1
mirror of https://github.com/mpv-player/mpv synced 2024-11-14 22:48:35 +01:00
mpv/input/input.c
wm4 2e84934be7 input: change license to LGPL
cehoyos adds the step_property command in 7a71da01d, and it could be
argued that copyright of this still applies to the later add/cycle
commands (a668ae0ff9). While I'm not sure if this is really the case,
stay conservative for now and mark these commands as GPL-only. Mark the
command.c code too, although that is not being relicensed yet.

I'm leaving the MP_CMD_* enum items, as they are obviously different.

In commit 116ca0c768, "veal" (essentially an anonymous author) adds an
"osd_show_property_text" command (well, the commit message says "based
on" that person's code, so it's not clear how much is from him or from
albeu, who agreed to LGPL). This was later merged again with the
"osd_show_text" command, and then all original code was removed in
commit 58cc0f637f, so I claim that no copyright applies anymore. (Though
technically the input.conf addition still might be copyrighted, so I'm
just dropping it to get rid of the thought.)

"kiriuja" added 2f376d1b39 (sub_load etc.) and be54f4813 (switch_audio).
The latter is gone. I would argue that the former is fully rewritten
with commits b7052b431c and 0f155921b0. But like in the step_property
case, I will be overly conservative for now, and mark them as GPL-only,
as this is potentially shaky and should be thought through first. (Not
bothering with the command define/enum in the header, as it will be
unused in LGPL mode anyway.)

keycodes.c/h can be GPL, except for commit 2b1f95dcc2, which is a
patch by someone who wasn't asked yet. Before doing something radical, I
will wait for a reply.
2017-06-19 13:28:19 +02:00

1617 lines
50 KiB
C

/*
* This file is part of mpv.
*
* mpv is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* mpv is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with mpv. If not, see <http://www.gnu.org/licenses/>.
*/
#include "config.h"
#include <stdlib.h>
#include <string.h>
#include <stdio.h>
#include <stdbool.h>
#include <unistd.h>
#include <math.h>
#include <errno.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <fcntl.h>
#include <pthread.h>
#include <assert.h>
#include <libavutil/avstring.h>
#include <libavutil/common.h>
#include "osdep/io.h"
#include "misc/rendezvous.h"
#include "input.h"
#include "keycodes.h"
#include "cmd_list.h"
#include "cmd_parse.h"
#include "osdep/threads.h"
#include "osdep/timer.h"
#include "common/msg.h"
#include "common/global.h"
#include "options/m_config.h"
#include "options/m_option.h"
#include "options/path.h"
#include "mpv_talloc.h"
#include "options/options.h"
#include "misc/bstr.h"
#include "stream/stream.h"
#include "common/common.h"
#if HAVE_COCOA
#include "osdep/macosx_events.h"
#endif
#define input_lock(ictx) pthread_mutex_lock(&ictx->mutex)
#define input_unlock(ictx) pthread_mutex_unlock(&ictx->mutex)
#define MP_MAX_KEY_DOWN 4
struct cmd_bind {
int keys[MP_MAX_KEY_DOWN];
int num_keys;
char *cmd;
char *location; // filename/line number of definition
bool is_builtin;
struct cmd_bind_section *owner;
};
struct cmd_bind_section {
char *owner;
struct cmd_bind *binds;
int num_binds;
char *section;
struct mp_rect mouse_area; // set at runtime, if at all
bool mouse_area_set; // mouse_area is valid and should be tested
struct cmd_bind_section *next;
};
#define MP_MAX_SOURCES 10
#define MAX_ACTIVE_SECTIONS 50
struct active_section {
char *name;
int flags;
};
struct cmd_queue {
struct mp_cmd *first;
};
struct axis_state {
double dead_zone_accum;
double unit_accum;
};
struct input_ctx {
pthread_mutex_t mutex;
struct mp_log *log;
struct mpv_global *global;
struct m_config_cache *opts_cache;
struct input_opts *opts;
bool using_ar;
bool using_cocoa_media_keys;
// Autorepeat stuff
short ar_state;
int64_t last_ar;
// history of key downs - the newest is in position 0
int key_history[MP_MAX_KEY_DOWN];
// key code of the last key that triggered MP_KEY_STATE_DOWN
int last_key_down;
int64_t last_key_down_time;
struct mp_cmd *current_down_cmd;
int last_doubleclick_key_down;
double last_doubleclick_time;
// Mouse position on the consumer side (as command.c sees it)
int mouse_x, mouse_y;
char *mouse_section; // last section to receive mouse event
// Mouse position on the producer side (as the VO sees it)
// Unlike mouse_x/y, this can be used to resolve mouse click bindings.
int mouse_vo_x, mouse_vo_y;
bool mouse_mangle, mouse_src_mangle;
struct mp_rect mouse_src, mouse_dst;
// Axis state (MP_AXIS_*)
struct axis_state axis_state_y; // MP_AXIS_UP/MP_AXIS_DOWN
struct axis_state axis_state_x; // MP_AXIS_LEFT/MP_AXIS_RIGHT
struct axis_state *axis_current; // Points to axis currently being scrolled
double last_axis_time; // mp_time_sec() of the last axis event
// List of command binding sections
struct cmd_bind_section *cmd_bind_sections;
// List currently active command sections
struct active_section active_sections[MAX_ACTIVE_SECTIONS];
int num_active_sections;
unsigned int mouse_event_counter;
struct mp_input_src *sources[MP_MAX_SOURCES];
int num_sources;
struct cmd_queue cmd_queue;
void (*cancel)(void *cancel_ctx);
void *cancel_ctx;
void (*wakeup_cb)(void *ctx);
void *wakeup_ctx;
};
static int parse_config(struct input_ctx *ictx, bool builtin, bstr data,
const char *location, const char *restrict_section);
static void close_input_sources(struct input_ctx *ictx);
#define OPT_BASE_STRUCT struct input_opts
struct input_opts {
char *config_file;
int doubleclick_time;
// Maximum number of queued commands from keypresses (limit to avoid
// repeated slow commands piling up)
int key_fifo_size;
// Autorepeat config (be aware of mp_input_set_repeat_info())
int ar_delay;
int ar_rate;
int use_alt_gr;
int use_appleremote;
int use_media_keys;
int default_bindings;
int enable_mouse_movements;
