mpv/audio/out/ao_audiotrack.c

838 lines
30 KiB
C

/*
* Android AudioTrack audio output driver.
* Copyright (C) 2018 Aman Gupta <aman@tmm1.net>
* Copyright (C) 2012-2015 VLC authors and VideoLAN, VideoLabs
* Authors: Thomas Guillem <thomas@gllm.fr>
* Ming Hu <tewilove@gmail.com>
*
* 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 "ao.h"
#include "internal.h"
#include "common/msg.h"
#include "audio/format.h"
#include "options/m_option.h"
#include "osdep/threads.h"
#include "osdep/timer.h"
#include "misc/jni.h"
struct priv {
jobject audiotrack;
jint samplerate;
jint channel_config;
jint format;
jint size;
jobject timestamp;
int64_t timestamp_fetched;
bool timestamp_set;
int timestamp_stable;
uint32_t written_frames; /* requires uint32_t rollover semantics */
uint32_t playhead_pos;
uint32_t playhead_offset;
bool reset_pending;
void *chunk;
int chunksize;
jbyteArray bytearray;
jshortArray shortarray;
jfloatArray floatarray;
jobject bbuf;
bool cfg_pcm_float;
int cfg_session_id;
bool thread_terminate;
bool thread_created;
mp_thread thread;
mp_mutex lock;
mp_cond wakeup;
};
static struct JNIByteBuffer {
jclass clazz;
jmethodID clear;
} ByteBuffer;
#define OFFSET(member) offsetof(struct JNIByteBuffer, member)
static const struct MPJniField ByteBuffer_mapping[] = {
{"java/nio/ByteBuffer", NULL, MP_JNI_CLASS, OFFSET(clazz), 1},
{"clear", "()Ljava/nio/Buffer;", MP_JNI_METHOD, OFFSET(clear), 1},
{0},
};
#undef OFFSET
static struct JNIAudioTrack {
jclass clazz;
jmethodID ctor;
jmethodID ctorV21;
jmethodID release;
jmethodID getState;
jmethodID getPlayState;
jmethodID play;
jmethodID stop;
jmethodID flush;
jmethodID pause;
jmethodID write;
jmethodID writeFloat;
jmethodID writeShortV23;
jmethodID writeBufferV21;
jmethodID getBufferSizeInFramesV23;
jmethodID getPlaybackHeadPosition;
jmethodID getTimestamp;
jmethodID getLatency;
jmethodID getMinBufferSize;
jmethodID getNativeOutputSampleRate;
jint STATE_INITIALIZED;
jint PLAYSTATE_STOPPED;
jint PLAYSTATE_PAUSED;
jint PLAYSTATE_PLAYING;
jint MODE_STREAM;
jint ERROR;
jint ERROR_BAD_VALUE;
jint ERROR_INVALID_OPERATION;
jint WRITE_BLOCKING;
jint WRITE_NON_BLOCKING;
} AudioTrack;
#define OFFSET(member) offsetof(struct JNIAudioTrack, member)
static const struct MPJniField AudioTrack_mapping[] = {
{"android/media/AudioTrack", NULL, MP_JNI_CLASS, OFFSET(clazz), 1},
{"<init>", "(IIIIIII)V", MP_JNI_METHOD, OFFSET(ctor), 1},
{"<init>", "(Landroid/media/AudioAttributes;Landroid/media/AudioFormat;III)V", MP_JNI_METHOD, OFFSET(ctorV21), 0},
{"release", "()V", MP_JNI_METHOD, OFFSET(release), 1},
{"getState", "()I", MP_JNI_METHOD, OFFSET(getState), 1},
{"getPlayState", "()I", MP_JNI_METHOD, OFFSET(getPlayState), 1},
{"play", "()V", MP_JNI_METHOD, OFFSET(play), 1},
{"stop", "()V", MP_JNI_METHOD, OFFSET(stop), 1},
{"flush", "()V", MP_JNI_METHOD, OFFSET(flush), 1},
{"pause", "()V", MP_JNI_METHOD, OFFSET(pause), 1},
{"write", "([BII)I", MP_JNI_METHOD, OFFSET(write), 1},
{"write", "([FIII)I", MP_JNI_METHOD, OFFSET(writeFloat), 1},
{"write", "([SIII)I", MP_JNI_METHOD, OFFSET(writeShortV23), 0},
{"write", "(Ljava/nio/ByteBuffer;II)I", MP_JNI_METHOD, OFFSET(writeBufferV21), 1},
{"getBufferSizeInFrames", "()I", MP_JNI_METHOD, OFFSET(getBufferSizeInFramesV23), 0},
{"getTimestamp", "(Landroid/media/AudioTimestamp;)Z", MP_JNI_METHOD, OFFSET(getTimestamp), 1},
{"getPlaybackHeadPosition", "()I", MP_JNI_METHOD, OFFSET(getPlaybackHeadPosition), 1},
{"getLatency", "()I", MP_JNI_METHOD, OFFSET(getLatency), 1},
{"getMinBufferSize", "(III)I", MP_JNI_STATIC_METHOD, OFFSET(getMinBufferSize), 1},
{"getNativeOutputSampleRate", "(I)I", MP_JNI_STATIC_METHOD, OFFSET(getNativeOutputSampleRate), 1},
