1// Copyright 2009 The Go Authors. All rights reserved.
2// Use of this source code is governed by a BSD-style
3// license that can be found in the LICENSE file.
4
5package runtime
6
7// This file contains the implementation of Go select statements.
8
9import (
10	"internal/abi"
11	"unsafe"
12)
13
14const debugSelect = false
15
16// Select case descriptor.
17// Known to compiler.
18// Changes here must also be made in src/cmd/compile/internal/walk/select.go's scasetype.
19type scase struct {
20	c    *hchan         // chan
21	elem unsafe.Pointer // data element
22}
23
24var (
25	chansendpc = abi.FuncPCABIInternal(chansend)
26	chanrecvpc = abi.FuncPCABIInternal(chanrecv)
27)
28
29func selectsetpc(pc *uintptr) {
30	*pc = getcallerpc()
31}
32
33func sellock(scases []scase, lockorder []uint16) {
34	var c *hchan
35	for _, o := range lockorder {
36		c0 := scases[o].c
37		if c0 != c {
38			c = c0
39			lock(&c.lock)
40		}
41	}
42}
43
44func selunlock(scases []scase, lockorder []uint16) {
45	// We must be very careful here to not touch sel after we have unlocked
46	// the last lock, because sel can be freed right after the last unlock.
47	// Consider the following situation.
48	// First M calls runtime·park() in runtime·selectgo() passing the sel.
49	// Once runtime·park() has unlocked the last lock, another M makes
50	// the G that calls select runnable again and schedules it for execution.
51	// When the G runs on another M, it locks all the locks and frees sel.
52	// Now if the first M touches sel, it will access freed memory.
53	for i := len(lockorder) - 1; i >= 0; i-- {
54		c := scases[lockorder[i]].c
55		if i > 0 && c == scases[lockorder[i-1]].c {
56			continue // will unlock it on the next iteration
57		}
58		unlock(&c.lock)
59	}
60}
61
62func selparkcommit(gp *g, _ unsafe.Pointer) bool {
63	// There are unlocked sudogs that point into gp's stack. Stack
64	// copying must lock the channels of those sudogs.
65	// Set activeStackChans here instead of before we try parking
66	// because we could self-deadlock in stack growth on a
67	// channel lock.
68	gp.activeStackChans = true
69	// Mark that it's safe for stack shrinking to occur now,
70	// because any thread acquiring this G's stack for shrinking
71	// is guaranteed to observe activeStackChans after this store.
72	gp.parkingOnChan.Store(false)
73	// Make sure we unlock after setting activeStackChans and
74	// unsetting parkingOnChan. The moment we unlock any of the
75	// channel locks we risk gp getting readied by a channel operation
76	// and so gp could continue running before everything before the
77	// unlock is visible (even to gp itself).
78
79	// This must not access gp's stack (see gopark). In
80	// particular, it must not access the *hselect. That's okay,
81	// because by the time this is called, gp.waiting has all
82	// channels in lock order.
83	var lastc *hchan
84	for sg := gp.waiting; sg != nil; sg = sg.waitlink {
85		if sg.c != lastc && lastc != nil {
86			// As soon as we unlock the channel, fields in
87			// any sudog with that channel may change,
88			// including c and waitlink. Since multiple
89			// sudogs may have the same channel, we unlock
90			// only after we've passed the last instance
91			// of a channel.
92			unlock(&lastc.lock)
93		}
94		lastc = sg.c
95	}
96	if lastc != nil {
97		unlock(&lastc.lock)
98	}
99	return true
100}
101
102func block() {
103	gopark(nil, nil, waitReasonSelectNoCases, traceBlockForever, 1) // forever
104}
105
106// selectgo implements the select statement.
107//
108// cas0 points to an array of type [ncases]scase, and order0 points to
109// an array of type [2*ncases]uint16 where ncases must be <= 65536.
110// Both reside on the goroutine's stack (regardless of any escaping in
111// selectgo).
112//
113// For race detector builds, pc0 points to an array of type
114// [ncases]uintptr (also on the stack); for other builds, it's set to
115// nil.
