linux new job queue stuff

master
insofaras 2016-07-28 19:09:08 +01:00
parent 468fe81f61
commit 56ece67eed
1 changed files with 364 additions and 34 deletions

View File

@ -103,6 +103,8 @@
#define SUPPORT_DPI 1
#define LINUX_FONTS 1
#define InterlockedCompareExchange(dest, ex, comp) __sync_val_compare_and_swap((dest), (comp), (ex))
//
// Linux structs / enums
//
@ -148,6 +150,8 @@ struct Thread_Group{
Thread_Context *threads;
i32 count;
Unbounded_Work_Queue queue;
i32 cancel_lock0;
i32 cancel_cv0;
};
@ -252,6 +256,9 @@ internal void LinuxStringDup(String*, void*, size_t);
internal Sys_Acquire_Lock_Sig(system_acquire_lock);
internal Sys_Release_Lock_Sig(system_release_lock);
internal void system_wait_cv(i32, i32);
internal void system_signal_cv(i32, i32);
//
// Linux static assertions
//
@ -983,8 +990,11 @@ Sys_CLI_End_Update_Sig(system_cli_end_update){
// Threads
//
//#define OLD_JOB_QUEUE
#ifdef OLD_JOB_QUEUE
internal void*
ThreadProc(void* arg){
JobThreadProc(void* arg){
Thread_Context *thread = (Thread_Context*)arg;
Work_Queue *queue = linuxvars.queues + thread->group_id;
Thread_Group *group = linuxvars.groups + thread->group_id;
@ -1007,20 +1017,20 @@ ThreadProc(void* arg){
u32 write_index = queue->write_position;
if (read_index != write_index){
u32 next_read_index = (read_index + 1) % JOB_ID_WRAP;
u32 next_read_index = (read_index + 1) % QUEUE_WRAP;
u32 safe_read_index =
__sync_val_compare_and_swap(&queue->read_position,
read_index, next_read_index);
__sync_val_compare_and_swap(&queue->read_position,
read_index, next_read_index);
if (safe_read_index == read_index){
Full_Job_Data *full_job = queue->jobs + (safe_read_index % QUEUE_WRAP);
Full_Job_Data *full_job = queue->jobs + safe_read_index;
// NOTE(allen): This is interlocked so that it plays nice
// with the cancel job routine, which may try to cancel this job
// at the same time that we try to run it
i32 safe_running_thread =
__sync_val_compare_and_swap(&full_job->running_thread,
THREAD_NOT_ASSIGNED, thread->id);
__sync_val_compare_and_swap(&full_job->running_thread,
THREAD_NOT_ASSIGNED, thread->id);
if (safe_running_thread == THREAD_NOT_ASSIGNED){
thread->job_id = full_job->id;
@ -1057,10 +1067,10 @@ Sys_Post_Job_Sig(system_post_job){
u32 result = 0;
while (!success){
u32 write_index = queue->write_position;
u32 next_write_index = (write_index + 1) % JOB_ID_WRAP;
u32 next_write_index = (write_index + 1) % QUEUE_WRAP;
u32 safe_write_index =
__sync_val_compare_and_swap(&queue->write_position,
write_index, next_write_index);
__sync_val_compare_and_swap(&queue->write_position,
write_index, next_write_index);
if (safe_write_index == write_index){
result = write_index;
write_index = write_index % QUEUE_WRAP;
@ -1081,17 +1091,13 @@ Sys_Cancel_Job_Sig(system_cancel_job){
Work_Queue *queue = linuxvars.queues + group_id;
Thread_Group *group = linuxvars.groups + group_id;
u32 job_index;
u32 thread_id;
Full_Job_Data *full_job;
job_index = job_id % QUEUE_WRAP;
full_job = queue->jobs + job_index;
u32 job_index = job_id % QUEUE_WRAP;
Full_Job_Data *full_job = queue->jobs + job_index;
Assert(full_job->id == job_id);
thread_id =
__sync_val_compare_and_swap(&full_job->running_thread,
THREAD_NOT_ASSIGNED, 0);
u32 thread_id =
__sync_val_compare_and_swap(&full_job->running_thread,
THREAD_NOT_ASSIGNED, 0);
if (thread_id != THREAD_NOT_ASSIGNED && thread_id != 0){
i32 thread_index = thread_id - 1;
@ -1151,6 +1157,299 @@ Sys_Grow_Thread_Memory_Sig(system_grow_thread_memory){
system_release_lock(CANCEL_LOCK0 + memory->id - 1);
}
#else // new job queue
internal void*
JobThreadProc(void* lpParameter){
Thread_Context *thread = (Thread_Context*)lpParameter;
Work_Queue *queue = linuxvars.queues + thread->group_id;
Thread_Group *group = linuxvars.groups + thread->group_id;
i32 thread_index = thread->id - 1;
i32 cancel_lock = group->cancel_lock0 + thread_index;
i32 cancel_cv = group->cancel_cv0 + thread_index;
Thread_Memory *thread_memory = linuxvars.thread_memory + thread_index;
if (thread_memory->size == 0){
i32 new_size = Kbytes(64);
thread_memory->data = LinuxGetMemory(new_size);
thread_memory->size = new_size;
}
for (;;){
u32 read_index = queue->read_position;
u32 write_index = queue->write_position;
if (read_index != write_index){
// NOTE(allen): Previously I was wrapping by the job wrap then
// wrapping by the queue wrap. That was super stupid what was that?