{"WRITE_BLOCKING", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(WRITE_BLOCKING), 0},
{"WRITE_NON_BLOCKING", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(WRITE_NON_BLOCKING), 0},
{"STATE_INITIALIZED", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(STATE_INITIALIZED), 1},
{"PLAYSTATE_STOPPED", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(PLAYSTATE_STOPPED), 1},
{"PLAYSTATE_PAUSED", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(PLAYSTATE_PAUSED), 1},
{"PLAYSTATE_PLAYING", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(PLAYSTATE_PLAYING), 1},
{"MODE_STREAM", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(MODE_STREAM), 1},
{"ERROR", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(ERROR), 1},
{"ERROR_BAD_VALUE", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(ERROR_BAD_VALUE), 1},
{"ERROR_INVALID_OPERATION", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(ERROR_INVALID_OPERATION), 1},
{0}
};
#undef OFFSET
static struct JNIAudioAttributes {
jclass clazz;
jint CONTENT_TYPE_MOVIE;
jint CONTENT_TYPE_MUSIC;
jint USAGE_MEDIA;
} AudioAttributes;
#define OFFSET(member) offsetof(struct JNIAudioAttributes, member)
static const struct MPJniField AudioAttributes_mapping[] = {
{"android/media/AudioAttributes", NULL, MP_JNI_CLASS, OFFSET(clazz), 0},
{"CONTENT_TYPE_MOVIE", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(CONTENT_TYPE_MOVIE), 0},
{"CONTENT_TYPE_MUSIC", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(CONTENT_TYPE_MUSIC), 0},
{"USAGE_MEDIA", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(USAGE_MEDIA), 0},
{0}
};
#undef OFFSET
static struct JNIAudioAttributesBuilder {
jclass clazz;
jmethodID ctor;
jmethodID setUsage;
jmethodID setContentType;
jmethodID build;
} AudioAttributesBuilder;
#define OFFSET(member) offsetof(struct JNIAudioAttributesBuilder, member)
static const struct MPJniField AudioAttributesBuilder_mapping[] = {
{"android/media/AudioAttributes$Builder", NULL, MP_JNI_CLASS, OFFSET(clazz), 0},
{"<init>", "()V", MP_JNI_METHOD, OFFSET(ctor), 0},
{"setUsage", "(I)Landroid/media/AudioAttributes$Builder;", MP_JNI_METHOD, OFFSET(setUsage), 0},
{"setContentType", "(I)Landroid/media/AudioAttributes$Builder;", MP_JNI_METHOD, OFFSET(setContentType), 0},
{"build", "()Landroid/media/AudioAttributes;", MP_JNI_METHOD, OFFSET(build), 0},
{0}
};
#undef OFFSET
static struct JNIAudioFormat {
jclass clazz;
jint ENCODING_PCM_8BIT;
jint ENCODING_PCM_16BIT;
jint ENCODING_PCM_FLOAT;
jint ENCODING_IEC61937;
jint CHANNEL_OUT_MONO;
jint CHANNEL_OUT_STEREO;
jint CHANNEL_OUT_FRONT_CENTER;
jint CHANNEL_OUT_QUAD;
jint CHANNEL_OUT_5POINT1;
jint CHANNEL_OUT_BACK_CENTER;
jint CHANNEL_OUT_7POINT1_SURROUND;
} AudioFormat;
#define OFFSET(member) offsetof(struct JNIAudioFormat, member)
static const struct MPJniField AudioFormat_mapping[] = {
{"android/media/AudioFormat", NULL, MP_JNI_CLASS, OFFSET(clazz), 1},
{"ENCODING_PCM_8BIT", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(ENCODING_PCM_8BIT), 1},
{"ENCODING_PCM_16BIT", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(ENCODING_PCM_16BIT), 1},
{"ENCODING_PCM_FLOAT", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(ENCODING_PCM_FLOAT), 1},
{"ENCODING_IEC61937", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(ENCODING_IEC61937), 0},
{"CHANNEL_OUT_MONO", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(CHANNEL_OUT_MONO), 1},
{"CHANNEL_OUT_STEREO", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(CHANNEL_OUT_STEREO), 1},
{"CHANNEL_OUT_FRONT_CENTER", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(CHANNEL_OUT_FRONT_CENTER), 1},
{"CHANNEL_OUT_QUAD", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(CHANNEL_OUT_QUAD), 1},