int vo_key_input;
int test;
int allow_win_drag;
};
const struct m_sub_options input_config = {
.opts = (const m_option_t[]) {
OPT_STRING("input-conf", config_file, M_OPT_FIXED | M_OPT_FILE),
OPT_INT("input-ar-delay", ar_delay, 0),
OPT_INT("input-ar-rate", ar_rate, 0),
OPT_PRINT("input-keylist", mp_print_key_list),
OPT_PRINT("input-cmdlist", mp_print_cmd_list),
OPT_FLAG("input-default-bindings", default_bindings, 0),
OPT_FLAG("input-test", test, 0),
OPT_INTRANGE("input-doubleclick-time", doubleclick_time, 0, 0, 1000),
OPT_FLAG("input-right-alt-gr", use_alt_gr, 0),
OPT_INTRANGE("input-key-fifo-size", key_fifo_size, 0, 2, 65000),
OPT_FLAG("input-cursor", enable_mouse_movements, 0),
OPT_FLAG("input-vo-keyboard", vo_key_input, 0),
#if HAVE_COCOA
OPT_FLAG("input-appleremote", use_appleremote, 0),
OPT_FLAG("input-media-keys", use_media_keys, 0),
#endif
OPT_FLAG("window-dragging", allow_win_drag, 0),
OPT_REPLACED("input-x11-keyboard", "input-vo-keyboard"),
{0}
},
.size = sizeof(struct input_opts),
.defaults = &(const struct input_opts){
.key_fifo_size = 7,
.doubleclick_time = 300,
.ar_delay = 200,
.ar_rate = 40,
.use_alt_gr = 1,
.enable_mouse_movements = 1,
#if HAVE_COCOA
.use_appleremote = 1,
.use_media_keys = 1,
#endif
.default_bindings = 1,
.vo_key_input = 1,
.allow_win_drag = 1,
},
.change_flags = UPDATE_INPUT,
};
static const char builtin_input_conf[] =
#include "input/input_conf.h"
;
static bool test_rect(struct mp_rect *rc, int x, int y)
{
return x >= rc->x0 && y >= rc->y0 && x < rc->x1 && y < rc->y1;
}
static int queue_count_cmds(struct cmd_queue *queue)
{
int res = 0;
for (struct mp_cmd *cmd = queue->first; cmd; cmd = cmd->queue_next)
res++;
return res;
}
static void queue_remove(struct cmd_queue *queue, struct mp_cmd *cmd)
{
struct mp_cmd **p_prev = &queue->first;
while (*p_prev != cmd) {
p_prev = &(*p_prev)->queue_next;
}
// if this fails, cmd was not in the queue
assert(*p_prev == cmd);
*p_prev = cmd->queue_next;
}
static struct mp_cmd *queue_remove_head(struct cmd_queue *queue)
{
struct mp_cmd *ret = queue->first;
if (ret)
queue_remove(queue, ret);
return ret;
}
static void queue_add_tail(struct cmd_queue *queue, struct mp_cmd *cmd)
{
struct mp_cmd **p_prev = &queue->first;
while (*p_prev)
p_prev = &(*p_prev)->queue_next;
*p_prev = cmd;
cmd->queue_next = NULL;
}
static struct mp_cmd *queue_peek_tail(struct cmd_queue *queue)
{
struct mp_cmd *cur = queue->first;
while (cur && cur->queue_next)
cur = cur->queue_next;
return cur;
}
static void append_bind_info(struct input_ctx *ictx, char **pmsg,
struct cmd_bind *bind)
{
char *msg = *pmsg;
struct mp_cmd *cmd = mp_input_parse_cmd(ictx, bstr0(bind->cmd),
bind->location);
bstr stripped = cmd ? cmd->original : bstr0(bind->cmd);
msg = talloc_asprintf_append(msg, " '%.*s'", BSTR_P(stripped));
if (!cmd)
msg = talloc_asprintf_append(msg, " (invalid)");
if (strcmp(bind->owner->section, "default") != 0)
msg = talloc_asprintf_append(msg, " in section {%s}",
bind->owner->section);
msg = talloc_asprintf_append(msg, " in %s", bind->location);
if (bind->is_builtin)
msg = talloc_asprintf_append(msg, " (default)");
talloc_free(cmd);
*pmsg = msg;
}
static mp_cmd_t *handle_test(struct input_ctx *ictx, int code)
{
if (code == MP_KEY_CLOSE_WIN) {
MP_WARN(ictx,
"CLOSE_WIN was received. This pseudo key can be remapped too,\n"
"but --input-test will always quit when receiving it.\n");
const char *args[] = {"quit", NULL};
mp_cmd_t *res = mp_input_parse_cmd_strv(ictx->log, args);
return res;
}
char *key_buf = mp_input_get_key_combo_name(&code, 1);
char *msg = talloc_asprintf(NULL, "Key %s is bound to:\n", key_buf);
talloc_free(key_buf);
int count = 0;
for (struct cmd_bind_section *bs = ictx->cmd_bind_sections;
bs; bs = bs->next)
{
for (int i = 0; i < bs->num_binds; i++) {
if (bs->binds[i].num_keys && bs->binds[i].keys[0] == code) {
count++;
if (count > 1)
msg = talloc_asprintf_append(msg, "\n");
msg = talloc_asprintf_append(msg, "%d. ", count);
append_bind_info(ictx, &msg, &bs->binds[i]);
}
}
}
if (!count)
msg = talloc_asprintf_append(msg, "(nothing)");
MP_INFO(ictx, "%s\n", msg);
const char *args[] = {"show-text", msg, NULL};
mp_cmd_t *res = mp_input_parse_cmd_strv(ictx->log, args);
talloc_free(msg);
return res;
}
static struct cmd_bind_section *get_bind_section(struct input_ctx *ictx,
bstr section)
{
struct cmd_bind_section *bind_section = ictx->cmd_bind_sections;
if (section.len == 0)
section = bstr0("default");
while (bind_section) {
if (bstrcmp0(section, bind_section->section) == 0)
return bind_section;
if (bind_section->next == NULL)
break;
bind_section = bind_section->next;
}
if (bind_section) {
bind_section->next = talloc_ptrtype(ictx, bind_section->next);
bind_section = bind_section->next;
} else {
ictx->cmd_bind_sections = talloc_ptrtype(ictx, ictx->cmd_bind_sections);
bind_section = ictx->cmd_bind_sections;
}
*bind_section = (struct cmd_bind_section) {
.section = bstrdup0(bind_section, section),
.mouse_area = {INT_MIN, INT_MIN, INT_MAX, INT_MAX},
.mouse_area_set = true,
};
return bind_section;
}
static void key_buf_add(int *buf, int code)
{
for (int n = MP_MAX_KEY_DOWN - 1; n > 0; n--)
buf[n] = buf[n - 1];
buf[0] = code;
}
static struct cmd_bind *find_bind_for_key_section(struct input_ctx *ictx,
char *section, int code)
{
struct cmd_bind_section *bs = get_bind_section(ictx, bstr0(section));
if (!bs->num_binds)
return NULL;
int keys[MP_MAX_KEY_DOWN];
memcpy(keys, ictx->key_history, sizeof(keys));
key_buf_add(keys, code);
struct cmd_bind *best = NULL;
// Prefer user-defined keys over builtin bindings
for (int builtin = 0; builtin < 2; builtin++) {
if (builtin && !ictx->opts->default_bindings)
break;
if (best)
break;
for (int n = 0; n < bs->num_binds; n++) {
if (bs->binds[n].is_builtin == (bool)builtin) {
struct cmd_bind *b = &bs->binds[n];
// we have: keys=[key2 key1 keyX ...]
