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vdr-plugin-softhdcuvid/audio.c

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///
/// @file audio.c @brief Audio module
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///
/// Copyright (c) 2009 - 2014 by Johns. All Rights Reserved.
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///
/// Contributor(s):
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///
/// License: AGPLv3
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///
/// This program is free software: you can redistribute it and/or modify
/// it under the terms of the GNU Affero General Public License as
/// published by the Free Software Foundation, either version 3 of the
/// License.
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///
/// This program 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 Affero General Public License for more details.
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///
/// $Id: 77fa65030b179e78c13d0bf69a7cc417dae89e1a $
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//////////////////////////////////////////////////////////////////////////////
///
/// @defgroup Audio The audio module.
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///
/// This module contains all audio output functions.
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///
/// ALSA PCM/Mixer api is supported.
/// @see http://www.alsa-project.org/alsa-doc/alsa-lib
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///
/// @note alsa async playback is broken, don't use it!
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///
///
/// @todo FIXME: there can be problems with little/big endian.
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///
#ifdef DEBUG
#undef DEBUG
#endif
#define USE_AUDIO_THREAD ///< use thread for audio playback
#define USE_AUDIO_MIXER ///< use audio module mixer
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#include <inttypes.h>
#include <math.h>
#include <sched.h>
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#include <stdint.h>
#include <stdio.h>
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#include <stdlib.h>
#include <string.h>
#include <sys/prctl.h>
#include <libintl.h>
#define _(str) gettext(str) ///< gettext shortcut
#define _N(str) str ///< gettext_noop shortcut
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#include <alsa/asoundlib.h>
#ifdef USE_AUDIO_THREAD
#include <pthread.h>
#include <sys/resource.h>
#include <sys/syscall.h>
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#endif
#include "iatomic.h" // portable atomic_t
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#include "audio.h"
#include "misc.h"
#include "ringbuffer.h"
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//----------------------------------------------------------------------------
// Declarations
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//----------------------------------------------------------------------------
/**
** Audio output module structure and typedef.
*/
typedef struct _audio_module_ {
const char *Name; ///< audio output module name
int (*const Thread)(void); ///< module thread handler
void (*const FlushBuffers)(void); ///< flush sample buffers
int64_t (*const GetDelay)(void); ///< get current audio delay
void (*const SetVolume)(int); ///< set output volume
int (*const Setup)(int *, int *, int); ///< setup channels, samplerate
void (*const Play)(void); ///< play audio
void (*const Pause)(void); ///< pause audio
void (*const Init)(void); ///< initialize audio output module
void (*const Exit)(void); ///< cleanup audio output module
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} AudioModule;
static const AudioModule NoopModule; ///< forward definition of noop module
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//----------------------------------------------------------------------------
// Variables
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//----------------------------------------------------------------------------
char AudioAlsaDriverBroken; ///< disable broken driver message
char AudioAlsaNoCloseOpen; ///< disable alsa close/open fix
char AudioAlsaCloseOpenDelay; ///< enable alsa close/open delay fix
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static const char *AudioModuleName; ///< which audio module to use
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/// Selected audio module.
