1 files changed, 465 insertions, 0 deletions
diff --git a/contrib/SDL-3.2.8/src/io/generic/SDL_asyncio_generic.c b/contrib/SDL-3.2.8/src/io/generic/SDL_asyncio_generic.c
new file mode 100644
index 0000000..4c2a562
--- /dev/null
+++ b/contrib/SDL-3.2.8/src/io/generic/SDL_asyncio_generic.c
@@ -0,0 +1,465 @@
+/*
+  Simple DirectMedia Layer
+  Copyright (C) 1997-2025 Sam Lantinga <slouken@libsdl.org>
+  This software is provided 'as-is', without any express or implied
+  warranty.  In no event will the authors be held liable for any damages
+  arising from the use of this software.
+  Permission is granted to anyone to use this software for any purpose,
+  including commercial applications, and to alter it and redistribute it
+  freely, subject to the following restrictions:
+  1. The origin of this software must not be misrepresented; you must not
+     claim that you wrote the original software. If you use this software
+     in a product, an acknowledgment in the product documentation would be
+     appreciated but is not required.
+  2. Altered source versions must be plainly marked as such, and must not be
+     misrepresented as being the original software.
+  3. This notice may not be removed or altered from any source distribution.
+*/
+// The generic backend uses a threadpool to block on synchronous i/o.
+// This is not ideal, it's meant to be used if there isn't a platform-specific
+// backend that can do something more efficient!
+#include "SDL_internal.h"
+#include "../SDL_sysasyncio.h"
+// on Emscripten without threads, async i/o is synchronous. Sorry. Almost
+// everything is MEMFS, so it's just a memcpy anyhow, and the Emscripten
+// filesystem APIs don't offer async. In theory, directly accessing
+// persistent storage _does_ offer async APIs at the browser level, but
+// that's not exposed in Emscripten's filesystem abstraction.
+#if defined(SDL_PLATFORM_EMSCRIPTEN) && !defined(__EMSCRIPTEN_PTHREADS__)
+#define SDL_ASYNCIO_USE_THREADPOOL 0
+#else
+#define SDL_ASYNCIO_USE_THREADPOOL 1
+#endif
+typedef struct GenericAsyncIOQueueData
+{
+    SDL_Mutex *lock;
+    SDL_Condition *condition;
+    SDL_AsyncIOTask completed_tasks;
+} GenericAsyncIOQueueData;
+typedef struct GenericAsyncIOData
+{
+    SDL_Mutex *lock;  // !!! FIXME: we can skip this lock if we have an equivalent of pread/pwrite
+    SDL_IOStream *io;
+} GenericAsyncIOData;
+static void AsyncIOTaskComplete(SDL_AsyncIOTask *task)
+{
+    SDL_assert(task->queue);
+    GenericAsyncIOQueueData *data = (GenericAsyncIOQueueData *) task->queue->userdata;
+    SDL_LockMutex(data->lock);
+    LINKED_LIST_PREPEND(task, data->completed_tasks, queue);
+    SDL_SignalCondition(data->condition);  // wake a thread waiting on the queue.
+    SDL_UnlockMutex(data->lock);
+}
+// synchronous i/o is offloaded onto the threadpool. This function does the threaded work.
+// This is called directly, without a threadpool, if !SDL_ASYNCIO_USE_THREADPOOL.
+static void SynchronousIO(SDL_AsyncIOTask *task)
+{
+    SDL_assert(task->result != SDL_ASYNCIO_CANCELED);  // shouldn't have gotten in here if canceled!
+    GenericAsyncIOData *data = (GenericAsyncIOData *) task->asyncio->userdata;
+    SDL_IOStream *io = data->io;
+    const size_t size = (size_t) task->requested_size;
+    void *ptr = task->buffer;
+    // this seek won't work if two tasks are reading from the same file at the same time,
+    // so we lock here. This makes multiple reads from a single file serialize, but different
+    // files will still run in parallel. An app can also open the same file twice to avoid this.
+    SDL_LockMutex(data->lock);
+    if (task->type == SDL_ASYNCIO_TASK_CLOSE) {
+        bool okay = true;
+        if (task->flush) {
+            okay = SDL_FlushIO(data->io);
+        }
+        okay = SDL_CloseIO(data->io) && okay;
+        task->result = okay ? SDL_ASYNCIO_COMPLETE : SDL_ASYNCIO_FAILURE;
+    } else if (SDL_SeekIO(io, (Sint64) task->offset, SDL_IO_SEEK_SET) < 0) {
+        task->result = SDL_ASYNCIO_FAILURE;
+    } else {
+        const bool writing = (task->type == SDL_ASYNCIO_TASK_WRITE);
+        task->result_size = (Uint64) (writing ? SDL_WriteIO(io, ptr, size) : SDL_ReadIO(io, ptr, size));
+        if (task->result_size == task->requested_size) {
+            task->result = SDL_ASYNCIO_COMPLETE;
+        } else {
+            if (writing) {
+                task->result = SDL_ASYNCIO_FAILURE;  // it's always a failure on short writes.
