// 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 #include "runtime.h" #include "arch_GOARCH.h" #include "type.h" #include "race.h" #include "malloc.h" #include "chan.h" #include "../../cmd/ld/textflag.h" uint32 runtime·Hchansize = sizeof(Hchan); static void dequeueg(WaitQ*); static SudoG* dequeue(WaitQ*); static void enqueue(WaitQ*, SudoG*); static void destroychan(Hchan*); static void racesync(Hchan*, SudoG*); static Hchan* makechan(ChanType *t, int64 hint) { Hchan *c; Type *elem; elem = t->elem; // compiler checks this but be safe. if(elem->size >= (1<<16)) runtime·throw("makechan: invalid channel element type"); if((sizeof(*c)%MAXALIGN) != 0 || elem->align > MAXALIGN) runtime·throw("makechan: bad alignment"); if(hint < 0 || (intgo)hint != hint || (elem->size > 0 && hint > (MaxMem - sizeof(*c)) / elem->size)) runtime·panicstring("makechan: size out of range"); // allocate memory in one call c = (Hchan*)runtime·mallocgc(sizeof(*c) + hint*elem->size, (uintptr)t | TypeInfo_Chan, 0); c->elemsize = elem->size; c->elemtype = elem; c->dataqsiz = hint; if(debug) runtime·printf("makechan: chan=%p; elemsize=%D; elemalg=%p; dataqsiz=%D\n", c, (int64)elem->size, elem->alg, (int64)c->dataqsiz); return c; } func reflect·makechan(t *ChanType, size uint64) (c *Hchan) { c = makechan(t, size); } func makechan(t *ChanType, size int64) (c *Hchan) { c = makechan(t, size); } /* * generic single channel send/recv * if the bool pointer is nil, * then the full exchange will * occur. if pres is not nil, * then the protocol will not * sleep but return if it could * not complete. * * sleep can wake up with g->param == nil * when a channel involved in the sleep has * been closed. it is easiest to loop and re-run * the operation; we'll see that it's now closed. */ static bool chansend(ChanType *t, Hchan *c, byte *ep, bool block, void *pc) { SudoG *sg; SudoG mysg; G* gp; int64 t0; if(raceenabled) runtime·racereadobjectpc(ep, t->elem, runtime·getcallerpc(&t), chansend); if(c == nil) { USED(t); if(!block) return false; runtime·park(nil, nil, "chan send (nil chan)"); return false; // not reached } if(debug) { runtime·printf("chansend: chan=%p; elem=", c); c->elemtype->alg->print(c->elemsize, ep); runtime·prints("\n"); } t0 = 0; mysg.releasetime = 0; if(runtime·blockprofilerate > 0) { t0 = runtime·cputicks(); mysg.releasetime = -1; } runtime·lock(c); if(raceenabled) runtime·racereadpc(c, pc, chansend); if(c->closed) goto closed; if(c->dataqsiz > 0) goto asynch; sg = dequeue(&c->recvq); if(sg != nil) { if(raceenabled) racesync(c, sg); runtime·unlock(c); gp = sg->g; gp->param = sg; if(sg->elem != nil) c->elemtype->alg->copy(c->elemsize, sg->elem, ep); if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); return true; } if(!block) { runtime·unlock(c); return false; } mysg.elem = ep; mysg.g = g; mysg.selectdone = nil; g->param = nil; enqueue(&c->sendq, &mysg); runtime·parkunlock(c, "chan send"); if(g->param == nil) { runtime·lock(c); if(!c->closed) runtime·throw("chansend: spurious wakeup"); goto closed; } if(mysg.releasetime > 0) runtime·blockevent(mysg.releasetime - t0, 2); return true; asynch: if(c->closed) goto closed; if(c->qcount >= c->dataqsiz) { if(!block) { runtime·unlock(c); return false; } mysg.g = g; mysg.elem = nil; mysg.selectdone = nil; enqueue(&c->sendq, &mysg); runtime·parkunlock(c, "chan send"); runtime·lock(c); goto asynch; } if(raceenabled) { if(c->dataqsiz == 1) runtime·raceacquire(chanbuf(c, c->sendx)); runtime·racerelease(chanbuf(c, c->sendx)); } c->elemtype->alg->copy(c->elemsize, chanbuf(c, c->sendx), ep); if(++c->sendx == c->dataqsiz) c->sendx = 0; c->qcount++; sg = dequeue(&c->recvq); if(sg != nil) { gp = sg->g; runtime·unlock(c); if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); } else runtime·unlock(c); if(mysg.releasetime > 0) runtime·blockevent(mysg.releasetime - t0, 2); return true; closed: runtime·unlock(c); runtime·panicstring("send on closed channel"); return false; // not reached } static bool chanrecv(ChanType *t, Hchan* c, byte *ep, bool block, bool *received) { SudoG *sg; SudoG mysg; G *gp; int64 t0; // raceenabled: don't need to check ep, as it is always on the stack. if(debug) runtime·printf("chanrecv: chan=%p\n", c); if(c == nil) { USED(t); if(!block) return false; runtime·park(nil, nil, "chan receive (nil chan)"); return false; // not reached } t0 = 0; mysg.releasetime = 0; if(runtime·blockprofilerate > 0) { t0 = runtime·cputicks(); mysg.releasetime = -1; } runtime·lock(c); if(c->dataqsiz > 0) goto asynch; if(c->closed) goto closed; sg = dequeue(&c->sendq); if(sg != nil) { if(raceenabled) racesync(c, sg); runtime·unlock(c); if(ep != nil) c->elemtype->alg->copy(c->elemsize, ep, sg->elem); gp = sg->g; gp->param = sg; if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); if(received != nil) *received = true; return true; } if(!block) { runtime·unlock(c); return false; } mysg.elem = ep; mysg.g = g; mysg.selectdone = nil; g->param = nil; enqueue(&c->recvq, &mysg); runtime·parkunlock(c, "chan receive"); if(g->param == nil) { runtime·lock(c); if(!c->closed) runtime·throw("chanrecv: spurious wakeup"); goto closed; } if(received != nil) *received = true; if(mysg.releasetime > 0) runtime·blockevent(mysg.releasetime - t0, 2); return true; asynch: if(c->qcount <= 0) { if(c->closed) goto closed; if(!block) { runtime·unlock(c); if(received != nil) *received = false; return false; } mysg.g = g; mysg.elem = nil; mysg.selectdone = nil; enqueue(&c->recvq, &mysg); runtime·parkunlock(c, "chan receive"); runtime·lock(c); goto asynch; } if(raceenabled) { runtime·raceacquire(chanbuf(c, c->recvx)); if(c->dataqsiz == 1) runtime·racerelease(chanbuf(c, c->recvx)); } if(ep != nil) c->elemtype->alg->copy(c->elemsize, ep, chanbuf(c, c->recvx)); c->elemtype->alg->copy(c->elemsize, chanbuf(c, c->recvx), nil); if(++c->recvx == c->dataqsiz) c->recvx = 0; c->qcount--; sg = dequeue(&c->sendq); if(sg != nil) { gp = sg->g; runtime·unlock(c); if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); } else runtime·unlock(c); if(received != nil) *received = true; if(mysg.releasetime > 0) runtime·blockevent(mysg.releasetime - t0, 2); return true; closed: if(ep != nil) c->elemtype->alg->copy(c->elemsize, ep, nil); if(received != nil) *received = false; if(raceenabled) runtime·raceacquire(c); runtime·unlock(c); if(mysg.releasetime > 0) runtime·blockevent(mysg.releasetime - t0, 2); return true; } #pragma textflag NOSPLIT func chansend1(t *ChanType, c *Hchan, elem *byte) { chansend(t, c, elem, true, runtime·getcallerpc(&t)); } #pragma textflag NOSPLIT func chanrecv1(t *ChanType, c *Hchan, elem *byte) { chanrecv(t, c, elem, true, nil); } // chanrecv2(hchan *chan any, elem *any) (received bool); #pragma textflag NOSPLIT func chanrecv2(t *ChanType, c *Hchan, elem *byte) (received bool) { chanrecv(t, c, elem, true, &received); } // compiler implements // // select { // case c <- v: // ... foo // default: // ... bar // } // // as // // if selectnbsend(c, v) { // ... foo // } else { // ... bar // } // #pragma textflag NOSPLIT func selectnbsend(t *ChanType, c *Hchan, elem *byte) (selected bool) { selected = chansend(t, c, elem, false, runtime·getcallerpc(&t)); } // compiler