#include "../includes/sched.h" #include #include #include #include #include struct task_info { void *closure; taskfunc f; }; struct scheduler { /* Dernier élément du deque (premier ajouter) */ int *bottom; /* Variable de conditions pour reveillé les threads au besoin */ pthread_cond_t cond; /* Mutex qui protège les piles */ pthread_mutex_t mutex; /* Nombre de threads instanciés */ int nthreads; /* Compteur des threads dormants */ int nthsleep; /* Taille des piles */ int qlen; /* Piles de tâches */ struct task_info **tasks; /* Liste des threads */ pthread_t *threads; /* Premier élément du deque (dernier ajouter) */ int *top; }; /* Lance une tâche de la pile */ void *sched_worker(void *); /* Nettoie les opérations effectuées par l'initialisation de l'ordonnanceur */ int sched_init_cleanup(struct scheduler, int); /* Récupère l'index du thread courant */ int current_thread(struct scheduler *); int sched_init(int nthreads, int qlen, taskfunc f, void *closure) { static struct scheduler sched; sched.tasks = NULL; sched.threads = NULL; sched.top = NULL; sched.bottom = NULL; if(qlen <= 0) { fprintf(stderr, "qlen must be greater than 0\n"); return -1; } sched.qlen = qlen + 1; // circular buffer if(nthreads < 0) { fprintf(stderr, "nthreads must be greater than 0\n"); return -1; } else if(nthreads == 0) { nthreads = sched_default_threads(); } sched.nthreads = 0; sched.nthsleep = 0; // Initialisation du mutex if(pthread_mutex_init(&sched.mutex, NULL) != 0) { fprintf(stderr, "Can't init mutex\n"); return sched_init_cleanup(sched, -1); } // Initialisation variable de condition if(pthread_cond_init(&sched.cond, NULL) != 0) { fprintf(stderr, "Can't init varcond\n"); return sched_init_cleanup(sched, -1); } // Initialisation du curseur suivant l'état de la pile de chaque processus if(!(sched.top = malloc(nthreads * sizeof(int)))) { perror("Cursor top stack"); return sched_init_cleanup(sched, -1); } if(!(sched.bottom = malloc(nthreads * sizeof(int)))) { perror("Cursor bottom stack"); return sched_init_cleanup(sched, -1); } for(int i = 0; i < nthreads; ++i) { sched.top[i] = 0; sched.bottom[i] = 0; } // Allocation mémoire pour la pile de chaque processus if(!(sched.tasks = malloc(nthreads * sizeof(struct task_info *)))) { perror("Deque list"); return sched_init_cleanup(sched, -1); } for(int i = 0; i < nthreads; ++i) { if(!(sched.tasks[i] = malloc(qlen * sizeof(struct task_info)))) { fprintf(stderr, "Deque for thread %d: %s\n", i, strerror(errno)); return sched_init_cleanup(sched, -1); } } // Initialise l'aléatoire srand(time(NULL)); // Créer les threads if(!(sched.threads = malloc(nthreads * sizeof(pthread_t)))) { perror("Threads"); return sched_init_cleanup(sched, -1); } // Ajoute la tâche initiale if(sched_spawn(f, closure, &sched) < 0) { fprintf(stderr, "Can't create the initial task\n"); return sched_init_cleanup(sched, -1); } // Démarre les threads for(int i = 0; i < nthreads; ++i) { if(pthread_create(&sched.threads[i], NULL, sched_worker, &sched) != 0) { fprintf(stderr, "Can't create the thread %d\n", i); if(i > 0) { fprintf(stderr, ", cancelling already created threads...\n"); for(int j = 0; j < i; ++j) { if(pthread_cancel(sched.threads[j]) != 0) { fprintf(stderr, "Can't cancel the thread %d\n", j); } } } else { fprintf(stderr, "\n"); } return sched_init_cleanup(sched, -1); } pthread_mutex_lock(&sched.mutex); sched.nthreads++; pthread_mutex_unlock(&sched.mutex); } for(int i = 0; i < nthreads; ++i) { if((pthread_join(sched.threads[i], NULL) != 0)) { fprintf(stderr, "Can't wait the thread %d\n", i); return sched_init_cleanup(sched, -1); } } return sched_init_cleanup(sched, 1); } int sched_init_cleanup(struct scheduler s, int ret_code) { pthread_mutex_destroy(&s.mutex); pthread_cond_destroy(&s.cond); if(s.tasks) { for(int i = 0; i < s.nthreads; ++i) { if(s.tasks[i]) { free(s.tasks[i]); s.tasks[i] = NULL; } } free(s.tasks); s.tasks = NULL; } if(s.threads) { free(s.threads); s.threads = NULL; } if(s.top) { free(s.top); s.top = NULL; } if(s.bottom) { free(s.bottom); s.bottom = NULL; } return ret_code; } int current_thread(struct scheduler *s) { pthread_t current = pthread_self(); pthread_mutex_lock(&s->mutex); for(int i = 0; i < s->nthreads; ++i) { if(pthread_equal(s->threads[i], current)) { pthread_mutex_unlock(&s->mutex); return i; } } pthread_mutex_unlock(&s->mutex); return -1; } int sched_spawn(taskfunc f, void *closure, struct scheduler *s) { int th; if((th = current_thread(s)) < 0) { th = 0; } pthread_mutex_lock(&s->mutex); int next = (s->top[th] + 1) % s->qlen; if(next == s->bottom[th]) { pthread_mutex_unlock(&s->mutex); fprintf(stderr, "Stack is full\n"); errno = EAGAIN; return -1; } s->tasks[th][s->top[th]] = (struct task_info){closure, f}; s->top[th] = next; pthread_mutex_unlock(&s->mutex); return 0; } void * sched_worker(void *arg) { struct scheduler *s = (struct scheduler *)arg; // Récupère le processus courant (index tableau) int curr_th; while((curr_th = current_thread(s)) < 0); struct task_info task; int found; while(1) { found = 0; pthread_mutex_lock(&s->mutex); if(s->bottom[curr_th] != s->top[curr_th]) { found = 1; s->top[curr_th] = (s->top[curr_th] - 1 + s->qlen) % s->qlen; task = s->tasks[curr_th][s->top[curr_th]]; } if(!found) { // Vol car aucune tâche trouvée for(int i = 0, k = rand() % (s->nthreads + 1), target; i < s->nthreads; ++i) { target = (i + k) % s->nthreads; if(s->bottom[target] != s->top[target]) { // Tâche trouvée found = 1; s->top[target] = (s->top[target] - 1 + s->qlen) % s->qlen; task = s->tasks[target][s->top[target]]; break; } } // Aucune tâche à faire if(!found) { s->nthsleep++; // Ne partir que si tout le monde dort if(s->nthsleep >= s->nthreads) { pthread_cond_broadcast(&s->cond); pthread_mutex_unlock(&s->mutex); break; } pthread_cond_wait(&s->cond, &s->mutex); s->nthsleep--; pthread_mutex_unlock(&s->mutex); continue; } } pthread_cond_broadcast(&s->cond); pthread_mutex_unlock(&s->mutex); // Exécute la tâche task.f(task.closure, s); } return NULL; }