+            } else {
+                const SDL_IOStatus status = SDL_GetIOStatus(io);
+                SDL_assert(status != SDL_IO_STATUS_READY);  // this should have either failed or been EOF.
+                SDL_assert(status != SDL_IO_STATUS_NOT_READY);  // these should not be non-blocking reads!
+                task->result = (status == SDL_IO_STATUS_EOF) ? SDL_ASYNCIO_COMPLETE : SDL_ASYNCIO_FAILURE;
+            }
+        }
+    }
+    SDL_UnlockMutex(data->lock);
+    AsyncIOTaskComplete(task);
+}
+#if SDL_ASYNCIO_USE_THREADPOOL
+static SDL_InitState threadpool_init;
+static SDL_Mutex *threadpool_lock = NULL;
+static bool stop_threadpool = false;
+static SDL_AsyncIOTask threadpool_tasks;
+static SDL_Condition *threadpool_condition = NULL;
+static int max_threadpool_threads = 0;
+static int running_threadpool_threads = 0;
+static int idle_threadpool_threads = 0;
+static int threadpool_threads_spun = 0;
+static int SDLCALL AsyncIOThreadpoolWorker(void *data)
+{
+    SDL_LockMutex(threadpool_lock);
+    while (!stop_threadpool) {
+        SDL_AsyncIOTask *task = LINKED_LIST_START(threadpool_tasks, threadpool);
+        if (!task) {
+            // if we go 30 seconds without a new task, terminate unless we're the only thread left.
+            idle_threadpool_threads++;
+            const bool rc = SDL_WaitConditionTimeout(threadpool_condition, threadpool_lock, 30000);
+            idle_threadpool_threads--;
+            if (!rc) {
+                // decide if we have too many idle threads, and if so, quit to let thread pool shrink when not busy.
+                if (idle_threadpool_threads) {
+                    break;
+                }
+            }
+            continue;
+        }
+        LINKED_LIST_UNLINK(task, threadpool);
+        SDL_UnlockMutex(threadpool_lock);
+        // bookkeeping is done, so we drop the mutex and fire the work.
+        SynchronousIO(task);
+        SDL_LockMutex(threadpool_lock);  // take the lock again and see if there's another task (if not, we'll wait on the Condition).
+    }
+    running_threadpool_threads--;
+    // this is kind of a hack, but this lets us reuse threadpool_condition to block on shutdown until all threads have exited.
+    if (stop_threadpool) {
+        SDL_BroadcastCondition(threadpool_condition);
+    }
+    SDL_UnlockMutex(threadpool_lock);
+    return 0;
+}
+static bool MaybeSpinNewWorkerThread(void)
+{
+    // if all existing threads are busy and the pool of threads isn't maxed out, make a new one.
+    if ((idle_threadpool_threads == 0) && (running_threadpool_threads < max_threadpool_threads)) {
+        char threadname[32];
+        SDL_snprintf(threadname, sizeof (threadname), "SDLasyncio%d", threadpool_threads_spun);
+        SDL_Thread *thread = SDL_CreateThread(AsyncIOThreadpoolWorker, threadname, NULL);
+        if (thread == NULL) {
+            return false;
+        }
+        SDL_DetachThread(thread);  // these terminate themselves when idle too long, so we never WaitThread.
+        running_threadpool_threads++;
+        threadpool_threads_spun++;
+    }
+    return true;
+}
+static void QueueAsyncIOTask(SDL_AsyncIOTask *task)
+{
+    SDL_assert(task != NULL);
+    SDL_LockMutex(threadpool_lock);
+    if (stop_threadpool) {  // just in case.
+        task->result = SDL_ASYNCIO_CANCELED;
+        AsyncIOTaskComplete(task);
+    } else {
+        LINKED_LIST_PREPEND(task, threadpool_tasks, threadpool);
+        MaybeSpinNewWorkerThread();  // okay if this fails or the thread pool is maxed out. Something will get there eventually.
+        // tell idle threads to get to work.
+        // This is a broadcast because we want someone from the thread pool to wake up, but
+        // also shutdown might also be blocking on this. One of the threads will grab
+        // it, the others will go back to sleep.
+        SDL_BroadcastCondition(threadpool_condition);
+    }
+    SDL_UnlockMutex(threadpool_lock);
+}
+// We don't initialize async i/o at all until it's used, so
+//  JUST IN CASE two things try to start at the same time,
+//  this will make sure everything gets the same mutex.
+static bool PrepareThreadpool(void)
+{
+    bool okay = true;
+    if (SDL_ShouldInit(&threadpool_init)) {
+        max_threadpool_threads = (SDL_GetNumLogicalCPUCores() * 2) + 1;  // !!! FIXME: this should probably have a hint to override.
+        max_threadpool_threads = SDL_clamp(max_threadpool_threads, 1, 8);  // 8 is probably more than enough.