116//
117// selectgo returns the index of the chosen scase, which matches the
118// ordinal position of its respective select{recv,send,default} call.
119// Also, if the chosen scase was a receive operation, it reports whether
120// a value was received.
121func selectgo(cas0 *scase, order0 *uint16, pc0 *uintptr, nsends, nrecvs int, block bool) (int, bool) {
122	if debugSelect {
123		print("select: cas0=", cas0, "\n")
124	}
125
126	// NOTE: In order to maintain a lean stack size, the number of scases
127	// is capped at 65536.
128	cas1 := (*[1 << 16]scase)(unsafe.Pointer(cas0))
129	order1 := (*[1 << 17]uint16)(unsafe.Pointer(order0))
130
131	ncases := nsends + nrecvs
132	scases := cas1[:ncases:ncases]
133	pollorder := order1[:ncases:ncases]
134	lockorder := order1[ncases:][:ncases:ncases]
135	// NOTE: pollorder/lockorder's underlying array was not zero-initialized by compiler.
136
137	// Even when raceenabled is true, there might be select
138	// statements in packages compiled without -race (e.g.,
139	// ensureSigM in runtime/signal_unix.go).
140	var pcs []uintptr
141	if raceenabled && pc0 != nil {
142		pc1 := (*[1 << 16]uintptr)(unsafe.Pointer(pc0))
143		pcs = pc1[:ncases:ncases]
144	}
145	casePC := func(casi int) uintptr {
146		if pcs == nil {
147			return 0
148		}
149		return pcs[casi]
150	}
151
152	var t0 int64
153	if blockprofilerate > 0 {
154		t0 = cputicks()
155	}
156
157	// The compiler rewrites selects that statically have
158	// only 0 or 1 cases plus default into simpler constructs.
159	// The only way we can end up with such small sel.ncase
160	// values here is for a larger select in which most channels
161	// have been nilled out. The general code handles those
162	// cases correctly, and they are rare enough not to bother
163	// optimizing (and needing to test).
164
165	// generate permuted order
166	norder := 0
167	for i := range scases {
168		cas := &scases[i]
169
170		// Omit cases without channels from the poll and lock orders.
171		if cas.c == nil {
172			cas.elem = nil // allow GC
173			continue
174		}
175
176		if cas.c.timer != nil {
177			cas.c.timer.maybeRunChan()
178		}
179
180		j := cheaprandn(uint32(norder + 1))
181		pollorder[norder] = pollorder[j]
182		pollorder[j] = uint16(i)
183		norder++
184	}
185	pollorder = pollorder[:norder]
186	lockorder = lockorder[:norder]
187
188	// sort the cases by Hchan address to get the locking order.
189	// simple heap sort, to guarantee n log n time and constant stack footprint.
190	for i := range lockorder {
191		j := i
192		// Start with the pollorder to permute cases on the same channel.
193		c := scases[pollorder[i]].c
194		for j > 0 && scases[lockorder[(j-1)/2]].c.sortkey() < c.sortkey() {
195			k := (j - 1) / 2
196			lockorder[j] = lockorder[k]
197			j = k
198		}
199		lockorder[j] = pollorder[i]
200	}
201	for i := len(lockorder) - 1; i >= 0; i-- {
202		o := lockorder[i]
203		c := scases[o].c
204		lockorder[i] = lockorder[0]
205		j := 0
206		for {
207			k := j*2 + 1
208			if k >= i {
209				break
210			}
211			if k+1 < i && scases[lockorder[k]].c.sortkey() < scases[lockorder[k+1]].c.sortkey() {
212				k++
213			}
214			if c.sortkey() < scases[lockorder[k]].c.sortkey() {
215				lockorder[j] = lockorder[k]
216				j = k
217				continue
218			}
219			break
220		}
221		lockorder[j] = o
222	}
223
224	if debugSelect {
225		for i := 0; i+1 < len(lockorder); i++ {
