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mpv/player/client.c
wm4 733bdebcb9 client API: minor optimizations for property notification
Internally, there are two mechanisms which can trigger property
notification as used with "observed" properties in the client API.

The first mechanism associates events with a group of properties that
are potentially changed by a certain event. mp_event_property_change[]
declares these associations, and maps each event to a set of strings.
When an event happens, the set of strings is matched against the list of
observed properties of each client. Make this more efficient by
comparing bitsets of events instead. This way, only a bit-wise "and" is
needed for each observed property. Even better, we can completely skip
clients which have no observed properties that match.

The second mechanism just updates individual properties explicitly by
name. Optimize this by using the property index instead. It would be
nice if we could reuse the first mechanism for the second one, but
there are too many properties to fit into a 64 bit mask.

(Though the limit on 64 events might get us into trouble later...)
2014-08-02 01:53:22 +02:00

1429 lines
43 KiB
C

/* 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 <stddef.h>
#include <stdint.h>
#include <stdlib.h>
#include <unistd.h>
#include <fcntl.h>
#include <errno.h>
#include <assert.h>
#include "common/common.h"
#include "common/msg.h"
#include "common/msg_control.h"
#include "input/input.h"
#include "misc/dispatch.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 "command.h"
#include "core.h"
#include "client.h"
#include "config.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;
};
struct observe_property {
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;
bool changed; // property change should be signaled to user
bool need_new_value; // a new value should be retrieved
bool updating; // a new value is being retrieved
bool dead; // property unobserved while retrieving value
bool new_value_valid, user_value_valid;
union m_option_value new_value, user_value;
struct mpv_handle *client;
};
struct mpv_handle {
// -- immmutable
char *name;
bool owner;
struct mp_log *log;
struct MPContext *mpctx;
struct mp_client_api *clients;
// -- not thread-safe
struct mpv_event *cur_event;
struct mpv_event_property cur_property_event;
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;
bool choke_warning;
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
struct observe_property **properties;
int num_properties;
int lowest_changed; // attempt at making change processing incremental
int properties_updating;
uint64_t property_event_masks; // or-ed together event masks of all properties
struct mp_log_buffer *messages;
};
static bool gen_property_change_event(struct mpv_handle *ctx);
static void notify_property_events(struct mpv_handle *ctx, uint64_t event_mask);
void mp_clients_init(struct MPContext *mpctx)
{
mpctx->clients = talloc_ptrtype(NULL, mpctx->clients);
*mpctx->clients = (struct mp_client_api) {
.mpctx = mpctx,
};
pthread_mutex_init(&mpctx->clients->lock, NULL);
}
void mp_clients_destroy(struct MPContext *mpctx)
{
if (!mpctx->clients)
return;
assert(mpctx->clients->num_clients == 0);
pthread_mutex_destroy(&mpctx->clients->lock);
talloc_free(mpctx->clients);
mpctx->clients = NULL;
}
int mp_clients_num(struct MPContext *mpctx)
{
pthread_mutex_lock(&mpctx->clients->lock);
int num_clients = mpctx->clients->num_clients;
pthread_mutex_unlock(&mpctx->clients->lock);
return num_clients;
}
static struct mpv_handle *find_client(struct mp_client_api *clients,
const char *name)
{
for (int n = 0; n < clients->num_clients; n++) {
if (strcmp(clients->clients[n]->name, name) == 0)
return clients->clients[n];
}
return NULL;
}
struct mpv_handle *mp_new_client(struct mp_client_api *clients, const char *name)
{
pthread_mutex_lock(&clients->lock);
char *unique_name = NULL;
if (find_client(clients, name)) {
