// won the right to complete the select, executing a second
	// communication and attempting to wake us (call ready) again.
	//
	// Then things break.
	//
	// The best break is that the goroutine doing ready sees the
	// _Gcopystack status and throws, as in #17007.
	// A worse break would be for us to continue on, start running real code,
	// block in a semaphore acquisition (sema.go), and have the other
	// goroutine wake us up without having really acquired the semaphore.
	// That would result in the goroutine spuriously running and then
	// queue up another spurious wakeup when the semaphore really is ready.
	// In general the situation can cascade until something notices the
	// problem and causes a crash.
	//
	// A stack shrink does not have this problem, because it locks
	// all the channels that are involved first, blocking out the
	// possibility of a cas on selectdone.
	//
	// A stack growth before gopark above does not have this
	// problem, because we hold those channel locks (released by
	// selparkcommit).
	//
	// A stack growth after sellock below does not have this
	// problem, because again we hold those channel locks.
	//
	// The only problem is a stack growth during sellock.
	// To keep that from happening, run sellock on the system stack.
	//
	// It might be that we could avoid this if copystack copied the
	// stack before calling adjustsudogs. In that case,
	// syncadjustsudogs would need to recopy the tiny part that
	// it copies today, resulting in a little bit of extra copying.
	//
	// An even better fix, not for the week before a release candidate,
	// would be to put space in every sudog and make selectdone
	// point at (say) the space in the first sudog.

	systemstack(func() {
	sellock(scases, lockorder)
	})

	sg = (*sudog)(gp.param)
	gp.param = nil

	// pass 3 - dequeue from unsuccessful chans
	// otherwise they stack up on quiet channels
	// record the successful case, if any.
	// We singly-linked up the SudoGs in lock order.
	cas = nil
	sglist = gp.waiting
	// Clear all elem before unlinking from gp.waiting.
	for sg1 := gp.waiting; sg1 != nil; sg1 = sg1.waitlink {
	sg1.selectdone = nil
	sg1.elem = nil
	sg1.c = nil
	}
	gp.waiting = nil

	for _, casei := range lockorder {
	k = &scases[casei]
	if sglist.releasetime > 0 {
	k.releasetime = sglist.releasetime
	}
	if sg == sglist {
	// sg has already been dequeued by the G that woke us up.
	cas = k
	} else {
	c = k.c
	if k.kind == caseSend {
	c.sendq.dequeueSudoG(sglist)
	} else {
	c.recvq.dequeueSudoG(sglist)
	}
	}
	sgnext = sglist.waitlink
	sglist.waitlink = nil
	releaseSudog(sglist)
	sglist = sgnext
	}

	if cas == nil {
	// We can wake up with gp.param == nil (so cas == nil)
	// when a channel involved in the select has been closed.
	// It is easiest to loop and re-run the operation;
	// we'll see that it's now closed.
	// Maybe some day we can signal the close explicitly,
	// but we'd have to distinguish close-on-reader from close-on-writer.
	// It's easiest not to duplicate the code and just recheck above.
	// We know that something closed, and things never un-close,
	// so we won't block again.
	goto loop
	}

	c = cas.c

	if debugSelect {
	print("wait-return: sel=", sel, " c=", c, " cas=", cas, " kind=", cas.kind, "\n")
	}

	if cas.kind == caseRecv {
	if cas.receivedp != nil {
	*cas.receivedp = true
	}
	}

	if raceenabled {
	if cas.kind == caseRecv && cas.elem != nil {
	raceWriteObjectPC(c.elemtype, cas.elem, cas.pc, chanrecvpc)
	} else if cas.kind == caseSend {
	raceReadObjectPC(c.elemtype, cas.elem, cas.pc, chansendpc)
	}
	}
	if msanenabled {
	if cas.kind == caseRecv && cas.elem != nil {
	msanwrite(cas.elem, c.elemtype.size)
	} else if cas.kind == caseSend {
	msanread(cas.elem, c.elemtype.size)
	}
	}

	selunlock(scases, lockorder)
	goto retc

	bufrecv:
	// can receive from buffer
	if raceenabled {
	if cas.elem != nil {
	raceWriteObjectPC(c.elemtype, cas.elem, cas.pc, chanrecvpc)
	}
	raceacquire(chanbuf(c, c.recvx))
	racerelease(chanbuf(c, c.recvx))
	}
	if msanenabled && cas.elem != nil {
	msanwrite(cas.elem, c.elemtype.size)
	}
	if cas.receivedp != nil {
	*cas.receivedp = true
	}
	qp = chanbuf(c, c.recvx)
	if cas.elem != nil {
	typedmemmove(c.elemtype, cas.elem, qp)
	}
	typedmemclr(c.elemtype, qp)
	c.recvx++
	if c.recvx == c.dataqsiz {
	c.recvx = 0
	}
	c.qcount--
	selunlock(scases, lockorder)
	goto retc

