// 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.
#include "runtime.h"
#include "defs.h"
#include "os.h"
int8 *goos = "nacl";
// Thread-safe allocation of a mutex.
// (The name sema is left over from the Darwin implementation.
// Native Client implements semaphores too, but it is just a shim
// over the host implementation, which on some hosts imposes a very
// low limit on how many semaphores can be created.)
//
// Psema points at a mutex descriptor.
// It starts out zero, meaning no mutex.
// Fill it in, being careful of others calling initsema
// simultaneously.
static void
initsema(uint32 *psema)
{
uint32 sema;
if(*psema != 0) // already have one
return;
sema = mutex_create();
if((int32)sema < 0) {
printf("mutex_create failed\n");
breakpoint();
}
// mutex_create returns a file descriptor;
// shift it up and add the 1 bit so that can
// distinguish unintialized from fd 0.
sema = (sema<<1) | 1;
if(!cas(psema, 0, sema)){
// Someone else filled it in. Use theirs.
close(sema);
return;
}
}
// Lock and unlock.
// Defer entirely to Native Client.
// The expense of a call into Native Client is more like
// a function call than a system call, so as long as the
// Native Client lock implementation is good, we can't
// do better ourselves.
static void
xlock(int32 fd)
{
if(mutex_lock(fd) < 0) {
printf("mutex_lock failed\n");
breakpoint();
}
}
static void
xunlock(int32 fd)
{
if(mutex_unlock(fd) < 0) {
printf("mutex_lock failed\n");
breakpoint();
}
}
void
lock(Lock *l)
{
if(m->locks < 0)
throw("lock count");
m->locks++;
if(l->sema == 0)
initsema(&l->sema);
xlock(l->sema>>1);
}
void
unlock(Lock *l)
{
m->locks--;
if(m->locks < 0)
throw("lock count");
xunlock(l->sema>>1);
}
// One-time notifications.
//
// Since the lock/unlock implementation already
// takes care of sleeping in the kernel, we just reuse it.
// (But it's a weird use, so it gets its own interface.)
//
// We use a lock to represent the event:
// unlocked == event has happened.
// Thus the lock starts out locked, and to wait for the
// event you try to lock the lock. To signal the event,
// you unlock the lock.
//
// Native Client does not require that the thread acquiring
// a lock be the thread that releases the lock, so this is safe.
void
noteclear(Note *n)
{
if(n->lock.sema == 0)
initsema(&n->lock.sema);
xlock(n->lock.sema>>1);
}
void
notewakeup(Note *n)
{
if(n->lock.sema == 0) {
printf("notewakeup without noteclear");
breakpoint();
}
xunlock(n->lock.sema>>1);
}
void
notesleep(Note *n)
{
if(n->lock.sema == 0) {
printf("notesleep without noteclear");
breakpoint();
}
xlock(n->lock.sema>>1);
xunlock(n->lock.sema>>1); // Let other sleepers find out too.
}
void
newosproc(M *m, G *g, void *stk, void (*fn)(void))
{
void **vstk;
// I wish every OS made thread creation this easy.
m->tls[0] = (uint32)g;
m->tls[1] = (uint32)m;
vstk = stk;
*--vstk = nil;
if(thread_create(fn, vstk, m->tls, sizeof m->tls) < 0) {
printf("thread_create failed\n");
breakpoint();
}
}
void
osinit(void)
{
}
// Called to initialize a new m (including the bootstrap m).
void
minit(void)
{
}
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