// Now it just wraps by the queue wrap.
u32 next_read_index = (read_index + 1) % QUEUE_WRAP;
u32 safe_read_index =
InterlockedCompareExchange(&queue->read_position,
next_read_index, read_index);
if (safe_read_index == read_index){
Full_Job_Data *full_job = queue->jobs + safe_read_index;
// NOTE(allen): This is interlocked so that it plays nice
// with the cancel job routine, which may try to cancel this job
// at the same time that we try to run it
i32 safe_running_thread =
InterlockedCompareExchange(&full_job->running_thread,
thread->id, THREAD_NOT_ASSIGNED);
if (safe_running_thread == THREAD_NOT_ASSIGNED){
thread->job_id = full_job->id;
thread->running = 1;
full_job->job.callback(&linuxvars.system,
thread, thread_memory, full_job->job.data);
LinuxScheduleStep();
//full_job->running_thread = 0;
thread->running = 0;
system_acquire_lock(cancel_lock);
if (thread->cancel){
thread->cancel = 0;
system_signal_cv(cancel_lock, cancel_cv);
}
system_release_lock(cancel_lock);
}
}
}
else{
sem_wait(LinuxHandleToSem(queue->semaphore));
}
}
}
internal void
initialize_unbounded_queue(Unbounded_Work_Queue *source_queue){
i32 max = 512;
source_queue->jobs = (Full_Job_Data*)system_get_memory(max*sizeof(Full_Job_Data));
source_queue->count = 0;
source_queue->max = max;
source_queue->skip = 0;
}
inline i32
get_work_queue_available_space(i32 write, i32 read){
// NOTE(allen): The only time that queue->write_position == queue->read_position
// is allowed is when the queue is empty. Thus if
// queue->write_position+1 == queue->read_position the available space is zero.
// So these computations both end up leaving one slot unused. The only way I can
// think to easily eliminate this is to have read and write wrap at twice the size
// of the underlying array but modulo their values into the array then if write
// has caught up with read it still will not be equal... but lots of modulos... ehh.
i32 available_space = 0;
if (write >= read){
available_space = QUEUE_WRAP - (write - read) - 1;
}
else{
available_space = (read - write) - 1;
}
return(available_space);
}
#define UNBOUNDED_SKIP_MAX 128
internal void
flush_to_direct_queue(Unbounded_Work_Queue *source_queue, Work_Queue *queue, i32 thread_count){
// NOTE(allen): It is understood that read_position may be changed by other
// threads but it will only make more space in the queue if it is changed.
