mirror of
https://github.com/autc04/Retro68.git
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300 lines
6.4 KiB
Plaintext
300 lines
6.4 KiB
Plaintext
// Copyright 2009 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Semaphore implementation exposed to Go.
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// Intended use is provide a sleep and wakeup
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// primitive that can be used in the contended case
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// of other synchronization primitives.
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// Thus it targets the same goal as Linux's futex,
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// but it has much simpler semantics.
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//
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// That is, don't think of these as semaphores.
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// Think of them as a way to implement sleep and wakeup
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// such that every sleep is paired with a single wakeup,
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// even if, due to races, the wakeup happens before the sleep.
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//
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// See Mullender and Cox, ``Semaphores in Plan 9,''
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// http://swtch.com/semaphore.pdf
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package sync
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#include "runtime.h"
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#include "arch.h"
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typedef struct SemaWaiter SemaWaiter;
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struct SemaWaiter
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{
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uint32 volatile* addr;
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G* g;
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int64 releasetime;
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int32 nrelease; // -1 for acquire
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SemaWaiter* prev;
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SemaWaiter* next;
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};
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typedef struct SemaRoot SemaRoot;
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struct SemaRoot
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{
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Lock;
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SemaWaiter* head;
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SemaWaiter* tail;
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// Number of waiters. Read w/o the lock.
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uint32 volatile nwait;
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};
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// Prime to not correlate with any user patterns.
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#define SEMTABLESZ 251
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struct semtable
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{
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SemaRoot;
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uint8 pad[CacheLineSize-sizeof(SemaRoot)];
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};
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static struct semtable semtable[SEMTABLESZ];
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static SemaRoot*
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semroot(uint32 volatile *addr)
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{
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return &semtable[((uintptr)addr >> 3) % SEMTABLESZ];
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}
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static void
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semqueue(SemaRoot *root, uint32 volatile *addr, SemaWaiter *s)
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{
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s->g = runtime_g();
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s->addr = addr;
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s->next = nil;
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s->prev = root->tail;
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if(root->tail)
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root->tail->next = s;
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else
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root->head = s;
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root->tail = s;
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}
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static void
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semdequeue(SemaRoot *root, SemaWaiter *s)
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{
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if(s->next)
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s->next->prev = s->prev;
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else
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root->tail = s->prev;
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if(s->prev)
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s->prev->next = s->next;
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else
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root->head = s->next;
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s->prev = nil;
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s->next = nil;
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}
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static int32
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cansemacquire(uint32 volatile *addr)
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{
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uint32 v;
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while((v = runtime_atomicload(addr)) > 0)
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if(runtime_cas(addr, v, v-1))
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return 1;
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return 0;
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}
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void
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runtime_semacquire(uint32 volatile *addr, bool profile)
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{
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SemaWaiter s; // Needs to be allocated on stack, otherwise garbage collector could deallocate it
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SemaRoot *root;
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int64 t0;
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// Easy case.
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if(cansemacquire(addr))
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return;
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// Harder case:
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// increment waiter count
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// try cansemacquire one more time, return if succeeded
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// enqueue itself as a waiter
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// sleep
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// (waiter descriptor is dequeued by signaler)
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root = semroot(addr);
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t0 = 0;
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s.releasetime = 0;
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if(profile && runtime_blockprofilerate > 0) {
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t0 = runtime_cputicks();
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s.releasetime = -1;
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}
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for(;;) {
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runtime_lock(root);
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// Add ourselves to nwait to disable "easy case" in semrelease.
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runtime_xadd(&root->nwait, 1);
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// Check cansemacquire to avoid missed wakeup.
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if(cansemacquire(addr)) {
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runtime_xadd(&root->nwait, -1);
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runtime_unlock(root);
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return;
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}
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// Any semrelease after the cansemacquire knows we're waiting
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// (we set nwait above), so go to sleep.
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semqueue(root, addr, &s);
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runtime_parkunlock(root, "semacquire");
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if(cansemacquire(addr)) {
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if(t0)
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runtime_blockevent(s.releasetime - t0, 3);
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return;
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}
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}
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}
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void
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runtime_semrelease(uint32 volatile *addr)
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{
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SemaWaiter *s;
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SemaRoot *root;
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root = semroot(addr);
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runtime_xadd(addr, 1);
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// Easy case: no waiters?
