mirror of https://github.com/mpv-player/mpv
341 lines
11 KiB
C
341 lines
11 KiB
C
/*
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* This file is part of mpv.
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*
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* mpv is free software; you can redistribute it and/or
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* modify it under the terms of the GNU Lesser General Public
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* License as published by the Free Software Foundation; either
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* version 2.1 of the License, or (at your option) any later version.
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*
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* mpv is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU Lesser General Public License for more details.
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*
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* You should have received a copy of the GNU Lesser General Public
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* License along with mpv. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <stddef.h>
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#include <inttypes.h>
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#include <assert.h>
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#include "ao.h"
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#include "internal.h"
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#include "audio/format.h"
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#include "common/msg.h"
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#include "common/common.h"
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#include "input/input.h"
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#include "osdep/timer.h"
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#include "osdep/threads.h"
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#include "osdep/atomic.h"
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#include "misc/ring.h"
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/*
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* Note: there is some stupid stuff in this file in order to avoid mutexes.
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* This requirement is dictated by several audio APIs, at least jackaudio.
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*/
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enum {
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AO_STATE_NONE, // idle (e.g. before playback started, or after playback
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// finished, but device is open)
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AO_STATE_WAIT, // wait for callback to go into AO_STATE_NONE state
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AO_STATE_PLAY, // play the buffer
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AO_STATE_BUSY, // like AO_STATE_PLAY, but ao_read_data() is being called
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};
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#define IS_PLAYING(st) ((st) == AO_STATE_PLAY || (st) == AO_STATE_BUSY)
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struct ao_pull_state {
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// Be very careful with the order when accessing planes.
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struct mp_ring *buffers[MP_NUM_CHANNELS];
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// AO_STATE_*
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atomic_int state;
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// Set when the buffer is intentionally not fed anymore in PLAY state.
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atomic_bool draining;
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// Set by the audio thread when an underflow was detected.
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// It adds the number of samples.
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atomic_int underflow;
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// Device delay of the last written sample, in realtime.
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atomic_llong end_time_us;
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char *convert_buffer;
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};
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static void set_state(struct ao *ao, int new_state)
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{
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struct ao_pull_state *p = ao->api_priv;
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while (1) {
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int old = atomic_load(&p->state);
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if (old == AO_STATE_BUSY) {
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// A spinlock, because some audio APIs don't want us to use mutexes.
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mp_sleep_us(1);
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continue;
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}
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if (atomic_compare_exchange_strong(&p->state, &old, new_state))
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break;
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}
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}
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static int get_space(struct ao *ao)
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{
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struct ao_pull_state *p = ao->api_priv;
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// Since the reader will read the last plane last, its free space is the
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// minimum free space across all planes.
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return mp_ring_available(p->buffers[ao->num_planes - 1]) / ao->sstride;
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}
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static int play(struct ao *ao, void **data, int samples, int flags)
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{
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struct ao_pull_state *p = ao->api_priv;
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int write_samples = get_space(ao);
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write_samples = MPMIN(write_samples, samples);
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// Write starting from the last plane - this way, the first plane will
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// always contain the minimum amount of data readable across all planes
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// (assumes the reader starts with the first plane).
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int write_bytes = write_samples * ao->sstride;
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for (int n = ao->num_planes - 1; n >= 0; n--) {
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int r = mp_ring_write(p->buffers[n], data[n], write_bytes);
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assert(r == write_bytes);
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}
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int state = atomic_load(&p->state);
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if (!IS_PLAYING(state)) {
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atomic_store(&p->draining, false);
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atomic_store(&p->underflow, 0);
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set_state(ao, AO_STATE_PLAY);
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if (!ao->stream_silence)
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ao->driver->resume(ao);
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}
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bool draining = write_samples == samples && (flags & AOPLAY_FINAL_CHUNK);
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atomic_store(&p->draining, draining);
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int underflow = atomic_fetch_and(&p->underflow, 0);
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if (underflow)
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MP_DBG(ao, "Audio underrun by %d samples.\n", underflow);
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return write_samples;
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}
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// Read the given amount of samples in the user-provided data buffer. Returns
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// the number of samples copied. If there is not enough data (buffer underrun
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// or EOF), return the number of samples that could be copied, and fill the
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// rest of the user-provided buffer with silence.