+        okay = (okay && ((threadpool_lock = SDL_CreateMutex()) != NULL));
+        okay = (okay && ((threadpool_condition = SDL_CreateCondition()) != NULL));
+        okay = (okay && MaybeSpinNewWorkerThread());  // make sure at least one thread is going, since we'll need it.
+        if (!okay) {
+            if (threadpool_condition) {
+                SDL_DestroyCondition(threadpool_condition);
+                threadpool_condition = NULL;
+            }
+            if (threadpool_lock) {
+                SDL_DestroyMutex(threadpool_lock);
+                threadpool_lock = NULL;
+            }
+        }
+        SDL_SetInitialized(&threadpool_init, okay);
+    }
+    return okay;
+}
+static void ShutdownThreadpool(void)
+{
+    if (SDL_ShouldQuit(&threadpool_init)) {
+        SDL_LockMutex(threadpool_lock);
+        // cancel anything that's still pending.
+        SDL_AsyncIOTask *task;
+        while ((task = LINKED_LIST_START(threadpool_tasks, threadpool)) != NULL) {
+            LINKED_LIST_UNLINK(task, threadpool);
+            task->result = SDL_ASYNCIO_CANCELED;
+            AsyncIOTaskComplete(task);
+        }
+        stop_threadpool = true;
+        SDL_BroadcastCondition(threadpool_condition);  // tell the whole threadpool to wake up and quit.
+        while (running_threadpool_threads > 0) {
+            // each threadpool thread will broadcast this condition before it terminates if stop_threadpool is set.
+            // we can't just join the threads because they are detached, so the thread pool can automatically shrink as necessary.
+            SDL_WaitCondition(threadpool_condition, threadpool_lock);
+        }
+        SDL_UnlockMutex(threadpool_lock);
+        SDL_DestroyMutex(threadpool_lock);
+        threadpool_lock = NULL;
+        SDL_DestroyCondition(threadpool_condition);
+        threadpool_condition = NULL;
+        max_threadpool_threads = running_threadpool_threads = idle_threadpool_threads = threadpool_threads_spun = 0;
+        stop_threadpool = false;
+        SDL_SetInitialized(&threadpool_init, false);
+    }
+}
+#endif
+static Sint64 generic_asyncio_size(void *userdata)
+{
+    GenericAsyncIOData *data = (GenericAsyncIOData *) userdata;
+    return SDL_GetIOSize(data->io);
+}
+static bool generic_asyncio_io(void *userdata, SDL_AsyncIOTask *task)
+{
+    return task->queue->iface.queue_task(task->queue->userdata, task);
+}
+static void generic_asyncio_destroy(void *userdata)
+{
+    GenericAsyncIOData *data = (GenericAsyncIOData *) userdata;
+    SDL_DestroyMutex(data->lock);
+    SDL_free(data);
+}
+static bool generic_asyncioqueue_queue_task(void *userdata, SDL_AsyncIOTask *task)
+{
+    #if SDL_ASYNCIO_USE_THREADPOOL
+    QueueAsyncIOTask(task);
+    #else
+    SynchronousIO(task);  // oh well. Get a better platform.
+    #endif
+    return true;
+}
+static void generic_asyncioqueue_cancel_task(void *userdata, SDL_AsyncIOTask *task)
+{
+    #if !SDL_ASYNCIO_USE_THREADPOOL  // in theory, this was all synchronous and should never call this, but just in case.
+    task->result = SDL_ASYNCIO_CANCELED;
+    AsyncIOTaskComplete(task);
+    #else
+    // we can't stop i/o that's in-flight, but we _can_ just refuse to start it if the threadpool hadn't picked it up yet.
+    SDL_LockMutex(threadpool_lock);
+    if (LINKED_LIST_PREV(task, threadpool) != NULL) {  // still in the queue waiting to be run? Take it out.
