/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2006 Dan Everton * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include #include #include #include #include #include #include #include "system-sdl.h" #include "thread-sdl.h" #include "system.h" #include "kernel.h" #include "thread.h" #include "debug.h" /* Define this as 1 to show informational messages that are not errors. */ #define THREAD_SDL_DEBUGF_ENABLED 0 #if THREAD_SDL_DEBUGF_ENABLED #define THREAD_SDL_DEBUGF(...) DEBUGF(__VA_ARGS__) static char __name[32]; #define THREAD_SDL_GET_NAME(thread) \ ({ thread_get_name(__name, ARRAYLEN(__name), thread); __name; }) #else #define THREAD_SDL_DEBUGF(...) #define THREAD_SDL_GET_NAME(thread) #endif #define THREAD_PANICF(str...) \ ({ fprintf(stderr, str); exit(-1); }) /* Thread/core entries as in rockbox core */ struct core_entry cores[NUM_CORES]; struct thread_entry threads[MAXTHREADS]; /* Jump buffers for graceful exit - kernel threads don't stay neatly * in their start routines responding to messages so this is the only * way to get them back in there so they may exit */ static jmp_buf thread_jmpbufs[MAXTHREADS]; static SDL_mutex *m; static bool threads_exit = false; extern long start_tick; void thread_sdl_shutdown(void) { int i; /* Take control */ SDL_LockMutex(m); /* Tell all threads jump back to their start routines, unlock and exit gracefully - we'll check each one in turn for it's status. Threads _could_ terminate via remove_thread or multiple threads could exit on each unlock but that is safe. */ threads_exit = true; for (i = 0; i < MAXTHREADS; i++) { struct thread_entry *thread = &threads[i]; if (thread->context.t != NULL) { /* Signal thread on delay or block */ SDL_Thread *t = thread->context.t; SDL_SemPost(thread->context.s); SDL_UnlockMutex(m); /* Wait for it to finish */ SDL_WaitThread(t, NULL); /* Relock for next thread signal */ SDL_LockMutex(m); } } SDL_UnlockMutex(m); SDL_DestroyMutex(m); } /* Do main thread creation in this file scope to avoid the need to double- return to a prior call-level which would be unaware of the fact setjmp was used */ extern void app_main(void *param); static int thread_sdl_app_main(void *param) { SDL_LockMutex(m); cores[CURRENT_CORE].running = &threads[0]; /* Set the jump address for return */ if (setjmp(thread_jmpbufs[0]) == 0) { app_main(param); /* should not ever be reached but... */ THREAD_PANICF("app_main returned!\n"); } /* Unlock and exit */ SDL_UnlockMutex(m); return 0; } /* Initialize SDL threading */ bool thread_sdl_init(void *param) { struct thread_entry *thread; memset(cores, 0, sizeof(cores)); memset(threads, 0, sizeof(threads)); m = SDL_CreateMutex(); if (SDL_LockMutex(m) == -1) { fprintf(stderr, "Couldn't lock mutex\n"); return false; } /* Slot 0 is reserved for the main thread - initialize it here and then create the SDL thread - it is possible to have a quick, early shutdown try to access the structure. */ thread = &threads[0]; thread->stack = (uintptr_t *)" "; thread->stack_size = 8; thread->name = "main"; thread->state = STATE_RUNNING; thread->context.s = SDL_CreateSemaphore(0); cores[CURRENT_CORE].running = thread; if (thread->context.s == NULL) { fprintf(stderr, "Failed to create main semaphore\n"); return false; } thread->context.t = SDL_CreateThread(thread_sdl_app_main, param); if (thread->context.t == NULL) { SDL_DestroySemaphore(thread->context.s); fprintf(stderr, "Failed to create main thread\n"); return false; } THREAD_SDL_DEBUGF("Main thread: %p\n", thread); SDL_UnlockMutex(m); return true; } /* A way to yield and leave the threading system for extended periods */ void thread_sdl_thread_lock(void *me) { SDL_LockMutex(m); cores[CURRENT_CORE].running = (struct thread_entry *)me; if (threads_exit) thread_exit(); } void * thread_sdl_thread_unlock(void) { struct thread_entry *current = cores[CURRENT_CORE].running; SDL_UnlockMutex(m); return current; } static struct