implements // // select { // case v = <-c: // ... foo // default: // ... bar // } // // as // // if selectnbrecv(&v, c) { // ... foo // } else { // ... bar // } // #pragma textflag NOSPLIT func selectnbrecv(t *ChanType, elem *byte, c *Hchan) (selected bool) { selected = chanrecv(t, c, elem, false, nil); } // compiler implements // // select { // case v, ok = <-c: // ... foo // default: // ... bar // } // // as // // if c != nil && selectnbrecv2(&v, &ok, c) { // ... foo // } else { // ... bar // } // #pragma textflag NOSPLIT func selectnbrecv2(t *ChanType, elem *byte, received *bool, c *Hchan) (selected bool) { selected = chanrecv(t, c, elem, false, received); } #pragma textflag NOSPLIT func reflect·chansend(t *ChanType, c *Hchan, elem *byte, nb bool) (selected bool) { selected = chansend(t, c, elem, !nb, runtime·getcallerpc(&t)); } func reflect·chanrecv(t *ChanType, c *Hchan, nb bool, elem *byte) (selected bool, received bool) { received = false; selected = chanrecv(t, c, elem, !nb, &received); } static Select* newselect(int32); #pragma textflag NOSPLIT func newselect(size int32) (sel *byte) { sel = (byte*)newselect(size); } static Select* newselect(int32 size) { int32 n; Select *sel; n = 0; if(size > 1) n = size-1; // allocate all the memory we need in a single allocation // start with Select with size cases // then lockorder with size entries // then pollorder with size entries sel = runtime·mal(sizeof(*sel) + n*sizeof(sel->scase[0]) + size*sizeof(sel->lockorder[0]) + size*sizeof(sel->pollorder[0])); sel->tcase = size; sel->ncase = 0; sel->lockorder = (void*)(sel->scase + size); sel->pollorder = (void*)(sel->lockorder + size); if(debug) runtime·printf("newselect s=%p size=%d\n", sel, size); return sel; } // cut in half to give stack a chance to split static void selectsend(Select *sel, Hchan *c, void *pc, void *elem, int32 so); #pragma textflag NOSPLIT func selectsend(sel *Select, c *Hchan, elem *byte) (selected bool) { selected = false; // nil cases do not compete if(c != nil) selectsend(sel, c, runtime·getcallerpc(&sel), elem, (byte*)&selected - (byte*)&sel); } static void selectsend(Select *sel, Hchan *c, void *pc, void *elem, int32 so) { int32 i; Scase *cas; i = sel->ncase; if(i >= sel->tcase) runtime·throw("selectsend: too many cases"); sel->ncase = i+1; cas = &sel->scase[i]; cas->pc = pc; cas->chan = c; cas->so = so; cas->kind = CaseSend; cas->sg.elem = elem; if(debug) runtime·printf("selectsend s=%p pc=%p chan=%p so=%d\n", sel, cas->pc, cas->chan, cas->so); } // cut in half to give stack a chance to split static void selectrecv(Select *sel, Hchan *c, void *pc, void *elem, bool*, int32 so); #pragma textflag NOSPLIT func selectrecv(sel *Select, c *Hchan, elem *byte) (selected bool) { selected = false; // nil cases do not compete if(c != nil) selectrecv(sel, c, runtime·getcallerpc(&sel), elem, nil, (byte*)&selected - (byte*)&sel); } #pragma textflag NOSPLIT func selectrecv2(sel *Select, c *Hchan, elem *byte, received *bool) (selected bool) { selected = false; // nil cases do not compete if(c != nil) selectrecv(sel, c, runtime·getcallerpc(&sel), elem, received, (byte*)&selected - (byte*)&sel); } static void selectrecv(Select *sel, Hchan *c, void *pc, void *elem, bool *received, int32 so) { int32 i; Scase *cas; i = sel->ncase; if(i >= sel->tcase) runtime·throw("selectrecv: too many cases"); sel->ncase = i+1; cas = &sel->scase[i]; cas->pc = pc; cas->chan = c; cas->so = so; cas->kind = CaseRecv; cas->sg.elem = elem; cas->receivedp = received; if(debug) runtime·printf("selectrecv s=%p pc=%p chan=%p