{"CHANNEL_OUT_5POINT1", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(CHANNEL_OUT_5POINT1), 1},
{"CHANNEL_OUT_BACK_CENTER", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(CHANNEL_OUT_BACK_CENTER), 1},
{"CHANNEL_OUT_7POINT1_SURROUND", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(CHANNEL_OUT_7POINT1_SURROUND), 0},
{0}
};
#undef OFFSET
static struct JNIAudioFormatBuilder {
jclass clazz;
jmethodID ctor;
jmethodID setEncoding;
jmethodID setSampleRate;
jmethodID setChannelMask;
jmethodID build;
} AudioFormatBuilder;
#define OFFSET(member) offsetof(struct JNIAudioFormatBuilder, member)
static const struct MPJniField AudioFormatBuilder_mapping[] = {
{"android/media/AudioFormat$Builder", NULL, MP_JNI_CLASS, OFFSET(clazz), 0},
{"<init>", "()V", MP_JNI_METHOD, OFFSET(ctor), 0},
{"setEncoding", "(I)Landroid/media/AudioFormat$Builder;", MP_JNI_METHOD, OFFSET(setEncoding), 0},
{"setSampleRate", "(I)Landroid/media/AudioFormat$Builder;", MP_JNI_METHOD, OFFSET(setSampleRate), 0},
{"setChannelMask", "(I)Landroid/media/AudioFormat$Builder;", MP_JNI_METHOD, OFFSET(setChannelMask), 0},
{"build", "()Landroid/media/AudioFormat;", MP_JNI_METHOD, OFFSET(build), 0},
{0}
};
#undef OFFSET
static struct JNIAudioManager {
jclass clazz;
jint ERROR_DEAD_OBJECT;
jint STREAM_MUSIC;
} AudioManager;
#define OFFSET(member) offsetof(struct JNIAudioManager, member)
static const struct MPJniField AudioManager_mapping[] = {
{"android/media/AudioManager", NULL, MP_JNI_CLASS, OFFSET(clazz), 1},
{"STREAM_MUSIC", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(STREAM_MUSIC), 1},
{"ERROR_DEAD_OBJECT", "I", MP_JNI_STATIC_FIELD_AS_INT, OFFSET(ERROR_DEAD_OBJECT), 0},
{0}
};
#undef OFFSET
static struct JNIAudioTimestamp {
jclass clazz;
jmethodID ctor;
jfieldID framePosition;
jfieldID nanoTime;
} AudioTimestamp;
#define OFFSET(member) offsetof(struct JNIAudioTimestamp, member)
static const struct MPJniField AudioTimestamp_mapping[] = {
{"android/media/AudioTimestamp", NULL, MP_JNI_CLASS, OFFSET(clazz), 1},
{"<init>", "()V", MP_JNI_METHOD, OFFSET(ctor), 1},
{"framePosition", "J", MP_JNI_FIELD, OFFSET(framePosition), 1},
{"nanoTime", "J", MP_JNI_FIELD, OFFSET(nanoTime), 1},
{0}
};
#undef OFFSET
#define ENTRY(name) { &name, name ## _mapping }
static const struct {
void *fields;
const struct MPJniField *mapping;
} jclass_list[] = {
ENTRY(ByteBuffer),
ENTRY(AudioTrack),
ENTRY(AudioAttributes),
ENTRY(AudioAttributesBuilder),
ENTRY(AudioFormat),
ENTRY(AudioFormatBuilder),
ENTRY(AudioManager),
ENTRY(AudioTimestamp),
};
#undef ENTRY
static int AudioTrack_New(struct ao *ao)
{
struct priv *p = ao->priv;
JNIEnv *env = MP_JNI_GET_ENV(ao);
jobject audiotrack = NULL;
if (AudioTrack.ctorV21) {
MP_VERBOSE(ao, "Using API21 initializer\n");
jobject tmp = NULL;
jobject format_builder = MP_JNI_NEW(AudioFormatBuilder.clazz, AudioFormatBuilder.ctor);
MP_JNI_EXCEPTION_LOG(ao);
tmp = MP_JNI_CALL_OBJECT(format_builder, AudioFormatBuilder.setEncoding, p->format);
MP_JNI_LOCAL_FREEP(&tmp);
tmp = MP_JNI_CALL_OBJECT(format_builder, AudioFormatBuilder.setSampleRate, p->samplerate);
MP_JNI_LOCAL_FREEP(&tmp);
tmp = MP_JNI_CALL_OBJECT(format_builder, AudioFormatBuilder.setChannelMask, p->channel_config);
MP_JNI_LOCAL_FREEP(&tmp);
jobject format = MP_JNI_CALL_OBJECT(format_builder, AudioFormatBuilder.build);
MP_JNI_LOCAL_FREEP(&format_builder);
jobject attr_builder = MP_JNI_NEW(AudioAttributesBuilder.clazz, AudioAttributesBuilder.ctor);
MP_JNI_EXCEPTION_LOG(ao);
tmp = MP_JNI_CALL_OBJECT(attr_builder, AudioAttributesBuilder.setUsage, AudioAttributes.USAGE_MEDIA);
MP_JNI_LOCAL_FREEP(&tmp);
jint content_type = (ao->init_flags & AO_INIT_MEDIA_ROLE_MUSIC) ?