+        LINKED_LIST_UNLINK(task, threadpool);
+        task->result = SDL_ASYNCIO_CANCELED;
+        AsyncIOTaskComplete(task);
+    }
+    SDL_UnlockMutex(threadpool_lock);
+    #endif
+}
+static SDL_AsyncIOTask *generic_asyncioqueue_get_results(void *userdata)
+{
+    GenericAsyncIOQueueData *data = (GenericAsyncIOQueueData *) userdata;
+    SDL_LockMutex(data->lock);
+    SDL_AsyncIOTask *task = LINKED_LIST_START(data->completed_tasks, queue);
+    if (task) {
+        LINKED_LIST_UNLINK(task, queue);
+    }
+    SDL_UnlockMutex(data->lock);
+    return task;
+}
+static SDL_AsyncIOTask *generic_asyncioqueue_wait_results(void *userdata, Sint32 timeoutMS)
+{
+    GenericAsyncIOQueueData *data = (GenericAsyncIOQueueData *) userdata;
+    SDL_LockMutex(data->lock);
+    SDL_AsyncIOTask *task = LINKED_LIST_START(data->completed_tasks, queue);
+    if (!task) {
+        SDL_WaitConditionTimeout(data->condition, data->lock, timeoutMS);
+        task = LINKED_LIST_START(data->completed_tasks, queue);
+    }
+    if (task) {
+        LINKED_LIST_UNLINK(task, queue);
+    }
+    SDL_UnlockMutex(data->lock);
+    return task;
+}
+static void generic_asyncioqueue_signal(void *userdata)
+{
+    GenericAsyncIOQueueData *data = (GenericAsyncIOQueueData *) userdata;
+    SDL_LockMutex(data->lock);
+    SDL_BroadcastCondition(data->condition);
+    SDL_UnlockMutex(data->lock);
+}
+static void generic_asyncioqueue_destroy(void *userdata)
+{
+    GenericAsyncIOQueueData *data = (GenericAsyncIOQueueData *) userdata;
+    SDL_DestroyMutex(data->lock);
+    SDL_DestroyCondition(data->condition);
+    SDL_free(data);
+}
+bool SDL_SYS_CreateAsyncIOQueue_Generic(SDL_AsyncIOQueue *queue)
+{
+    #if SDL_ASYNCIO_USE_THREADPOOL
+    if (!PrepareThreadpool()) {
+        return false;
+    }
+    #endif
+    GenericAsyncIOQueueData *data = (GenericAsyncIOQueueData *) SDL_calloc(1, sizeof (*data));
+    if (!data) {
+        return false;
+    }
+    data->lock = SDL_CreateMutex();
+    if (!data->lock) {
+        SDL_free(data);
+        return false;
+    }
+    data->condition = SDL_CreateCondition();
+    if (!data->condition) {
+        SDL_DestroyMutex(data->lock);
+        SDL_free(data);
+        return false;
+    }
+    static const SDL_AsyncIOQueueInterface SDL_AsyncIOQueue_Generic = {
+        generic_asyncioqueue_queue_task,
+        generic_asyncioqueue_cancel_task,
+        generic_asyncioqueue_get_results,
+        generic_asyncioqueue_wait_results,
+        generic_asyncioqueue_signal,
+        generic_asyncioqueue_destroy
+    };
+    SDL_copyp(&queue->iface, &SDL_AsyncIOQueue_Generic);
+    queue->userdata = data;
+    return true;
+}
+bool SDL_SYS_AsyncIOFromFile_Generic(const char *file, const char *mode, SDL_AsyncIO *asyncio)
+{
+    #if SDL_ASYNCIO_USE_THREADPOOL
+    if (!PrepareThreadpool()) {
+        return false;
+    }
+    #endif
+    GenericAsyncIOData *data = (GenericAsyncIOData *) SDL_calloc(1, sizeof (*data));
+    if (!data) {
+        return false;
+    }
+    data->lock = SDL_CreateMutex();
+    if (!data->lock) {
+        SDL_free(data);
+        return false;
+    }
+    data->io = SDL_IOFromFile(file, mode);
+    if (!data->io) {
+        SDL_DestroyMutex(data->lock);
+        SDL_free(data);
+        return false;
+    }
+    static const SDL_AsyncIOInterface SDL_AsyncIOFile_Generic = {
+        generic_asyncio_size,
+        generic_asyncio_io,
+        generic_asyncio_io,
+        generic_asyncio_io,
+        generic_asyncio_destroy
+    };
+    SDL_copyp(&asyncio->iface, &SDL_AsyncIOFile_Generic);
+    asyncio->userdata = data;
+    return true;
+}
+void SDL_SYS_QuitAsyncIO_Generic(void)
+{
+    #if SDL_ASYNCIO_USE_THREADPOOL
+    ShutdownThreadpool();
+    #endif
+}
+#if SDL_ASYNCIO_ONLY_HAVE_GENERIC
+bool SDL_SYS_AsyncIOFromFile(const char *file, const char *mode, SDL_AsyncIO *asyncio)
+{
+    return SDL_SYS_AsyncIOFromFile_Generic(file, mode, asyncio);
+}
+bool SDL_SYS_CreateAsyncIOQueue(SDL_AsyncIOQueue *queue)
+{
+    return SDL_SYS_CreateAsyncIOQueue_Generic(queue);
+}
+void SDL_SYS_QuitAsyncIO(void)
+{
+    SDL_SYS_QuitAsyncIO_Generic();
+}
+#endif

diff --git a/contrib/SDL-3.2.8/src/io/generic/SDL_asyncio_generic.c b/contrib/SDL-3.2.8/src/io/generic/SDL_asyncio_generic.c new file mode 100644 index 0000000..4c2a562 --- /dev/null +++ b/contrib/SDL-3.2.8/src/io/generic/SDL_asyncio_generic.c
@@ -0,0 +1,465 @@
	1	/*
	2	Simple DirectMedia Layer
	3	Copyright (C) 1997-2025 Sam Lantinga <slouken@libsdl.org>
	4
	5	This software is provided 'as-is', without any express or implied
	6	warranty. In no event will the authors be held liable for any damages
	7	arising from the use of this software.