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// This basically assumes that the audio device doesn't care about underruns.
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// If this is called in paused mode, it will always return 0.
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// The caller should set out_time_us to the expected delay until the last sample
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// reaches the speakers, in microseconds, using mp_time_us() as reference.
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int ao_read_data(struct ao *ao, void **data, int samples, int64_t out_time_us)
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{
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assert(ao->api == &ao_api_pull);
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struct ao_pull_state *p = ao->api_priv;
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int full_bytes = samples * ao->sstride;
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bool need_wakeup = false;
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int bytes = 0;
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// Play silence in states other than AO_STATE_PLAY.
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if (!atomic_compare_exchange_strong(&p->state, &(int){AO_STATE_PLAY},
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AO_STATE_BUSY))
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goto end;
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// Since the writer will write the first plane last, its buffered amount
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// of data is the minimum amount across all planes.
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int buffered_bytes = mp_ring_buffered(p->buffers[0]);
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bytes = MPMIN(buffered_bytes, full_bytes);
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if (full_bytes > bytes && !atomic_load(&p->draining)) {
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atomic_fetch_add(&p->underflow, (full_bytes - bytes) / ao->sstride);
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ao_underrun_event(ao);
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}
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if (bytes > 0)
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atomic_store(&p->end_time_us, out_time_us);
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for (int n = 0; n < ao->num_planes; n++) {
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int r = mp_ring_read(p->buffers[n], data[n], bytes);
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bytes = MPMIN(bytes, r);
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}
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// Half of the buffer played -> request more.
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need_wakeup = buffered_bytes - bytes <= mp_ring_size(p->buffers[0]) / 2;
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// Should never fail.
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atomic_compare_exchange_strong(&p->state, &(int){AO_STATE_BUSY}, AO_STATE_PLAY);
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end:
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if (need_wakeup)
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ao->wakeup_cb(ao->wakeup_ctx);
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// pad with silence (underflow/paused/eof)
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for (int n = 0; n < ao->num_planes; n++)
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af_fill_silence((char *)data[n] + bytes, full_bytes - bytes, ao->format);
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ao_post_process_data(ao, data, samples);
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return bytes / ao->sstride;
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}
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// Same as ao_read_data(), but convert data according to *fmt.
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// fmt->src_fmt and fmt->channels must be the same as the AO parameters.
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int ao_read_data_converted(struct ao *ao, struct ao_convert_fmt *fmt,
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void **data, int samples, int64_t out_time_us)
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{
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assert(ao->api == &ao_api_pull);
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struct ao_pull_state *p = ao->api_priv;
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void *ndata[MP_NUM_CHANNELS] = {0};
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if (!ao_need_conversion(fmt))
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return ao_read_data(ao, data, samples, out_time_us);
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assert(ao->format == fmt->src_fmt);
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assert(ao->channels.num == fmt->channels);
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bool planar = af_fmt_is_planar(fmt->src_fmt);
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int planes = planar ? fmt->channels : 1;
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int plane_samples = samples * (planar ? 1: fmt->channels);
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int src_plane_size = plane_samples * af_fmt_to_bytes(fmt->src_fmt);
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int dst_plane_size = plane_samples * fmt->dst_bits / 8;
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int needed = src_plane_size * planes;
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if (needed > talloc_get_size(p->convert_buffer) || !p->convert_buffer) {
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talloc_free(p->convert_buffer);
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p->convert_buffer = talloc_size(NULL, needed);
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}
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for (int n = 0; n < planes; n++)
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ndata[n] = p->convert_buffer + n * src_plane_size;
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int res = ao_read_data(ao, ndata, samples, out_time_us);
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ao_convert_inplace(fmt, ndata, samples);
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for (int n = 0; n < planes; n++)
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memcpy(data[n], ndata[n], dst_plane_size);
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return res;
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}
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static int control(struct ao *ao, enum aocontrol cmd, void *arg)
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{
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if (ao->driver->control)
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return ao->driver->control(ao, cmd, arg);
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return CONTROL_UNKNOWN;
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}
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// Return size of the buffered data in seconds. Can include the device latency.