AudioAttributes.CONTENT_TYPE_MUSIC : AudioAttributes.CONTENT_TYPE_MOVIE;
tmp = MP_JNI_CALL_OBJECT(attr_builder, AudioAttributesBuilder.setContentType, content_type);
MP_JNI_LOCAL_FREEP(&tmp);
jobject attr = MP_JNI_CALL_OBJECT(attr_builder, AudioAttributesBuilder.build);
MP_JNI_LOCAL_FREEP(&attr_builder);
audiotrack = MP_JNI_NEW(
AudioTrack.clazz,
AudioTrack.ctorV21,
attr,
format,
p->size,
AudioTrack.MODE_STREAM,
p->cfg_session_id
);
MP_JNI_LOCAL_FREEP(&format);
MP_JNI_LOCAL_FREEP(&attr);
} else {
MP_VERBOSE(ao, "Using legacy initializer\n");
audiotrack = MP_JNI_NEW(
AudioTrack.clazz,
AudioTrack.ctor,
AudioManager.STREAM_MUSIC,
p->samplerate,
p->channel_config,
p->format,
p->size,
AudioTrack.MODE_STREAM,
p->cfg_session_id
);
}
if (MP_JNI_EXCEPTION_LOG(ao) < 0 || !audiotrack) {
MP_FATAL(ao, "AudioTrack Init failed\n");
return -1;
}
if (MP_JNI_CALL_INT(audiotrack, AudioTrack.getState) != AudioTrack.STATE_INITIALIZED) {
MP_JNI_CALL_VOID(audiotrack, AudioTrack.release);
MP_JNI_EXCEPTION_LOG(ao);
MP_JNI_LOCAL_FREEP(&audiotrack);
MP_ERR(ao, "AudioTrack.getState failed\n");
return -1;
}
if (AudioTrack.getBufferSizeInFramesV23) {
int bufferSize = MP_JNI_CALL_INT(audiotrack, AudioTrack.getBufferSizeInFramesV23);
if (bufferSize > 0) {
MP_VERBOSE(ao, "AudioTrack.getBufferSizeInFrames = %d\n", bufferSize);
ao->device_buffer = bufferSize;
}
}
p->audiotrack = (*env)->NewGlobalRef(env, audiotrack);
MP_JNI_LOCAL_FREEP(&audiotrack);
if (!p->audiotrack)
return -1;
return 0;
}
static int AudioTrack_Recreate(struct ao *ao)
{
struct priv *p = ao->priv;
JNIEnv *env = MP_JNI_GET_ENV(ao);
MP_JNI_CALL_VOID(p->audiotrack, AudioTrack.release);
MP_JNI_EXCEPTION_LOG(ao);
MP_JNI_GLOBAL_FREEP(&p->audiotrack);
return AudioTrack_New(ao);
}
static uint32_t AudioTrack_getPlaybackHeadPosition(struct ao *ao)
{
struct priv *p = ao->priv;
if (!p->audiotrack)
return 0;
JNIEnv *env = MP_JNI_GET_ENV(ao);
uint32_t pos = 0;
int64_t now = mp_raw_time_ns();
int state = MP_JNI_CALL_INT(p->audiotrack, AudioTrack.getPlayState);
int stable_count = 20;
int64_t wait = p->timestamp_stable < stable_count ? 50000000 : 3000000000;
if (state == AudioTrack.PLAYSTATE_PLAYING && p->format != AudioFormat.ENCODING_IEC61937 &&
(p->timestamp_fetched == 0 || now - p->timestamp_fetched >= wait)) {
if (!p->timestamp_fetched)
p->timestamp_stable = 0;
int64_t time1 = MP_JNI_GET_LONG(p->timestamp, AudioTimestamp.nanoTime);
if (MP_JNI_CALL_BOOL(p->audiotrack, AudioTrack.getTimestamp, p->timestamp)) {
p->timestamp_set = true;
p->timestamp_fetched = now;
if (p->timestamp_stable < stable_count) {
uint32_t fpos = 0xFFFFFFFFL & MP_JNI_GET_LONG(p->timestamp, AudioTimestamp.framePosition);
int64_t time2 = MP_JNI_GET_LONG(p->timestamp, AudioTimestamp.nanoTime);
//MP_VERBOSE(ao, "getTimestamp: fpos= %u / time= %"PRId64" / now= %"PRId64" / stable= %d\n", fpos, time2, now, p->timestamp_stable);
if (time1 != time2 && time2 != 0 && fpos != 0) {
p->timestamp_stable++;
}
}
}
}
/* AudioTrack's framePosition and playbackHeadPosition return a signed integer,
* but documentation states it should be interpreted as a 32-bit unsigned integer.