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static const AudioModule *AudioUsedModule = &NoopModule;
static const char *AudioPCMDevice; ///< PCM device name
static const char *AudioPassthroughDevice; ///< Passthrough device name
static char AudioAppendAES; ///< flag automatic append AES
static const char *AudioMixerDevice; ///< mixer device name
static const char *AudioMixerChannel; ///< mixer channel name
static char AudioDoingInit; ///> flag in init, reduce error
static volatile char AudioRunning; ///< thread running / stopped
static volatile char AudioPaused; ///< audio paused
static volatile char AudioVideoIsReady; ///< video ready start early
static int AudioSkip; ///< skip audio to sync to video
static const int AudioBytesProSample = 2; ///< number of bytes per sample
static int AudioBufferTime = 336; ///< audio buffer time in ms
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#ifdef USE_AUDIO_THREAD
static pthread_t AudioThread; ///< audio play thread
static pthread_mutex_t AudioMutex; ///< audio condition mutex
static pthread_cond_t AudioStartCond; ///< condition variable
static char AudioThreadStop; ///< stop audio thread
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#else
static const int AudioThread; ///< dummy audio thread
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#endif
static char AudioSoftVolume; ///< flag use soft volume
static char AudioNormalize; ///< flag use volume normalize
static char AudioCompression; ///< flag use compress volume
static char AudioMute; ///< flag muted
static int AudioAmplifier; ///< software volume factor
static int AudioNormalizeFactor; ///< current normalize factor
static const int AudioMinNormalize = 100; ///< min. normalize factor
static int AudioMaxNormalize; ///< max. normalize factor
static int AudioCompressionFactor; ///< current compression factor
static int AudioMaxCompression; ///< max. compression factor
static int AudioStereoDescent; ///< volume descent for stereo
static int AudioVolume; ///< current volume (0 .. 1000)
extern int VideoAudioDelay; ///< import audio/video delay
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/// default ring buffer size ~2s 8ch 16bit (3 * 5 * 7 * 8)
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static const unsigned AudioRingBufferSize = 3 * 5 * 7 * 8 * 2 * 1000;
static int AudioChannelsInHw[9]; ///< table which channels are supported
enum _audio_rates { ///< sample rates enumeration
// HW: 32000 44100 48000 88200 96000 176400 192000
// Audio32000, ///< 32.0Khz
Audio44100, ///< 44.1Khz
Audio48000, ///< 48.0Khz
// Audio88200, ///< 88.2Khz
// Audio96000, ///< 96.0Khz
// Audio176400, ///< 176.4Khz
Audio192000, ///< 192.0Khz
AudioRatesMax ///< max index
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};
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/// table which rates are supported
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static int AudioRatesInHw[AudioRatesMax];
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/// input to hardware channel matrix
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static int AudioChannelMatrix[AudioRatesMax][9];
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/// rates tables (must be sorted by frequency)
static const unsigned AudioRatesTable[AudioRatesMax] = {44100, 48000, 192000};
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//----------------------------------------------------------------------------
// filter
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//----------------------------------------------------------------------------
static const int AudioNormSamples = 4096; ///< number of samples
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#define AudioNormMaxIndex 128 ///< number of average values
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/// average of n last sample blocks
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static uint32_t AudioNormAverage[AudioNormMaxIndex];
static int AudioNormIndex; ///< index into average table
static int AudioNormReady; ///< index counter
static int AudioNormCounter; ///< sample counter
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/**
** Audio normalizer.
**
** @param samples sample buffer
** @param count number of bytes in sample buffer
*/
static void AudioNormalizer(int16_t *samples, int count) {
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int i;
int l;
int n;
uint32_t avg;
int factor;
int16_t *data;
// average samples
l = count / AudioBytesProSample;
data = samples;
do {
n = l;
if (AudioNormCounter + n > AudioNormSamples) {
n = AudioNormSamples - AudioNormCounter;
}
avg = AudioNormAverage[AudioNormIndex];
for (i = 0; i < n; ++i) {
int t;
t = data[i];
avg += (t * t) / AudioNormSamples;
}
AudioNormAverage[AudioNormIndex] = avg;
AudioNormCounter += n;
if (AudioNormCounter >= AudioNormSamples) {
if (AudioNormReady < AudioNormMaxIndex) {
AudioNormReady++;
} else {
avg = 0;
for (i = 0; i < AudioNormMaxIndex; ++i) {
avg += AudioNormAverage[i] / AudioNormMaxIndex;
}
// calculate normalize factor
if (avg > 0) {
factor = ((INT16_MAX / 8) * 1000U) / (uint32_t)sqrt(avg);
// smooth normalize
AudioNormalizeFactor = (AudioNormalizeFactor * 500 + factor * 500) / 1000;
if (AudioNormalizeFactor < AudioMinNormalize) {
AudioNormalizeFactor = AudioMinNormalize;
}
if (AudioNormalizeFactor > AudioMaxNormalize) {
AudioNormalizeFactor = AudioMaxNormalize;
}
} else {
factor = 1000;
}
Debug(4, "audio/noramlize: avg %8d, fac=%6.3f, norm=%6.3f\n", avg, factor / 1000.0,
AudioNormalizeFactor / 1000.0);
}
AudioNormIndex = (AudioNormIndex + 1) % AudioNormMaxIndex;
AudioNormCounter = 0;
AudioNormAverage[AudioNormIndex] = 0U;
}
data += n;
l -= n;
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} while (l > 0);
// apply normalize factor
for (i = 0; i < count / AudioBytesProSample; ++i) {
int t;
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t = (samples[i] * AudioNormalizeFactor) / 1000;
if (t < INT16_MIN) {
t = INT16_MIN;
} else if (t > INT16_MAX) {
t = INT16_MAX;
}
samples[i] = t;