// and: b->keys=[key1 key2] (and may be just a prefix)
for (int i = 0; i < b->num_keys; i++) {
if (b->keys[i] != keys[b->num_keys - 1 - i])
goto skip;
}
if (!best || b->num_keys >= best->num_keys)
best = b;
skip: ;
}
}
}
return best;
}
static struct cmd_bind *find_any_bind_for_key(struct input_ctx *ictx,
char *force_section, int code)
{
if (force_section)
return find_bind_for_key_section(ictx, force_section, code);
bool use_mouse = MP_KEY_DEPENDS_ON_MOUSE_POS(code);
// First look whether a mouse section is capturing all mouse input
// exclusively (regardless of the active section stack order).
if (use_mouse && MP_KEY_IS_MOUSE_BTN_SINGLE(ictx->last_key_down)) {
struct cmd_bind *bind =
find_bind_for_key_section(ictx, ictx->mouse_section, code);
if (bind)
return bind;
}
struct cmd_bind *best_bind = NULL;
for (int i = ictx->num_active_sections - 1; i >= 0; i--) {
struct active_section *s = &ictx->active_sections[i];
struct cmd_bind *bind = find_bind_for_key_section(ictx, s->name, code);
if (bind) {
struct cmd_bind_section *bs = bind->owner;
if (!use_mouse || (bs->mouse_area_set && test_rect(&bs->mouse_area,
ictx->mouse_vo_x,
ictx->mouse_vo_y)))
{
if (!best_bind || (best_bind->is_builtin && !bind->is_builtin))
best_bind = bind;
}
}
if (s->flags & MP_INPUT_EXCLUSIVE)
break;
if (best_bind && (s->flags & MP_INPUT_ON_TOP))
break;
}
return best_bind;
}
static mp_cmd_t *get_cmd_from_keys(struct input_ctx *ictx, char *force_section,
int code)
{
if (ictx->opts->test)
return handle_test(ictx, code);
struct cmd_bind *cmd = find_any_bind_for_key(ictx, force_section, code);
if (!cmd)
cmd = find_any_bind_for_key(ictx, force_section, MP_KEY_UNMAPPED);
if (!cmd) {
if (code == MP_KEY_CLOSE_WIN)
return mp_input_parse_cmd_strv(ictx->log, (const char*[]){"quit", 0});
int msgl = MSGL_WARN;
if (MP_KEY_IS_MOUSE_MOVE(code))
msgl = MSGL_DEBUG;
char *key_buf = mp_input_get_key_combo_name(&code, 1);
MP_MSG(ictx, msgl, "No key binding found for key '%s'.\n", key_buf);
talloc_free(key_buf);
return NULL;
}
mp_cmd_t *ret = mp_input_parse_cmd(ictx, bstr0(cmd->cmd), cmd->location);
if (ret) {
ret->input_section = cmd->owner->section;
ret->key_name = talloc_steal(ret, mp_input_get_key_combo_name(&code, 1));
MP_DBG(ictx, "key '%s' -> '%s' in '%s'\n",
ret->key_name, cmd->cmd, ret->input_section);
ret->is_mouse_button = code & MP_KEY_EMIT_ON_UP;
} else {
char *key_buf = mp_input_get_key_combo_name(&code, 1);
MP_ERR(ictx, "Invalid command for key binding '%s': '%s'\n",
key_buf, cmd->cmd);
talloc_free(key_buf);
}
return ret;
}
static void update_mouse_section(struct input_ctx *ictx)
{
struct cmd_bind *bind =
find_any_bind_for_key(ictx, NULL, MP_KEY_MOUSE_MOVE);
char *new_section = bind ? bind->owner->section : "default";
char *old = ictx->mouse_section;
ictx->mouse_section = new_section;
if (strcmp(old, ictx->mouse_section) != 0) {
MP_DBG(ictx, "input: switch section %s -> %s\n",
old, ictx->mouse_section);
mp_input_queue_cmd(ictx, get_cmd_from_keys(ictx, old, MP_KEY_MOUSE_LEAVE));
}
}
// Called when the currently held-down key is released. This (usually) sends
// the a key-up version of the command associated with the keys that were held
// down.
// If the drop_current parameter is set to true, then don't send the key-up
// command. Unless we've already sent a key-down event, in which case the
// input receiver (the player) must get a key-up event, or it would get stuck
// thinking a key is still held down.
static void release_down_cmd(struct input_ctx *ictx, bool drop_current)
{
if (ictx->current_down_cmd && ictx->current_down_cmd->emit_on_up &&
(!drop_current || ictx->current_down_cmd->def->on_updown))
{
memset(ictx->key_history, 0, sizeof(ictx->key_history));
ictx->current_down_cmd->is_up = true;
mp_input_queue_cmd(ictx, ictx->current_down_cmd);
} else {
talloc_free(ictx->current_down_cmd);
}
ictx->current_down_cmd = NULL;
ictx->last_key_down = 0;
ictx->last_key_down_time = 0;
ictx->ar_state = -1;
update_mouse_section(ictx);
}
// We don't want the append to the command queue indefinitely, because that
// could lead to situations where recovery would take too long. On the other
// hand, don't drop commands that will abort playback.
static bool should_drop_cmd(struct input_ctx *ictx, struct mp_cmd *cmd)
{
struct cmd_queue *queue = &ictx->cmd_queue;
return queue_count_cmds(queue) >= ictx->opts->key_fifo_size &&
!mp_input_is_abort_cmd(cmd);
}
static struct mp_cmd *resolve_key(struct input_ctx *ictx, int code)
{
update_mouse_section(ictx);
struct mp_cmd *cmd = get_cmd_from_keys(ictx, NULL, code);
key_buf_add(ictx->key_history, code);
if (cmd && cmd->id != MP_CMD_IGNORE && !should_drop_cmd(ictx, cmd))
return cmd;
talloc_free(cmd);
return NULL;
}
static void interpret_key(struct input_ctx *ictx, int code, double scale,
int scale_units)
{
int state = code & (MP_KEY_STATE_DOWN | MP_KEY_STATE_UP);
code = code & ~(unsigned)state;
if (mp_msg_test(ictx->log, MSGL_DEBUG)) {
char *key = mp_input_get_key_name(code);
MP_DBG(ictx, "key code=%#x '%s'%s%s\n",
code, key, (state & MP_KEY_STATE_DOWN) ? " down" : "",
(state & MP_KEY_STATE_UP) ? " up" : "");
talloc_free(key);
}
if (MP_KEY_DEPENDS_ON_MOUSE_POS(code & ~MP_KEY_MODIFIER_MASK)) {
ictx->mouse_event_counter++;
mp_input_wakeup(ictx);
}
struct mp_cmd *cmd = NULL;
if (state == MP_KEY_STATE_DOWN) {
// Protect against VOs which send STATE_DOWN with autorepeat
if (ictx->last_key_down == code)
return;
// Cancel current down-event (there can be only one)
release_down_cmd(ictx, true);
cmd = resolve_key(ictx, code);
if (cmd) {
cmd->is_up_down = true;
cmd->emit_on_up = (code & MP_KEY_EMIT_ON_UP) || cmd->def->on_updown;
ictx->current_down_cmd = mp_cmd_clone(cmd);
}
ictx->last_key_down = code;
ictx->last_key_down_time = mp_time_us();
ictx->ar_state = 0;
mp_input_wakeup(ictx); // possibly start timer for autorepeat
} else if (state == MP_KEY_STATE_UP) {
// Most VOs send RELEASE_ALL anyway
release_down_cmd(ictx, false);
} else {
// Press of key with no separate down/up events
// Mixing press events and up/down with the same key is not supported,
// and input sources shouldn't do this, but can happen anyway if
// multiple input sources interfere with each others.