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// Basically, this returns how much data there is still to play, and how long
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// it takes until the last sample in the buffer reaches the speakers. This is
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// used for audio/video synchronization, so it's very important to implement
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// this correctly.
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static double get_delay(struct ao *ao)
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{
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struct ao_pull_state *p = ao->api_priv;
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int64_t end = atomic_load(&p->end_time_us);
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int64_t now = mp_time_us();
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double driver_delay = MPMAX(0, (end - now) / (1000.0 * 1000.0));
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return mp_ring_buffered(p->buffers[0]) / (double)ao->bps + driver_delay;
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}
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static void reset(struct ao *ao)
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{
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struct ao_pull_state *p = ao->api_priv;
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if (!ao->stream_silence && ao->driver->reset)
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ao->driver->reset(ao); // assumes the audio callback thread is stopped
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set_state(ao, AO_STATE_NONE);
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for (int n = 0; n < ao->num_planes; n++)
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mp_ring_reset(p->buffers[n]);
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atomic_store(&p->end_time_us, 0);
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}
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static void pause(struct ao *ao)
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{
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if (!ao->stream_silence && ao->driver->reset)
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ao->driver->reset(ao);
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set_state(ao, AO_STATE_NONE);
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}
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static void resume(struct ao *ao)
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{
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set_state(ao, AO_STATE_PLAY);
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if (!ao->stream_silence)
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ao->driver->resume(ao);
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}
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static bool get_eof(struct ao *ao)
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{
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struct ao_pull_state *p = ao->api_priv;
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// For simplicity, ignore the latency. Otherwise, we would have to run an
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// extra thread to time it.
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return mp_ring_buffered(p->buffers[0]) == 0;
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}
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static void drain(struct ao *ao)
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{
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struct ao_pull_state *p = ao->api_priv;
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int state = atomic_load(&p->state);
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if (IS_PLAYING(state)) {
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atomic_store(&p->draining, true);
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// Wait for lower bound.
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mp_sleep_us(mp_ring_buffered(p->buffers[0]) / (double)ao->bps * 1e6);
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// And then poll for actual end. (Unfortunately, this code considers
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// audio APIs which do not want you to use mutexes in the audio
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// callback, and an extra semaphore would require slightly more effort.)
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// Limit to arbitrary ~250ms max. waiting for robustness.
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int64_t max = mp_time_us() + 250000;
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while (mp_time_us() < max && !get_eof(ao))
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mp_sleep_us(1);
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}
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reset(ao);
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}
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static void uninit(struct ao *ao)
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{
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struct ao_pull_state *p = ao->api_priv;
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ao->driver->uninit(ao);
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talloc_free(p->convert_buffer);
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}
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static int init(struct ao *ao)
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{
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struct ao_pull_state *p = ao->api_priv;
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for (int n = 0; n < ao->num_planes; n++)
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p->buffers[n] = mp_ring_new(ao, ao->buffer * ao->sstride);
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atomic_store(&p->state, AO_STATE_NONE);
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assert(ao->driver->resume);
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if (ao->stream_silence)
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ao->driver->resume(ao);
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return 0;
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}
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const struct ao_driver ao_api_pull = {
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.init = init,
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.control = control,
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.uninit = uninit,
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.drain = drain,
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.reset = reset,
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.get_space = get_space,
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.play = play,
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.get_delay = get_delay,
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.get_eof = get_eof,
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.pause = pause,
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.resume = resume,
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.priv_size = sizeof(struct ao_pull_state),
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};
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