	8
	9	Permission is granted to anyone to use this software for any purpose,
	10	including commercial applications, and to alter it and redistribute it
	11	freely, subject to the following restrictions:
	12
	13	1. The origin of this software must not be misrepresented; you must not
	14	claim that you wrote the original software. If you use this software
	15	in a product, an acknowledgment in the product documentation would be
	16	appreciated but is not required.
	17	2. Altered source versions must be plainly marked as such, and must not be
	18	misrepresented as being the original software.
	19	3. This notice may not be removed or altered from any source distribution.
	20	*/
	21
	22	// The generic backend uses a threadpool to block on synchronous i/o.
	23	// This is not ideal, it's meant to be used if there isn't a platform-specific
	24	// backend that can do something more efficient!
	25
	26	#include "SDL_internal.h"
	27	#include "../SDL_sysasyncio.h"
	28
	29	// on Emscripten without threads, async i/o is synchronous. Sorry. Almost
	30	// everything is MEMFS, so it's just a memcpy anyhow, and the Emscripten
	31	// filesystem APIs don't offer async. In theory, directly accessing
	32	// persistent storage _does_ offer async APIs at the browser level, but
	33	// that's not exposed in Emscripten's filesystem abstraction.
	34	#if defined(SDL_PLATFORM_EMSCRIPTEN) && !defined(__EMSCRIPTEN_PTHREADS__)
	35	#define SDL_ASYNCIO_USE_THREADPOOL 0
	36	#else
	37	#define SDL_ASYNCIO_USE_THREADPOOL 1
	38	#endif
	39
	40	typedef struct GenericAsyncIOQueueData
	41	{
	42	SDL_Mutex *lock;
	43	SDL_Condition *condition;
	44	SDL_AsyncIOTask completed_tasks;
	45	} GenericAsyncIOQueueData;
	46
	47	typedef struct GenericAsyncIOData
	48	{
	49	SDL_Mutex *lock; // !!! FIXME: we can skip this lock if we have an equivalent of pread/pwrite
	50	SDL_IOStream *io;
	51	} GenericAsyncIOData;
	52
	53	static void AsyncIOTaskComplete(SDL_AsyncIOTask *task)
	54	{
	55	SDL_assert(task->queue);
	56	GenericAsyncIOQueueData data = (GenericAsyncIOQueueData ) task->queue->userdata;
	57	SDL_LockMutex(data->lock);
	58	LINKED_LIST_PREPEND(task, data->completed_tasks, queue);
	59	SDL_SignalCondition(data->condition); // wake a thread waiting on the queue.
	60	SDL_UnlockMutex(data->lock);
	61	}
	62
	63	// synchronous i/o is offloaded onto the threadpool. This function does the threaded work.
	64	// This is called directly, without a threadpool, if !SDL_ASYNCIO_USE_THREADPOOL.
	65	static void SynchronousIO(SDL_AsyncIOTask *task)
	66	{
	67	SDL_assert(task->result != SDL_ASYNCIO_CANCELED); // shouldn't have gotten in here if canceled!
	68
	69	GenericAsyncIOData data = (GenericAsyncIOData ) task->asyncio->userdata;
	70	SDL_IOStream *io = data->io;
	71	const size_t size = (size_t) task->requested_size;
	72	void *ptr = task->buffer;
	73
	74	// this seek won't work if two tasks are reading from the same file at the same time,
	75	// so we lock here. This makes multiple reads from a single file serialize, but different
	76	// files will still run in parallel. An app can also open the same file twice to avoid this.
	77	SDL_LockMutex(data->lock);
	78	if (task->type == SDL_ASYNCIO_TASK_CLOSE) {
	79	bool okay = true;
	80	if (task->flush) {
	81	okay = SDL_FlushIO(data->io);
	82	}
	83	okay = SDL_CloseIO(data->io) && okay;
	84	task->result = okay ? SDL_ASYNCIO_COMPLETE : SDL_ASYNCIO_FAILURE;
	85	} else if (SDL_SeekIO(io, (Sint64) task->offset, SDL_IO_SEEK_SET) < 0) {
	86	task->result = SDL_ASYNCIO_FAILURE;
	87	} else {
	88	const bool writing = (task->type == SDL_ASYNCIO_TASK_WRITE);
	89	task->result_size = (Uint64) (writing ? SDL_WriteIO(io, ptr, size) : SDL_ReadIO(io, ptr, size));
	90	if (task->result_size == task->requested_size) {
	91	task->result = SDL_ASYNCIO_COMPLETE;
	92	} else {
	93	if (writing) {
	94	task->result = SDL_ASYNCIO_FAILURE; // it's always a failure on short writes.