if (ictx->last_key_down == code)
release_down_cmd(ictx, false);
cmd = resolve_key(ictx, code);
}
if (!cmd)
return;
// Don't emit a command on key-down if the key is designed to emit commands
// on key-up (like mouse buttons). Also, if the command specifically should
// be sent both on key down and key up, still emit the command.
if (cmd->emit_on_up && !cmd->def->on_updown) {
talloc_free(cmd);
return;
}
memset(ictx->key_history, 0, sizeof(ictx->key_history));
if (mp_input_is_scalable_cmd(cmd)) {
cmd->scale = scale;
cmd->scale_units = scale_units;
mp_input_queue_cmd(ictx, cmd);
} else {
// Non-scalable commands won't understand cmd->scale, so synthesize
// multiple commands with cmd->scale = 1
cmd->scale = 1;
cmd->scale_units = 1;
// Avoid spamming the player with too many commands
scale_units = FFMIN(scale_units, 20);
for (int i = 0; i < scale_units - 1; i++)
mp_input_queue_cmd(ictx, mp_cmd_clone(cmd));
if (scale_units)
mp_input_queue_cmd(ictx, cmd);
}
}
// Pre-processing for MP_AXIS_* events. If this returns false, the caller
// should discard the event.
static bool process_axis(struct input_ctx *ictx, int code, double *scale,
int *scale_units)
{
// Size of the deadzone in scroll units. The user must scroll at least this
// much in any direction before their scroll is registered.
static const double DEADZONE_DIST = 0.125;
// The deadzone accumulator is reset if no scrolls happened in this many
// seconds, eg. the user is assumed to have finished scrolling.
static const double DEADZONE_SCROLL_TIME = 0.2;
// The scale_units accumulator is reset if no scrolls happened in this many
// seconds. This value should be fairly large, so commands will still be
// sent when the user scrolls slowly.
static const double UNIT_SCROLL_TIME = 0.5;
// Determine which axis is being scrolled
double dir;
struct axis_state *state;
switch (code) {
case MP_AXIS_UP: dir = -1; state = &ictx->axis_state_y; break;
case MP_AXIS_DOWN: dir = +1; state = &ictx->axis_state_y; break;
case MP_AXIS_LEFT: dir = -1; state = &ictx->axis_state_x; break;
case MP_AXIS_RIGHT: dir = +1; state = &ictx->axis_state_x; break;
default:
return true;
}
// Reset accumulators if it's determined that the user finished scrolling
double now = mp_time_sec();
if (now > ictx->last_axis_time + DEADZONE_SCROLL_TIME) {
ictx->axis_current = NULL;
ictx->axis_state_y.dead_zone_accum = 0;
ictx->axis_state_x.dead_zone_accum = 0;
}
if (now > ictx->last_axis_time + UNIT_SCROLL_TIME) {
ictx->axis_state_y.unit_accum = 0;
ictx->axis_state_x.unit_accum = 0;
}
ictx->last_axis_time = now;
// Process axis deadzone. A lot of touchpad drivers don't filter scroll
// input, which makes it difficult for the user to send AXIS_UP/DOWN
// without accidentally triggering AXIS_LEFT/RIGHT. We try to fix this by
// implementing a deadzone. When the value of either axis breaks out of the
// deadzone, events from the other axis will be ignored until the user
// finishes scrolling.
if (ictx->axis_current == NULL) {
state->dead_zone_accum += *scale * dir;
if (state->dead_zone_accum * dir > DEADZONE_DIST) {
ictx->axis_current = state;
*scale = state->dead_zone_accum * dir;
}
}
if (ictx->axis_current != state)
return false;
// Determine scale_units. This is incremented every time the accumulated
// scale value crosses 1.0. Non-scalable input commands will be ran that
// many times.