for (int n = 2; n < 1000; n++) {
unique_name = talloc_asprintf(NULL, "%s%d", name, n);
if (!find_client(clients, unique_name))
break;
talloc_free(unique_name);
unique_name = NULL;
}
if (!unique_name) {
pthread_mutex_unlock(&clients->lock);
return NULL;
}
}
if (!unique_name)
unique_name = talloc_strdup(NULL, name);
int num_events = 1000;
struct mpv_handle *client = talloc_ptrtype(NULL, client);
*client = (struct mpv_handle){
.name = talloc_steal(client, unique_name),
.log = mp_log_new(client, clients->mpctx->log, unique_name),
.mpctx = clients->mpctx,
.clients = clients,
.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);
mpv_request_event(client, MPV_EVENT_TICK, 0);
MP_TARRAY_APPEND(clients, clients->clients, clients->num_clients, client);
pthread_mutex_unlock(&clients->lock);
return client;
}
const char *mpv_client_name(mpv_handle *ctx)
{
return ctx->name;
}
struct mp_log *mp_client_get_log(struct mpv_handle *ctx)
{
return ctx->log;
}
struct MPContext *mp_client_get_core(struct mpv_handle *ctx)
{
return ctx->mpctx;
}
static void wakeup_client(struct mpv_handle *ctx)
{
pthread_mutex_lock(&ctx->wakeup_lock);
if (!ctx->need_wakeup) {
ctx->need_wakeup = true;
pthread_cond_signal(&ctx->wakeup);
if (ctx->wakeup_cb)
ctx->wakeup_cb(ctx->wakeup_cb_ctx);
if (ctx->wakeup_pipe[0] != -1)
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)
r = mpthread_cond_timedwait(&ctx->wakeup, &ctx->wakeup_lock, end);
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);
}
void mpv_suspend(mpv_handle *ctx)
{
mp_dispatch_suspend(ctx->mpctx->dispatch);
}
void mpv_resume(mpv_handle *ctx)
{
mp_dispatch_resume(ctx->mpctx->dispatch);
}
static void lock_core(mpv_handle *ctx)
{
if (ctx->mpctx->initialized)
mp_dispatch_lock(ctx->mpctx->dispatch);
}
static void unlock_core(mpv_handle *ctx)
{
if (ctx->mpctx->initialized)
mp_dispatch_unlock(ctx->mpctx->dispatch);
}
void mpv_detach_destroy(mpv_handle *ctx)
{
if (!ctx)
return;
pthread_mutex_lock(&ctx->lock);
// 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.
ctx->event_mask = 0;
while (ctx->reserved_events || ctx->properties_updating)
wait_wakeup(ctx, INT64_MAX);
pthread_mutex_unlock(&ctx->lock);
struct mp_client_api *clients = ctx->clients;
pthread_mutex_lock(&clients->lock);
for (int n = 0; n < clients->num_clients; n++) {
if (clients->clients[n] == ctx) {
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;
// shutdown_clients() sleeps to avoid wasting CPU
if (clients->mpctx->input)
mp_input_wakeup(clients->mpctx->input);
break;
}
}
pthread_mutex_unlock(&clients->lock);
assert(!ctx);
}
static void get_thread(void *ptr)
{
*(pthread_t *)ptr = pthread_self();
}
void mpv_terminate_destroy(mpv_handle *ctx)
{
if (!ctx)
return;
mpv_command(ctx, (const char*[]){"quit", NULL});
if (!ctx->owner || !ctx->mpctx->initialized) {
mpv_detach_destroy(ctx);
return;
}
mp_dispatch_lock(ctx->mpctx->dispatch);
assert(ctx->mpctx->autodetach);
ctx->mpctx->autodetach = false;
mp_dispatch_unlock(ctx->mpctx->dispatch);
pthread_t playthread;
mp_dispatch_run(ctx->mpctx->dispatch, get_thread, &playthread);
mpv_detach_destroy(ctx);
// And this is also the reason why we only allow 1 thread (the owner) to
// call this function.
pthread_join(playthread, NULL);
}
mpv_handle *mpv_create(void)
{
struct MPContext *mpctx = mp_create();
mpv_handle *ctx = mp_new_client(mpctx->clients, "main");
if (ctx) {
ctx->owner = true;
// Set some defaults.
mpv_set_option_string(ctx, "config", "no");
mpv_set_option_string(ctx, "idle", "yes");
mpv_set_option_string(ctx, "terminal", "no");
mpv_set_option_string(ctx, "osc", "no");
mpv_set_option_string(ctx, "input-default-bindings", "no");
mpv_set_option_string(ctx, "input-lirc", "no");
} else {
mp_destroy(mpctx);
}
return ctx;
}
static void *playback_thread(void *p)
{
struct MPContext *mpctx = p;
mpctx->autodetach = true;
mp_play_files(mpctx);
// This actually waits until all clients are gone before actually
// destroying mpctx.