// Meanwhile write_position should not ever be changed by anything but the
// main thread in this system, so it will not be interlocked.
u32 read_position = queue->read_position;
u32 write_position = queue->write_position;
u32 available_space = get_work_queue_available_space(write_position, read_position);
u32 available_jobs = source_queue->count - source_queue->skip;
u32 writable_count = Min(available_space, available_jobs);
if (writable_count > 0){
u32 count1 = writable_count;
if (count1+write_position > QUEUE_WRAP){
count1 = QUEUE_WRAP - write_position;
}
u32 count2 = writable_count - count1;
Full_Job_Data *job_src1 = source_queue->jobs + source_queue->skip;
Full_Job_Data *job_src2 = job_src1 + count1;
Full_Job_Data *job_dst1 = queue->jobs + write_position;
Full_Job_Data *job_dst2 = queue->jobs;
Assert((job_src1->id % QUEUE_WRAP) == write_position);
memcpy(job_dst1, job_src1, sizeof(Full_Job_Data)*count1);
memcpy(job_dst2, job_src2, sizeof(Full_Job_Data)*count2);
queue->write_position = (write_position + writable_count) % QUEUE_WRAP;
source_queue->skip += writable_count;
if (source_queue->skip == source_queue->count){
source_queue->skip = source_queue->count = 0;
}
else if (source_queue->skip > UNBOUNDED_SKIP_MAX){
u32 left_over = source_queue->count - source_queue->skip;
memmove(source_queue->jobs, source_queue->jobs + source_queue->skip,
sizeof(Full_Job_Data)*left_over);
source_queue->count = left_over;
source_queue->skip = 0;
}
}
i32 semaphore_release_count = writable_count;
if (semaphore_release_count > thread_count){
semaphore_release_count = thread_count;
}
// NOTE(allen): platform dependent portion...
// TODO(allen): pull out the duplicated part once I see
// that this is pretty much the same on linux.
for (i32 i = 0; i < semaphore_release_count; ++i){
sem_post(LinuxHandleToSem(queue->semaphore));
}
}
internal void
flush_thread_group(i32 group_id){
Thread_Group *group = linuxvars.groups + group_id;
Work_Queue *queue = linuxvars.queues + group_id;
Unbounded_Work_Queue *source_queue = &group->queue;
flush_to_direct_queue(source_queue, queue, group->count);
}
// Note(allen): post_job puts the job on the unbounded queue.
// The unbounded queue is entirely managed by the main thread.
// The thread safe queue is bounded in size so the unbounded
// queue is periodically flushed into the direct work queue.
internal
Sys_Post_Job_Sig(system_post_job){
Thread_Group *group = linuxvars.groups + group_id;
Unbounded_Work_Queue *queue = &group->queue;
u32 result = queue->next_job_id++;
while (queue->count >= queue->max){
i32 new_max = queue->max*2;
Full_Job_Data *new_jobs = (Full_Job_Data*)
system_get_memory(new_max*sizeof(Full_Job_Data));
memcpy(new_jobs, queue->jobs, queue->count);
system_free_memory(queue->jobs);
queue->jobs = new_jobs;
queue->max = new_max;
}
Full_Job_Data full_job;
full_job.job = job;
full_job.running_thread = THREAD_NOT_ASSIGNED;
full_job.id = result;
queue->jobs[queue->count++] = full_job;
Work_Queue *direct_queue = linuxvars.queues + group_id;
flush_to_direct_queue(queue, direct_queue, group->count);
return(result);
}
internal
Sys_Cancel_Job_Sig(system_cancel_job){
Thread_Group *group = linuxvars.groups + group_id;
Unbounded_Work_Queue *source_queue = &group->queue;
b32 handled_in_unbounded = false;
if (source_queue->skip < source_queue->count){
Full_Job_Data *first_job = source_queue->jobs + source_queue->skip;
if (first_job->id <= job_id){
u32 index = source_queue->skip + (job_id - first_job->id);
Full_Job_Data *job = source_queue->jobs + index;
job->running_thread = 0;
handled_in_unbounded = true;
}
}
if (!handled_in_unbounded){
Work_Queue *queue = linuxvars.queues + group_id;
Full_Job_Data *job = queue->jobs + (job_id % QUEUE_WRAP);
