/* Copyright (C) 2017 the mpv developers * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include "common/common.h" #include "common/global.h" #include "common/msg.h" #include "common/msg_control.h" #include "common/global.h" #include "input/input.h" #include "input/cmd.h" #include "misc/ctype.h" #include "misc/dispatch.h" #include "misc/node.h" #include "misc/rendezvous.h" #include "misc/thread_tools.h" #include "options/m_config.h" #include "options/m_option.h" #include "options/m_property.h" #include "options/path.h" #include "options/parse_configfile.h" #include "osdep/threads.h" #include "osdep/timer.h" #include "osdep/io.h" #include "stream/stream.h" #include "command.h" #include "core.h" #include "client.h" /* * Locking hierarchy: * * MPContext > mp_client_api.lock > mpv_handle.lock > * > mpv_handle.wakeup_lock * * MPContext strictly speaking has no locks, and instead is implicitly managed * by MPContext.dispatch, which basically stops the playback thread at defined * points in order to let clients access it in a synchronized manner. Since * MPContext code accesses the client API, it's on top of the lock hierarchy. * */ struct mp_client_api { struct MPContext *mpctx; pthread_mutex_t lock; // -- protected by lock struct mpv_handle **clients; int num_clients; bool shutting_down; // do not allow new clients bool have_terminator; // a client took over the role of destroying the core bool terminate_core_thread; // make libmpv core thread exit // This is incremented whenever the clients[] array above changes. This is // used to safely unlock mp_client_api.lock while iterating the list of // clients. uint64_t clients_list_change_ts; int64_t id_alloc; struct mp_custom_protocol *custom_protocols; int num_custom_protocols; struct mpv_render_context *render_context; }; struct observe_property { // -- immutable struct mpv_handle *owner; char *name; int id; // ==mp_get_property_id(name) uint64_t event_mask; // ==mp_get_property_event_mask(name) int64_t reply_id; mpv_format format; const struct m_option *type; // -- protected by owner->lock size_t refcount; uint64_t change_ts; // logical timestamp incremented on each change uint64_t value_ts; // logical timestamp for value contents bool value_valid; union m_option_value value; uint64_t value_ret_ts; // logical timestamp of value returned to user union m_option_value value_ret; bool waiting_for_hook; // flag for draining old property changes on a hook }; struct mpv_handle { // -- immutable char name[MAX_CLIENT_NAME]; struct mp_log *log; struct MPContext *mpctx; struct mp_client_api *clients; int64_t id; // -- not thread-safe struct mpv_event *cur_event; struct mpv_event_property cur_property_event; struct observe_property *cur_property; pthread_mutex_t lock; pthread_mutex_t wakeup_lock; pthread_cond_t wakeup; // -- protected by wakeup_lock bool need_wakeup; void (*wakeup_cb)(void *d); void *wakeup_cb_ctx; int wakeup_pipe[2]; // -- protected by lock uint64_t event_mask; bool queued_wakeup; mpv_event *events; // ringbuffer of max_events entries int max_events; // allocated number of entries in events int first_event; // events[first_event] is the first readable event int num_events; // number of readable events int reserved_events; // number of entries reserved for replies size_t async_counter; // pending other async events bool choked; // recovering from queue overflow bool destroying; // pending destruction; no API accesses allowed bool hook_pending; // hook events are returned after draining properties struct observe_property **properties; int num_properties; bool has_pending_properties; // (maybe) new property events (producer side) bool new_property_events; // new property events (consumer side) int cur_property_index; // round-robin for property events (consumer side) uint64_t property_event_masks; // or-ed together event masks of all properties // This is incremented whenever the properties[] array above changes. This // is used to safely unlock mpv_handle.lock while reading a property. If // the counter didn't change between unlock and relock, then it will assume // the array did not change. uint64_t properties_change_ts; bool fuzzy_initialized; // see scripting.c wait_loaded() bool is_weak; // can not keep core alive on its own struct mp_log_buffer *messages; int messages_level; }; static bool gen_log_message_event(struct mpv_handle *ctx); static bool gen_property_change_event(struct mpv_handle *ctx); static void notify_property_events(struct mpv_handle *ctx, int event); // Must be called with prop->owner->lock held. static void prop_unref(struct observe_property *prop) { if (!prop) return; assert(prop->refcount > 0); prop->refcount -= 1; if (!prop->refcount) talloc_free(prop); } void mp_clients_init(struct MPContext *mpctx) { mpctx->clients = talloc_ptrtype(NULL, mpctx->clients); *mpctx->clients = (struct mp_client_api) { .mpctx = mpctx, }; mpctx->global->client_api = mpctx->clients; pthread_mutex_init(&mpctx->clients->lock, NULL); } void mp_clients_destroy(struct MPContext *mpctx) { if (!mpctx->clients) return; assert(mpctx->clients->num_clients == 0); // The API user is supposed to call mpv_render_context_free(). It's simply // not allowed not to do this. if (mpctx->clients->render_context) { MP_FATAL(mpctx, "Broken API use: mpv_render_context_free() not called.\n"); abort(); } pthread_mutex_destroy(&mpctx->clients->lock); talloc_free(mpctx->clients); mpctx->clients = NULL; } // Test for "fuzzy" initialization of all clients. That is, all clients have // at least called mpv_wait_event() at least once since creation (or exited). bool mp_clients_all_initialized(struct MPContext *mpctx) { bool all_ok = true; pthread_mutex_lock(&mpctx->clients->lock); for (int n = 0; n < mpctx->clients->num_clients; n++) { struct mpv_handle *ctx = mpctx->clients->clients[n]; pthread_mutex_lock(&ctx->lock); all_ok &= ctx->fuzzy_initialized; pthread_mutex_unlock(&ctx->lock); } pthread_mutex_unlock(&mpctx->clients->lock); return all_ok; } static struct mpv_handle *find_client_id(struct mp_client_api *clients, int64_t id) { for (int n = 0; n < clients->num_clients; n++) { if (clients->clients[n]->id == id) return clients->clients[n]; } return NULL; } static struct mpv_handle *find_client(struct mp_client_api *clients, const char *name) { if (name[0] == '@') { char *end; errno = 0; long long int id = strtoll(name + 1, &end, 10); if (errno || end[0]) return NULL; return find_client_id(clients, id); } for (int n = 0; n < clients->num_clients; n++) { if (strcmp(clients->clients[n]->name, name) == 0) return clients->clients[n]; } return NULL; } bool mp_client_id_exists(struct MPContext *mpctx, int64_t id) { pthread_mutex_lock(&mpctx->clients->lock); bool r = find_client_id(mpctx->clients, id); pthread_mutex_unlock(&mpctx->clients->lock); return r; } struct mpv_handle *mp_new_client(struct mp_client_api *clients, const char *name) { pthread_mutex_lock(&clients->lock); char nname[MAX_CLIENT_NAME]; for (int n = 1; n < 1000; n++) { if (!name) name = "client"; snprintf(nname, sizeof(nname) - 3, "%s", name); // - space for number for (int i = 0; nname[i]; i++) nname[i] = mp_isalnum(nname[i]) ? nname[i] : '_'; if (n > 1) mp_snprintf_cat(nname, sizeof(nname), "%d", n); if (!find_client(clients, nname)) break; nname[0] = '\0'; } if (!nname[0] || clients->shutting_down) { pthread_mutex_unlock(&clients->lock); return NULL; } int num_events = 1000; struct mpv_handle *client = talloc_ptrtype(NULL, client); *client = (struct mpv_handle){ .log = mp_log_new(client, clients->mpctx->log, nname), .mpctx = clients->mpctx, .clients = clients, .id = ++(clients->id_alloc), .cur_event = talloc_zero(client, struct mpv_event), .events = talloc_array(client, mpv_event, num_events), .max_events = num_events, .event_mask = (1ULL << INTERNAL_EVENT_BASE) - 1, // exclude internal events .wakeup_pipe = {-1, -1}, }; pthread_mutex_init(&client->lock, NULL); pthread_mutex_init(&client->wakeup_lock, NULL); pthread_cond_init(&client->wakeup, NULL); snprintf(client->name, sizeof(client->name), "%s", nname); clients->clients_list_change_ts += 1; MP_TARRAY_APPEND(clients, clients->clients, clients->num_clients, client); if (clients->num_clients == 1 && !clients->mpctx->is_cli) client->fuzzy_initialized = true; pthread_mutex_unlock(&clients->lock); mpv_request_event(client, MPV_EVENT_TICK, 0); return client; } void mp_client_set_weak(struct mpv_handle *ctx) { pthread_mutex_lock(&ctx->lock); ctx->is_weak = true; pthread_mutex_unlock(&ctx->lock); } const char *mpv_client_name(mpv_handle *ctx) { return ctx->name; } int64_t mpv_client_id(mpv_handle *ctx) { return ctx->id; } struct mp_log *mp_client_get_log(struct mpv_handle *ctx) { return ctx->log; } struct mpv_global *mp_client_get_global(struct mpv_handle *ctx) { return ctx->mpctx->global; } static void wakeup_client(struct mpv_handle *ctx) { pthread_mutex_lock(&ctx->wakeup_lock); if (!ctx->need_wakeup) { ctx->need_wakeup = true; pthread_cond_broadcast(&ctx->wakeup); if (ctx->wakeup_cb) ctx->wakeup_cb(ctx->wakeup_cb_ctx); if (ctx->wakeup_pipe[0] != -1) (void)write(ctx->wakeup_pipe[1], &(char){0}, 1); } pthread_mutex_unlock(&ctx->wakeup_lock); } // Note: the caller has to deal with sporadic wakeups. static int wait_wakeup(struct mpv_handle *ctx, int64_t end) { int r = 0; pthread_mutex_unlock(&ctx->lock); pthread_mutex_lock(&ctx->wakeup_lock); if (!ctx->need_wakeup) { struct timespec ts = mp_time_ns_to_realtime(end); r = pthread_cond_timedwait(&ctx->wakeup, &ctx->wakeup_lock, &ts); } if (r == 0) ctx->need_wakeup = false; pthread_mutex_unlock(&ctx->wakeup_lock); pthread_mutex_lock(&ctx->lock); return r; } void mpv_set_wakeup_callback(mpv_handle *ctx, void (*cb)(void *d), void *d) { pthread_mutex_lock(&ctx->wakeup_lock); ctx->wakeup_cb = cb; ctx->wakeup_cb_ctx = d; if (ctx->wakeup_cb) ctx->wakeup_cb(ctx->wakeup_cb_ctx); pthread_mutex_unlock(&ctx->wakeup_lock); } static void lock_core(mpv_handle *ctx) { mp_dispatch_lock(ctx->mpctx->dispatch); } static void unlock_core(mpv_handle *ctx) { mp_dispatch_unlock(ctx->mpctx->dispatch); } void mpv_wait_async_requests(mpv_handle *ctx) { pthread_mutex_lock(&ctx->lock); while (ctx->reserved_events || ctx->async_counter) wait_wakeup(ctx, INT64_MAX); pthread_mutex_unlock(&ctx->lock); } // Send abort signal to all matching work items. // If type==0, destroy all of the matching ctx. // If ctx==0, destroy all. static void abort_async(struct MPContext *mpctx, mpv_handle *ctx, int type, uint64_t id) { pthread_mutex_lock(&mpctx->abort_lock); // Destroy all => ensure any newly appearing work is aborted immediately. if (ctx == NULL) mpctx->abort_all = true; for (int n = 0; n < mpctx->num_abort_list; n++) { struct mp_abort_entry *abort = mpctx->abort_list[n]; if (!ctx || (abort->client == ctx && (!type || (abort->client_work_type == type && abort->client_work_id == id)))) { mp_abort_trigger_locked(mpctx, abort); } } pthread_mutex_unlock(&mpctx->abort_lock); } static void get_thread(void *ptr) { *(pthread_t *)ptr = pthread_self(); } static void mp_destroy_client(mpv_handle *ctx, bool terminate) { if (!ctx) return; struct MPContext *mpctx = ctx->mpctx; struct mp_client_api *clients = ctx->clients; MP_DBG(ctx, "Exiting...\n"); if (terminate) mpv_command(ctx, (const char*[]){"quit", NULL}); pthread_mutex_lock(&ctx->lock); ctx->destroying = true; for (int n = 0; n < ctx->num_properties; n++) prop_unref(ctx->properties[n]); ctx->num_properties = 0; ctx->properties_change_ts += 1; prop_unref(ctx->cur_property); ctx->cur_property = NULL; pthread_mutex_unlock(&ctx->lock); abort_async(mpctx, ctx, 0, 0); // reserved_events equals the number of asynchronous requests that weren't // yet replied. In order to avoid that trying to reply to a removed client // causes a crash, block until all asynchronous requests were served. mpv_wait_async_requests(ctx); osd_set_external_remove_owner(mpctx->osd, ctx); mp_input_remove_sections_by_owner(mpctx->input, ctx->name); pthread_mutex_lock(&clients->lock); for (int n = 0; n < clients->num_clients; n++) { if (clients->clients[n] == ctx) { clients->clients_list_change_ts += 1; MP_TARRAY_REMOVE_AT(clients->clients, clients->num_clients, n); while (ctx->num_events) { talloc_free(ctx->events[ctx->first_event].data); ctx->first_event = (ctx->first_event + 1) % ctx->max_events; ctx->num_events--; } mp_msg_log_buffer_destroy(ctx->messages); pthread_cond_destroy(&ctx->wakeup); pthread_mutex_destroy(&ctx->wakeup_lock); pthread_mutex_destroy(&ctx->lock); if (ctx->wakeup_pipe[0] != -1) { close(ctx->wakeup_pipe[0]); close(ctx->wakeup_pipe[1]); } talloc_free(ctx); ctx = NULL; break; } } assert(!ctx); if (mpctx->is_cli) { terminate = false; } else { // If the last strong mpv_handle got destroyed, destroy the core. bool has_strong_ref = false; for (int n = 0; n < clients->num_clients; n++) has_strong_ref |= !clients->clients[n]->is_weak; if (!has_strong_ref) terminate = true; // Reserve the right to destroy mpctx for us. if (clients->have_terminator) terminate = false; clients->have_terminator |= terminate; } // mp_shutdown_clients() sleeps to avoid wasting CPU. // mp_hook_test_completion() also relies on this a bit. mp_wakeup_core(mpctx); pthread_mutex_unlock(&clients->lock); // Note that even if num_clients==0, having set have_terminator keeps mpctx // and the core thread alive. if (terminate) { // Make sure the core stops playing files etc. Being able to lock the // dispatch queue requires that the core thread is still active. mp_dispatch_lock(mpctx->dispatch); mpctx->stop_play = PT_QUIT; mp_dispatch_unlock(mpctx->dispatch); pthread_t playthread; mp_dispatch_run(mpctx->dispatch, get_thread, &playthread); // Ask the core thread to stop. pthread_mutex_lock(&clients->lock); clients->terminate_core_thread = true; pthread_mutex_unlock(&clients->lock); mp_wakeup_core(mpctx); // Blocking wait for all clients and core thread to terminate. pthread_join(playthread, NULL); mp_destroy(mpctx); } } void mpv_destroy(mpv_handle *ctx) { mp_destroy_client(ctx, false); } void mpv_terminate_destroy(mpv_handle *ctx) { mp_destroy_client(ctx, true); } // Can be called on the core thread only. Idempotent. // Also happens to take care of shutting down any async work. void mp_shutdown_clients(struct MPContext *mpctx) { struct mp_client_api *clients = mpctx->clients; // Forcefully abort async work after 2 seconds of waiting. double abort_time = mp_time_sec() + 2; pthread_mutex_lock(&clients->lock); // Prevent that new clients can appear. clients->shutting_down = true; // Wait until we can terminate. while (clients->num_clients || mpctx->outstanding_async || !