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}
}
/**
** Reset normalizer.
*/
static void AudioResetNormalizer(void) {
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int i;
AudioNormCounter = 0;
AudioNormReady = 0;
for (i = 0; i < AudioNormMaxIndex; ++i) {
AudioNormAverage[i] = 0U;
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}
AudioNormalizeFactor = 1000;
}
/**
** Audio compression.
**
** @param samples sample buffer
** @param count number of bytes in sample buffer
*/
static void AudioCompressor(int16_t *samples, int count) {
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int max_sample;
int i;
int factor;
// find loudest sample
max_sample = 0;
for (i = 0; i < count / AudioBytesProSample; ++i) {
int t;
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t = abs(samples[i]);
if (t > max_sample) {
max_sample = t;
}
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}
// calculate compression factor
if (max_sample > 0) {
factor = (INT16_MAX * 1000) / max_sample;
// smooth compression (FIXME: make configurable?)
AudioCompressionFactor = (AudioCompressionFactor * 950 + factor * 50) / 1000;
if (AudioCompressionFactor > factor) {
AudioCompressionFactor = factor; // no clipping
}
if (AudioCompressionFactor > AudioMaxCompression) {
AudioCompressionFactor = AudioMaxCompression;
}
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} else {
return; // silent nothing todo
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}
Debug(4, "audio/compress: max %5d, fac=%6.3f, com=%6.3f\n", max_sample, factor / 1000.0,
AudioCompressionFactor / 1000.0);
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// apply compression factor
for (i = 0; i < count / AudioBytesProSample; ++i) {
int t;
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t = (samples[i] * AudioCompressionFactor) / 1000;
if (t < INT16_MIN) {
t = INT16_MIN;
} else if (t > INT16_MAX) {
t = INT16_MAX;
}
samples[i] = t;
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}
}
/**
** Reset compressor.
*/
static void AudioResetCompressor(void) {
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AudioCompressionFactor = 2000;
if (AudioCompressionFactor > AudioMaxCompression) {
AudioCompressionFactor = AudioMaxCompression;
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}
}
/**
** Audio software amplifier.
**
** @param samples sample buffer
** @param count number of bytes in sample buffer
**
** @todo FIXME: this does hard clipping
*/
static void AudioSoftAmplifier(int16_t *samples, int count) {
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int i;
// silence
if (AudioMute || !AudioAmplifier) {
memset(samples, 0, count);
return;
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}
for (i = 0; i < count / AudioBytesProSample; ++i) {
int t;
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t = (samples[i] * AudioAmplifier) / 1000;
if (t < INT16_MIN) {
t = INT16_MIN;
} else if (t > INT16_MAX) {
t = INT16_MAX;
}
samples[i] = t;
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}
}
#ifdef USE_AUDIO_MIXER
/**
** Upmix mono to stereo.
**
** @param in input sample buffer
** @param frames number of frames in sample buffer
** @param out output sample buffer
*/
static void AudioMono2Stereo(const int16_t *in, int frames, int16_t *out) {
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int i;
for (i = 0; i < frames; ++i) {
int t;
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t = in[i];
out[i * 2 + 0] = t;
out[i * 2 + 1] = t;
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}
}
/**
** Downmix stereo to mono.
**
** @param in input sample buffer
** @param frames number of frames in sample buffer
** @param out output sample buffer
*/
static void AudioStereo2Mono(const int16_t *in, int frames, int16_t *out) {
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int i;
for (i = 0; i < frames; i += 2) {
out[i / 2] = (in[i + 0] + in[i + 1]) / 2;
