/*** This file is part of PulseAudio. Copyright 2006-2008 Lennart Poettering PulseAudio 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. PulseAudio 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 PulseAudio; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. ***/ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include #include "asyncq.h" #include "fdsem.h" #define ASYNCQ_SIZE 256 /* For debugging purposes we can define _Y to put an extra thread * yield between each operation. */ /* #define PROFILE */ #ifdef PROFILE #define _Y pa_thread_yield() #else #define _Y do { } while(0) #endif struct localq { void *data; PA_LLIST_FIELDS(struct localq); }; struct pa_asyncq { unsigned size; unsigned read_idx; unsigned write_idx; pa_fdsem *read_fdsem, *write_fdsem; PA_LLIST_HEAD(struct localq, localq); struct localq *last_localq; pa_bool_t waiting_for_post; }; PA_STATIC_FLIST_DECLARE(localq, 0, pa_xfree); #define PA_ASYNCQ_CELLS(x) ((pa_atomic_ptr_t*) ((uint8_t*) (x) + PA_ALIGN(sizeof(struct pa_asyncq)))) static int reduce(pa_asyncq *l, int value) { return value & (unsigned) (l->size - 1); } pa_asyncq *pa_asyncq_new(unsigned size) { pa_asyncq *l; if (!size) size = ASYNCQ_SIZE; pa_assert(pa_is_power_of_two(size)); l = pa_xmalloc0(PA_ALIGN(sizeof(pa_asyncq)) + (sizeof(pa_atomic_ptr_t) * size)); l->size = size; PA_LLIST_HEAD_INIT(struct localq, l->localq); l->last_localq = NULL; l->waiting_for_post = FALSE; if (!(l->read_fdsem = pa_fdsem_new())) { pa_xfree(l); return NULL; } if (!(l->write_fdsem = pa_fdsem_new())) { pa_fdsem_free(l->read_fdsem); pa_xfree(l); return NULL; } return l; } void pa_asyncq_free(pa_asyncq *l, pa_free_cb_t free_cb) { struct localq *q; pa_assert(l); if (free_cb) { void *p; while ((p = pa_asyncq_pop(l, 0))) free_cb(p); } while ((q = l->localq)) { if (free_cb) free_cb(q->data); PA_LLIST_REMOVE(struct localq, l->localq, q); if (pa_flist_push(PA_STATIC_FLIST_GET(localq), q) < 0) pa_xfree(q); } pa_fdsem_free(l->read_fdsem); pa_fdsem_free(l->write_fdsem); pa_xfree(l); } static int push(pa_asyncq*l, void *p, pa_bool_t wait) { int idx; pa_atomic_ptr_t *cells; pa_assert(l); pa_assert(p); cells = PA_ASYNCQ_CELLS(l); _Y; idx = reduce(l, l->write_idx); if (!pa_atomic_ptr_cmpxchg(&cells[idx], NULL, p)) { if (!wait) return -1; /* pa_log("sleeping on push"); */ do { pa_fdsem_wait(l->read_fdsem); } while (!pa_atomic_ptr_cmpxchg(&cells[idx], NULL, p)); } _Y; l->write_idx++; pa_fdsem_post(l->write_fdsem); return 0; } static pa_bool_t flush_postq(pa_asyncq *l) { struct localq *q; pa_assert(l); while ((q = l->last_localq)) { if (push(l, q->data, FALSE) < 0) return FALSE; l->last_localq = q->prev; PA_LLIST_REMOVE(struct localq, l->localq, q); if (pa_flist_push(PA_STATIC_FLIST_GET(localq), q) < 0) pa_xfree(q); } return TRUE; } int pa_asyncq_push(pa_asyncq*l, void *p, pa_bool_t wait) { pa_assert(l); if (!flush_postq(l)) return -1; return push(l, p, wait); } void pa_asyncq_post(pa_asyncq*l, void *p) { struct localq *q; pa_assert(l); pa_assert(p); if (pa_asyncq_push(l, p, FALSE) >= 0) return; /* OK, we couldn't push anything in the queue. So let's queue it * locally and push it later */ pa_log("q overrun, queuing locally"); if (!(q = pa_flist_pop(PA_STATIC_FLIST_GET(localq)))) q = pa_xnew(struct localq, 1); q->data = p; PA_LLIST_PREPEND(struct localq, l->localq, q); if (!l->last_localq) l->last_localq = q; return; } void* pa_asyncq_pop(pa_asyncq*l, pa_bool_t wait) { int idx; void *ret; pa_atomic_ptr_t *cells; pa_assert(l); cells = PA_ASYNCQ_CELLS(l); _Y; idx = reduce(l, l->read_idx); if (!(ret = pa_atomic_ptr_load(&cells[idx]))) { if (!wait) return NULL; /* pa_log("sleeping on pop"); */ do { pa_fdsem_wait(l->write_fdsem); } while (!(ret = pa_atomic_ptr_load(&cells[idx]))); } pa_assert(ret); /* Guaranteed to succeed if we only have a single reader */ pa_assert_se(pa_atomic_ptr_cmpxchg(&cells[idx], ret, NULL)); _Y; l->read_idx++; pa_fdsem_post(l->read_fdsem); return ret; } int pa_asyncq_read_fd(pa_asyncq *q) { pa_assert(q); return pa_fdsem_get(q->write_fdsem); } int pa_asyncq_read_before_poll(pa_asyncq *l) { int idx; pa_atomic_ptr_t *cells; pa_assert(l); cells = PA_ASYNCQ_CELLS(l); _Y; idx = reduce(l, l->read_idx); for (;;) { if (pa_atomic_ptr_load(&cells[idx])) return -1; if (pa_fdsem_before_poll(l->write_fdsem) >= 0) return 0; } return 0; } void pa_asyncq_read_after_poll(pa_asyncq *l) { pa_assert(l); pa_fdsem_after_poll(l->write_fdsem); } int pa_asyncq_write_fd(pa_asyncq *q) { pa_assert(q); return pa_fdsem_get(q->read_fdsem); } void pa_asyncq_write_before_poll(pa_asyncq *l) { pa_assert(l); for (;;) { if (flush_postq(l)) break; if (pa_fdsem_before_poll(l->read_fdsem) >= 0) { l->waiting_for_post = TRUE; break; } } } void pa_asyncq_write_after_poll(pa_asyncq *l) { pa_assert(l); if (l->waiting_for_post) { pa_fdsem_after_poll(l->read_fdsem); l->waiting_for_post = FALSE; } }