so=%d\n", sel, cas->pc, cas->chan, cas->so); } // cut in half to give stack a chance to split static void selectdefault(Select*, void*, int32); #pragma textflag NOSPLIT func selectdefault(sel *Select) (selected bool) { selected = false; selectdefault(sel, runtime·getcallerpc(&sel), (byte*)&selected - (byte*)&sel); } static void selectdefault(Select *sel, void *callerpc, int32 so) { int32 i; Scase *cas; i = sel->ncase; if(i >= sel->tcase) runtime·throw("selectdefault: too many cases"); sel->ncase = i+1; cas = &sel->scase[i]; cas->pc = callerpc; cas->chan = nil; cas->so = so; cas->kind = CaseDefault; if(debug) runtime·printf("selectdefault s=%p pc=%p so=%d\n", sel, cas->pc, cas->so); } static void sellock(Select *sel) { uint32 i; Hchan *c, *c0; c = nil; for(i=0; incase; i++) { c0 = sel->lockorder[i]; if(c0 && c0 != c) { c = sel->lockorder[i]; runtime·lock(c); } } } static void selunlock(Select *sel) { int32 i, n, r; Hchan *c; // 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 = (int32)sel->ncase; r = 0; // skip the default case if(n>0 && sel->lockorder[0] == nil) r = 1; for(i = n-1; i >= r; i--) { c = sel->lockorder[i]; if(i>0 && sel->lockorder[i-1] == c) continue; // will unlock it on the next iteration runtime·unlock(c); } } static bool selparkcommit(G *gp, void *sel) { USED(gp); selunlock(sel); return true; } func block() { runtime·park(nil, nil, "select (no cases)"); // forever } static void* selectgo(Select**); // selectgo(sel *byte); // // overwrites return pc on stack to signal which case of the select // to run, so cannot appear at the top of a split stack. #pragma textflag NOSPLIT func selectgo(sel *Select) { runtime·setcallerpc(&sel, selectgo(&sel)); } static void* selectgo(Select **selp) { Select *sel; uint32 o, i, j, k, done; int64 t0; Scase *cas, *dfl; Hchan *c; SudoG *sg; G *gp; byte *as; void *pc; sel = *selp; if(debug) runtime·printf("select: sel=%p\n", sel); t0 = 0; if(runtime·blockprofilerate > 0) { t0 = runtime·cputicks(); for(i=0; incase; i++) sel->scase[i].sg.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 for(i=0; incase; i++) sel->pollorder[i] = i; for(i=1; incase; i++) { o = sel->pollorder[i]; j = runtime·fastrand1()%(i+1); sel->pollorder[i] = sel->pollorder[j]; sel->pollorder[j] = o; } // sort the cases by Hchan address to get the locking order. // simple heap sort, to guarantee n log n time and constant stack footprint. for(i=0; incase; i++) { j = i; c = sel->scase[j].chan; while(j > 0 && sel->lockorder[k=(j-1)/2] < c) { sel->lockorder[j] = sel->lockorder[k]; j = k; } sel->lockorder[j] = c; } for(i=sel->ncase; i-->0; ) { c = sel->lockorder[i]; sel->lockorder[i] = sel->lockorder[0]; j = 0; for(;;) { k = j*2+1; if(k >= i) break; if(k+1 < i && sel->lockorder[k] < sel->lockorder[k+1]) k++; if(c < sel->lockorder[k]) { sel->lockorder[j] = sel->lockorder[k]; j = k; continue; } break; } sel->lockorder[j] = c; } /* for(i=0; i+1ncase; i++) if(sel->lockorder[i] > sel->lockorder[i+1]) { runtime·printf("i=%d %p %p\n", i, sel->lockorder[i], sel->lockorder[i+1]); runtime·throw("select: broken sort"); } */ sellock(sel); loop: // pass 1 - look for something already waiting dfl = nil; for(i=0; incase; i++) { o = sel->pollorder[i]; cas = &sel->scase[o]; c = cas->chan; switch(cas->kind) { case CaseRecv: if(c->dataqsiz > 0) { if(c->qcount > 0) goto asyncrecv; } else { sg = dequeue(&c->sendq); if(sg != nil) goto syncrecv; } if(c->closed) goto rclose; break; case CaseSend: if(raceenabled) runtime·racereadpc(c, cas->pc, chansend); if(c->closed) goto sclose; if(c->dataqsiz > 0) { if(c->qcount < c->dataqsiz) goto