state->unit_accum += *scale * dir;
*scale_units = trunc(state->unit_accum * dir);
state->unit_accum -= *scale_units * dir;
return true;
}
static void mp_input_feed_key(struct input_ctx *ictx, int code, double scale,
bool force_mouse)
{
struct input_opts *opts = ictx->opts;
code = mp_normalize_keycode(code);
int unmod = code & ~MP_KEY_MODIFIER_MASK;
if (code == MP_INPUT_RELEASE_ALL) {
MP_DBG(ictx, "release all\n");
release_down_cmd(ictx, false);
return;
}
if (!opts->enable_mouse_movements && MP_KEY_IS_MOUSE(unmod) && !force_mouse)
return;
if (unmod == MP_KEY_MOUSE_LEAVE || unmod == MP_KEY_MOUSE_ENTER) {
update_mouse_section(ictx);
mp_input_queue_cmd(ictx, get_cmd_from_keys(ictx, NULL, code));
return;
}
double now = mp_time_sec();
// ignore system-doubleclick if we generate these events ourselves
if (!force_mouse && opts->doubleclick_time && MP_KEY_IS_MOUSE_BTN_DBL(unmod))
return;
int units = 1;
if (MP_KEY_IS_AXIS(unmod) && !process_axis(ictx, unmod, &scale, &units))
return;
interpret_key(ictx, code, scale, units);
if (code & MP_KEY_STATE_DOWN) {
code &= ~MP_KEY_STATE_DOWN;
if (ictx->last_doubleclick_key_down == code &&
now - ictx->last_doubleclick_time < opts->doubleclick_time / 1000.0)
{
if (code >= MP_MOUSE_BTN0 && code <= MP_MOUSE_BTN2) {
interpret_key(ictx, code - MP_MOUSE_BTN0 + MP_MOUSE_BTN0_DBL,
1, 1);
}
}
ictx->last_doubleclick_key_down = code;
ictx->last_doubleclick_time = now;
}
}
void mp_input_put_key(struct input_ctx *ictx, int code)
{
input_lock(ictx);
mp_input_feed_key(ictx, code, 1, false);
input_unlock(ictx);
}
void mp_input_put_key_artificial(struct input_ctx *ictx, int code)
{
input_lock(ictx);
mp_input_feed_key(ictx, code, 1, true);
input_unlock(ictx);
}
void mp_input_put_key_utf8(struct input_ctx *ictx, int mods, struct bstr t)
{
while (t.len) {
int code = bstr_decode_utf8(t, &t);
if (code < 0)
break;
mp_input_put_key(ictx, code | mods);
}
}
void mp_input_put_axis(struct input_ctx *ictx, int direction, double value)
{
if (value == 0.0)
return;
input_lock(ictx);
mp_input_feed_key(ictx, direction, value, false);
input_unlock(ictx);
}
void mp_input_set_mouse_transform(struct input_ctx *ictx, struct mp_rect *dst,
struct mp_rect *src)
{
input_lock(ictx);
ictx->mouse_mangle = dst || src;
if (ictx->mouse_mangle) {
ictx->mouse_dst = *dst;
ictx->mouse_src_mangle = !!src;
if (ictx->mouse_src_mangle)
ictx->mouse_src = *src;
}
input_unlock(ictx);
}
bool mp_input_mouse_enabled(struct input_ctx *ictx)
{
input_lock(ictx);
bool r = ictx->opts->enable_mouse_movements;
input_unlock(ictx);
return r;
}
bool mp_input_vo_keyboard_enabled(struct input_ctx *ictx)
{
input_lock(ictx);
bool r = ictx->opts->vo_key_input;
input_unlock(ictx);
return r;
}
void mp_input_set_mouse_pos(struct input_ctx *ictx, int x, int y)
{
input_lock(ictx);
if (ictx->opts->enable_mouse_movements)
mp_input_set_mouse_pos_artificial(ictx, x, y);
input_unlock(ictx);
}
void mp_input_set_mouse_pos_artificial(struct input_ctx *ictx, int x, int y)
{
input_lock(ictx);
MP_DBG(ictx, "mouse move %d/%d\n", x, y);
if (ictx->mouse_vo_x == x && ictx->mouse_vo_y == y) {
input_unlock(ictx);
return;
}
if (ictx->mouse_mangle) {
struct mp_rect *src = &ictx->mouse_src;
struct mp_rect *dst = &ictx->mouse_dst;
x = MPCLAMP(x, dst->x0, dst->x1) - dst->x0;
y = MPCLAMP(y, dst->y0, dst->y1) - dst->y0;
if (ictx->mouse_src_mangle) {
x = x * 1.0 / (dst->x1 - dst->x0) * (src->x1 - src->x0) + src->x0;
y = y * 1.0 / (dst->y1 - dst->y0) * (src->y1 - src->y0) + src->y0;
}
MP_DBG(ictx, "-> %d/%d\n", x, y);
}
ictx->mouse_event_counter++;
ictx->mouse_vo_x = x;
ictx->mouse_vo_y = y;
update_mouse_section(ictx);
struct mp_cmd *cmd = get_cmd_from_keys(ictx, NULL, MP_KEY_MOUSE_MOVE);
if (!cmd)
cmd = mp_input_parse_cmd(ictx, bstr0("ignore"), "<internal>");
if (cmd) {
cmd->mouse_move = true;
cmd->mouse_x = x;
cmd->mouse_y = y;
if (should_drop_cmd(ictx, cmd)) {
talloc_free(cmd);
} else {
// Coalesce with previous mouse move events (i.e. replace it)
struct mp_cmd *tail = queue_peek_tail(&ictx->cmd_queue);
if (tail && tail->mouse_move) {
queue_remove(&ictx->cmd_queue, tail);
talloc_free(tail);
}
mp_input_queue_cmd(ictx, cmd);
}
}
input_unlock(ictx);
}
unsigned int mp_input_get_mouse_event_counter(struct input_ctx *ictx)
{
// Make the frontend always display the mouse cursor (as long as it's not
// forced invisible) if mouse input is desired.
input_lock(ictx);
if (mp_input_test_mouse_active(ictx, ictx->mouse_x, ictx->mouse_y))
ictx->mouse_event_counter++;
int ret = ictx->mouse_event_counter;
input_unlock(ictx);
return ret;
}
// adjust min time to wait until next repeat event
static void adjust_max_wait_time(struct input_ctx *ictx, double *time)
{
struct input_opts *opts = ictx->opts;
if (ictx->last_key_down && opts->ar_rate > 0 && ictx->ar_state >= 0) {
*time = FFMIN(*time, 1.0 / opts->ar_rate);
*time = FFMIN(*time, opts->ar_delay / 1000.0);
}
}
static bool test_abort_cmd(struct input_ctx *ictx, struct mp_cmd *new)
{
if (!mp_input_is_maybe_abort_cmd(new))
return false;
if (mp_input_is_abort_cmd(new))
return true;
// Abort only if there are going to be at least 2 commands in the queue.
for (struct mp_cmd *cmd = ictx->cmd_queue.first; cmd; cmd = cmd->queue_next) {
if (mp_input_is_maybe_abort_cmd(cmd))
return true;
}
return false;
}
int mp_input_queue_cmd(struct input_ctx *ictx, mp_cmd_t *cmd)
{
input_lock(ictx);
if (cmd) {
if (ictx->cancel && test_abort_cmd(ictx, cmd))
ictx->cancel(ictx->cancel_ctx);
queue_add_tail(&ictx->cmd_queue, cmd);
mp_input_wakeup(ictx);
}
input_unlock(ictx);
return 1;
}
static mp_cmd_t *check_autorepeat(struct input_ctx *ictx)
{
struct input_opts *opts = ictx->opts;
// No input : autorepeat ?