226			if scases[lockorder[i]].c.sortkey() > scases[lockorder[i+1]].c.sortkey() {
227				print("i=", i, " x=", lockorder[i], " y=", lockorder[i+1], "\n")
228				throw("select: broken sort")
229			}
230		}
231	}
232
233	// lock all the channels involved in the select
234	sellock(scases, lockorder)
235
236	var (
237		gp     *g
238		sg     *sudog
239		c      *hchan
240		k      *scase
241		sglist *sudog
242		sgnext *sudog
243		qp     unsafe.Pointer
244		nextp  **sudog
245	)
246
247	// pass 1 - look for something already waiting
248	var casi int
249	var cas *scase
250	var caseSuccess bool
251	var caseReleaseTime int64 = -1
252	var recvOK bool
253	for _, casei := range pollorder {
254		casi = int(casei)
255		cas = &scases[casi]
256		c = cas.c
257
258		if casi >= nsends {
259			sg = c.sendq.dequeue()
260			if sg != nil {
261				goto recv
262			}
263			if c.qcount > 0 {
264				goto bufrecv
265			}
266			if c.closed != 0 {
267				goto rclose
268			}
269		} else {
270			if raceenabled {
271				racereadpc(c.raceaddr(), casePC(casi), chansendpc)
272			}
273			if c.closed != 0 {
274				goto sclose
275			}
276			sg = c.recvq.dequeue()
277			if sg != nil {
278				goto send
279			}
280			if c.qcount < c.dataqsiz {
281				goto bufsend
282			}
283		}
284	}
285
286	if !block {
287		selunlock(scases, lockorder)
288		casi = -1
289		goto retc
290	}
291
292	// pass 2 - enqueue on all chans
293	gp = getg()
294	if gp.waiting != nil {
295		throw("gp.waiting != nil")
296	}
297	nextp = &gp.waiting
298	for _, casei := range lockorder {
299		casi = int(casei)
300		cas = &scases[casi]
301		c = cas.c
302		sg := acquireSudog()
303		sg.g = gp
304		sg.isSelect = true
305		// No stack splits between assigning elem and enqueuing
306		// sg on gp.waiting where copystack can find it.
307		sg.elem = cas.elem
308		sg.releasetime = 0
309		if t0 != 0 {
310			sg.releasetime = -1
311		}
312		sg.c = c
313		// Construct waiting list in lock order.
314		*nextp = sg
315		nextp = &sg.waitlink
316
317		if casi < nsends {
318			c.sendq.enqueue(sg)
319		} else {
320			c.recvq.enqueue(sg)
321		}
322
323		if c.timer != nil {
324			blockTimerChan(c)
325		}
326	}
327
328	// wait for someone to wake us up
329	gp.param = nil
330	// Signal to anyone trying to shrink our stack that we're about
331	// to park on a channel. The window between when this G's status
332	// changes and when we set gp.activeStackChans is not safe for
333	// stack shrinking.
334	gp.parkingOnChan.Store(true)
335	gopark(selparkcommit, nil, waitReasonSelect, traceBlockSelect, 1)
336	gp.activeStackChans = false
337
338	sellock(scases, lockorder)
339
340	gp.selectDone.Store(0)
341	sg = (*sudog)(gp.param)
342	gp.param = nil
343
344	// pass 3 - dequeue from unsuccessful chans
345	// otherwise they stack up on quiet channels
346	// record the successful case, if any.
347	// We singly-linked up the SudoGs in lock order.
348	casi = -1
349	cas = nil
350	caseSuccess = false
351	sglist = gp.waiting
352	// Clear all elem before unlinking from gp.waiting.
353	for sg1 := gp.waiting; sg1 != nil; sg1 = sg1.waitlink {
354		sg1.isSelect = false
355		sg1.elem = nil
356		sg1.c = nil
357	}
358	gp.waiting = nil
359
360	for _, casei := range lockorder {
361		k = &scases[casei]
362		if k.c.timer != nil {
363			unblockTimerChan(k.c)
364		}
365		if sg == sglist {
366			// sg has already been dequeued by the G that woke us up.