thread_entry * find_empty_thread_slot(void) { struct thread_entry *thread = NULL; int n; for (n = 0; n < MAXTHREADS; n++) { int state = threads[n].state; if (state == STATE_KILLED) { thread = &threads[n]; break; } } return thread; } static void add_to_list_l(struct thread_entry **list, struct thread_entry *thread) { if (*list == NULL) { /* Insert into unoccupied list */ thread->l.next = thread; thread->l.prev = thread; *list = thread; } else { /* Insert last */ thread->l.next = *list; thread->l.prev = (*list)->l.prev; thread->l.prev->l.next = thread; (*list)->l.prev = thread; } } static void remove_from_list_l(struct thread_entry **list, struct thread_entry *thread) { if (thread == thread->l.next) { /* The only item */ *list = NULL; return; } if (thread == *list) { /* List becomes next item */ *list = thread->l.next; } /* Fix links to jump over the removed entry. */ thread->l.prev->l.next = thread->l.next; thread->l.next->l.prev = thread->l.prev; } struct thread_entry *thread_get_current(void) { return cores[CURRENT_CORE].running; } void switch_thread(void) { struct thread_entry *current = cores[CURRENT_CORE].running; enable_irq(); switch (current->state) { case STATE_RUNNING: { SDL_UnlockMutex(m); /* Any other thread waiting already will get it first */ SDL_LockMutex(m); break; } /* STATE_RUNNING: */ case STATE_BLOCKED: { int oldlevel; SDL_UnlockMutex(m); SDL_SemWait(current->context.s); SDL_LockMutex(m); oldlevel = disable_irq_save(); current->state = STATE_RUNNING; restore_irq(oldlevel); break; } /* STATE_BLOCKED: */ case STATE_BLOCKED_W_TMO: { int result, oldlevel; SDL_UnlockMutex(m); result = SDL_SemWaitTimeout(current->context.s, current->tmo_tick); SDL_LockMutex(m); oldlevel = disable_irq_save(); if (current->state == STATE_BLOCKED_W_TMO) { /* Timed out */ remove_from_list_l(current->bqp, current); #ifdef HAVE_WAKEUP_EXT_CB if (current->wakeup_ext_cb != NULL) current->wakeup_ext_cb(current); #endif current->state = STATE_RUNNING; } if (result == SDL_MUTEX_TIMEDOUT) { /* Other signals from an explicit wake could have been made before * arriving here if we timed out waiting for the semaphore. Make * sure the count is reset. */ while (SDL_SemValue(current->context.s) > 0) SDL_SemTryWait(current->context.s); } restore_irq(oldlevel); break; } /* STATE_BLOCKED_W_TMO: */ case STATE_SLEEPING: { SDL_UnlockMutex(m); SDL_SemWaitTimeout(current->context.s, current->tmo_tick); SDL_LockMutex(m); current->state = STATE_RUNNING; break; } /* STATE_SLEEPING: */ } cores[CURRENT_CORE].running = current; if (threads_exit) thread_exit(); } void sleep_thread(int ticks) { struct thread_entry *current = cores[CURRENT_CORE].running; int rem; current->state = STATE_SLEEPING; rem = (SDL_GetTicks() - start_tick) % (1000/HZ); if (rem < 0) rem = 0; current->tmo_tick = (1000/HZ) * ticks + ((1000/HZ)-1) - rem; } void block_thread(struct thread_entry *current) { current->state = STATE_BLOCKED; add_to_list_l(current->bqp, current); } void block_thread_w_tmo(struct thread_entry *current, int ticks) { current->state = STATE_BLOCKED_W_TMO; current->tmo_tick = (1000/HZ)*ticks; add_to_list_l(current->bqp, current); } unsigned int wakeup_thread(struct thread_entry **list) { struct thread_entry *thread = *list; if (thread != NULL) { switch (thread->state) { case STATE_BLOCKED: case STATE_BLOCKED_W_TMO: remove_from_list_l(list, thread); thread->state = STATE_RUNNING; SDL_SemPost(thread->context.s); return THREAD_OK; } } return THREAD_NONE; } unsigned int thread_queue_wake(struct thread_entry **list) { unsigned int result = THREAD_NONE; for (;;) { unsigned int rc = wakeup_thread(list); if (rc == THREAD_NONE) break; result |= rc; } return result; } void thread_thaw(struct thread_entry *thread) { if (thread->state == STATE_FROZEN) { thread->state = STATE_RUNNING; SDL_SemPost(thread->context.s); } } int runthread(void *data) { struct thread_entry *current; jmp_buf *current_jmpbuf; /* Cannot