Assert(job->id == job_id);
u32 thread_id =
InterlockedCompareExchange(&job->running_thread,
0, THREAD_NOT_ASSIGNED);
if (thread_id != THREAD_NOT_ASSIGNED && thread_id != 0){
i32 thread_index = thread_id - 1;
i32 cancel_lock = group->cancel_lock0 + thread_index;
i32 cancel_cv = group->cancel_cv0 + thread_index;
Thread_Context *thread = group->threads + thread_index;
system_acquire_lock(cancel_lock);
thread->cancel = 1;
system_release_lock(FRAME_LOCK);
do{
system_wait_cv(cancel_lock, cancel_cv);
}while (thread->cancel == 1);
system_acquire_lock(FRAME_LOCK);
system_release_lock(cancel_lock);
}
}
}
internal
Sys_Check_Cancel_Sig(system_check_cancel){
b32 result = 0;
Thread_Group *group = linuxvars.groups + thread->group_id;
i32 thread_index = thread->id - 1;
i32 cancel_lock = group->cancel_lock0 + thread_index;
system_acquire_lock(cancel_lock);
if (thread->cancel){
result = 1;
}
system_release_lock(cancel_lock);
return(result);
}
internal
Sys_Grow_Thread_Memory_Sig(system_grow_thread_memory){
void *old_data;
i32 old_size, new_size;
system_acquire_lock(CANCEL_LOCK0 + memory->id - 1);
old_data = memory->data;
old_size = memory->size;
new_size = LargeRoundUp(memory->size*2, Kbytes(4));
memory->data = system_get_memory(new_size);
memory->size = new_size;
if (old_data){
memcpy(memory->data, old_data, old_size);
system_free_memory(old_data);
}
system_release_lock(CANCEL_LOCK0 + memory->id - 1);
}
#endif // OLD_JOB_QUEUE
internal
Sys_Acquire_Lock_Sig(system_acquire_lock){
pthread_mutex_lock(linuxvars.locks + id);
@ -1161,6 +1460,16 @@ Sys_Release_Lock_Sig(system_release_lock){
pthread_mutex_unlock(linuxvars.locks + id);
}
internal void
system_wait_cv(i32 lock_id, i32 cv_id){
pthread_cond_wait(linuxvars.conds + cv_id, linuxvars.locks + lock_id);
}
internal void
system_signal_cv(i32 lock_id, i32 cv_id){
pthread_cond_signal(linuxvars.conds + cv_id);
}
//
// Debug
//
@ -1172,12 +1481,13 @@ INTERNAL_Sys_Sentinel_Sig(internal_sentinel){
return (&linuxvars.internal_bubble);
}
#ifdef OLD_JOB_QUEUE
internal
INTERNAL_Sys_Get_Thread_States_Sig(internal_get_thread_states){
Work_Queue *queue = linuxvars.queues + id;
u32 write = queue->write_position;
u32 read = queue->read_position;
if (write < read) write += JOB_ID_WRAP;
if (write < read) write += QUEUE_WRAP;
*pending = (i32)(write - read);
Thread_Group *group = linuxvars.groups + id;
@ -1185,6 +1495,22 @@ INTERNAL_Sys_Get_Thread_States_Sig(internal_get_thread_states){
running[i] = (group->threads[i].running != 0);
}
}
#else
internal
INTERNAL_Sys_Get_Thread_States_Sig(internal_get_thread_states){
Thread_Group *group = linuxvars.groups + id;
Unbounded_Work_Queue *source_queue = &group->queue;
Work_Queue *queue = linuxvars.queues + id;
u32 write = queue->write_position;
u32 read = queue->read_position;
if (write < read) write += QUEUE_WRAP;
*pending = (i32)(write - read) + source_queue->count - source_queue->skip;
for (i32 i = 0; i < group->count; ++i){
running[i] = (group->threads[i].running != 0);
}
}
#endif
internal
INTERNAL_Sys_Debug_Message_Sig(internal_debug_message){
@ -2798,9 +3124,11 @@ main(int argc, char **argv)
memory->id = thread->id;
thread->queue = &linuxvars.queues[BACKGROUND_THREADS];
pthread_create(&thread->handle, NULL, &ThreadProc, thread);
pthread_create(&thread->handle, NULL, &JobThreadProc, thread);
}
initialize_unbounded_queue(&linuxvars.groups[BACKGROUND_THREADS].queue);
for(i32 i = 0; i < LOCK_COUNT; ++i){
pthread_mutex_init(linuxvars.locks + i, NULL);
}
@ -3082,6 +3410,8 @@ main(int argc, char **argv)
linuxvars.cursor = result.mouse_cursor_type;
}
flush_thread_group(BACKGROUND_THREADS);
linuxvars.input.first_step = 0;
linuxvars.input.keys = key_input_data_zero();
linuxvars.input.mouse.press_l = 0;