367			casi = int(casei)
368			cas = k
369			caseSuccess = sglist.success
370			if sglist.releasetime > 0 {
371				caseReleaseTime = sglist.releasetime
372			}
373		} else {
374			c = k.c
375			if int(casei) < nsends {
376				c.sendq.dequeueSudoG(sglist)
377			} else {
378				c.recvq.dequeueSudoG(sglist)
379			}
380		}
381		sgnext = sglist.waitlink
382		sglist.waitlink = nil
383		releaseSudog(sglist)
384		sglist = sgnext
385	}
386
387	if cas == nil {
388		throw("selectgo: bad wakeup")
389	}
390
391	c = cas.c
392
393	if debugSelect {
394		print("wait-return: cas0=", cas0, " c=", c, " cas=", cas, " send=", casi < nsends, "\n")
395	}
396
397	if casi < nsends {
398		if !caseSuccess {
399			goto sclose
400		}
401	} else {
402		recvOK = caseSuccess
403	}
404
405	if raceenabled {
406		if casi < nsends {
407			raceReadObjectPC(c.elemtype, cas.elem, casePC(casi), chansendpc)
408		} else if cas.elem != nil {
409			raceWriteObjectPC(c.elemtype, cas.elem, casePC(casi), chanrecvpc)
410		}
411	}
412	if msanenabled {
413		if casi < nsends {
414			msanread(cas.elem, c.elemtype.Size_)
415		} else if cas.elem != nil {
416			msanwrite(cas.elem, c.elemtype.Size_)
417		}
418	}
419	if asanenabled {
420		if casi < nsends {
421			asanread(cas.elem, c.elemtype.Size_)
422		} else if cas.elem != nil {
423			asanwrite(cas.elem, c.elemtype.Size_)
424		}
425	}
426
427	selunlock(scases, lockorder)
428	goto retc
429
430bufrecv:
431	// can receive from buffer
432	if raceenabled {
433		if cas.elem != nil {
434			raceWriteObjectPC(c.elemtype, cas.elem, casePC(casi), chanrecvpc)
435		}
436		racenotify(c, c.recvx, nil)
437	}
438	if msanenabled && cas.elem != nil {
439		msanwrite(cas.elem, c.elemtype.Size_)
440	}
441	if asanenabled && cas.elem != nil {
442		asanwrite(cas.elem, c.elemtype.Size_)
443	}
444	recvOK = true
445	qp = chanbuf(c, c.recvx)
446	if cas.elem != nil {
447		typedmemmove(c.elemtype, cas.elem, qp)
448	}
449	typedmemclr(c.elemtype, qp)
450	c.recvx++
451	if c.recvx == c.dataqsiz {
452		c.recvx = 0
453	}
454	c.qcount--
455	selunlock(scases, lockorder)
456	goto retc
457
458bufsend:
459	// can send to buffer
460	if raceenabled {
461		racenotify(c, c.sendx, nil)
462		raceReadObjectPC(c.elemtype, cas.elem, casePC(casi), chansendpc)
463	}
464	if msanenabled {
465		msanread(cas.elem, c.elemtype.Size_)
466	}
467	if asanenabled {
468		asanread(cas.elem, c.elemtype.Size_)
469	}
470	typedmemmove(c.elemtype, chanbuf(c, c.sendx), cas.elem)
471	c.sendx++
472	if c.sendx == c.dataqsiz {
473		c.sendx = 0
474	}
475	c.qcount++
476	selunlock(scases, lockorder)
477	goto retc
478
479recv:
480	// can receive from sleeping sender (sg)
481	recv(c, sg, cas.elem, func() { selunlock(scases, lockorder) }, 2)
482	if debugSelect {
483		print("syncrecv: cas0=", cas0, " c=", c, "\n")
484	}
485	recvOK = true
486	goto retc
487
488rclose:
489	// read at end of closed channel
490	selunlock(scases, lockorder)
491	recvOK = false
492	if cas.elem != nil {
493		typedmemclr(c.elemtype, cas.elem)
494	}
495	if raceenabled {
496		raceacquire(c.raceaddr())
497	}
498	goto retc
499
500send:
501	// can send to a sleeping receiver (sg)
502	if raceenabled {
503		raceReadObjectPC(c.elemtype, cas.elem, casePC(casi), chansendpc)
504	}
505	if msanenabled {
506		msanread(cas.elem, c.elemtype.Size_)
507	}
508	if asanenabled {
509		asanread(cas.elem, c.elemtype.Size_)
510	}
511	send(c, sg, cas.elem, func() { selunlock(scases, lockorder) }, 2)
512	if debugSelect {
513		print("syncsend: cas0=", cas0, " c=", c, "\n")
514	}
515	goto retc
516
517retc:
518	if caseReleaseTime > 0 {
519		blockevent(caseReleaseTime-t0, 1)
520	}
521	return casi, recvOK
522
523sclose:
524	// send on closed channel
525	selunlock(scases, lockorder)
526	panic(plainError("send on closed channel"))
527}
528
529func (c *hchan) sortkey() uintptr {
530	return uintptr(unsafe.Pointer(c))
531}
532
533// A runtimeSelect is a single case passed to rselect.