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}
}
/**
** Downmix surround to stereo.
**
** ffmpeg L R C Ls Rs -> alsa L R Ls Rs C
** ffmpeg L R C LFE Ls Rs -> alsa L R Ls Rs C LFE
** ffmpeg L R C LFE Ls Rs Rl Rr -> alsa L R Ls Rs C LFE Rl Rr
**
** @param in input sample buffer
** @param in_chan nr. of input channels
** @param frames number of frames in sample buffer
** @param out output sample buffer
*/
static void AudioSurround2Stereo(const int16_t *in, int in_chan, int frames, int16_t *out) {
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while (frames--) {
int l;
int r;
switch (in_chan) {
case 3: // stereo or surround? =>stereo
l = in[0] * 600; // L
r = in[1] * 600; // R
l += in[2] * 400; // C
r += in[2] * 400;
break;
case 4: // quad or surround? =>quad
l = in[0] * 600; // L
r = in[1] * 600; // R
l += in[2] * 400; // Ls
r += in[3] * 400; // Rs
break;
case 5: // 5.0
l = in[0] * 500; // L
r = in[1] * 500; // R
l += in[2] * 200; // Ls
r += in[3] * 200; // Rs
l += in[4] * 300; // C
r += in[4] * 300;
break;
case 6: // 5.1
l = in[0] * 400; // L
r = in[1] * 400; // R
l += in[2] * 200; // Ls
r += in[3] * 200; // Rs
l += in[4] * 300; // C
r += in[4] * 300;
l += in[5] * 100; // LFE
r += in[5] * 100;
break;
case 7: // 7.0
l = in[0] * 400; // L
r = in[1] * 400; // R
l += in[2] * 200; // Ls
r += in[3] * 200; // Rs
l += in[4] * 300; // C
r += in[4] * 300;
l += in[5] * 100; // RL
r += in[6] * 100; // RR
break;
case 8: // 7.1
l = in[0] * 400; // L
r = in[1] * 400; // R
l += in[2] * 150; // Ls
r += in[3] * 150; // Rs
l += in[4] * 250; // C
r += in[4] * 250;
l += in[5] * 100; // LFE
r += in[5] * 100;
l += in[6] * 100; // RL
r += in[7] * 100; // RR
break;
default:
abort();
}
in += in_chan;
out[0] = l / 1000;
out[1] = r / 1000;
out += 2;
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}
}
/**
** Upmix @a in_chan channels to @a out_chan.
**
** @param in input sample buffer
** @param in_chan nr. of input channels
** @param frames number of frames in sample buffer
** @param out output sample buffer
** @param out_chan nr. of output channels
*/
static void AudioUpmix(const int16_t *in, int in_chan, int frames, int16_t *out, int out_chan) {
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while (frames--) {
int i;
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for (i = 0; i < in_chan; ++i) { // copy existing channels
*out++ = *in++;
}
for (; i < out_chan; ++i) { // silents missing channels
*out++ = 0;
}
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}
}
/**
** Resample ffmpeg sample format to hardware format.
**
** FIXME: use libswresample for this and move it to codec.
** FIXME: ffmpeg to alsa conversion is already done in codec.c.
**
** ffmpeg L R C Ls Rs -> alsa L R Ls Rs C
** ffmpeg L R C LFE Ls Rs -> alsa L R Ls Rs C LFE
** ffmpeg L R C LFE Ls Rs Rl Rr -> alsa L R Ls Rs C LFE Rl Rr
**
** @param in input sample buffer
** @param in_chan nr. of input channels
** @param frames number of frames in sample buffer
** @param out output sample buffer
** @param out_chan nr. of output channels
*/
static void AudioResample(const int16_t *in, int in_chan, int frames, int16_t *out, int out_chan) {
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switch (in_chan * 8 + out_chan) {
case 1 * 8 + 1:
case 2 * 8 + 2:
case 3 * 8 + 3:
case 4 * 8 + 4:
case 5 * 8 + 5:
case 6 * 8 + 6:
case 7 * 8 + 7:
case 8 * 8 + 8: // input = output channels
memcpy(out, in, frames * in_chan * AudioBytesProSample);
break;
case 2 * 8 + 1:
AudioStereo2Mono(in, frames, out);
break;
case 1 * 8 + 2:
AudioMono2Stereo(in, frames, out);
break;
case 3 * 8 + 2:
case 4 * 8 + 2:
case 5 * 8 + 2:
case 6 * 8 + 2:
case 7 * 8 + 2:
case 8 * 8 + 2:
AudioSurround2Stereo(in, in_chan, frames, out);
break;
case 5 * 8 + 6:
case 3 * 8 + 8:
case 5 * 8 + 8:
case 6 * 8 + 8:
AudioUpmix(in, in_chan, frames, out, out_chan);
break;
default:
Error("audio: unsupported %d -> %d channels resample\n", in_chan, out_chan);
// play silence
memset(out, 0, frames * out_chan * AudioBytesProSample);
break;
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}
}
#endif
//----------------------------------------------------------------------------
// ring buffer
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//----------------------------------------------------------------------------
#define AUDIO_RING_MAX 8 ///< number of audio ring buffers
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/**
** Audio ring buffer.
*/
typedef struct _audio_ring_ring_ {
char FlushBuffers; ///< flag: flush buffers
char Passthrough; ///< flag: use pass-through (AC-3, ...)