(mpctx->is_cli || clients->terminate_core_thread)) { pthread_mutex_unlock(&clients->lock); double left = abort_time - mp_time_sec(); if (left >= 0) { mp_set_timeout(mpctx, left); } else { // Forcefully abort any ongoing async work. This is quite rude and // probably not what everyone wants, so it happens only after a // timeout. abort_async(mpctx, NULL, 0, 0); } mp_client_broadcast_event(mpctx, MPV_EVENT_SHUTDOWN, NULL); mp_wait_events(mpctx); pthread_mutex_lock(&clients->lock); } pthread_mutex_unlock(&clients->lock); } bool mp_is_shutting_down(struct MPContext *mpctx) { struct mp_client_api *clients = mpctx->clients; pthread_mutex_lock(&clients->lock); bool res = clients->shutting_down; pthread_mutex_unlock(&clients->lock); return res; } static void *core_thread(void *p) { struct MPContext *mpctx = p; mpthread_set_name("mpv core"); while (!mpctx->initialized && mpctx->stop_play != PT_QUIT) mp_idle(mpctx); if (mpctx->initialized) mp_play_files(mpctx); // This actually waits until all clients are gone before actually // destroying mpctx. Actual destruction is done by whatever destroys // the last mpv_handle. mp_shutdown_clients(mpctx); return NULL; } mpv_handle *mpv_create(void) { struct MPContext *mpctx = mp_create(); if (!mpctx) return NULL; m_config_set_profile(mpctx->mconfig, "libmpv", 0); mpv_handle *ctx = mp_new_client(mpctx->clients, "main"); if (!ctx) { mp_destroy(mpctx); return NULL; } pthread_t thread; if (pthread_create(&thread, NULL, core_thread, mpctx) != 0) { ctx->clients->have_terminator = true; // avoid blocking mpv_terminate_destroy(ctx); mp_destroy(mpctx); return NULL; } return ctx; } mpv_handle *mpv_create_client(mpv_handle *ctx, const char *name) { if (!ctx) return mpv_create(); mpv_handle *new = mp_new_client(ctx->mpctx->clients, name); if (new) mpv_wait_event(new, 0); // set fuzzy_initialized return new; } mpv_handle *mpv_create_weak_client(mpv_handle *ctx, const char *name) { mpv_handle *new = mpv_create_client(ctx, name); if (new) mp_client_set_weak(new); return new; } int mpv_initialize(mpv_handle *ctx) { lock_core(ctx); int res = mp_initialize(ctx->mpctx, NULL) ? MPV_ERROR_INVALID_PARAMETER : 0; mp_wakeup_core(ctx->mpctx); unlock_core(ctx); return res; } // set ev->data to a new copy of the original data // (done only for message types that are broadcast) static void dup_event_data(struct mpv_event *ev) { switch (ev->event_id) { case MPV_EVENT_CLIENT_MESSAGE: { struct mpv_event_client_message *src = ev->data; struct mpv_event_client_message *msg = talloc_zero(NULL, struct mpv_event_client_message); for (int n = 0; n < src->num_args; n++) { MP_TARRAY_APPEND(msg, msg->args, msg->num_args, talloc_strdup(msg, src->args[n])); } ev->data = msg; break; } case MPV_EVENT_START_FILE: ev->data = talloc_memdup(NULL, ev->data, sizeof(mpv_event_start_file)); break; case MPV_EVENT_END_FILE: ev->data = talloc_memdup(NULL, ev->data, sizeof(mpv_event_end_file)); break; default: // Doesn't use events with memory allocation. if (ev->data) abort(); } } // Reserve an entry in the ring buffer. This can be used to guarantee that the // reply can be made, even if the buffer becomes congested _after_ sending // the request. // Returns an error code if the buffer is full. static int reserve_reply(struct mpv_handle *ctx) { int res = MPV_ERROR_EVENT_QUEUE_FULL; pthread_mutex_lock(&ctx->lock); if (ctx->reserved_events + ctx->num_events < ctx->max_events && !ctx->choked) { ctx->reserved_events++; res = 0; } pthread_mutex_unlock(&ctx->lock); return res; } static int append_event(struct mpv_handle *ctx, struct mpv_event event, bool copy) { if (ctx->num_events + ctx->reserved_events >= ctx->max_events) return -1; if (copy) dup_event_data(&event); ctx->events[(ctx->first_event + ctx->num_events) % ctx->max_events] = event; ctx->num_events++; wakeup_client(ctx); if (event.event_id == MPV_EVENT_SHUTDOWN) ctx->event_mask &= ctx->event_mask & ~(1ULL << MPV_EVENT_SHUTDOWN); return 0; } static int send_event(struct mpv_handle *ctx, struct mpv_event *event, bool copy) { pthread_mutex_lock(&ctx->lock); uint64_t mask = 1ULL << event->event_id; if (ctx->property_event_masks & mask) notify_property_events(ctx, event->event_id); int r; if (!(ctx->event_mask & mask)) { r = 0; } else if (ctx->choked) { r = -1; } else { r = append_event(ctx, *event, copy); if (r < 0) { MP_ERR(ctx, "Too many events queued.\n"); ctx->choked = true; } } pthread_mutex_unlock(&ctx->lock); return r; } // Send a reply; the reply must have been previously reserved with // reserve_reply (otherwise, use send_event()). static void send_reply(struct mpv_handle *ctx, uint64_t userdata, struct mpv_event *event) { event->reply_userdata = userdata; pthread_mutex_lock(&ctx->lock); // If this fails, reserve_reply() probably wasn't called. assert(ctx->reserved_events > 0); ctx->reserved_events--; if (append_event(ctx, *event, false) < 0) MP_ASSERT_UNREACHABLE(); pthread_mutex_unlock(&ctx->lock); } void mp_client_broadcast_event(struct MPContext *mpctx, int event, void *data) { struct mp_client_api *clients = mpctx->clients; pthread_mutex_lock(&clients->lock); for (int n = 0; n < clients->num_clients; n++) { struct mpv_event event_data = { .event_id = event, .data = data, }; send_event(clients->clients[n], &event_data, true); } pthread_mutex_unlock(&clients->lock); } // Like mp_client_broadcast_event(), but can be called from any thread. // Avoid using this. void mp_client_broadcast_event_external(struct mp_client_api *api, int event, void *data) { struct MPContext *mpctx = api->mpctx; mp_client_broadcast_event(mpctx, event, data); mp_wakeup_core(mpctx); } // If client_name == NULL, then broadcast and free the event. int mp_client_send_event(struct MPContext *mpctx, const char *client_name, uint64_t reply_userdata, int event, void *data) { if (!client_name) { mp_client_broadcast_event(mpctx, event, data); talloc_free(data); return 0; } struct mp_client_api *clients = mpctx->clients; int r = 0; struct mpv_event event_data = { .event_id = event, .data = data, .reply_userdata = reply_userdata, }; pthread_mutex_lock(&clients->lock); struct mpv_handle *ctx = find_client(clients, client_name); if (ctx) { r = send_event(ctx, &event_data, false); } else { r = -1; talloc_free(data); } pthread_mutex_unlock(&clients->lock); return r; } int mp_client_send_event_dup(struct MPContext *mpctx, const char *client_name, int event, void *data) { if (!client_name) { mp_client_broadcast_event(mpctx, event, data); return 0; } struct mpv_event event_data = { .event_id = event, .data = data, }; dup_event_data(&event_data); return mp_client_send_event(mpctx, client_name, 0, event, event_data.data); } const static bool deprecated_events[] = { [MPV_EVENT_IDLE] = true, [MPV_EVENT_TICK] = true, }; int mpv_request_event(mpv_handle *ctx, mpv_event_id event, int enable) { if (!mpv_event_name(event) || enable < 0 || enable > 1) return MPV_ERROR_INVALID_PARAMETER; if (event == MPV_EVENT_SHUTDOWN && !enable) return MPV_ERROR_INVALID_PARAMETER; assert(event < (int)INTERNAL_EVENT_BASE); // excluded above; they have no name pthread_mutex_lock(&ctx->lock); uint64_t bit = 1ULL << event; ctx->event_mask = enable ? ctx->event_mask | bit : ctx->event_mask & ~bit; if (enable && event < MP_ARRAY_SIZE(deprecated_events) && deprecated_events[event]) { MP_WARN(ctx, "The '%s' event is deprecated and will be removed.