if (opts->ar_rate <= 0 || !ictx->current_down_cmd || !ictx->last_key_down ||
(ictx->last_key_down & MP_NO_REPEAT_KEY) ||
!mp_input_is_repeatable_cmd(ictx->current_down_cmd))
ictx->ar_state = -1; // disable
if (ictx->ar_state >= 0) {
int64_t t = mp_time_us();
if (ictx->last_ar + 2000000 < t)
ictx->last_ar = t;
// First time : wait delay
if (ictx->ar_state == 0
&& (t - ictx->last_key_down_time) >= opts->ar_delay * 1000)
{
ictx->ar_state = 1;
ictx->last_ar = ictx->last_key_down_time + opts->ar_delay * 1000;
// Then send rate / sec event
} else if (ictx->ar_state == 1
&& (t - ictx->last_ar) >= 1000000 / opts->ar_rate) {
ictx->last_ar += 1000000 / opts->ar_rate;
} else {
return NULL;
}
struct mp_cmd *ret = mp_cmd_clone(ictx->current_down_cmd);
ret->repeated = true;
return ret;
}
return NULL;
}
double mp_input_get_delay(struct input_ctx *ictx)
{
input_lock(ictx);
double seconds = INFINITY;
adjust_max_wait_time(ictx, &seconds);
input_unlock(ictx);
return seconds;
}
void mp_input_wakeup(struct input_ctx *ictx)
{
ictx->wakeup_cb(ictx->wakeup_ctx);
}
mp_cmd_t *mp_input_read_cmd(struct input_ctx *ictx)
{
input_lock(ictx);
struct mp_cmd *ret = queue_remove_head(&ictx->cmd_queue);
if (!ret)
ret = check_autorepeat(ictx);
if (ret && ret->mouse_move) {
ictx->mouse_x = ret->mouse_x;
ictx->mouse_y = ret->mouse_y;
}
input_unlock(ictx);
return ret;
}
void mp_input_get_mouse_pos(struct input_ctx *ictx, int *x, int *y)
{
input_lock(ictx);
*x = ictx->mouse_x;
*y = ictx->mouse_y;
input_unlock(ictx);
}
// If name is NULL, return "default".
// Return a statically allocated name of the section (i.e. return value never
// gets deallocated).
static char *normalize_section(struct input_ctx *ictx, char *name)
{
return get_bind_section(ictx, bstr0(name))->section;
}
void mp_input_disable_section(struct input_ctx *ictx, char *name)
{
input_lock(ictx);
name = normalize_section(ictx, name);
// Remove old section, or make sure it's on top if re-enabled
for (int i = ictx->num_active_sections - 1; i >= 0; i--) {
struct active_section *as = &ictx->active_sections[i];
if (strcmp(as->name, name) == 0) {
MP_TARRAY_REMOVE_AT(ictx->active_sections,
ictx->num_active_sections, i);
}
}
input_unlock(ictx);
}
void mp_input_enable_section(struct input_ctx *ictx, char *name, int flags)
{
input_lock(ictx);
name = normalize_section(ictx, name);
mp_input_disable_section(ictx, name);
MP_DBG(ictx, "enable section '%s'\n", name);
if (ictx->num_active_sections < MAX_ACTIVE_SECTIONS) {
int top = ictx->num_active_sections;
if (!(flags & MP_INPUT_ON_TOP)) {
// insert before the first top entry
for (top = 0; top < ictx->num_active_sections; top++) {
if (ictx->active_sections[top].flags & MP_INPUT_ON_TOP)
break;
}
for (int n = ictx->num_active_sections; n > top; n--)
ictx->active_sections[n] = ictx->active_sections[n - 1];
}
ictx->active_sections[top] = (struct active_section){name, flags};
ictx->num_active_sections++;
}
MP_DBG(ictx, "active section stack:\n");
for (int n = 0; n < ictx->num_active_sections; n++) {
MP_DBG(ictx, " %s %d\n", ictx->active_sections[n].name,
ictx->active_sections[n].flags);
}
input_unlock(ictx);
}
void mp_input_disable_all_sections(struct input_ctx *ictx)
{
input_lock(ictx);
ictx->num_active_sections = 0;
input_unlock(ictx);
}
void mp_input_set_section_mouse_area(struct input_ctx *ictx, char *name,
int x0, int y0, int x1, int y1)
{
input_lock(ictx);
struct cmd_bind_section *s = get_bind_section(ictx, bstr0(name));
s->mouse_area = (struct mp_rect){x0, y0, x1, y1};
s->mouse_area_set = x0 != x1 && y0 != y1;
input_unlock(ictx);
}
static bool test_mouse(struct input_ctx *ictx, int x, int y, int rej_flags)
{
input_lock(ictx);
bool res = false;
for (int i = 0; i < ictx->num_active_sections; i++) {
struct active_section *as = &ictx->active_sections[i];
if (as->flags & rej_flags)
continue;
struct cmd_bind_section *s = get_bind_section(ictx, bstr0(as->name));
if (s->mouse_area_set && test_rect(&s->mouse_area, x, y)) {
res = true;
break;
}
}
input_unlock(ictx);
return res;
}
bool mp_input_test_mouse_active(struct input_ctx *ictx, int x, int y)
{
return test_mouse(ictx, x, y, MP_INPUT_ALLOW_HIDE_CURSOR);
}
bool mp_input_test_dragging(struct input_ctx *ictx, int x, int y)
{
input_lock(ictx);
bool r = !ictx->opts->allow_win_drag ||
test_mouse(ictx, x, y, MP_INPUT_ALLOW_VO_DRAGGING);
input_unlock(ictx);
return r;
}
static void bind_dealloc(struct cmd_bind *bind)
{
talloc_free(bind->cmd);
talloc_free(bind->location);
}
// builtin: if true, remove all builtin binds, else remove all user binds
static void remove_binds(struct cmd_bind_section *bs, bool builtin)
{
for (int n = bs->num_binds - 1; n >= 0; n--) {
if (bs->binds[n].is_builtin == builtin) {
bind_dealloc(&bs->binds[n]);
assert(bs->num_binds >= 1);
bs->binds[n] = bs->binds[bs->num_binds - 1];
bs->num_binds--;
}
}
}
void mp_input_define_section(struct input_ctx *ictx, char *name, char *location,
char *contents, bool builtin, char *owner)
{
if (!name || !name[0])
return; // parse_config() changes semantics with restrict_section==empty
input_lock(ictx);
// Delete:
struct cmd_bind_section *bs = get_bind_section(ictx, bstr0(name));
if ((!bs->owner || (owner && strcmp(bs->owner, owner) != 0)) &&
strcmp(bs->section, "default") != 0)
{
talloc_free(bs->owner);
bs->owner = talloc_strdup(bs, owner);
}
remove_binds(bs, builtin);
if (contents && contents[0]) {
// Redefine:
parse_config(ictx, builtin, bstr0(contents), location, name);
} else {
// Disable:
mp_input_disable_section(ictx, name);
}
input_unlock(ictx);
}
void mp_input_remove_sections_by_owner(struct input_ctx *ictx, char *owner)
{
input_lock(ictx);
struct cmd_bind_section *bs = ictx->cmd_bind_sections;