	95	} else {
	96	const SDL_IOStatus status = SDL_GetIOStatus(io);
	97	SDL_assert(status != SDL_IO_STATUS_READY); // this should have either failed or been EOF.
	98	SDL_assert(status != SDL_IO_STATUS_NOT_READY); // these should not be non-blocking reads!
	99	task->result = (status == SDL_IO_STATUS_EOF) ? SDL_ASYNCIO_COMPLETE : SDL_ASYNCIO_FAILURE;
	100	}
	101	}
	102	}
	103	SDL_UnlockMutex(data->lock);
	104
	105	AsyncIOTaskComplete(task);
	106	}
	107
	108	#if SDL_ASYNCIO_USE_THREADPOOL
	109	static SDL_InitState threadpool_init;
	110	static SDL_Mutex *threadpool_lock = NULL;
	111	static bool stop_threadpool = false;
	112	static SDL_AsyncIOTask threadpool_tasks;
	113	static SDL_Condition *threadpool_condition = NULL;
	114	static int max_threadpool_threads = 0;
	115	static int running_threadpool_threads = 0;
	116	static int idle_threadpool_threads = 0;
	117	static int threadpool_threads_spun = 0;
	118
	119	static int SDLCALL AsyncIOThreadpoolWorker(void *data)
	120	{
	121	SDL_LockMutex(threadpool_lock);
	122
	123	while (!stop_threadpool) {
	124	SDL_AsyncIOTask *task = LINKED_LIST_START(threadpool_tasks, threadpool);
	125	if (!task) {
	126	// if we go 30 seconds without a new task, terminate unless we're the only thread left.
	127	idle_threadpool_threads++;
	128	const bool rc = SDL_WaitConditionTimeout(threadpool_condition, threadpool_lock, 30000);
	129	idle_threadpool_threads--;
	130
	131	if (!rc) {
	132	// decide if we have too many idle threads, and if so, quit to let thread pool shrink when not busy.
	133	if (idle_threadpool_threads) {
	134	break;
	135	}
	136	}
	137
	138	continue;
	139	}
	140
	141	LINKED_LIST_UNLINK(task, threadpool);
	142
	143	SDL_UnlockMutex(threadpool_lock);
	144
	145	// bookkeeping is done, so we drop the mutex and fire the work.
	146	SynchronousIO(task);
	147
	148	SDL_LockMutex(threadpool_lock); // take the lock again and see if there's another task (if not, we'll wait on the Condition).
	149	}
	150
	151	running_threadpool_threads--;
	152
	153	// this is kind of a hack, but this lets us reuse threadpool_condition to block on shutdown until all threads have exited.
	154	if (stop_threadpool) {
	155	SDL_BroadcastCondition(threadpool_condition);
	156	}
	157
	158	SDL_UnlockMutex(threadpool_lock);
	159
	160	return 0;
	161	}
	162
	163	static bool MaybeSpinNewWorkerThread(void)
	164	{
	165	// if all existing threads are busy and the pool of threads isn't maxed out, make a new one.
	166	if ((idle_threadpool_threads == 0) && (running_threadpool_threads < max_threadpool_threads)) {
	167	char threadname[32];
	168	SDL_snprintf(threadname, sizeof (threadname), "SDLasyncio%d", threadpool_threads_spun);
	169	SDL_Thread *thread = SDL_CreateThread(AsyncIOThreadpoolWorker, threadname, NULL);
	170	if (thread == NULL) {
	171	return false;
	172	}
	173	SDL_DetachThread(thread); // these terminate themselves when idle too long, so we never WaitThread.
	174	running_threadpool_threads++;
	175	threadpool_threads_spun++;
	176	}
	177	return true;
	178	}
	179
	180	static void QueueAsyncIOTask(SDL_AsyncIOTask *task)
	181	{
	182	SDL_assert(task != NULL);
	183
	184	SDL_LockMutex(threadpool_lock);
	185
	186	if (stop_threadpool) { // just in case.
	187	task->result = SDL_ASYNCIO_CANCELED;
	188	AsyncIOTaskComplete(task);
	189	} else {
	190	LINKED_LIST_PREPEND(task, threadpool_tasks, threadpool);
	191	MaybeSpinNewWorkerThread(); // okay if this fails or the thread pool is maxed out. Something will get there eventually.
	192
	193	// tell idle threads to get to work.
	194	// This is a broadcast because we want someone from the thread pool to wake up, but
	195	// also shutdown might also be blocking on this. One of the threads will grab
	196	// it, the others will go back to sleep.
	197	SDL_BroadcastCondition(threadpool_condition);
	198	}
	199
	200	SDL_UnlockMutex(threadpool_lock);
	201	}
	202
	203	// We don't initialize async i/o at all until it's used, so
	204	// JUST IN CASE two things try to start at the same time,
	205	// this will make sure everything gets the same mutex.
	206	static bool PrepareThreadpool(void)
	207	{
	208	bool okay = true;
	209	if (SDL_ShouldInit(&threadpool_init)) {
	210	max_threadpool_threads = (SDL_GetNumLogicalCPUCores() * 2) + 1; // !!! FIXME: this should probably have a hint to override.
	211	max_threadpool_threads = SDL_clamp(max_threadpool_threads, 1, 8); // 8 is probably more than enough.
	212
	213	okay = (okay && ((threadpool_lock = SDL_CreateMutex()) != NULL));
	214	okay = (okay && ((threadpool_condition = SDL_CreateCondition()) != NULL));
	215	okay = (okay && MaybeSpinNewWorkerThread()); // make sure at least one thread is going, since we'll need it.