asyncsend; } else { sg = dequeue(&c->recvq); if(sg != nil) goto syncsend; } break; case CaseDefault: dfl = cas; break; } } if(dfl != nil) { selunlock(sel); cas = dfl; goto retc; } // pass 2 - enqueue on all chans done = 0; for(i=0; incase; i++) { o = sel->pollorder[i]; cas = &sel->scase[o]; c = cas->chan; sg = &cas->sg; sg->g = g; sg->selectdone = &done; switch(cas->kind) { case CaseRecv: enqueue(&c->recvq, sg); break; case CaseSend: enqueue(&c->sendq, sg); break; } } g->param = nil; runtime·park(selparkcommit, sel, "select"); sellock(sel); sg = g->param; // pass 3 - dequeue from unsuccessful chans // otherwise they stack up on quiet channels for(i=0; incase; i++) { cas = &sel->scase[i]; if(cas != (Scase*)sg) { c = cas->chan; if(cas->kind == CaseSend) dequeueg(&c->sendq); else dequeueg(&c->recvq); } } if(sg == nil) goto loop; cas = (Scase*)sg; c = cas->chan; if(c->dataqsiz > 0) runtime·throw("selectgo: shouldn't happen"); if(debug) runtime·printf("wait-return: sel=%p c=%p cas=%p kind=%d\n", sel, c, cas, cas->kind); if(cas->kind == CaseRecv) { if(cas->receivedp != nil) *cas->receivedp = true; } if(raceenabled) { if(cas->kind == CaseRecv && cas->sg.elem != nil) runtime·racewriteobjectpc(cas->sg.elem, c->elemtype, cas->pc, chanrecv); else if(cas->kind == CaseSend) runtime·racereadobjectpc(cas->sg.elem, c->elemtype, cas->pc, chansend); } selunlock(sel); goto retc; asyncrecv: // can receive from buffer if(raceenabled) { if(cas->sg.elem != nil) runtime·racewriteobjectpc(cas->sg.elem, c->elemtype, cas->pc, chanrecv); runtime·raceacquire(chanbuf(c, c->recvx)); if(c->dataqsiz == 1) runtime·racerelease(chanbuf(c, c->recvx)); } if(cas->receivedp != nil) *cas->receivedp = true; if(cas->sg.elem != nil) c->elemtype->alg->copy(c->elemsize, cas->sg.elem, chanbuf(c, c->recvx)); c->elemtype->alg->copy(c->elemsize, chanbuf(c, c->recvx), nil); if(++c->recvx == c->dataqsiz) c->recvx = 0; c->qcount--; sg = dequeue(&c->sendq); if(sg != nil) { gp = sg->g; selunlock(sel); if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); } else { selunlock(sel); } goto retc; asyncsend: // can send to buffer if(raceenabled) { if(c->dataqsiz == 1) runtime·raceacquire(chanbuf(c, c->sendx)); runtime·racerelease(chanbuf(c, c->sendx)); runtime·racereadobjectpc(cas->sg.elem, c->elemtype, cas->pc, chansend); } c->elemtype->alg->copy(c->elemsize, chanbuf(c, c->sendx), cas->sg.elem); if(++c->sendx == c->dataqsiz) c->sendx = 0; c->qcount++; sg = dequeue(&c->recvq); if(sg != nil) { gp = sg->g; selunlock(sel); if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); } else { selunlock(sel); } goto retc; syncrecv: // can receive from sleeping sender (sg) if(raceenabled) { if(cas->sg.elem != nil) runtime·racewriteobjectpc(cas->sg.elem, c->elemtype, cas->pc, chanrecv); racesync(c, sg); } selunlock(sel); if(debug) runtime·printf("syncrecv: sel=%p c=%p o=%d\n", sel, c, o); if(cas->receivedp != nil) *cas->receivedp = true; if(cas->sg.elem != nil) c->elemtype->alg->copy(c->elemsize, cas->sg.elem, sg->elem); gp = sg->g; gp->param = sg; if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); goto retc; rclose: // read at end of closed channel selunlock(sel); if(cas->receivedp != nil) *cas->receivedp = false; if(cas->sg.elem != nil) c->elemtype->alg->copy(c->elemsize, cas->sg.elem, nil); if(raceenabled) runtime·raceacquire(c); goto retc; syncsend: // can send to sleeping receiver (sg) if(raceenabled) { runtime·racereadobjectpc(cas->sg.elem, c->elemtype, cas->pc, chansend); racesync(c, sg); } selunlock(sel); if(debug) runtime·printf("syncsend: sel=%p c=%p o=%d\n", sel, c, o); if(sg->elem != nil) c->elemtype->alg->copy(c->elemsize, sg->elem, cas->sg.elem); gp = sg->g; gp->param = sg; if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); retc: // return pc corresponding to chosen case. // Set boolean passed during select creation // (at offset selp + cas->so) to true. // If cas->so == 0, this is a reflect-driven select and we // don't need to update the boolean. pc = cas->pc; if(cas->so > 0) { as = (byte*)selp + cas->so; *as = true; } if(cas->sg.releasetime > 0) runtime·blockevent(cas->sg.releasetime - t0, 2); runtime·free(sel); return pc; sclose: // send on closed channel selunlock(sel); runtime·panicstring("send on closed channel"); return nil; // not reached } // This struct must match ../reflect/value.go:/runtimeSelect. typedef struct runtimeSelect runtimeSelect; struct runtimeSelect { uintptr dir; ChanType *typ; Hchan *ch; byte *val; }; // This enum must match ../reflect/value.go:/SelectDir. enum SelectDir { SelectSend = 1, SelectRecv, SelectDefault, }; func reflect·rselect(cases Slice) (chosen int, recvOK bool) { int32 i; Select *sel; runtimeSelect* rcase, *rc; chosen = -1; recvOK = false; rcase = (runtimeSelect*)cases.array; sel = newselect(cases.len); for(i=0; idir) { case SelectDefault: selectdefault(sel, (void*)i, 0); break; case SelectSend: if(rc->ch == nil) break; selectsend(sel, rc->ch, (void*)i, rc->val, 0); break; case SelectRecv: if(rc->ch == nil) break; selectrecv(sel, rc->ch, (void*)i, rc->val, &recvOK, 0); break; } } chosen = (intgo)(uintptr)selectgo(&sel); } static void closechan(Hchan *c, void *pc); #pragma textflag NOSPLIT func closechan(c *Hchan) { closechan(c, runtime·getcallerpc(&c)); } #pragma textflag NOSPLIT func reflect·chanclose(c *Hchan) { closechan(c, runtime·getcallerpc(&c)); } static void closechan(Hchan *c, void *pc) { SudoG *sg; G* gp; if(c == nil) runtime·panicstring("close of nil channel"); runtime·lock(c); if(c->closed) { runtime·unlock(c); runtime·panicstring("close of closed channel"); } if(raceenabled) { runtime·racewritepc(c, pc, runtime·closechan); runtime·racerelease(c); } c->closed = true; // release all readers for(;;) { sg = dequeue(&c->recvq); if(sg == nil) break; gp = sg->g; gp->param = nil; if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); } // release all writers for(;;) { sg = dequeue(&c->sendq); if(sg == nil) break; gp = sg->g; gp->param = nil; if(sg->releasetime) sg->releasetime = runtime·cputicks(); runtime·ready(gp); } runtime·unlock(c); } func reflect·chanlen(c *Hchan) (len int) { if(c == nil) len = 0; else len = c->qcount; } func reflect·chancap(c *Hchan) (cap int) { if(c == nil) cap = 0; else cap = c->dataqsiz; } static SudoG* dequeue(WaitQ *q) { SudoG *sgp; loop: sgp = q->first; if(sgp == nil) return nil; q->first = sgp->link; // if sgp participates in a select and is already signaled, ignore it if(sgp->selectdone != nil) { // claim the right to signal if(*sgp->selectdone != 0 || !runtime·cas(sgp->selectdone, 0, 1)) goto loop; } return sgp; } static void dequeueg(WaitQ *q) { SudoG **l, *sgp, *prevsgp; prevsgp = nil; for(l=&q->first; (sgp=*l) != nil; l=&sgp->link, prevsgp=sgp) { if(sgp->g == g) { *l = sgp->link; if(q->last == sgp) q->last = prevsgp; break; } } } static void enqueue(WaitQ *q, SudoG *sgp) { sgp->link = nil; if(q->first == nil) { q->first = sgp; q->last = sgp; return; } q->last->link = sgp; q->last = sgp; } static void racesync(Hchan *c, SudoG *sg) { runtime·racerelease(chanbuf(c, 0)); runtime·raceacquireg(sg->g, chanbuf(c, 0)); runtime·racereleaseg(sg->g, chanbuf(c, 0)); runtime·raceacquire(chanbuf(c, 0)); }