while (bs) {
if (bs->owner && owner && strcmp(bs->owner, owner) == 0) {
mp_input_disable_section(ictx, bs->section);
remove_binds(bs, false);
remove_binds(bs, true);
}
bs = bs->next;
}
input_unlock(ictx);
}
static bool bind_matches_key(struct cmd_bind *bind, int num_keys, const int *keys)
{
if (bind->num_keys != num_keys)
return false;
for (int i = 0; i < num_keys; i++) {
if (bind->keys[i] != keys[i])
return false;
}
return true;
}
static void bind_keys(struct input_ctx *ictx, bool builtin, bstr section,
const int *keys, int num_keys, bstr command,
const char *loc)
{
struct cmd_bind_section *bs = get_bind_section(ictx, section);
struct cmd_bind *bind = NULL;
assert(num_keys <= MP_MAX_KEY_DOWN);
for (int n = 0; n < bs->num_binds; n++) {
struct cmd_bind *b = &bs->binds[n];
if (bind_matches_key(b, num_keys, keys) && b->is_builtin == builtin) {
bind = b;
break;
}
}
if (!bind) {
struct cmd_bind empty = {{0}};
MP_TARRAY_APPEND(bs, bs->binds, bs->num_binds, empty);
bind = &bs->binds[bs->num_binds - 1];
}
bind_dealloc(bind);
*bind = (struct cmd_bind) {
.cmd = bstrdup0(bs->binds, command),
.location = talloc_strdup(bs->binds, loc),
.owner = bs,
.is_builtin = builtin,
.num_keys = num_keys,
};
memcpy(bind->keys, keys, num_keys * sizeof(bind->keys[0]));
if (mp_msg_test(ictx->log, MSGL_DEBUG)) {
char *s = mp_input_get_key_combo_name(keys, num_keys);
MP_DBG(ictx, "add: section='%s' key='%s'%s cmd='%s' location='%s'\n",
bind->owner->section, s, bind->is_builtin ? " builtin" : "",
bind->cmd, bind->location);
talloc_free(s);
}
}
// restrict_section: every entry is forced to this section name
// if NULL, load normally and allow any sections
static int parse_config(struct input_ctx *ictx, bool builtin, bstr data,
const char *location, const char *restrict_section)
{
int n_binds = 0;
int line_no = 0;
char *cur_loc = NULL;
while (data.len) {
line_no++;
if (cur_loc)
talloc_free(cur_loc);
cur_loc = talloc_asprintf(NULL, "%s:%d", location, line_no);
bstr line = bstr_strip_linebreaks(bstr_getline(data, &data));
line = bstr_lstrip(line);
if (line.len == 0 || bstr_startswith0(line, "#"))
continue;
if (bstr_eatstart0(&line, "default-bindings ")) {
bstr orig = line;
bstr_split_tok(line, "#", &line, &(bstr){0});
line = bstr_strip(line);
if (bstr_equals0(line, "start")) {
builtin = true;
} else {
MP_ERR(ictx, "Broken line: %.*s at %s\n", BSTR_P(orig), cur_loc);
}
continue;
}
struct bstr command;
// Find the key name starting a line
struct bstr keyname = bstr_split(line, WHITESPACE, &command);
command = bstr_strip(command);
if (command.len == 0) {
MP_ERR(ictx, "Unfinished key binding: %.*s at %s\n", BSTR_P(line),
cur_loc);
continue;
}
char *name = bstrdup0(NULL, keyname);
int keys[MP_MAX_KEY_DOWN];
int num_keys = 0;
if (!mp_input_get_keys_from_string(name, MP_MAX_KEY_DOWN, &num_keys, keys))
{
talloc_free(name);
MP_ERR(ictx, "Unknown key '%.*s' at %s\n", BSTR_P(keyname), cur_loc);
continue;
}
talloc_free(name);
bstr section = bstr0(restrict_section);
if (!section.len) {
if (bstr_startswith0(command, "{")) {
int p = bstrchr(command, '}');
if (p != -1) {
section = bstr_strip(bstr_splice(command, 1, p));
command = bstr_lstrip(bstr_cut(command, p + 1));
}
}
}
bind_keys(ictx, builtin, section, keys, num_keys, command, cur_loc);
n_binds++;
// Print warnings if invalid commands are encountered.
talloc_free(mp_input_parse_cmd(ictx, command, cur_loc));
}
talloc_free(cur_loc);
return n_binds;
}
static int parse_config_file(struct input_ctx *ictx, char *file, bool warn)
{
int r = 0;
void *tmp = talloc_new(NULL);
stream_t *s = NULL;
file = mp_get_user_path(tmp, ictx->global, file);
s = stream_open(file, ictx->global);
if (!s) {
MP_ERR(ictx, "Can't open input config file %s.\n", file);
goto done;
}
stream_skip_bom(s);
bstr data = stream_read_complete(s, tmp, 1000000);
if (data.start) {
MP_VERBOSE(ictx, "Parsing input config file %s\n", file);
int num = parse_config(ictx, false, data, file, NULL);
MP_VERBOSE(ictx, "Input config file %s parsed: %d binds\n", file, num);
r = 1;
} else {
MP_ERR(ictx, "Error reading input config file %s\n", file);
}
done:
free_stream(s);
talloc_free(tmp);
return r;
}
struct input_ctx *mp_input_init(struct mpv_global *global,
void (*wakeup_cb)(void *ctx),
void *wakeup_ctx)
{
struct input_ctx *ictx = talloc_ptrtype(NULL, ictx);
*ictx = (struct input_ctx){
.global = global,
.ar_state = -1,
.log = mp_log_new(ictx, global->log, "input"),
.mouse_section = "default",
.opts_cache = m_config_cache_alloc(ictx, global, &input_config),
.wakeup_cb = wakeup_cb,
.wakeup_ctx = wakeup_ctx,
};
ictx->opts = ictx->opts_cache->opts;
mpthread_mutex_init_recursive(&ictx->mutex);
// Setup default section, so that it does nothing.
mp_input_enable_section(ictx, NULL, MP_INPUT_ALLOW_VO_DRAGGING |
MP_INPUT_ALLOW_HIDE_CURSOR);
return ictx;
}
static void reload_opts(struct input_ctx *ictx, bool shutdown)
{
m_config_cache_update(ictx->opts_cache);
#if HAVE_COCOA
struct input_opts *opts = ictx->opts;
if (ictx->using_ar != (opts->use_appleremote && !shutdown)) {
ictx->using_ar = !ictx->using_ar;
if (ictx->using_ar) {
cocoa_init_apple_remote();
} else {
cocoa_uninit_apple_remote();
}
}
if (ictx->using_cocoa_media_keys != (opts->use_media_keys && !shutdown)) {
ictx->using_cocoa_media_keys = !ictx->using_cocoa_media_keys;
if (ictx->using_cocoa_media_keys) {
cocoa_init_media_keys();
} else {
cocoa_uninit_media_keys();
}
}
#endif
}
void mp_input_update_opts(struct input_ctx *ictx)
{
input_lock(ictx);
reload_opts(ictx, false);
input_unlock(ictx);
}
void mp_input_load_config(struct input_ctx *ictx)
{
input_lock(ictx);
reload_opts(ictx, false);
// "Uncomment" the default key bindings in etc/input.conf and add them.