*/
if (p->timestamp_set) {
pos = 0xFFFFFFFFL & MP_JNI_GET_LONG(p->timestamp, AudioTimestamp.framePosition);
uint32_t fpos = pos;
int64_t time = MP_JNI_GET_LONG(p->timestamp, AudioTimestamp.nanoTime);
if (time == 0)
fpos = pos = 0;
if (fpos != 0 && time != 0 && state == AudioTrack.PLAYSTATE_PLAYING) {
double diff = (double)(now - time) / 1e9;
pos += diff * ao->samplerate;
}
//MP_VERBOSE(ao, "position = %u via getTimestamp (state = %d / fpos= %u / time= %"PRId64")\n", pos, state, fpos, time);
} else {
pos = 0xFFFFFFFFL & MP_JNI_CALL_INT(p->audiotrack, AudioTrack.getPlaybackHeadPosition);
//MP_VERBOSE(ao, "playbackHeadPosition = %u (reset_pending=%d)\n", pos, p->reset_pending);
}
if (p->format == AudioFormat.ENCODING_IEC61937) {
if (p->reset_pending) {
// after a flush(), playbackHeadPosition will not reset to 0 right away.
// sometimes, it will never reset at all.
// save the initial offset after the reset, to subtract it going forward.
if (p->playhead_offset == 0)
p->playhead_offset = pos;
p->reset_pending = false;
MP_VERBOSE(ao, "IEC/playbackHead offset = %d\n", pos);
}
// usually shortly after a flush(), playbackHeadPosition will reset to 0.
// clear out the position and offset to avoid regular "rollover" below
if (pos == 0 && p->playhead_offset != 0) {
MP_VERBOSE(ao, "IEC/playbackHeadPosition %d -> %d (flush)\n", p->playhead_pos, pos);
p->playhead_offset = 0;
p->playhead_pos = 0;
}
// sometimes on a new AudioTrack instance, playbackHeadPosition will reset
// to 0 shortly after playback starts for no reason.
if (pos == 0 && p->playhead_pos != 0) {
MP_VERBOSE(ao, "IEC/playbackHeadPosition %d -> %d (reset)\n", p->playhead_pos, pos);
p->playhead_offset = 0;
p->playhead_pos = 0;
p->written_frames = 0;
}
}
p->playhead_pos = pos;
return p->playhead_pos - p->playhead_offset;
}
static double AudioTrack_getLatency(struct ao *ao)
{
JNIEnv *env = MP_JNI_GET_ENV(ao);
struct priv *p = ao->priv;
if (!p->audiotrack)
return 0;
uint32_t playhead = AudioTrack_getPlaybackHeadPosition(ao);
uint32_t diff = p->written_frames - playhead;
double delay = diff / (double)(ao->samplerate);
if (!p->timestamp_set &&
p->format != AudioFormat.ENCODING_IEC61937)
delay += (double)MP_JNI_CALL_INT(p->audiotrack, AudioTrack.getLatency)/1000.0;
if (delay > 2.0) {
//MP_WARN(ao, "getLatency: written=%u playhead=%u diff=%u delay=%f\n", p->written_frames, playhead, diff, delay);
p->timestamp_fetched = 0;
return 0;
}
return MPCLAMP(delay, 0.0, 2.0);
}
static int AudioTrack_write(struct ao *ao, int len)
{
struct priv *p = ao->priv;
if (!p->audiotrack)
return -1;
JNIEnv *env = MP_JNI_GET_ENV(ao);
void *buf = p->chunk;
jint ret;
if (p->format == AudioFormat.ENCODING_IEC61937) {
(*env)->SetShortArrayRegion(env, p->shortarray, 0, len / 2, buf);
if (MP_JNI_EXCEPTION_LOG(ao) < 0) return -1;
ret = MP_JNI_CALL_INT(p->audiotrack, AudioTrack.writeShortV23, p->shortarray, 0, len / 2, AudioTrack.WRITE_BLOCKING);
if (MP_JNI_EXCEPTION_LOG(ao) < 0) return -1;
if (ret > 0) ret *= 2;
} else if (AudioTrack.writeBufferV21) {
// reset positions for reading
jobject bbuf = MP_JNI_CALL_OBJECT(p->bbuf, ByteBuffer.clear);