	216
	217	if (!okay) {
	218	if (threadpool_condition) {
	219	SDL_DestroyCondition(threadpool_condition);
	220	threadpool_condition = NULL;
	221	}
	222	if (threadpool_lock) {
	223	SDL_DestroyMutex(threadpool_lock);
	224	threadpool_lock = NULL;
	225	}
	226	}
	227
	228	SDL_SetInitialized(&threadpool_init, okay);
	229	}
	230	return okay;
	231	}
	232
	233	static void ShutdownThreadpool(void)
	234	{
	235	if (SDL_ShouldQuit(&threadpool_init)) {
	236	SDL_LockMutex(threadpool_lock);
	237
	238	// cancel anything that's still pending.
	239	SDL_AsyncIOTask *task;
	240	while ((task = LINKED_LIST_START(threadpool_tasks, threadpool)) != NULL) {
	241	LINKED_LIST_UNLINK(task, threadpool);
	242	task->result = SDL_ASYNCIO_CANCELED;
	243	AsyncIOTaskComplete(task);
	244	}
	245
	246	stop_threadpool = true;
	247	SDL_BroadcastCondition(threadpool_condition); // tell the whole threadpool to wake up and quit.
	248
	249	while (running_threadpool_threads > 0) {
	250	// each threadpool thread will broadcast this condition before it terminates if stop_threadpool is set.
	251	// we can't just join the threads because they are detached, so the thread pool can automatically shrink as necessary.
	252	SDL_WaitCondition(threadpool_condition, threadpool_lock);
	253	}
	254
	255	SDL_UnlockMutex(threadpool_lock);
	256
	257	SDL_DestroyMutex(threadpool_lock);
	258	threadpool_lock = NULL;
	259	SDL_DestroyCondition(threadpool_condition);
	260	threadpool_condition = NULL;
	261
	262	max_threadpool_threads = running_threadpool_threads = idle_threadpool_threads = threadpool_threads_spun = 0;
	263
	264	stop_threadpool = false;
	265	SDL_SetInitialized(&threadpool_init, false);
	266	}
	267	}
	268	#endif
	269
	270
	271	static Sint64 generic_asyncio_size(void *userdata)
	272	{
	273	GenericAsyncIOData data = (GenericAsyncIOData ) userdata;
	274	return SDL_GetIOSize(data->io);
	275	}
	276
	277	static bool generic_asyncio_io(void userdata, SDL_AsyncIOTask task)
	278	{
	279	return task->queue->iface.queue_task(task->queue->userdata, task);
	280	}
	281
	282	static void generic_asyncio_destroy(void *userdata)
	283	{
	284	GenericAsyncIOData data = (GenericAsyncIOData ) userdata;
	285	SDL_DestroyMutex(data->lock);
	286	SDL_free(data);
	287	}
	288
	289
	290	static bool generic_asyncioqueue_queue_task(void userdata, SDL_AsyncIOTask task)
	291	{
	292	#if SDL_ASYNCIO_USE_THREADPOOL
	293	QueueAsyncIOTask(task);
	294	#else
	295	SynchronousIO(task); // oh well. Get a better platform.
	296	#endif
	297	return true;
	298	}
	299
	300	static void generic_asyncioqueue_cancel_task(void userdata, SDL_AsyncIOTask task)
	301	{
	302	#if !SDL_ASYNCIO_USE_THREADPOOL // in theory, this was all synchronous and should never call this, but just in case.
	303	task->result = SDL_ASYNCIO_CANCELED;
	304	AsyncIOTaskComplete(task);
	305	#else
	306	// we can't stop i/o that's in-flight, but we _can_ just refuse to start it if the threadpool hadn't picked it up yet.
	307	SDL_LockMutex(threadpool_lock);
	308	if (LINKED_LIST_PREV(task, threadpool) != NULL) { // still in the queue waiting to be run? Take it out.
