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view src/thread/dc/SDL_syscond.c @ 1982:3b4ce57c6215

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First shot at new audio data types (int32 and float32). Notable changes: - Converters between types are autogenerated. Instead of making multiple passes over the data with seperate filters for endianess, size, signedness, etc, converting between data types is always one specialized filter. This simplifies SDL_BuildAudioCVT(), which otherwise had a million edge cases with the new types, and makes the actually conversions more CPU cache friendly. Left a stub for adding specific optimized versions of these routines (SSE/MMX/Altivec, assembler, etc) - Autogenerated converters are built by SDL/src/audio/sdlgenaudiocvt.pl. This does not need to be run unless tweaking the code, and thus doesn't need integration into the build system. - Went through all the drivers and tried to weed out all the "Uint16" references that are better specified with the new SDL_AudioFormat typedef. - Cleaned out a bunch of hardcoded bitwise magic numbers and replaced them with new SDL_AUDIO_* macros. - Added initial float32 and int32 support code. Theoretically, existing drivers will push these through converters to get the data they want to feed to the hardware. Still TODO: - Optimize and debug new converters. - Update the CoreAudio backend to accept float32 data directly. - Other backends, too? - SDL_LoadWAV() needs to be updated to support int32 and float32 .wav files (both of which exist and can be generated by 'sox' for testing purposes). - Update the mixer to handle new datatypes. - Optionally update SDL_sound and SDL_mixer, etc.
author Ryan C. Gordon <icculus@icculus.org>
date Thu, 24 Aug 2006 12:10:46 +0000
parents c121d94672cb
children 99210400e8b9
line wrap: on
line source

/*
    SDL - Simple DirectMedia Layer
    Copyright (C) 1997-2006 Sam Lantinga

    This library is free software; you can redistribute it and/or
    modify it under the terms of the GNU Lesser General Public
    License as published by the Free Software Foundation; either
    version 2.1 of the License, or (at your option) any later version.

    This library is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
    Lesser General Public License for more details.

    You should have received a copy of the GNU Lesser General Public
    License along with this library; if not, write to the Free Software
    Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301  USA

    Sam Lantinga
    slouken@libsdl.org
*/
#include "SDL_config.h"

/* An implementation of condition variables using semaphores and mutexes */
/*
   This implementation borrows heavily from the BeOS condition variable
   implementation, written by Christopher Tate and Owen Smith.  Thanks!
 */

#include "SDL_thread.h"

struct SDL_cond
{
    SDL_mutex *lock;
    int waiting;
    int signals;
    SDL_sem *wait_sem;
    SDL_sem *wait_done;
};

/* Create a condition variable */
SDL_cond *
SDL_CreateCond(void)
{
    SDL_cond *cond;

    cond = (SDL_cond *) SDL_malloc(sizeof(SDL_cond));
    if (cond) {
        cond->lock = SDL_CreateMutex();
        cond->wait_sem = SDL_CreateSemaphore(0);
        cond->wait_done = SDL_CreateSemaphore(0);
        cond->waiting = cond->signals = 0;
        if (!cond->lock || !cond->wait_sem || !cond->wait_done) {
            SDL_DestroyCond(cond);
            cond = NULL;
        }
    } else {
        SDL_OutOfMemory();
    }
    return (cond);
}

/* Destroy a condition variable */
void
SDL_DestroyCond(SDL_cond * cond)
{
    if (cond) {
        if (cond->wait_sem) {
            SDL_DestroySemaphore(cond->wait_sem);
        }
        if (cond->wait_done) {
            SDL_DestroySemaphore(cond->wait_done);
        }
        if (cond->lock) {
            SDL_DestroyMutex(cond->lock);
        }
        SDL_free(cond);
    }
}

/* Restart one of the threads that are waiting on the condition variable */
int
SDL_CondSignal(SDL_cond * cond)
{
    if (!cond) {
        SDL_SetError("Passed a NULL condition variable");
        return -1;
    }