mp_destroy(mpctx);
return NULL;
}
int mpv_initialize(mpv_handle *ctx)
{
if (mp_initialize(ctx->mpctx) < 0)
return MPV_ERROR_INVALID_PARAMETER;
pthread_t thread;
if (pthread_create(&thread, NULL, playback_thread, ctx->mpctx) != 0)
return MPV_ERROR_NOMEM;
return 0;
}
// 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->reserved_events++;
res = 0;
}
pthread_mutex_unlock(&ctx->lock);
return res;
}
static int append_event(struct mpv_handle *ctx, struct mpv_event *event)
{
if (ctx->num_events + ctx->reserved_events >= ctx->max_events)
return -1;
ctx->events[(ctx->first_event + ctx->num_events) % ctx->max_events] = *event;
ctx->num_events++;
wakeup_client(ctx);
return 0;
}
static int send_event(struct mpv_handle *ctx, struct mpv_event *event)
{
pthread_mutex_lock(&ctx->lock);
uint64_t mask = 1ULL << event->event_id;
if (ctx->property_event_masks & mask)
notify_property_events(ctx, mask);
if (!(ctx->event_mask & mask)) {
pthread_mutex_unlock(&ctx->lock);
return 0;
}
int r = append_event(ctx, event);
if (r < 0 && !ctx->choke_warning) {
mp_err(ctx->log, "Too many events queued.\n");
ctx->choke_warning = 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) < 0)
abort();
pthread_mutex_unlock(&ctx->lock);
}
static void status_reply(struct mpv_handle *ctx, int event,
uint64_t userdata, int status)
{
struct mpv_event reply = {
.event_id = event,
.error = status,
};
send_reply(ctx, userdata, &reply);
}
// 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_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();
}
}
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,
};
dup_event_data(&event_data);
send_event(clients->clients[n], &event_data);
}
pthread_mutex_unlock(&clients->lock);
}
int mp_client_send_event(struct MPContext *mpctx, const char *client_name,
int event, void *data)
{
struct mp_client_api *clients = mpctx->clients;
int r = 0;
struct mpv_event event_data = {
.event_id = event,
.data = data,
};
pthread_mutex_lock(&clients->lock);
struct mpv_handle *ctx = find_client(clients, client_name);
if (ctx) {
r = send_event(ctx, &event_data);
} else {
r = -1;
talloc_free(data);
}
pthread_mutex_unlock(&clients->lock);
return r;
}
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;
assert(event < 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;
pthread_mutex_unlock(&ctx->lock);
return 0;
}
mpv_event *mpv_wait_event(mpv_handle *ctx, double timeout)
{
mpv_event *event = ctx->cur_event;
pthread_mutex_lock(&ctx->lock);
if (timeout < 0)
timeout = 1e20;
if (ctx->queued_wakeup)
timeout = 0;
int64_t deadline = mp_add_timeout(mp_time_us(), timeout);
*event = (mpv_event){0};
talloc_free_children(event);
while (1) {
if (ctx->num_events) {
*event = ctx->events[ctx->first_event];
ctx->first_event = (ctx->first_event + 1) % ctx->max_events;
ctx->num_events--;
talloc_steal(event, event->data);
break;
}
if (gen_property_change_event(ctx))
break;
if (ctx->messages) {
// Poll the log message queue. Currently we can't/don't do better.
struct mp_log_buffer_entry *msg =
mp_msg_log_buffer_read(ctx->messages);
if (msg) {
event->event_id = MPV_EVENT_LOG_MESSAGE;
struct mpv_event_log_message *cmsg = talloc_ptrtype(event, cmsg);
*cmsg = (struct mpv_event_log_message){
.prefix = talloc_steal(event, msg->prefix),
.level = mp_log_levels[msg->level],
.text = talloc_steal(event, msg->text),
};
event->data = cmsg;
talloc_free(msg);
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 (format < 0 || 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;
}
return false;
}
// Note: for MPV_FORMAT_NODE_MAP, this (incorrectly) takes the order into
// account, instead of treating it as set.