if (MP_JNI_EXCEPTION_LOG(ao) < 0) return -1;
MP_JNI_LOCAL_FREEP(&bbuf);
ret = MP_JNI_CALL_INT(p->audiotrack, AudioTrack.writeBufferV21, p->bbuf, len, AudioTrack.WRITE_BLOCKING);
if (MP_JNI_EXCEPTION_LOG(ao) < 0) return -1;
} else if (p->format == AudioFormat.ENCODING_PCM_FLOAT) {
(*env)->SetFloatArrayRegion(env, p->floatarray, 0, len / sizeof(float), buf);
if (MP_JNI_EXCEPTION_LOG(ao) < 0) return -1;
ret = MP_JNI_CALL_INT(p->audiotrack, AudioTrack.writeFloat, p->floatarray, 0, len / sizeof(float), AudioTrack.WRITE_BLOCKING);
if (MP_JNI_EXCEPTION_LOG(ao) < 0) return -1;
if (ret > 0) ret *= sizeof(float);
} else {
(*env)->SetByteArrayRegion(env, p->bytearray, 0, len, buf);
if (MP_JNI_EXCEPTION_LOG(ao) < 0) return -1;
ret = MP_JNI_CALL_INT(p->audiotrack, AudioTrack.write, p->bytearray, 0, len);
if (MP_JNI_EXCEPTION_LOG(ao) < 0) return -1;
}
return ret;
}
static void uninit_jni(struct ao *ao)
{
JNIEnv *env = MP_JNI_GET_ENV(ao);
for (int i = 0; i < MP_ARRAY_SIZE(jclass_list); i++) {
mp_jni_reset_jfields(env, jclass_list[i].fields,
jclass_list[i].mapping, 1, ao->log);
}
}
static int init_jni(struct ao *ao)
{
JNIEnv *env = MP_JNI_GET_ENV(ao);
for (int i = 0; i < MP_ARRAY_SIZE(jclass_list); i++) {
if (mp_jni_init_jfields(env, jclass_list[i].fields,
jclass_list[i].mapping, 1, ao->log) < 0) {
goto error;
}
}
return 0;
error:
uninit_jni(ao);
return -1;
}
static MP_THREAD_VOID ao_thread(void *arg)
{
struct ao *ao = arg;
struct priv *p = ao->priv;
JNIEnv *env = MP_JNI_GET_ENV(ao);
mp_thread_set_name("ao/audiotrack");
mp_mutex_lock(&p->lock);
while (!p->thread_terminate) {
int state = AudioTrack.PLAYSTATE_PAUSED;
if (p->audiotrack) {
state = MP_JNI_CALL_INT(p->audiotrack, AudioTrack.getPlayState);
}
if (state == AudioTrack.PLAYSTATE_PLAYING) {
int read_samples = p->chunksize / ao->sstride;
int64_t ts = mp_time_ns();
ts += MP_TIME_S_TO_NS(read_samples / (double)(ao->samplerate));
ts += MP_TIME_S_TO_NS(AudioTrack_getLatency(ao));
int samples = ao_read_data_nonblocking(ao, &p->chunk, read_samples, ts);
int ret = AudioTrack_write(ao, samples * ao->sstride);
if (ret >= 0) {
p->written_frames += ret / ao->sstride;
} else if (ret == AudioManager.ERROR_DEAD_OBJECT) {
MP_WARN(ao, "AudioTrack.write failed with ERROR_DEAD_OBJECT. Recreating AudioTrack...\n");
if (AudioTrack_Recreate(ao) < 0) {
MP_ERR(ao, "AudioTrack_Recreate failed\n");
}
} else {
MP_ERR(ao, "AudioTrack.write failed with %d\n", ret);
}
} else {
mp_cond_timedwait(&p->wakeup, &p->lock, MP_TIME_MS_TO_NS(300));
}
}
mp_mutex_unlock(&p->lock);
MP_THREAD_RETURN();
}
static void uninit(struct ao *ao)
{
struct priv *p = ao->priv;
JNIEnv *env = MP_JNI_GET_ENV(ao);
if (p->audiotrack) {
MP_JNI_CALL_VOID(p->audiotrack, AudioTrack.stop);
MP_JNI_EXCEPTION_LOG(ao);
MP_JNI_CALL_VOID(p->audiotrack, AudioTrack.flush);
MP_JNI_EXCEPTION_LOG(ao);
}
mp_mutex_lock(&p->lock);
p->thread_terminate = true;
mp_cond_signal(&p->wakeup);
mp_mutex_unlock(&p->lock);
if (p->thread_created)
mp_thread_join(p->thread);
if (p->audiotrack) {
MP_JNI_CALL_VOID(p->audiotrack, AudioTrack.release);
MP_JNI_EXCEPTION_LOG(ao);
