newlib/winsup/cygwin/sync.cc

150 lines
4.1 KiB
C++

/* sync.cc: Synchronization functions for cygwin.
This file implements the methods for controlling the "muto" class
which is intended to operate similarly to a mutex but attempts to
avoid making expensive calls to the kernel.
Copyright 2000, 2001, 2002 Red Hat, Inc.
Written by Christopher Faylor <cgf@cygnus.com>
This file is part of Cygwin.
This software is a copyrighted work licensed under the terms of the
Cygwin license. Please consult the file "CYGWIN_LICENSE" for
details. */
#include "winsup.h"
#include <stdlib.h>
#include <time.h>
#include <sys/wait.h>
#include <errno.h>
#include <stdlib.h>
#include "sync.h"
#include "security.h"
muto NO_COPY muto_start;
#undef WaitForSingleObject
/* Constructor */
muto *
muto::init (const char *s)
{
waiters = -1;
/* Create event which is used in the fallback case when blocking is necessary */
if (!(bruteforce = CreateEvent (&sec_none_nih, FALSE, FALSE, NULL)))
{
DWORD oerr = GetLastError ();
SetLastError (oerr);
return NULL;
}
name = s;
next = muto_start.next;
muto_start.next = this;
return this;
}
#if 0 /* FIXME: Do we need this? mutos aren't destroyed until process exit */
/* Destructor (racy?) */
muto::~muto ()
{
while (visits)
release ();
HANDLE h = bruteforce;
bruteforce = NULL;
/* Just need to close the event handle */
if (h)
CloseHandle (h);
}
#endif
/* Acquire the lock. Argument is the number of milliseconds to wait for
the lock. Multiple visits from the same thread are allowed and should
be handled correctly.
Note: The goal here is to minimize, as much as possible, calls to the
OS. Hence the use of InterlockedIncrement, etc., rather than (much) more
expensive OS mutexes. */
int
muto::acquire (DWORD ms)
{
DWORD this_tid = GetCurrentThreadId ();
if (tid != this_tid)
{
/* Increment the waiters part of the class. Need to do this first to
avoid potential races. */
LONG was_waiting = InterlockedIncrement (&waiters);
/* This is deceptively simple. Basically, it allows multiple attempts to
lock the same muto to succeed without attempting to manipulate sync.
If the muto is already locked then this thread will wait for ms until
it is signalled by muto::release. Then it will attempt to grab the
sync field. If it succeeds, then this thread owns the muto.
There is a pathological condition where a thread times out waiting for
bruteforce but the release code triggers the bruteforce event. In this
case, it is possible for a thread which is going to wait for bruteforce
to wake up immediately. It will then attempt to grab sync but will fail
and go back to waiting. */
if (tid != this_tid && (was_waiting || InterlockedExchange (&sync, 1) != 0))
{
switch (WaitForSingleObject (bruteforce, ms))
{
case WAIT_OBJECT_0:
goto gotit;
break;
default:
InterlockedDecrement (&waiters);
return 0; /* failed. */
}
}
}
gotit:
tid = this_tid; /* register this thread. */
return ++visits; /* Increment visit count. */
}
/* Return the muto lock. Needs to be called once per every acquire. */
int
muto::release ()
{
DWORD this_tid = GetCurrentThreadId ();
if (tid != this_tid || !visits)
{
SetLastError (ERROR_NOT_OWNER); /* Didn't have the lock. */
return 0; /* failed. */
}
/* FIXME: Need to check that other thread has not exited, too. */
if (!--visits)
{
tid = 0; /* We were the last unlocker. */
(void) InterlockedExchange (&sync, 0); /* Reset trigger. */
/* This thread had incremented waiters but had never decremented it.
Decrement it now. If it is >= 0 then there are possibly other
threads waiting for the lock, so trigger bruteforce. */
if (InterlockedDecrement (&waiters) >= 0)
(void) SetEvent (bruteforce); /* Wake up one of the waiting threads */
}
return 1; /* success. */
}
/* Call only when we're exiting. This is not thread safe. */
void
muto::reset ()
{
visits = sync = tid = 0;
InterlockedExchange (&waiters, -1);
if (bruteforce)
{
CloseHandle (bruteforce);
bruteforce = CreateEvent (&sec_none_nih, FALSE, FALSE, name);
}
}