\n", mpv_event_name(event)); } pthread_mutex_unlock(&ctx->lock); return 0; } // Set waiting_for_hook==true for all possibly pending properties. static void set_wait_for_hook_flags(mpv_handle *ctx) { for (int n = 0; n < ctx->num_properties; n++) { struct observe_property *prop = ctx->properties[n]; if (prop->value_ret_ts != prop->change_ts) prop->waiting_for_hook = true; } } // Return whether any property still has waiting_for_hook set. static bool check_for_for_hook_flags(mpv_handle *ctx) { for (int n = 0; n < ctx->num_properties; n++) { if (ctx->properties[n]->waiting_for_hook) return true; } return false; } mpv_event *mpv_wait_event(mpv_handle *ctx, double timeout) { mpv_event *event = ctx->cur_event; pthread_mutex_lock(&ctx->lock); if (!ctx->fuzzy_initialized) mp_wakeup_core(ctx->clients->mpctx); ctx->fuzzy_initialized = true; if (timeout < 0) timeout = 1e20; int64_t deadline = mp_time_ns_add(mp_time_ns(), timeout); *event = (mpv_event){0}; talloc_free_children(event); while (1) { if (ctx->queued_wakeup) deadline = 0; // Recover from overflow. if (ctx->choked && !ctx->num_events) { ctx->choked = false; event->event_id = MPV_EVENT_QUEUE_OVERFLOW; break; } struct mpv_event *ev = ctx->num_events ? &ctx->events[ctx->first_event] : NULL; if (ev && ev->event_id == MPV_EVENT_HOOK) { // Give old property notifications priority over hooks. This is a // guarantee given to clients to simplify their logic. New property // changes after this are treated normally, so if (!ctx->hook_pending) { ctx->hook_pending = true; set_wait_for_hook_flags(ctx); } if (check_for_for_hook_flags(ctx)) { ev = NULL; // delay } else { ctx->hook_pending = false; } } if (ev) { *event = *ev; ctx->first_event = (ctx->first_event + 1) % ctx->max_events; ctx->num_events--; talloc_steal(event, event->data); break; } // If there's a changed property, generate change event (never queued). if (gen_property_change_event(ctx)) break; // Pop item from message queue, and return as event. if (gen_log_message_event(ctx)) break; int r = wait_wakeup(ctx, deadline); if (r == ETIMEDOUT) break; } ctx->queued_wakeup = false; pthread_mutex_unlock(&ctx->lock); return event; } void mpv_wakeup(mpv_handle *ctx) { pthread_mutex_lock(&ctx->lock); ctx->queued_wakeup = true; wakeup_client(ctx); pthread_mutex_unlock(&ctx->lock); } // map client API types to internal types static const struct m_option type_conv[] = { [MPV_FORMAT_STRING] = { .type = CONF_TYPE_STRING }, [MPV_FORMAT_FLAG] = { .type = CONF_TYPE_FLAG }, [MPV_FORMAT_INT64] = { .type = CONF_TYPE_INT64 }, [MPV_FORMAT_DOUBLE] = { .type = CONF_TYPE_DOUBLE }, [MPV_FORMAT_NODE] = { .type = CONF_TYPE_NODE }, }; static const struct m_option *get_mp_type(mpv_format format) { if ((unsigned)format >= MP_ARRAY_SIZE(type_conv)) return NULL; if (!type_conv[format].type) return NULL; return &type_conv[format]; } // for read requests - MPV_FORMAT_OSD_STRING special handling static const struct m_option *get_mp_type_get(mpv_format format) { if (format == MPV_FORMAT_OSD_STRING) format = MPV_FORMAT_STRING; // it's string data, just other semantics return get_mp_type(format); } // move src->dst, and do implicit conversion if possible (conversions to or // from strings are handled otherwise) static bool conv_node_to_format(void *dst, mpv_format dst_fmt, mpv_node *src) { if (dst_fmt == src->format) { const struct m_option *type = get_mp_type(dst_fmt); memcpy(dst, &src->u, type->type->size); return true; } if (dst_fmt == MPV_FORMAT_DOUBLE && src->format == MPV_FORMAT_INT64) { *(double *)dst = src->u.int64; return true; } if (dst_fmt == MPV_FORMAT_INT64 && src->format == MPV_FORMAT_DOUBLE) { if (src->u.double_ > (double)INT64_MIN && src->u.double_ < (double)INT64_MAX) { *(int64_t *)dst = src->u.double_; return true; } } return false; } void mpv_free_node_contents(mpv_node *node) { static const struct m_option type = { .type = CONF_TYPE_NODE }; m_option_free(&type, node); } int mpv_set_option(mpv_handle *ctx, const char *name, mpv_format format, void *data) { const struct m_option *type = get_mp_type(format); if (!type) return MPV_ERROR_OPTION_FORMAT; struct mpv_node tmp; if (format != MPV_FORMAT_NODE) { tmp.format = format; memcpy(&tmp.u, data, type->type->size); data = &tmp; } lock_core(ctx); int err = m_config_set_option_node(ctx->mpctx->mconfig, bstr0(name), data, 0); unlock_core(ctx); switch (err) { case M_OPT_MISSING_PARAM: case M_OPT_INVALID: return MPV_ERROR_OPTION_ERROR; case M_OPT_OUT_OF_RANGE: return MPV_ERROR_OPTION_FORMAT; case M_OPT_UNKNOWN: return MPV_ERROR_OPTION_NOT_FOUND; default: if (err >= 0) return 0; return MPV_ERROR_OPTION_ERROR; } } int mpv_set_option_string(mpv_handle *ctx, const char *name, const char *data) { return mpv_set_option(ctx, name, MPV_FORMAT_STRING, &data); } // Run a command in the playback thread. static void run_locked(mpv_handle *ctx, void (*fn)(void *fn_data), void *fn_data) { mp_dispatch_lock(ctx->mpctx->dispatch); fn(fn_data); mp_dispatch_unlock(ctx->mpctx->dispatch); } // Run a command asynchronously. It's the responsibility of the caller to // actually send the reply. This helper merely saves a small part of the // required boilerplate to do so. // fn: callback to execute the request // fn_data: opaque caller-defined argument for fn. This will be automatically // freed with talloc_free(fn_data). static int run_async(mpv_handle *ctx, void (*fn)(void *fn_data), void *fn_data) { int err = reserve_reply(ctx); if (err < 0) { talloc_free(fn_data); return err; } mp_dispatch_enqueue(ctx->mpctx->dispatch, fn, fn_data); return 0; } struct cmd_request { struct MPContext *mpctx; struct mp_cmd *cmd; int status; struct mpv_node *res; struct mp_waiter completion; }; static void cmd_complete(struct mp_cmd_ctx *cmd) { struct cmd_request *req = cmd->on_completion_priv; req->status = cmd->success ? 0 : MPV_ERROR_COMMAND; if (req->res) { *req->res = cmd->result; cmd->result = (mpv_node){0}; } // Unblock the waiting thread (especially for async commands). mp_waiter_wakeup(&req->completion, 0); } static int run_client_command(mpv_handle *ctx, struct mp_cmd *cmd, mpv_node *res) { if (!cmd) return MPV_ERROR_INVALID_PARAMETER; if (!ctx->mpctx->initialized) { talloc_free(cmd); return MPV_ERROR_UNINITIALIZED; } cmd->sender = ctx->name; struct cmd_request req = { .mpctx = ctx->mpctx, .cmd = cmd, .res = res, .completion = MP_WAITER_INITIALIZER, }; bool async = cmd->flags & MP_ASYNC_CMD; lock_core(ctx); if (async) { run_command(ctx->mpctx, cmd, NULL, NULL, NULL); } else { struct mp_abort_entry *abort = NULL; if (cmd->def->can_abort) { abort = talloc_zero(NULL, struct mp_abort_entry); abort->client = ctx; } run_command(ctx->mpctx, cmd, abort, cmd_complete, &req); } unlock_core(ctx); if (!async) mp_waiter_wait(&req.completion); return req.status; } int mpv_command(mpv_handle *ctx, const char **args) { return run_client_command(ctx, mp_input_parse_cmd_strv(ctx->log, args), NULL); } int mpv_command_node(mpv_handle *ctx, mpv_node *args, mpv_node *result) { struct mpv_node rn = {.format = MPV_FORMAT_NONE}; int r = run_client_command(ctx, mp_input_parse_cmd_node(ctx->log, args), &rn); if (result && r >= 0) *result = rn; return r; } int mpv_command_ret(mpv_handle *ctx, const char **args, mpv_node *result) { struct mpv_node rn = {.format = MPV_FORMAT_NONE}; int r = run_client_command(ctx, mp_input_parse_cmd_strv(ctx->log, args), &rn); if (result && r >= 0) *result = rn; return r; } int mpv_command_string(mpv_handle *ctx, const char *args) { return run_client_command(ctx, mp_input_parse_cmd(ctx->mpctx->input, bstr0((char*)args), ctx->name), NULL); } struct async_cmd_request { struct MPContext *mpctx; struct mp_cmd *cmd; struct mpv_handle *reply_ctx; uint64_t userdata; }; static void async_cmd_complete(struct mp_cmd_ctx *cmd) { struct async_cmd_request *req = cmd->on_completion_priv; struct mpv_event_command *data = talloc_zero(NULL, struct mpv_event_command); data->result = cmd->result; cmd->result = (mpv_node){0}; talloc_steal(data, node_get_alloc(&data->result)); struct mpv_event reply = { .event_id = MPV_EVENT_COMMAND_REPLY, .data = data, .error = cmd->success ? 0 : MPV_ERROR_COMMAND, }; send_reply(req->reply_ctx, req->userdata, &reply); talloc_free(req); } static void async_cmd_fn(void *data) { struct async_cmd_request *req = data; struct mp_cmd *cmd = req->cmd; ta_set_parent(cmd, NULL); req->cmd = NULL; struct mp_abort_entry *abort = NULL; if (cmd->def->can_abort) { abort = talloc_zero(NULL, struct mp_abort_entry); abort->client = req->reply_ctx; abort->client_work_type = MPV_EVENT_COMMAND_REPLY; abort->client_work_id = req->userdata; } // This will synchronously or asynchronously call cmd_complete (depending // on the command). run_command(req->mpctx, cmd, abort, async_cmd_complete, req); } static int run_async_cmd(mpv_handle *ctx, uint64_t ud, struct mp_cmd *cmd) { if (!cmd) return MPV_ERROR_INVALID_PARAMETER; if (!ctx->mpctx->initialized) { talloc_free(cmd); return MPV_ERROR_UNINITIALIZED; } cmd->sender = ctx->name; struct async_cmd_request *req = talloc_ptrtype(NULL, req); *req = (struct async_cmd_request){ .mpctx = ctx->mpctx, .cmd = talloc_steal(req, cmd), .reply_ctx = ctx, .userdata = ud, }; return run_async(ctx, async_cmd_fn, req); } int mpv_command_async(mpv_handle *ctx, uint64_t ud, const char **args) { return run_async_cmd(ctx, ud, mp_input_parse_cmd_strv(ctx->log, args)); } int mpv_command_node_async(mpv_handle *ctx, uint64_t ud, mpv_node *args) { return run_async_cmd(ctx, ud, mp_input_parse_cmd_node(ctx->log, args)); } void mpv_abort_async_command(mpv_handle *ctx, uint64_t reply_userdata) { abort_async(ctx->mpctx, ctx, MPV_EVENT_COMMAND_REPLY, reply_userdata); } static int translate_property_error(int errc) { switch (errc) { case M_PROPERTY_OK: return 0; case M_PROPERTY_ERROR: return MPV_ERROR_PROPERTY_ERROR; case M_PROPERTY_UNAVAILABLE: return MPV_ERROR_PROPERTY_UNAVAILABLE; case M_PROPERTY_NOT_IMPLEMENTED: return MPV_ERROR_PROPERTY_ERROR; case M_PROPERTY_UNKNOWN: return MPV_ERROR_PROPERTY_NOT_FOUND; case M_PROPERTY_INVALID_FORMAT: return MPV_ERROR_PROPERTY_FORMAT; // shouldn't happen default: return MPV_ERROR_PROPERTY_ERROR; } } struct setproperty_request { struct MPContext *mpctx; const char *name; int format; void *data; int status; struct mpv_handle *reply_ctx; uint64_t userdata; }; static void setproperty_fn(void *arg) { struct setproperty_request *req = arg; const struct m_option *type = get_mp_type(req->format); struct mpv_node *node; struct mpv_node tmp; if (req->format == MPV_FORMAT_NODE) { node = req->data; } else { tmp.format = req->format; memcpy(&tmp.u, req->data, type->type->size); node = &tmp; } int err = mp_property_do(req->name, M_PROPERTY_SET_NODE, node, req->mpctx); req->status = translate_property_error(err); if (req->reply_ctx) { struct mpv_event reply = { .event_id = MPV_EVENT_SET_PROPERTY_REPLY, .error = req->status, }; send_reply(req->reply_ctx, req->userdata, &reply); talloc_free(req); } } int mpv_set_property(mpv_handle *ctx, const char *name, mpv_format format, void *data) { if (!ctx->mpctx->initialized) { int r = mpv_set_option(ctx, name, format, data); if (r == MPV_ERROR_OPTION_NOT_FOUND && mp_get_property_id(ctx->mpctx, name) >= 0) return MPV_ERROR_PROPERTY_UNAVAILABLE; switch (r) { case MPV_ERROR_SUCCESS: return MPV_ERROR_SUCCESS; case MPV_ERROR_OPTION_FORMAT: return MPV_ERROR_PROPERTY_FORMAT; case MPV_ERROR_OPTION_NOT_FOUND: return MPV_ERROR_PROPERTY_NOT_FOUND; default: return MPV_ERROR_PROPERTY_ERROR; } } if (!get_mp_type(format)) return MPV_ERROR_PROPERTY_FORMAT; struct setproperty_request req = { .mpctx = ctx->mpctx, .name = name, .format = format, .data = data, }; run_locked(ctx, setproperty_fn, &req); return req.status; } int mpv_del_property(mpv_handle *ctx, const char *name) { const char* args[] = { "del", name, NULL }; return mpv_command(ctx, args); } int mpv_set_property_string(mpv_handle *ctx, const char *name, const char *data) { return mpv_set_property(ctx, name, MPV_FORMAT_STRING, &data); } static void free_prop_set_req(void *ptr) { struct setproperty_request *req = ptr; const struct m_option *type = get_mp_type(req->format); m_option_free(type, req->data); } int mpv_set_property_async(mpv_handle *ctx, uint64_t ud, const char *name, mpv_format format, void *data) { const struct m_option *type = get_mp_type(format); if (!ctx->mpctx->initialized) return MPV_ERROR_UNINITIALIZED; if (!type) return MPV_ERROR_PROPERTY_FORMAT; struct setproperty_request *req = talloc_ptrtype(NULL, req); *req = (struct setproperty_request){ .mpctx = ctx->mpctx, .name = talloc_strdup(req, name), .format = format, .data = talloc_zero_size(req, type->type->size), .reply_ctx = ctx, .userdata = ud, }; m_option_copy(type, req->data, data); talloc_set_destructor(req, free_prop_set_req); return run_async(ctx, setproperty_fn, req); } struct getproperty_request { struct MPContext *mpctx; const char *name; mpv_format format; void *data; int status; struct mpv_handle *reply_ctx; uint64_t userdata; }; static void free_prop_data(void *ptr) { struct mpv_event_property *prop = ptr; const struct m_option *type = get_mp_type_get(prop->format); m_option_free(type, prop->data); } static void getproperty_fn(void *arg) { struct getproperty_request *req = arg; const struct m_option *type = get_mp_type_get(req->format); union m_option_value xdata = {0}; void *data = req->data ? req->data : &xdata; int err = -1; switch (req->format) { case MPV_FORMAT_OSD_STRING: err = mp_property_do(req->name, M_PROPERTY_PRINT, data, req->mpctx); break; case MPV_FORMAT_STRING: { char *s = NULL; err = mp_property_do(req->name, M_PROPERTY_GET_STRING, &s, req->mpctx); if (err == M_PROPERTY_OK) *(char **)data = s; break; } case MPV_FORMAT_NODE: case MPV_FORMAT_FLAG: case MPV_FORMAT_INT64: case MPV_FORMAT_DOUBLE: { struct mpv_node node = {{0}}; err = mp_property_do(req->name, M_PROPERTY_GET_NODE, &node, req->mpctx); if (err == M_PROPERTY_NOT_IMPLEMENTED) { // Go through explicit string conversion. Same reasoning as on the // GET code path. char *s = NULL; err = mp_property_do(req->name, M_PROPERTY_GET_STRING, &s, req->mpctx); if (err != M_PROPERTY_OK) break; node.format = MPV_FORMAT_STRING; node.u.string = s; } else if (err <= 0) break; if (req->format == MPV_FORMAT_NODE) { *(struct mpv_node *)data = node; } else { if (!conv_node_to_format(data, req->format, &node)) { err = M_PROPERTY_INVALID_FORMAT; mpv_free_node_contents(&node); } } break; } default: abort(); } req->status = translate_property_error(err); if (req->reply_ctx) { struct mpv_event_property *prop = talloc_ptrtype(NULL, prop); *prop = (struct mpv_event_property){ .name = talloc_steal(prop, (char *)req->name), .format = req->format, .data = talloc_size(prop, type->type->size), }; // move data memcpy(prop->data, &xdata, type->type->size); talloc_set_destructor(prop, free_prop_data); struct mpv_event reply = { .event_id = MPV_EVENT_GET_PROPERTY_REPLY, .data = prop, .error = req->status, }; send_reply(req->reply_ctx, req->userdata, &reply); talloc_free(req); } } int mpv_get_property(mpv_handle *ctx, const char *name, mpv_format format, void *data) { if (!ctx->mpctx->initialized) return MPV_ERROR_UNINITIALIZED; if (!data) return MPV_ERROR_INVALID_PARAMETER; if (!get_mp_type_get(format)) return MPV_ERROR_PROPERTY_FORMAT; struct getproperty_request req = { .mpctx = ctx->mpctx, .name = name, .format = format, .data = data, }; run_locked(ctx, getproperty_fn, &req); return req.status; } char *mpv_get_property_string(mpv_handle *ctx, const char *name) { char *str = NULL; mpv_get_property(ctx, name, MPV_FORMAT_STRING, &str); return str; } char *mpv_get_property_osd_string(mpv_handle *ctx, const char *name) { char *str = NULL; mpv_get_property(ctx, name, MPV_FORMAT_OSD_STRING, &str); return str; } int mpv_get_property_async(mpv_handle *ctx, uint64_t ud, const char *name, mpv_format format) { if (!ctx->mpctx->initialized) return MPV_ERROR_UNINITIALIZED; if (!get_mp_type_get(format)) return MPV_ERROR_PROPERTY_FORMAT; struct getproperty_request *req = talloc_ptrtype(NULL, req); *req = (struct getproperty_request){ .mpctx = ctx->mpctx, .name = talloc_strdup(req, name), .format = format, .reply_ctx = ctx, .userdata = ud, }; return run_async(ctx, getproperty_fn, req); } static void property_free(void *p) { struct observe_property *prop = p; assert(prop->refcount == 0); if (prop->type) { m_option_free(prop->type, &prop->value); m_option_free(prop->type, &prop->value_ret); } } int mpv_observe_property(mpv_handle *ctx, uint64_t userdata, const char *name, mpv_format format) { const struct m_option *type = get_mp_type_get(format); if (format != MPV_FORMAT_NONE && !type) return MPV_ERROR_PROPERTY_FORMAT; // Explicitly disallow this, because it would require a special code path. if (format == MPV_FORMAT_OSD_STRING) return MPV_ERROR_PROPERTY_FORMAT; pthread_mutex_lock(&ctx->lock); assert(!ctx->destroying); struct observe_property *prop = talloc_ptrtype(ctx, prop); talloc_set_destructor(prop, property_free); *prop = (struct observe_property){ .owner = ctx, .name = talloc_strdup(prop, name), .id = mp_get_property_id(ctx->mpctx, name), .event_mask = mp_get_property_event_mask(name), .reply_id = userdata, .format = format, .type = type, .change_ts = 1, // force initial event .refcount = 1, }; ctx->properties_change_ts += 1; MP_TARRAY_APPEND(ctx, ctx->properties, ctx->num_properties, prop); ctx->property_event_masks |= prop->event_mask; ctx->new_property_events = true; ctx->cur_property_index = 0; ctx->has_pending_properties = true; pthread_mutex_unlock(&ctx->lock); mp_wakeup_core(ctx->mpctx); return 0; } int mpv_unobserve_property(mpv_handle *ctx, uint64_t userdata) { pthread_mutex_lock(&ctx->lock); int count = 0; for (int n = ctx->num_properties - 1; n >= 0; n--) { struct observe_property *prop = ctx->properties[n]; // Perform actual removal of the property lazily to avoid creating // dangling pointers and such. if (prop->reply_id == userdata) { prop_unref(prop); ctx->properties_change_ts += 1; MP_TARRAY_REMOVE_AT(ctx->properties, ctx->num_properties, n); ctx->cur_property_index = 0; count++; } } pthread_mutex_unlock(&ctx->lock); return count; } static bool property_shared_prefix(const char *a0, const char *b0) { bstr a = bstr0(a0); bstr b = bstr0(b0); // Treat options and properties as equivalent. bstr_eatstart0(&a, "options/"); bstr_eatstart0(&b, "options/"); // Compare the potentially-common portion if (memcmp(a.start, b.start, MPMIN(a.len, b.len))) return false; // If lengths were equal, we're done if (a.len == b.len) return true; // Check for a slash in the first non-common byte of the longer string if (a.len > b.len) return a.start[b.len] == '/'; else return b.start[a.len] == '/'; } // Broadcast that a property has changed. void mp_client_property_change(struct MPContext *mpctx, const char *name) { struct mp_client_api *clients = mpctx->clients; int id = mp_get_property_id(mpctx, name); bool any_pending = false; pthread_mutex_lock(&clients->lock); for (int n = 0; n < clients->num_clients; n++) { struct mpv_handle *client = clients->clients[n]; pthread_mutex_lock(&client->lock); for (int i = 0; i < client->num_properties; i++) { if (client->properties[i]->id == id && property_shared_prefix(name, client->properties[i]->name)) { client->properties[i]->change_ts += 1; client->has_pending_properties = true; any_pending = true; } } pthread_mutex_unlock(&client->lock); } pthread_mutex_unlock(&clients->lock); // If we're inside mp_dispatch_queue_process(), this will cause the playloop // to be re-run (to get mp_client_send_property_changes() called). If we're // inside the normal playloop, this does nothing, but the latter function // will be called at the end of the playloop anyway. if (any_pending) mp_dispatch_adjust_timeout(mpctx->dispatch, 0); } // Mark properties as changed in reaction to specific events. // Called with ctx->lock held. static void notify_property_events(struct mpv_handle *ctx, int event) { uint64_t mask = 1ULL << event; for (int i = 0; i < ctx->num_properties; i++) { if (ctx->properties[i]->event_mask & mask) { ctx->properties[i]->change_ts += 1; ctx->has_pending_properties = true; } } // Same as in mp_client_property_change(). if (ctx->has_pending_properties) mp_dispatch_adjust_timeout(ctx->mpctx->dispatch, 0); } // Call with ctx->lock held (only). May temporarily drop the lock. static void send_client_property_changes(struct mpv_handle *ctx) { uint64_t cur_ts = ctx->properties_change_ts; ctx->has_pending_properties = false; for (int n = 0; n < ctx->num_properties; n++) { struct observe_property *prop = ctx->properties[n]; if (prop->value_ts == prop->change_ts) continue; bool changed = false; if (prop->format) { const struct m_option *type = prop->type; union m_option_value val = {0}; struct getproperty_request req = { .mpctx = ctx->mpctx, .name = prop->name, .format = prop->format, .data = &val, }; // Temporarily unlock and read the property. The very important // thing is that property getters can do whatever they want, _and_ // that they may wait on the client API user thread (if vo_libmpv // or similar things are involved). prop->refcount += 1; // keep prop alive (esp. prop->name) ctx->async_counter += 1; // keep ctx alive pthread_mutex_unlock(&ctx->lock); getproperty_fn(&req); pthread_mutex_lock(&ctx->lock); ctx->async_counter -= 1; prop_unref(prop); // Set if observed properties was changed or something