// All lines that do not start with '# ' are parsed.
bstr builtin = bstr0(builtin_input_conf);
while (builtin.len) {
bstr line = bstr_getline(builtin, &builtin);
bstr_eatstart0(&line, "#");
if (!bstr_startswith0(line, " "))
parse_config(ictx, true, line, "<builtin>", NULL);
}
bool config_ok = false;
if (ictx->opts->config_file && ictx->opts->config_file[0])
config_ok = parse_config_file(ictx, ictx->opts->config_file, true);
if (!config_ok) {
// Try global conf dir
void *tmp = talloc_new(NULL);
char **files = mp_find_all_config_files(tmp, ictx->global, "input.conf");
for (int n = 0; files && files[n]; n++)
parse_config_file(ictx, files[n], false);
talloc_free(tmp);
}
#if defined(__MINGW32__)
if (ictx->global->opts->input_file && *ictx->global->opts->input_file)
mp_input_pipe_add(ictx, ictx->global->opts->input_file);
#endif
input_unlock(ictx);
}
static void clear_queue(struct cmd_queue *queue)
{
while (queue->first) {
struct mp_cmd *item = queue->first;
queue_remove(queue, item);
talloc_free(item);
}
}
void mp_input_uninit(struct input_ctx *ictx)
{
if (!ictx)
return;
input_lock(ictx);
reload_opts(ictx, true);
input_unlock(ictx);
close_input_sources(ictx);
clear_queue(&ictx->cmd_queue);
talloc_free(ictx->current_down_cmd);
pthread_mutex_destroy(&ictx->mutex);
talloc_free(ictx);
}
void mp_input_set_cancel(struct input_ctx *ictx, void (*cb)(void *c), void *c)
{
input_lock(ictx);
ictx->cancel = cb;
ictx->cancel_ctx = c;
input_unlock(ictx);
}
bool mp_input_use_alt_gr(struct input_ctx *ictx)
{
input_lock(ictx);
bool r = ictx->opts->use_alt_gr;
input_unlock(ictx);
return r;
}
struct mp_cmd *mp_input_parse_cmd(struct input_ctx *ictx, bstr str,
const char *location)
{
return mp_input_parse_cmd_(ictx->log, str, location);
}
void mp_input_run_cmd(struct input_ctx *ictx, const char **cmd)
{
mp_input_queue_cmd(ictx, mp_input_parse_cmd_strv(ictx->log, cmd));
}
struct mp_input_src_internal {
pthread_t thread;
bool thread_running;
bool init_done;
char *cmd_buffer;
size_t cmd_buffer_size;
bool drop;
};
static struct mp_input_src *mp_input_add_src(struct input_ctx *ictx)
{
input_lock(ictx);
if (ictx->num_sources == MP_MAX_SOURCES) {
input_unlock(ictx);
return NULL;
}
char name[80];
snprintf(name, sizeof(name), "#%d", ictx->num_sources + 1);
struct mp_input_src *src = talloc_ptrtype(NULL, src);
*src = (struct mp_input_src){
.global = ictx->global,
.log = mp_log_new(src, ictx->log, name),
.input_ctx = ictx,
.in = talloc_zero(src, struct mp_input_src_internal),
};
ictx->sources[ictx->num_sources++] = src;
input_unlock(ictx);
return src;
}
static void mp_input_src_kill(struct mp_input_src *src);
static void close_input_sources(struct input_ctx *ictx)
{
// To avoid lock-order issues, we first remove each source from the context,
// and then destroy it.
while (1) {
input_lock(ictx);
struct mp_input_src *src = ictx->num_sources ? ictx->sources[0] : NULL;
input_unlock(ictx);
if (!src)
break;
mp_input_src_kill(src);
}
}
static void mp_input_src_kill(struct mp_input_src *src)
{
if (!src)
return;
struct input_ctx *ictx = src->input_ctx;
input_lock(ictx);
for (int n = 0; n < ictx->num_sources; n++) {
if (ictx->sources[n] == src) {
MP_TARRAY_REMOVE_AT(ictx->sources, ictx->num_sources, n);
input_unlock(ictx);
if (src->cancel)
src->cancel(src);
if (src->in->thread_running)
pthread_join(src->in->thread, NULL);
if (src->uninit)
src->uninit(src);
talloc_free(src);
return;
}
}
abort();
}
void mp_input_src_init_done(struct mp_input_src *src)
{
assert(!src->in->init_done);
assert(src->in->thread_running);
assert(pthread_equal(src->in->thread, pthread_self()));
src->in->init_done = true;
mp_rendezvous(&src->in->init_done, 0);
}
static void *input_src_thread(void *ptr)
{
void **args = ptr;
struct mp_input_src *src = args[0];
void (*loop_fn)(struct mp_input_src *src, void *ctx) = args[1];
void *ctx = args[2];
mpthread_set_name("input source");
src->in->thread_running = true;
loop_fn(src, ctx);
if (!src->in->init_done)
mp_rendezvous(&src->in->init_done, -1);
return NULL;
}
int mp_input_add_thread_src(struct input_ctx *ictx, void *ctx,
void (*loop_fn)(struct mp_input_src *src, void *ctx))
{
struct mp_input_src *src = mp_input_add_src(ictx);
if (!src)
return -1;
void *args[] = {src, loop_fn, ctx};
if (pthread_create(&src->in->thread, NULL, input_src_thread, args)) {
mp_input_src_kill(src);
return -1;
}
if (mp_rendezvous(&src->in->init_done, 0) < 0) {
mp_input_src_kill(src);
return -1;
}
return 0;
}
#define CMD_BUFFER (4 * 4096)
void mp_input_src_feed_cmd_text(struct mp_input_src *src, char *buf, size_t len)
{
struct mp_input_src_internal *in = src->in;
if (!in->cmd_buffer)
in->cmd_buffer = talloc_size(in, CMD_BUFFER);
while (len) {
char *next = memchr(buf, '\n', len);
bool term = !!next;
next = next ? next + 1 : buf + len;
size_t copy = next - buf;
bool overflow = copy > CMD_BUFFER - in->cmd_buffer_size;
if (overflow || in->drop) {
in->cmd_buffer_size = 0;
in->drop = overflow || !term;
MP_WARN(src, "Dropping overlong line.\n");
} else {
memcpy(in->cmd_buffer + in->cmd_buffer_size, buf, copy);
in->cmd_buffer_size += copy;
buf += copy;
len -= copy;
if (term) {
bstr s = {in->cmd_buffer, in->cmd_buffer_size};
s = bstr_strip(s);
struct mp_cmd *cmd= mp_input_parse_cmd_(src->log, s, "<>");
if (cmd)
mp_input_queue_cmd(src->input_ctx, cmd);
in->cmd_buffer_size = 0;
}
}
}
}
void mp_input_set_repeat_info(struct input_ctx *ictx, int rate, int delay)
{
input_lock(ictx);
ictx->opts->ar_rate = rate;
ictx->opts->ar_delay = delay;
input_unlock(ictx);
}