access thread variables before locking the mutex as the data structures may not be filled-in yet. */ SDL_LockMutex(m); cores[CURRENT_CORE].running = (struct thread_entry *)data; current = cores[CURRENT_CORE].running; current_jmpbuf = &thread_jmpbufs[current - threads]; /* Setup jump for exit */ if (setjmp(*current_jmpbuf) == 0) { /* Run the thread routine */ if (current->state == STATE_FROZEN) { SDL_UnlockMutex(m); SDL_SemWait(current->context.s); SDL_LockMutex(m); cores[CURRENT_CORE].running = current; } if (!threads_exit) { current->context.start(); THREAD_SDL_DEBUGF("Thread Done: %d (%s)\n", current - threads, THREAD_SDL_GET_NAME(current)); /* Thread routine returned - suicide */ } thread_exit(); } else { /* Unlock and exit */ SDL_UnlockMutex(m); } return 0; } struct thread_entry* create_thread(void (*function)(void), void* stack, size_t stack_size, unsigned flags, const char *name) { struct thread_entry *thread; SDL_Thread* t; SDL_sem *s; THREAD_SDL_DEBUGF("Creating thread: (%s)\n", name ? name : ""); thread = find_empty_thread_slot(); if (thread == NULL) { DEBUGF("Failed to find thread slot\n"); return NULL; } s = SDL_CreateSemaphore(0); if (s == NULL) { DEBUGF("Failed to create semaphore\n"); return NULL; } t = SDL_CreateThread(runthread, thread); if (t == NULL) { DEBUGF("Failed to create SDL thread\n"); SDL_DestroySemaphore(s); return NULL; } thread->stack = stack; thread->stack_size = stack_size; thread->name = name; thread->state = (flags & CREATE_THREAD_FROZEN) ? STATE_FROZEN : STATE_RUNNING; thread->context.start = function; thread->context.t = t; thread->context.s = s; THREAD_SDL_DEBUGF("New Thread: %d (%s)\n", thread - threads, THREAD_SDL_GET_NAME(thread)); return thread; } void init_threads(void) { /* Main thread is already initialized */ if (cores[CURRENT_CORE].running != &threads[0]) { THREAD_PANICF("Wrong main thread in init_threads: %p\n", cores[CURRENT_CORE].running); } THREAD_SDL_DEBUGF("First Thread: %d (%s)\n", 0, THREAD_SDL_GET_NAME(&threads[0])); } void remove_thread(struct thread_entry *thread) { struct thread_entry *current = cores[CURRENT_CORE].running; SDL_Thread *t; SDL_sem *s; int oldlevel = disable_irq_save(); if (thread == NULL) { thread = current; } t = thread->context.t; s = thread->context.s; thread->context.t = NULL; if (thread != current) { switch (thread->state) { case STATE_BLOCKED: case STATE_BLOCKED_W_TMO: /* Remove thread from object it's waiting on */ remove_from_list_l(thread->bqp, thread); #ifdef HAVE_WAKEUP_EXT_CB if (thread->wakeup_ext_cb != NULL) thread->wakeup_ext_cb(thread); #endif break; } SDL_SemPost(s); } THREAD_SDL_DEBUGF("Removing thread: %d (%s)\n", thread - threads, THREAD_SDL_GET_NAME(thread)); thread->state = STATE_KILLED; thread_queue_wake(&thread->queue); SDL_DestroySemaphore(s); if (thread == current) { /* Do a graceful exit - perform the longjmp back into the thread function to return */ restore_irq(oldlevel); longjmp(thread_jmpbufs[current - threads], 1); } SDL_KillThread(t); restore_irq(oldlevel); } void thread_exit(void) { remove_thread(NULL); } void thread_wait(struct thread_entry *thread) { struct thread_entry *current = cores[CURRENT_CORE].running; if (thread == NULL) thread = current; if (thread->state != STATE_KILLED) { current->bqp = &thread->queue; block_thread(current); switch_thread(); } } int thread_stack_usage(const struct thread_entry *thread) { return 50; (void)thread; } unsigned thread_get_status(const struct thread_entry *thread) { return thread->state; } /* Return name if one or ID if none */ void thread_get_name(char *buffer, int size, struct thread_entry *thread) { if (size <= 0) return; *buffer = '\0'; if (thread) { /* Display thread name if one or ID if none */ bool named = thread->name && *thread->name; const char *fmt = named ? "%s" : "%08lX"; intptr_t name = named ? (intptr_t)thread->name : (intptr_t)thread; snprintf(buffer, size, fmt, name); } }