	309	LINKED_LIST_UNLINK(task, threadpool);
	310	task->result = SDL_ASYNCIO_CANCELED;
	311	AsyncIOTaskComplete(task);
	312	}
	313	SDL_UnlockMutex(threadpool_lock);
	314	#endif
	315	}
	316
	317	static SDL_AsyncIOTask generic_asyncioqueue_get_results(void userdata)
	318	{
	319	GenericAsyncIOQueueData data = (GenericAsyncIOQueueData ) userdata;
	320	SDL_LockMutex(data->lock);
	321	SDL_AsyncIOTask *task = LINKED_LIST_START(data->completed_tasks, queue);
	322	if (task) {
	323	LINKED_LIST_UNLINK(task, queue);
	324	}
	325	SDL_UnlockMutex(data->lock);
	326	return task;
	327	}
	328
	329	static SDL_AsyncIOTask generic_asyncioqueue_wait_results(void userdata, Sint32 timeoutMS)
	330	{
	331	GenericAsyncIOQueueData data = (GenericAsyncIOQueueData ) userdata;
	332	SDL_LockMutex(data->lock);
	333	SDL_AsyncIOTask *task = LINKED_LIST_START(data->completed_tasks, queue);
	334	if (!task) {
	335	SDL_WaitConditionTimeout(data->condition, data->lock, timeoutMS);
	336	task = LINKED_LIST_START(data->completed_tasks, queue);
	337	}
	338	if (task) {
	339	LINKED_LIST_UNLINK(task, queue);
	340	}
	341	SDL_UnlockMutex(data->lock);
	342	return task;
	343	}
	344
	345	static void generic_asyncioqueue_signal(void *userdata)
	346	{
	347	GenericAsyncIOQueueData data = (GenericAsyncIOQueueData ) userdata;
	348	SDL_LockMutex(data->lock);
	349	SDL_BroadcastCondition(data->condition);
	350	SDL_UnlockMutex(data->lock);
	351	}
	352
	353	static void generic_asyncioqueue_destroy(void *userdata)
	354	{
	355	GenericAsyncIOQueueData data = (GenericAsyncIOQueueData ) userdata;
	356	SDL_DestroyMutex(data->lock);
	357	SDL_DestroyCondition(data->condition);
	358	SDL_free(data);
	359	}
	360
	361	bool SDL_SYS_CreateAsyncIOQueue_Generic(SDL_AsyncIOQueue *queue)
	362	{
	363	#if SDL_ASYNCIO_USE_THREADPOOL
	364	if (!PrepareThreadpool()) {
	365	return false;
	366	}
	367	#endif
	368
	369	GenericAsyncIOQueueData data = (GenericAsyncIOQueueData ) SDL_calloc(1, sizeof (*data));
	370	if (!data) {
	371	return false;
	372	}
	373
	374	data->lock = SDL_CreateMutex();
	375	if (!data->lock) {
	376	SDL_free(data);
	377	return false;
	378	}
	379
	380	data->condition = SDL_CreateCondition();
	381	if (!data->condition) {
	382	SDL_DestroyMutex(data->lock);
	383	SDL_free(data);
	384	return false;
	385	}
	386
	387	static const SDL_AsyncIOQueueInterface SDL_AsyncIOQueue_Generic = {
	388	generic_asyncioqueue_queue_task,
	389	generic_asyncioqueue_cancel_task,
	390	generic_asyncioqueue_get_results,
	391	generic_asyncioqueue_wait_results,
	392	generic_asyncioqueue_signal,
	393	generic_asyncioqueue_destroy
	394	};
	395
	396	SDL_copyp(&queue->iface, &SDL_AsyncIOQueue_Generic);
	397	queue->userdata = data;
	398	return true;
	399	}
	400
	401
	402	bool SDL_SYS_AsyncIOFromFile_Generic(const char file, const char mode, SDL_AsyncIO *asyncio)
	403	{
	404	#if SDL_ASYNCIO_USE_THREADPOOL
	405	if (!PrepareThreadpool()) {
	406	return false;
	407	}
	408	#endif
	409
	410	GenericAsyncIOData data = (GenericAsyncIOData ) SDL_calloc(1, sizeof (*data));
	411	if (!data) {
	412	return false;
	413	}
	414
	415	data->lock = SDL_CreateMutex();
	416	if (!data->lock) {
	417	SDL_free(data);
	418	return false;
	419	}
	420
	421	data->io = SDL_IOFromFile(file, mode);
	422	if (!data->io) {
	423	SDL_DestroyMutex(data->lock);
	424	SDL_free(data);
	425	return false;
	426	}
	427
	428	static const SDL_AsyncIOInterface SDL_AsyncIOFile_Generic = {
	429	generic_asyncio_size,
	430	generic_asyncio_io,
	431	generic_asyncio_io,
	432	generic_asyncio_io,
	433	generic_asyncio_destroy
	434	};
	435
	436	SDL_copyp(&asyncio->iface, &SDL_AsyncIOFile_Generic);
	437	asyncio->userdata = data;
	438	return true;
	439	}
	440
	441	void SDL_SYS_QuitAsyncIO_Generic(void)
	442	{
	443	#if SDL_ASYNCIO_USE_THREADPOOL
	444	ShutdownThreadpool();
	445	#endif
	446	}
	447
	448
	449	#if SDL_ASYNCIO_ONLY_HAVE_GENERIC
	450	bool SDL_SYS_AsyncIOFromFile(const char file, const char mode, SDL_AsyncIO *asyncio)
	451	{
	452	return SDL_SYS_AsyncIOFromFile_Generic(file, mode, asyncio);
	453	}
	454
	455	bool SDL_SYS_CreateAsyncIOQueue(SDL_AsyncIOQueue *queue)
	456	{
	457	return SDL_SYS_CreateAsyncIOQueue_Generic(queue);
	458	}
	459
	460	void SDL_SYS_QuitAsyncIO(void)
	461	{
	462	SDL_SYS_QuitAsyncIO_Generic();
	463	}
	464	#endif
	465