	bufsend:
	// can send to buffer
	if raceenabled {
	raceacquire(chanbuf(c, c.sendx))
	racerelease(chanbuf(c, c.sendx))
	raceReadObjectPC(c.elemtype, cas.elem, cas.pc, chansendpc)
	}
	if msanenabled {
	msanread(cas.elem, c.elemtype.size)
	}
	typedmemmove(c.elemtype, chanbuf(c, c.sendx), cas.elem)
	c.sendx++
	if c.sendx == c.dataqsiz {
	c.sendx = 0
	}
	c.qcount++
	selunlock(scases, lockorder)
	goto retc

	recv:
	// can receive from sleeping sender (sg)
	recv(c, sg, cas.elem, func() { selunlock(scases, lockorder) })
	if debugSelect {
	print("syncrecv: sel=", sel, " c=", c, "\n")
	}
	if cas.receivedp != nil {
	*cas.receivedp = true
	}
	goto retc

	rclose:
	// read at end of closed channel
	selunlock(scases, lockorder)
	if cas.receivedp != nil {
	*cas.receivedp = false
	}
	if cas.elem != nil {
	typedmemclr(c.elemtype, cas.elem)
	}
	if raceenabled {
	raceacquire(unsafe.Pointer(c))
	}
	goto retc

	send:
	// can send to a sleeping receiver (sg)
	if raceenabled {
	raceReadObjectPC(c.elemtype, cas.elem, cas.pc, chansendpc)
	}
	if msanenabled {
	msanread(cas.elem, c.elemtype.size)
	}
	send(c, sg, cas.elem, func() { selunlock(scases, lockorder) })
	if debugSelect {
	print("syncsend: sel=", sel, " c=", c, "\n")
	}
	goto retc

	retc:
	if cas.releasetime > 0 {
	blockevent(cas.releasetime-t0, 2)
	}
	return cas.pc, cas.so

	sclose:
	// send on closed channel
	selunlock(scases, lockorder)
	panic(plainError("send on closed channel"))
	}

	func (c *hchan) sortkey() uintptr {
	// TODO(khr): if we have a moving garbage collector, we'll need to
	// change this function.
	return uintptr(unsafe.Pointer(c))
	}

	// A runtimeSelect is a single case passed to rselect.
	// This must match ../reflect/value.go:/runtimeSelect
	type runtimeSelect struct {
	dir selectDir
	typ unsafe.Pointer // channel type (not used here)
	ch *hchan // channel
	val unsafe.Pointer // ptr to data (SendDir) or ptr to receive buffer (RecvDir)
	}

	// These values must match ../reflect/value.go:/SelectDir.
	type selectDir int

	const (
	_ selectDir = iota
	selectSend // case Chan <- Send
	selectRecv // case <-Chan:
	selectDefault // default
	)

	//go:linkname reflect_rselect reflect.rselect
	func reflect_rselect(cases []runtimeSelect) (chosen int, recvOK bool) {
	// flagNoScan is safe here, because all objects are also referenced from cases.
	size := selectsize(uintptr(len(cases)))
	sel := (*hselect)(mallocgc(size, nil, true))
	newselect(sel, int64(size), int32(len(cases)))
	r := new(bool)
	for i := range cases {
	rc := &cases[i]
	switch rc.dir {
	case selectDefault:
	selectdefaultImpl(sel, uintptr(i), 0)
	case selectSend:
	if rc.ch == nil {
	break
	}
	selectsendImpl(sel, rc.ch, uintptr(i), rc.val, 0)
	case selectRecv:
	if rc.ch == nil {
	break
	}
	selectrecvImpl(sel, rc.ch, uintptr(i), rc.val, r, 0)
	}
	}

	pc, _ := selectgoImpl(sel)
	chosen = int(pc)
	recvOK = *r
	return
	}

	func (q waitq) dequeueSudoG(sgp sudog) {
	x := sgp.prev
	y := sgp.next
	if x != nil {
	if y != nil {
	// middle of queue
	x.next = y
	y.prev = x
	sgp.next = nil
	sgp.prev = nil
	return
	}
	// end of queue
	x.next = nil
	q.last = x
	sgp.prev = nil
	return
	}
	if y != nil {
	// start of queue
	y.prev = nil
	q.first = y
	sgp.next = nil
	return
	}

	// x==y==nil. Either sgp is the only element in the queue,
	// or it has already been removed. Use q.first to disambiguate.
	if q.first == sgp {
	q.first = nil
	q.last = nil
	}
	}