static bool compare_value(void *a, void *b, mpv_format format)
{
switch (format) {
case MPV_FORMAT_NONE:
return true;
case MPV_FORMAT_STRING:
case MPV_FORMAT_OSD_STRING:
return strcmp(*(char **)a, *(char **)b) == 0;
case MPV_FORMAT_FLAG:
return *(int *)a == *(int *)b;
case MPV_FORMAT_INT64:
return *(int64_t *)a == *(int64_t *)b;
case MPV_FORMAT_DOUBLE:
return *(double *)a == *(double *)b;
case MPV_FORMAT_NODE: {
struct mpv_node *a_n = a, *b_n = b;
if (a_n->format != b_n->format)
return false;
return compare_value(&a_n->u, &b_n->u, a_n->format);
}
case MPV_FORMAT_NODE_ARRAY:
case MPV_FORMAT_NODE_MAP:
{
mpv_node_list *l_a = *(mpv_node_list **)a, *l_b = *(mpv_node_list **)b;
if (l_a->num != l_b->num)
return false;
for (int n = 0; n < l_a->num; n++) {
if (!compare_value(&l_a->values[n], &l_b->values[n], MPV_FORMAT_NODE))
return false;
if (format == MPV_FORMAT_NODE_MAP) {
if (strcmp(l_a->keys[n], l_b->keys[n]) != 0)
return false;
}
}
return true;
}
}
abort();
}
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)
{
int flags = ctx->mpctx->initialized ? M_SETOPT_RUNTIME : 0;
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);
format = MPV_FORMAT_NODE;
data = &tmp;
}
lock_core(ctx);
int err = m_config_set_option_node(ctx->mpctx->mconfig, bstr0(name),
data, flags);
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.
// Note: once some things are fixed (like vo_opengl not being safe to be
// called from any thread other than the playback thread), this can
// be replaced by a simpler method.
static void run_locked(mpv_handle *ctx, void (*fn)(void *fn_data), void *fn_data)
{
mp_dispatch_run(ctx->mpctx->dispatch, fn, fn_data);
}
// 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_autofree(ctx->mpctx->dispatch, fn, fn_data);
return 0;
}
struct cmd_request {
struct MPContext *mpctx;
struct mp_cmd *cmd;
int status;
struct mpv_handle *reply_ctx;
uint64_t userdata;
};
static void cmd_fn(void *data)
{
struct cmd_request *req = data;
int r = run_command(req->mpctx, req->cmd);
req->status = r >= 0 ? 0 : MPV_ERROR_COMMAND;
talloc_free(req->cmd);
if (req->reply_ctx) {
status_reply(req->reply_ctx, MPV_EVENT_COMMAND_REPLY,
req->userdata, req->status);
}
}
static int run_client_command(mpv_handle *ctx, struct mp_cmd *cmd)
{
if (!ctx->mpctx->initialized)
return MPV_ERROR_UNINITIALIZED;
if (!cmd)
return MPV_ERROR_INVALID_PARAMETER;
struct cmd_request req = {
.mpctx = ctx->mpctx,
.cmd = cmd,
};
run_locked(ctx, cmd_fn, &req);
return req.status;
}
int mpv_command(mpv_handle *ctx, const char **args)
{
return run_client_command(ctx, mp_input_parse_cmd_strv(ctx->log, 0, args,
ctx->name));
}
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));
}
int mpv_command_async(mpv_handle *ctx, uint64_t ud, const char **args)
{
if (!ctx->mpctx->initialized)
return MPV_ERROR_UNINITIALIZED;
struct mp_cmd *cmd = mp_input_parse_cmd_strv(ctx->log, 0, args, "<client>");
if (!cmd)
return MPV_ERROR_INVALID_PARAMETER;
struct cmd_request *req = talloc_ptrtype(NULL, req);
*req = (struct cmd_request){
.mpctx = ctx->mpctx,
.cmd = cmd,
.reply_ctx = ctx,
.userdata = ud,
};
return run_async(ctx, cmd_fn, req);
}
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);
int err;
switch (req->format) {
case MPV_FORMAT_STRING: {
// Go through explicit string conversion. M_PROPERTY_SET_NODE doesn't
// do this, because it tries to be somewhat type-strict. But the client
// needs a way to set everything by string.