534// This must match ../reflect/value.go:/runtimeSelect
535type runtimeSelect struct {
536	dir selectDir
537	typ unsafe.Pointer // channel type (not used here)
538	ch  *hchan         // channel
539	val unsafe.Pointer // ptr to data (SendDir) or ptr to receive buffer (RecvDir)
540}
541
542// These values must match ../reflect/value.go:/SelectDir.
543type selectDir int
544
545const (
546	_             selectDir = iota
547	selectSend              // case Chan <- Send
548	selectRecv              // case <-Chan:
549	selectDefault           // default
550)
551
552//go:linkname reflect_rselect reflect.rselect
553func reflect_rselect(cases []runtimeSelect) (int, bool) {
554	if len(cases) == 0 {
555		block()
556	}
557	sel := make([]scase, len(cases))
558	orig := make([]int, len(cases))
559	nsends, nrecvs := 0, 0
560	dflt := -1
561	for i, rc := range cases {
562		var j int
563		switch rc.dir {
564		case selectDefault:
565			dflt = i
566			continue
567		case selectSend:
568			j = nsends
569			nsends++
570		case selectRecv:
571			nrecvs++
572			j = len(cases) - nrecvs
573		}
574
575		sel[j] = scase{c: rc.ch, elem: rc.val}
576		orig[j] = i
577	}
578
579	// Only a default case.
580	if nsends+nrecvs == 0 {
581		return dflt, false
582	}
583
584	// Compact sel and orig if necessary.
585	if nsends+nrecvs < len(cases) {
586		copy(sel[nsends:], sel[len(cases)-nrecvs:])
587		copy(orig[nsends:], orig[len(cases)-nrecvs:])
588	}
589
590	order := make([]uint16, 2*(nsends+nrecvs))
591	var pc0 *uintptr
592	if raceenabled {
593		pcs := make([]uintptr, nsends+nrecvs)
594		for i := range pcs {
595			selectsetpc(&pcs[i])
596		}
597		pc0 = &pcs[0]
598	}
599
600	chosen, recvOK := selectgo(&sel[0], &order[0], pc0, nsends, nrecvs, dflt == -1)
601
602	// Translate chosen back to caller's ordering.
603	if chosen < 0 {
604		chosen = dflt
605	} else {
606		chosen = orig[chosen]
607	}
608	return chosen, recvOK
609}
610
611func (q *waitq) dequeueSudoG(sgp *sudog) {
612	x := sgp.prev
613	y := sgp.next
614	if x != nil {
615		if y != nil {
616			// middle of queue
617			x.next = y
618			y.prev = x
619			sgp.next = nil
620			sgp.prev = nil
621			return
622		}
623		// end of queue
624		x.next = nil
625		q.last = x
626		sgp.prev = nil
627		return
628	}
629	if y != nil {
630		// start of queue
631		y.prev = nil
632		q.first = y
633		sgp.next = nil
634		return
635	}
636
637	// x==y==nil. Either sgp is the only element in the queue,
638	// or it has already been removed. Use q.first to disambiguate.
639	if q.first == sgp {
640		q.first = nil
641		q.last = nil
642	}
643}
644