    /* If there are waiting threads not already signalled, then
       signal the condition and wait for the thread to respond.
     */
    SDL_LockMutex(cond->lock);
    if (cond->waiting > cond->signals) {
        ++cond->signals;
        SDL_SemPost(cond->wait_sem);
        SDL_UnlockMutex(cond->lock);
        SDL_SemWait(cond->wait_done);
    } else {
        SDL_UnlockMutex(cond->lock);
    }

    return 0;
}

/* Restart all threads that are waiting on the condition variable */
int
SDL_CondBroadcast(SDL_cond * cond)
{
    if (!cond) {
        SDL_SetError("Passed a NULL condition variable");
        return -1;
    }

    /* If there are waiting threads not already signalled, then
       signal the condition and wait for the thread to respond.
     */
    SDL_LockMutex(cond->lock);
    if (cond->waiting > cond->signals) {
        int i, num_waiting;

        num_waiting = (cond->waiting - cond->signals);
        cond->signals = cond->waiting;
        for (i = 0; i < num_waiting; ++i) {
            SDL_SemPost(cond->wait_sem);
        }
        /* Now all released threads are blocked here, waiting for us.
           Collect them all (and win fabulous prizes!) :-)
         */
        SDL_UnlockMutex(cond->lock);
        for (i = 0; i < num_waiting; ++i) {
            SDL_SemWait(cond->wait_done);
        }
    } else {
        SDL_UnlockMutex(cond->lock);
    }

    return 0;
}

/* Wait on the condition variable for at most 'ms' milliseconds.
   The mutex must be locked before entering this function!
   The mutex is unlocked during the wait, and locked again after the wait.

Typical use:

Thread A:
	SDL_LockMutex(lock);
	while ( ! condition ) {
		SDL_CondWait(cond);
	}
	SDL_UnlockMutex(lock);

Thread B:
	SDL_LockMutex(lock);
	...
	condition = true;
	...
	SDL_UnlockMutex(lock);
 */
int
SDL_CondWaitTimeout(SDL_cond * cond, SDL_mutex * mutex, Uint32 ms)
{
    int retval;

    if (!cond) {
        SDL_SetError("Passed a NULL condition variable");
        return -1;
    }

    /* Obtain the protection mutex, and increment the number of waiters.
       This allows the signal mechanism to only perform a signal if there
       are waiting threads.
     */
    SDL_LockMutex(cond->lock);
    ++cond->waiting;
    SDL_UnlockMutex(cond->lock);

    /* Unlock the mutex, as is required by condition variable semantics */
    SDL_UnlockMutex(mutex);

    /* Wait for a signal */
    if (ms == SDL_MUTEX_MAXWAIT) {
        retval = SDL_SemWait(cond->wait_sem);
    } else {
        retval = SDL_SemWaitTimeout(cond->wait_sem, ms);
    }

    /* Let the signaler know we have completed the wait, otherwise
       the signaler can race ahead and get the condition semaphore
       if we are stopped between the mutex unlock and semaphore wait,
       giving a deadlock.  See the following URL for details:
       http://www-classic.be.com/aboutbe/benewsletter/volume_III/Issue40.html
     */
    SDL_LockMutex(cond->lock);
    if (cond->signals > 0) {
        /* If we timed out, we need to eat a condition signal */
        if (retval > 0) {
            SDL_SemWait(cond->wait_sem);
        }
        /* We always notify the signal thread that we are done */
        SDL_SemPost(cond->wait_done);

        /* Signal handshake complete */
        --cond->signals;
    }
    --cond->waiting;
    SDL_UnlockMutex(cond->lock);

    /* Lock the mutex, as is required by condition variable semantics */
    SDL_LockMutex(mutex);

    return retval;
}

/* Wait on the condition variable forever */
int
SDL_CondWait(SDL_cond * cond, SDL_mutex * mutex)
{
    return SDL_CondWaitTimeout(cond, mutex, SDL_MUTEX_MAXWAIT);
}

/* vi: set ts=4 sw=4 expandtab: */