similar // => start over, retry next time. if (cur_ts != ctx->properties_change_ts || ctx->destroying) { m_option_free(type, &val); mp_wakeup_core(ctx->mpctx); ctx->has_pending_properties = true; break; } assert(prop->refcount > 0); bool val_valid = req.status >= 0; changed = prop->value_valid != val_valid; if (prop->value_valid && val_valid) changed = !equal_mpv_value(&prop->value, &val, prop->format); if (prop->value_ts == 0) changed = true; // initial event prop->value_valid = val_valid; if (changed && val_valid) { // move val to prop->value m_option_free(type, &prop->value); memcpy(&prop->value, &val, type->type->size); memset(&val, 0, type->type->size); } m_option_free(prop->type, &val); } else { changed = true; } if (prop->waiting_for_hook) ctx->new_property_events = true; // make sure to wakeup // Avoid retriggering the change event if the property didn't change, // and the previous value was actually returned to the client. if (!changed && prop->value_ret_ts == prop->value_ts) { prop->value_ret_ts = prop->change_ts; // no change => no event prop->waiting_for_hook = false; } else { ctx->new_property_events = true; } prop->value_ts = prop->change_ts; } if (ctx->destroying || ctx->new_property_events) wakeup_client(ctx); } void mp_client_send_property_changes(struct MPContext *mpctx) { struct mp_client_api *clients = mpctx->clients; pthread_mutex_lock(&clients->lock); uint64_t cur_ts = clients->clients_list_change_ts; for (int n = 0; n < clients->num_clients; n++) { struct mpv_handle *ctx = clients->clients[n]; pthread_mutex_lock(&ctx->lock); if (!ctx->has_pending_properties || ctx->destroying) { pthread_mutex_unlock(&ctx->lock); continue; } // Keep ctx->lock locked (unlock order does not matter). pthread_mutex_unlock(&clients->lock); send_client_property_changes(ctx); pthread_mutex_unlock(&ctx->lock); pthread_mutex_lock(&clients->lock); if (cur_ts != clients->clients_list_change_ts) { // List changed; need to start over. Do it in the next iteration. mp_wakeup_core(mpctx); break; } } pthread_mutex_unlock(&clients->lock); } // Set ctx->cur_event to a generated property change event, if there is any // outstanding property. static bool gen_property_change_event(struct mpv_handle *ctx) { if (!ctx->mpctx->initialized) return false; while (1) { if (ctx->cur_property_index >= ctx->num_properties) { ctx->new_property_events &= ctx->num_properties > 0; if (!ctx->new_property_events) break; ctx->new_property_events = false; ctx->cur_property_index = 0; } struct observe_property *prop = ctx->properties[ctx->cur_property_index++]; if (prop->value_ts == prop->change_ts && // not a stale value? prop->value_ret_ts != prop->value_ts) // other value than last time? { prop->value_ret_ts = prop->value_ts; prop->waiting_for_hook = false; prop_unref(ctx->cur_property); ctx->cur_property = prop; prop->refcount += 1; if (prop->value_valid) m_option_copy(prop->type, &prop->value_ret, &prop->value); ctx->cur_property_event = (struct mpv_event_property){ .name = prop->name, .format = prop->value_valid ? prop->format : 0, .data = prop->value_valid ? &prop->value_ret : NULL, }; *ctx->cur_event = (struct mpv_event){ .event_id = MPV_EVENT_PROPERTY_CHANGE, .reply_userdata = prop->reply_id, .data = &ctx->cur_property_event, }; return true; } } return false; } int mpv_hook_add(mpv_handle *ctx, uint64_t reply_userdata, const char *name, int priority) { lock_core(ctx); mp_hook_add(ctx->mpctx, ctx->name, ctx->id, name, reply_userdata, priority); unlock_core(ctx); return 0; } int mpv_hook_continue(mpv_handle *ctx, uint64_t id) { lock_core(ctx); int r = mp_hook_continue(ctx->mpctx, ctx->id, id); unlock_core(ctx); return r; } int mpv_load_config_file(mpv_handle *ctx, const char *filename) { lock_core(ctx); int r = m_config_parse_config_file(ctx->mpctx->mconfig, ctx->mpctx->global, filename, NULL, 0); unlock_core(ctx); if (r == 0) return MPV_ERROR_INVALID_PARAMETER; if (r < 0) return MPV_ERROR_OPTION_ERROR; return 0; } static void msg_wakeup(void *p) { mpv_handle *ctx = p; wakeup_client(ctx); } // Undocumented: if min_level starts with "silent:", then log messages are not // returned to the API user, but are stored until logging is enabled normally // again by calling this without "silent:". (Using a different level will // flush it, though.) int mpv_request_log_messages(mpv_handle *ctx, const char *min_level) { bstr blevel = bstr0(min_level); bool silent = bstr_eatstart0(&blevel, "silent:"); int level = -1; for (int n = 0; n < MSGL_MAX + 1; n++) { if (mp_log_levels[n] && bstr_equals0(blevel, mp_log_levels[n])) { level = n; break; } } if (bstr_equals0(blevel, "terminal-default")) level = MP_LOG_BUFFER_MSGL_TERM; if (level < 0 && strcmp(min_level, "no") != 0) return MPV_ERROR_INVALID_PARAMETER; pthread_mutex_lock(&ctx->lock); if (level < 0 || level != ctx->messages_level) { mp_msg_log_buffer_destroy(ctx->messages); ctx->messages = NULL; } if (level >= 0) { if (!ctx->messages) { int size = level >= MSGL_V ? 10000 : 1000; ctx->messages = mp_msg_log_buffer_new(ctx->mpctx->global, size, level, msg_wakeup, ctx); ctx->messages_level = level; } mp_msg_log_buffer_set_silent(ctx->messages, silent); } wakeup_client(ctx); pthread_mutex_unlock(&ctx->lock); return 0; } // Set ctx->cur_event to a generated log message event, if any available. static bool gen_log_message_event(struct mpv_handle *ctx) { if (ctx->messages) { struct mp_log_buffer_entry *msg = mp_msg_log_buffer_read(ctx->messages); if (msg) { struct mpv_event_log_message *cmsg = talloc_ptrtype(ctx->cur_event, cmsg); talloc_steal(cmsg, msg); *cmsg = (struct mpv_event_log_message){ .prefix = msg->prefix, .level = mp_log_levels[msg->level], .log_level = mp_mpv_log_levels[msg->level], .text = msg->text, }; *ctx->cur_event = (struct mpv_event){ .event_id = MPV_EVENT_LOG_MESSAGE, .data = cmsg, }; return true; } } return false; } int mpv_get_wakeup_pipe(mpv_handle *ctx) { pthread_mutex_lock(&ctx->wakeup_lock); if (ctx->wakeup_pipe[0] == -1) { if (mp_make_wakeup_pipe(ctx->wakeup_pipe) >= 0) (void)write(ctx->wakeup_pipe[1], &(char){0}, 1); } int fd = ctx->wakeup_pipe[0]; pthread_mutex_unlock(&ctx->wakeup_lock); return fd; } unsigned long mpv_client_api_version(void) { return MPV_CLIENT_API_VERSION; } int mpv_event_to_node(mpv_node *dst, mpv_event *event) { *dst = (mpv_node){0}; node_init(dst, MPV_FORMAT_NODE_MAP, NULL); node_map_add_string(dst, "event", mpv_event_name(event->event_id)); if (event->error < 0) node_map_add_string(dst, "error", mpv_error_string(event->error)); if (event->reply_userdata) node_map_add_int64(dst, "id", event->reply_userdata); switch (event->event_id) { case MPV_EVENT_START_FILE: { mpv_event_start_file *esf = event->data; node_map_add_int64(dst, "playlist_entry_id", esf->playlist_entry_id); break; } case MPV_EVENT_END_FILE: { mpv_event_end_file *eef = event->data; const char *reason; switch (eef->reason) { case MPV_END_FILE_REASON_EOF: reason = "eof"; break; case MPV_END_FILE_REASON_STOP: reason = "stop"; break; case MPV_END_FILE_REASON_QUIT: reason = "quit"; break; case MPV_END_FILE_REASON_ERROR: reason = "error"; break; case MPV_END_FILE_REASON_REDIRECT: reason = "redirect"; break; default: reason = "unknown"; } node_map_add_string(dst, "reason", reason); node_map_add_int64(dst, "playlist_entry_id", eef->playlist_entry_id); if (eef->playlist_insert_id) { node_map_add_int64(dst, "playlist_insert_id", eef->playlist_insert_id); node_map_add_int64(dst, "playlist_insert_num_entries", eef->playlist_insert_num_entries); } if (eef->reason == MPV_END_FILE_REASON_ERROR) node_map_add_string(dst, "file_error", mpv_error_string(eef->error)); break; } case MPV_EVENT_LOG_MESSAGE: { mpv_event_log_message *msg = event->data; node_map_add_string(dst, "prefix", msg->prefix); node_map_add_string(dst, "level", msg->level); node_map_add_string(dst, "text", msg->text); break; } case MPV_EVENT_CLIENT_MESSAGE: { mpv_event_client_message *msg = event->data; struct mpv_node *args = node_map_add(dst, "args", MPV_FORMAT_NODE_ARRAY); for (int n = 0; n < msg->num_args; n++) { struct mpv_node *sn = node_array_add(args, MPV_FORMAT_NONE); sn->format = MPV_FORMAT_STRING; sn->u.string = (char *)msg->args[n]; } break; } case MPV_EVENT_PROPERTY_CHANGE: { mpv_event_property *prop = event->data; node_map_add_string(dst, "name", prop->name); switch (prop->format) { case MPV_FORMAT_NODE: *node_map_add(dst, "data", MPV_FORMAT_NONE) = *(struct mpv_node *)prop->data; break; case MPV_FORMAT_DOUBLE: node_map_add_double(dst, "data", *(double *)prop->data); break; case MPV_FORMAT_FLAG: node_map_add_flag(dst, "data", *(int *)prop->data); break; case MPV_FORMAT_STRING: node_map_add_string(dst, "data", *(char **)prop->data); break; default: ; } break; } case MPV_EVENT_COMMAND_REPLY: { mpv_event_command *cmd = event->data; *node_map_add(dst, "result", MPV_FORMAT_NONE) = cmd->result; break; } case MPV_EVENT_HOOK: { mpv_event_hook *hook = event->data; node_map_add_int64(dst, "hook_id", hook->id); break; } } return 0; } static const char *const err_table[] = { [-MPV_ERROR_SUCCESS] = "success", [-MPV_ERROR_EVENT_QUEUE_FULL] = "event queue full", [-MPV_ERROR_NOMEM] = "memory allocation failed", [-MPV_ERROR_UNINITIALIZED] = "core not uninitialized", [-MPV_ERROR_INVALID_PARAMETER] = "invalid parameter", [-MPV_ERROR_OPTION_NOT_FOUND] = "option not found", [-MPV_ERROR_OPTION_FORMAT] = "unsupported format for accessing option", [-MPV_ERROR_OPTION_ERROR] = "error setting option", [-MPV_ERROR_PROPERTY_NOT_FOUND] = "property not found", [-MPV_ERROR_PROPERTY_FORMAT] = "unsupported format for accessing property", [-MPV_ERROR_PROPERTY_UNAVAILABLE] = "property unavailable", [-MPV_ERROR_PROPERTY_ERROR] = "error accessing property", [-MPV_ERROR_COMMAND] = "error running command", [-MPV_ERROR_LOADING_FAILED] = "loading failed", [-MPV_ERROR_AO_INIT_FAILED] = "audio output initialization failed", [-MPV_ERROR_VO_INIT_FAILED] = "video output initialization failed", [-MPV_ERROR_NOTHING_TO_PLAY] = "no audio or video data played", [-MPV_ERROR_UNKNOWN_FORMAT] = "unrecognized file format", [-MPV_ERROR_UNSUPPORTED] = "not supported", [-MPV_ERROR_NOT_IMPLEMENTED] = "operation not implemented", [-MPV_ERROR_GENERIC] = "something happened", }; const char *mpv_error_string(int error) { error = -error; if (error < 0) error = 0; const char *name = NULL; if (error < MP_ARRAY_SIZE(err_table)) name = err_table[error]; return name ? name : "unknown error"; } static const char *const event_table[] = { [MPV_EVENT_NONE] = "none", [MPV_EVENT_SHUTDOWN] = "shutdown", [MPV_EVENT_LOG_MESSAGE] = "log-message", [MPV_EVENT_GET_PROPERTY_REPLY] = "get-property-reply", [MPV_EVENT_SET_PROPERTY_REPLY] = "set-property-reply", [MPV_EVENT_COMMAND_REPLY] = "command-reply", [MPV_EVENT_START_FILE] = "start-file", [MPV_EVENT_END_FILE] = "end-file", [MPV_EVENT_FILE_LOADED] = "file-loaded", [MPV_EVENT_IDLE] = "idle", [MPV_EVENT_TICK] = "tick", [MPV_EVENT_CLIENT_MESSAGE] = "client-message", [MPV_EVENT_VIDEO_RECONFIG] = "video-reconfig", [MPV_EVENT_AUDIO_RECONFIG] = "audio-reconfig", [MPV_EVENT_SEEK] = "seek", [MPV_EVENT_PLAYBACK_RESTART] = "playback-restart", [MPV_EVENT_PROPERTY_CHANGE] = "property-change", [MPV_EVENT_QUEUE_OVERFLOW] = "event-queue-overflow", [MPV_EVENT_HOOK] = "hook", }; const char *mpv_event_name(mpv_event_id event) { if ((unsigned)event >= MP_ARRAY_SIZE(event_table)) return NULL; return event_table[event]; } void mpv_free(void *data) { talloc_free(data); } int64_t mpv_get_time_ns(mpv_handle *ctx) { return mp_time_ns(); } int64_t mpv_get_time_us(mpv_handle *ctx) { return mp_time_ns() / 1000; } #include "video/out/libmpv.h" static void do_kill(void *ptr) { struct MPContext *mpctx = ptr; struct track *track = mpctx->vo_chain ? mpctx->vo_chain->track : NULL; uninit_video_out(mpctx); if (track) { mpctx->error_playing = MPV_ERROR_VO_INIT_FAILED; error_on_track(mpctx, track); } } // Used by vo_libmpv to (a)synchronously uninitialize video. void kill_video_async(struct mp_client_api *client_api) { struct MPContext *mpctx = client_api->mpctx; mp_dispatch_enqueue(mpctx->dispatch, do_kill, mpctx); } // Used by vo_libmpv to set the current render context. bool mp_set_main_render_context(struct mp_client_api *client_api, struct mpv_render_context *ctx, bool active) { assert(ctx); pthread_mutex_lock(&client_api->lock); bool is_set = !!client_api->render_context; bool is_same = client_api->render_context == ctx; // Can set if it doesn't remove another existing ctx. bool res = is_same || !is_set; if (res) client_api->render_context = active ? ctx : NULL; pthread_mutex_unlock(&client_api->lock); return res; } // Used by vo_libmpv. Relies on guarantees by mp_render_context_acquire(). struct mpv_render_context * mp_client_api_acquire_render_context(struct mp_client_api *ca) { struct mpv_render_context *res = NULL; pthread_mutex_lock(&ca->lock); if (ca->render_context && mp_render_context_acquire(ca->render_context)) res = ca->render_context; pthread_mutex_unlock(&ca->lock); return res; } // stream_cb struct mp_custom_protocol { char *protocol; void *user_data; mpv_stream_cb_open_ro_fn open_fn; }; int mpv_stream_cb_add_ro(mpv_handle *ctx, const char *protocol, void *user_data, mpv_stream_cb_open_ro_fn open_fn) { if (!open_fn) return MPV_ERROR_INVALID_PARAMETER; struct mp_client_api *clients = ctx->clients; int r = 0; pthread_mutex_lock(&clients->lock); for (int n = 0; n < clients->num_custom_protocols; n++) { struct mp_custom_protocol *proto = &clients->custom_protocols[n]; if (strcmp(proto->protocol, protocol) == 0) { r = MPV_ERROR_INVALID_PARAMETER; break; } } if (stream_has_proto(protocol)) r = MPV_ERROR_INVALID_PARAMETER; if (r >= 0) { struct mp_custom_protocol proto = { .protocol = talloc_strdup(clients, protocol), .user_data = user_data, .open_fn = open_fn, }; MP_TARRAY_APPEND(clients, clients->custom_protocols, clients->num_custom_protocols, proto); } pthread_mutex_unlock(&clients->lock); return r; } bool mp_streamcb_lookup(struct mpv_global *g, const char *protocol, void **out_user_data, mpv_stream_cb_open_ro_fn *out_fn) { struct mp_client_api *clients = g->client_api; bool found = false; pthread_mutex_lock(&clients->lock); for (int n = 0; n < clients->num_custom_protocols; n++) { struct mp_custom_protocol *proto = &clients->custom_protocols[n]; if (strcmp(proto->protocol, protocol) == 0) { *out_user_data = proto->user_data; *out_fn = proto->open_fn; found = true; break; } } pthread_mutex_unlock(&clients->lock); return found; }