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// This check must happen after the xadd, to avoid a missed wakeup
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// (see loop in semacquire).
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if(runtime_atomicload(&root->nwait) == 0)
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return;
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// Harder case: search for a waiter and wake it.
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runtime_lock(root);
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if(runtime_atomicload(&root->nwait) == 0) {
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// The count is already consumed by another goroutine,
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// so no need to wake up another goroutine.
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runtime_unlock(root);
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return;
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}
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for(s = root->head; s; s = s->next) {
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if(s->addr == addr) {
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runtime_xadd(&root->nwait, -1);
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semdequeue(root, s);
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break;
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}
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}
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runtime_unlock(root);
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if(s) {
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if(s->releasetime)
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s->releasetime = runtime_cputicks();
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runtime_ready(s->g);
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}
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}
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// TODO(dvyukov): move to netpoll.goc once it's used by all OSes.
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void net_runtime_Semacquire(uint32 *addr)
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__asm__ (GOSYM_PREFIX "net.runtime_Semacquire");
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void net_runtime_Semacquire(uint32 *addr)
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{
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runtime_semacquire(addr, true);
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}
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void net_runtime_Semrelease(uint32 *addr)
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__asm__ (GOSYM_PREFIX "net.runtime_Semrelease");
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void net_runtime_Semrelease(uint32 *addr)
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{
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runtime_semrelease(addr);
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}
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func runtime_Semacquire(addr *uint32) {
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runtime_semacquire(addr, true);
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}
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func runtime_Semrelease(addr *uint32) {
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runtime_semrelease(addr);
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}
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typedef struct SyncSema SyncSema;
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struct SyncSema
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{
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Lock;
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SemaWaiter* head;
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SemaWaiter* tail;
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};
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func runtime_Syncsemcheck(size uintptr) {
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if(size != sizeof(SyncSema)) {
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runtime_printf("bad SyncSema size: sync:%D runtime:%D\n", (int64)size, (int64)sizeof(SyncSema));
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runtime_throw("bad SyncSema size");
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}
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}
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// Syncsemacquire waits for a pairing Syncsemrelease on the same semaphore s.
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func runtime_Syncsemacquire(s *SyncSema) {
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SemaWaiter w, *wake;
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int64 t0;
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w.g = runtime_g();
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w.nrelease = -1;
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w.next = nil;
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w.releasetime = 0;
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t0 = 0;
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if(runtime_blockprofilerate > 0) {
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t0 = runtime_cputicks();
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w.releasetime = -1;
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}
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runtime_lock(s);
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if(s->head && s->head->nrelease > 0) {
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// have pending release, consume it
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wake = nil;
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s->head->nrelease--;
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if(s->head->nrelease == 0) {
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wake = s->head;
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s->head = wake->next;
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if(s->head == nil)
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s->tail = nil;
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}
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runtime_unlock(s);
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if(wake)
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runtime_ready(wake->g);
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} else {
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// enqueue itself
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if(s->tail == nil)
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s->head = &w;
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else
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s->tail->next = &w;
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s->tail = &w;
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runtime_parkunlock(s, "semacquire");
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if(t0)
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runtime_blockevent(w.releasetime - t0, 2);
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}
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}
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// Syncsemrelease waits for n pairing Syncsemacquire on the same semaphore s.
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func runtime_Syncsemrelease(s *SyncSema, n uint32) {
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SemaWaiter w, *wake;
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w.g = runtime_g();
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w.nrelease = (int32)n;
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w.next = nil;
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w.releasetime = 0;
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runtime_lock(s);
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while(w.nrelease > 0 && s->head && s->head->nrelease < 0) {
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// have pending acquire, satisfy it
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wake = s->head;
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s->head = wake->next;
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if(s->head == nil)
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s->tail = nil;
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if(wake->releasetime)
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wake->releasetime = runtime_cputicks();
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runtime_ready(wake->g);
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w.nrelease--;
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}
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if(w.nrelease > 0) {
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// enqueue itself
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if(s->tail == nil)
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s->head = &w;
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else
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s->tail->next = &w;
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s->tail = &w;
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runtime_parkunlock(s, "semarelease");
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} else
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runtime_unlock(s);
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}
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