char *s = *(char **)req->data;
err = mp_property_do(req->name, M_PROPERTY_SET_STRING, s, req->mpctx);
break;
}
case MPV_FORMAT_NODE:
case MPV_FORMAT_FLAG:
case MPV_FORMAT_INT64:
case MPV_FORMAT_DOUBLE: {
struct mpv_node node;
if (req->format == MPV_FORMAT_NODE) {
node = *(struct mpv_node *)req->data;
} else {
// These are basically emulated via mpv_node.
node.format = req->format;
memcpy(&node.u, req->data, type->type->size);
}
err = mp_property_do(req->name, M_PROPERTY_SET_NODE, &node, req->mpctx);
break;
}
default:
abort();
}
req->status = translate_property_error(err);
if (req->reply_ctx) {
status_reply(req->reply_ctx, MPV_EVENT_SET_PROPERTY_REPLY,
req->userdata, req->status);
}
}
int mpv_set_property(mpv_handle *ctx, const char *name, mpv_format format,
void *data)
{
if (!ctx->mpctx->initialized)
return MPV_ERROR_UNINITIALIZED;
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_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 **)req->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,
.reply_userdata = req->userdata,
};
send_reply(req->reply_ctx, req->userdata, &reply);
}
}
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;
const struct m_option *type = get_mp_type_get(prop->format);
if (type) {
m_option_free(type, &prop->new_value);
m_option_free(type, &prop->user_value);
}
}
int mpv_observe_property(mpv_handle *ctx, uint64_t userdata,
const char *name, mpv_format format)
{
if (format != MPV_FORMAT_NONE && !get_mp_type_get(format))
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);
struct observe_property *prop = talloc_ptrtype(ctx, prop);
talloc_set_destructor(prop, property_free);
*prop = (struct observe_property){
.client = ctx,
.name = talloc_strdup(prop, name),
.id = mp_get_property_id(name),
.event_mask = mp_get_property_event_mask(name),
.reply_id = userdata,
.format = format,
.changed = true,
.need_new_value = true,
};
MP_TARRAY_APPEND(ctx, ctx->properties, ctx->num_properties, prop);
ctx->property_event_masks |= prop->event_mask;
ctx->lowest_changed = 0;
pthread_mutex_unlock(&ctx->lock);
return 0;
}
int mpv_unobserve_property(mpv_handle *ctx, uint64_t userdata)
{
pthread_mutex_lock(&ctx->lock);
ctx->property_event_masks = 0;
int count = 0;
for (int n = ctx->num_properties - 1; n >= 0; n--) {
struct observe_property *prop = ctx->properties[n];
if (prop->reply_id == userdata) {
if (prop->updating) {
prop->dead = true;
} else {
// In case mpv_unobserve_property() is called after mpv_wait_event()
// returned, and the mpv_event still references the name somehow,
// make sure it's not freed while in use. The same can happen
// with the value update mechanism.
talloc_steal(ctx->cur_event, prop);
}
MP_TARRAY_REMOVE_AT(ctx->properties, ctx->num_properties, n);
count++;
}
if (!prop->dead)
ctx->property_event_masks |= prop->event_mask;
}
ctx->lowest_changed = 0;
pthread_mutex_unlock(&ctx->lock);
return count;
}
static void mark_property_changed(struct mpv_handle *client, int index)
{
struct observe_property *prop = client->properties[index];
if (!prop->changed && !prop->need_new_value) {
prop->changed = true;
prop->need_new_value = prop->format != 0;
client->lowest_changed = MPMIN(client->lowest_changed, index);
}
}
// 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(name);
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)
mark_property_changed(client, i);
}
if (client->lowest_changed < client->num_properties)
wakeup_client(client);
pthread_mutex_unlock(&client->lock);
}
pthread_mutex_unlock(&clients->lock);
}
// Mark properties as changed in reaction to specific events.