MP_JNI_GLOBAL_FREEP(&p->audiotrack);
}
MP_JNI_GLOBAL_FREEP(&p->bytearray);
MP_JNI_GLOBAL_FREEP(&p->shortarray);
MP_JNI_GLOBAL_FREEP(&p->floatarray);
MP_JNI_GLOBAL_FREEP(&p->bbuf);
MP_JNI_GLOBAL_FREEP(&p->timestamp);
mp_cond_destroy(&p->wakeup);
mp_mutex_destroy(&p->lock);
uninit_jni(ao);
}
static int init(struct ao *ao)
{
struct priv *p = ao->priv;
JNIEnv *env = MP_JNI_GET_ENV(ao);
if (!env)
return -1;
mp_mutex_init(&p->lock);
mp_cond_init(&p->wakeup);
if (init_jni(ao) < 0)
return -1;
if (af_fmt_is_spdif(ao->format)) {
p->format = AudioFormat.ENCODING_IEC61937;
if (!p->format || !AudioTrack.writeShortV23) {
MP_ERR(ao, "spdif passthrough not supported by API\n");
return -1;
}
} else if (ao->format == AF_FORMAT_U8) {
p->format = AudioFormat.ENCODING_PCM_8BIT;
} else if (p->cfg_pcm_float && af_fmt_is_float(ao->format)) {
ao->format = AF_FORMAT_FLOAT;
p->format = AudioFormat.ENCODING_PCM_FLOAT;
} else {
ao->format = AF_FORMAT_S16;
p->format = AudioFormat.ENCODING_PCM_16BIT;
}
if (AudioTrack.getNativeOutputSampleRate) {
jint samplerate = MP_JNI_CALL_STATIC_INT(
AudioTrack.clazz,
AudioTrack.getNativeOutputSampleRate,
AudioManager.STREAM_MUSIC
);
if (MP_JNI_EXCEPTION_LOG(ao) == 0) {
MP_VERBOSE(ao, "AudioTrack.nativeOutputSampleRate = %d\n", samplerate);
ao->samplerate = MPMIN(samplerate, ao->samplerate);
}
}
p->samplerate = ao->samplerate;
/* https://developer.android.com/reference/android/media/AudioFormat#channelPositionMask */
static const struct mp_chmap layouts[] = {
{0}, // empty
MP_CHMAP_INIT_MONO, // mono
MP_CHMAP_INIT_STEREO, // stereo
MP_CHMAP3(FL, FR, FC), // 3.0
MP_CHMAP4(FL, FR, BL, BR), // quad
MP_CHMAP5(FL, FR, FC, BL, BR), // 5.0
MP_CHMAP6(FL, FR, FC, LFE, BL, BR), // 5.1
MP_CHMAP7(FL, FR, FC, LFE, BL, BR, BC), // 6.1
MP_CHMAP8(FL, FR, FC, LFE, BL, BR, SL, SR), // 7.1
};
const jint layout_map[] = {
0,
AudioFormat.CHANNEL_OUT_MONO,
AudioFormat.CHANNEL_OUT_STEREO,
AudioFormat.CHANNEL_OUT_STEREO | AudioFormat.CHANNEL_OUT_FRONT_CENTER,
AudioFormat.CHANNEL_OUT_QUAD,
AudioFormat.CHANNEL_OUT_QUAD | AudioFormat.CHANNEL_OUT_FRONT_CENTER,
AudioFormat.CHANNEL_OUT_5POINT1,
AudioFormat.CHANNEL_OUT_5POINT1 | AudioFormat.CHANNEL_OUT_BACK_CENTER,
AudioFormat.CHANNEL_OUT_7POINT1_SURROUND,
};
static_assert(MP_ARRAY_SIZE(layout_map) == MP_ARRAY_SIZE(layouts), "");
if (p->format == AudioFormat.ENCODING_IEC61937) {
p->channel_config = AudioFormat.CHANNEL_OUT_STEREO;
} else {
struct mp_chmap_sel sel = {0};
for (int i = 0; i < MP_ARRAY_SIZE(layouts); i++) {
if (layout_map[i])
mp_chmap_sel_add_map(&sel, &layouts[i]);
}
if (!ao_chmap_sel_adjust(ao, &sel, &ao->channels))
goto error;
p->channel_config = layout_map[ao->channels.num];
assert(p->channel_config);
}
jint buffer_size = MP_JNI_CALL_STATIC_INT(
AudioTrack.clazz,
AudioTrack.getMinBufferSize,
p->samplerate,
p->channel_config,
p->format
);
if (MP_JNI_EXCEPTION_LOG(ao) < 0 || buffer_size <= 0) {
MP_FATAL(ao, "AudioTrack.getMinBufferSize returned an invalid size: %d", buffer_size);
return -1;
}
// Choose double of the minimum buffer size suggested by the driver, but not
// less than 75ms or more than 150ms.