// Called with ctx->lock held.
static void notify_property_events(struct mpv_handle *ctx, uint64_t event_mask)
{
for (int i = 0; i < ctx->num_properties; i++) {
if (ctx->properties[i]->event_mask & event_mask)
mark_property_changed(ctx, i);
}
if (ctx->lowest_changed < ctx->num_properties)
wakeup_client(ctx);
}
static void update_prop(void *p)
{
struct observe_property *prop = p;
struct mpv_handle *ctx = prop->client;
const struct m_option *type = get_mp_type_get(prop->format);
union m_option_value val = {0};
struct getproperty_request req = {
.mpctx = ctx->mpctx,
.name = prop->name,
.format = prop->format,
.data = &val,
};
getproperty_fn(&req);
pthread_mutex_lock(&ctx->lock);
ctx->properties_updating--;
prop->updating = false;
m_option_free(type, &prop->new_value);
prop->new_value_valid = req.status >= 0;
if (prop->new_value_valid)
memcpy(&prop->new_value, &val, type->type->size);
if (prop->user_value_valid != prop->new_value_valid) {
prop->changed = true;
} else if (prop->user_value_valid && prop->new_value_valid) {
if (!compare_value(&prop->user_value, &prop->new_value, prop->format))
prop->changed = true;
}
if (prop->dead)
talloc_steal(ctx->cur_event, prop);
wakeup_client(ctx);
pthread_mutex_unlock(&ctx->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;
int start = ctx->lowest_changed;
ctx->lowest_changed = ctx->num_properties;
for (int n = start; n < ctx->num_properties; n++) {
struct observe_property *prop = ctx->properties[n];
if ((prop->changed || prop->updating) && n < ctx->lowest_changed)
ctx->lowest_changed = n;
if (prop->changed) {
bool get_value = prop->need_new_value;
prop->need_new_value = false;
prop->changed = false;
if (prop->format && get_value) {
ctx->properties_updating++;
prop->updating = true;
mp_dispatch_enqueue(ctx->mpctx->dispatch, update_prop, prop);
} else {
const struct m_option *type = get_mp_type_get(prop->format);
prop->user_value_valid = prop->new_value_valid;
if (prop->new_value_valid)
m_option_copy(type, &prop->user_value, &prop->new_value);
ctx->cur_property_event = (struct mpv_event_property){
.name = prop->name,
.format = prop->user_value_valid ? prop->format : 0,
};
if (prop->user_value_valid)
ctx->cur_property_event.data = &prop->user_value;
*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_load_config_file(mpv_handle *ctx, const char *filename)
{
int flags = ctx->mpctx->initialized ? M_SETOPT_RUNTIME : 0;
lock_core(ctx);
int r = m_config_parse_config_file(ctx->mpctx->mconfig, filename, NULL, flags);
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);
}
int mpv_request_log_messages(mpv_handle *ctx, const char *min_level)
{
int level = -1;
for (int n = 0; n < MSGL_MAX + 1; n++) {
if (mp_log_levels[n] && strcmp(min_level, mp_log_levels[n]) == 0) {
level = n;
break;
}
}
if (level < 0 && strcmp(min_level, "no") != 0)
return MPV_ERROR_INVALID_PARAMETER;
pthread_mutex_lock(&ctx->lock);
mp_msg_log_buffer_destroy(ctx->messages);
ctx->messages = NULL;
if (level >= 0) {
int size = level >= MSGL_V ? 10000 : 1000;
ctx->messages = mp_msg_log_buffer_new(ctx->mpctx->global, size, level,
msg_wakeup, ctx);
}
pthread_mutex_unlock(&ctx->lock);
return 0;
}
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)
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;
}
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",
};
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_TRACKS_CHANGED] = "tracks-changed",
[MPV_EVENT_TRACK_SWITCHED] = "track-switched",
[MPV_EVENT_IDLE] = "idle",
[MPV_EVENT_PAUSE] = "pause",
[MPV_EVENT_UNPAUSE] = "unpause",
[MPV_EVENT_TICK] = "tick",
[MPV_EVENT_SCRIPT_INPUT_DISPATCH] = "script-input-dispatch",
[MPV_EVENT_CLIENT_MESSAGE] = "client-message",
[MPV_EVENT_VIDEO_RECONFIG] = "video-reconfig",
[MPV_EVENT_AUDIO_RECONFIG] = "audio-reconfig",
[MPV_EVENT_METADATA_UPDATE] = "metadata-update",
[MPV_EVENT_SEEK] = "seek",
[MPV_EVENT_PLAYBACK_RESTART] = "playback-restart",
[MPV_EVENT_PROPERTY_CHANGE] = "property-change",
[MPV_EVENT_CHAPTER_CHANGE] = "chapter-change",
};
const char *mpv_event_name(mpv_event_id event)
{
if (event < 0 || 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_us(mpv_handle *ctx)
{
return mp_time_us();
}