const int bps = af_fmt_to_bytes(ao->format);
int min = 0.075 * p->samplerate * bps * ao->channels.num;
int max = min * 2;
min = MP_ALIGN_UP(min, bps);
max = MP_ALIGN_UP(max, bps);
p->size = MPCLAMP(buffer_size * 2, min, max);
MP_VERBOSE(ao, "Setting bufferSize = %d (driver=%d, min=%d, max=%d)\n", p->size, buffer_size, min, max);
assert(p->size % bps == 0);
ao->device_buffer = p->size / bps;
p->chunksize = p->size;
p->chunk = talloc_size(ao, p->size);
jobject timestamp = MP_JNI_NEW(AudioTimestamp.clazz, AudioTimestamp.ctor);
if (MP_JNI_EXCEPTION_LOG(ao) < 0 || !timestamp) {
MP_FATAL(ao, "AudioTimestamp could not be created\n");
return -1;
}
p->timestamp = (*env)->NewGlobalRef(env, timestamp);
MP_JNI_LOCAL_FREEP(&timestamp);
// decide and create buffer of right type
if (p->format == AudioFormat.ENCODING_IEC61937) {
jshortArray shortarray = (*env)->NewShortArray(env, p->chunksize / 2);
p->shortarray = (*env)->NewGlobalRef(env, shortarray);
MP_JNI_LOCAL_FREEP(&shortarray);
} else if (AudioTrack.writeBufferV21) {
MP_VERBOSE(ao, "Using NIO ByteBuffer\n");
jobject bbuf = (*env)->NewDirectByteBuffer(env, p->chunk, p->chunksize);
p->bbuf = (*env)->NewGlobalRef(env, bbuf);
MP_JNI_LOCAL_FREEP(&bbuf);
} else if (p->format == AudioFormat.ENCODING_PCM_FLOAT) {
jfloatArray floatarray = (*env)->NewFloatArray(env, p->chunksize / sizeof(float));
p->floatarray = (*env)->NewGlobalRef(env, floatarray);
MP_JNI_LOCAL_FREEP(&floatarray);
} else {
jbyteArray bytearray = (*env)->NewByteArray(env, p->chunksize);
p->bytearray = (*env)->NewGlobalRef(env, bytearray);
MP_JNI_LOCAL_FREEP(&bytearray);
}
/* create AudioTrack object */
if (AudioTrack_New(ao) != 0) {
MP_FATAL(ao, "Failed to create AudioTrack\n");
goto error;
}
if (mp_thread_create(&p->thread, ao_thread, ao)) {
MP_ERR(ao, "pthread creation failed\n");
goto error;
}
p->thread_created = true;
return 1;
error:
uninit(ao);
return -1;
}
static void stop(struct ao *ao)
{
struct priv *p = ao->priv;
if (!p->audiotrack) {
MP_ERR(ao, "AudioTrack does not exist to stop!\n");
return;
}
JNIEnv *env = MP_JNI_GET_ENV(ao);
MP_JNI_CALL_VOID(p->audiotrack, AudioTrack.pause);
MP_JNI_EXCEPTION_LOG(ao);
MP_JNI_CALL_VOID(p->audiotrack, AudioTrack.flush);
MP_JNI_EXCEPTION_LOG(ao);
p->playhead_offset = 0;
p->reset_pending = true;
p->written_frames = 0;
p->timestamp_fetched = 0;
p->timestamp_set = false;
}
static void start(struct ao *ao)
{
struct priv *p = ao->priv;
if (!p->audiotrack) {
MP_ERR(ao, "AudioTrack does not exist to start!\n");
return;
}
JNIEnv *env = MP_JNI_GET_ENV(ao);
MP_JNI_CALL_VOID(p->audiotrack, AudioTrack.play);
MP_JNI_EXCEPTION_LOG(ao);
mp_cond_signal(&p->wakeup);
}
#define OPT_BASE_STRUCT struct priv
const struct ao_driver audio_out_audiotrack = {
.description = "Android AudioTrack audio output",
.name = "audiotrack",
.init = init,
.uninit = uninit,
.reset = stop,
.start = start,
.priv_size = sizeof(struct priv),
.priv_defaults = &(const OPT_BASE_STRUCT) {
.cfg_pcm_float = 1,
},
.options = (const struct m_option[]) {
{"pcm-float", OPT_BOOL(cfg_pcm_float)},
{"session-id", OPT_INT(cfg_session_id)},
{0}
},
.options_prefix = "audiotrack",
};