int16_t PacketSize; ///< packet size
unsigned HwSampleRate; ///< hardware sample rate in Hz
unsigned HwChannels; ///< hardware number of channels
unsigned InSampleRate; ///< input sample rate in Hz
unsigned InChannels; ///< input number of channels
int64_t PTS; ///< pts clock
RingBuffer *RingBuffer; ///< sample ring buffer
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} AudioRingRing;
/// ring of audio ring buffers
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static AudioRingRing AudioRing[AUDIO_RING_MAX];
static int AudioRingWrite; ///< audio ring write pointer
static int AudioRingRead; ///< audio ring read pointer
static atomic_t AudioRingFilled; ///< how many of the ring is used
static unsigned AudioStartThreshold; ///< start play, if filled
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/**
** Add sample-rate, number of channels change to ring.
**
** @param sample_rate sample-rate frequency
** @param channels number of channels
** @param passthrough use /pass-through (AC-3, ...) device
**
** @retval -1 error
** @retval 0 okay
**
** @note this function shouldn't fail. Checks are done during AudoInit.
*/
static int AudioRingAdd(unsigned sample_rate, int channels, int passthrough) {
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unsigned u;
// search supported sample-rates
for (u = 0; u < AudioRatesMax; ++u) {
if (AudioRatesTable[u] == sample_rate) {
goto found;
}
if (AudioRatesTable[u] > sample_rate) {
break;
}
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}
Error(_("audio: %dHz sample-rate unsupported\n"), sample_rate);
return -1; // unsupported sample-rate
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found:
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if (!AudioChannelMatrix[u][channels]) {
Error(_("audio: %d channels unsupported\n"), channels);
return -1; // unsupported nr. of channels
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}
if (atomic_read(&AudioRingFilled) == AUDIO_RING_MAX) { // no free slot
// FIXME: can wait for ring buffer empty
Error(_("audio: out of ring buffers\n"));
return -1;
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}
AudioRingWrite = (AudioRingWrite + 1) % AUDIO_RING_MAX;
AudioRing[AudioRingWrite].FlushBuffers = 0;
AudioRing[AudioRingWrite].Passthrough = passthrough;
AudioRing[AudioRingWrite].PacketSize = 0;
AudioRing[AudioRingWrite].InSampleRate = sample_rate;
AudioRing[AudioRingWrite].InChannels = channels;
AudioRing[AudioRingWrite].HwSampleRate = sample_rate;
AudioRing[AudioRingWrite].HwChannels = AudioChannelMatrix[u][channels];
AudioRing[AudioRingWrite].PTS = AV_NOPTS_VALUE;
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RingBufferReset(AudioRing[AudioRingWrite].RingBuffer);
Debug(3, "audio: %d ring buffer prepared\n", atomic_read(&AudioRingFilled) + 1);
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atomic_inc(&AudioRingFilled);
#ifdef USE_AUDIO_THREAD
if (AudioThread) {
// tell thread, that there is something todo
AudioRunning = 1;
pthread_cond_signal(&AudioStartCond);
Debug(3, "Start on AudioRingAdd\n");
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}
#endif
return 0;
}
/**
** Setup audio ring.
*/
static void AudioRingInit(void) {
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int i;
for (i = 0; i < AUDIO_RING_MAX; ++i) {
// ~2s 8ch 16bit
AudioRing[i].RingBuffer = RingBufferNew(AudioRingBufferSize);
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}
atomic_set(&AudioRingFilled, 0);
}
/**
** Cleanup audio ring.
*/
static void AudioRingExit(void) {
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int i;
for (i = 0; i < AUDIO_RING_MAX; ++i) {
if (AudioRing[i].RingBuffer) {
RingBufferDel(AudioRing[i].RingBuffer);
AudioRing[i].RingBuffer = NULL;
}
AudioRing[i].HwSampleRate = 0; // checked for valid setup
AudioRing[i].InSampleRate = 0;
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}
AudioRingRead = 0;
AudioRingWrite = 0;
}
//============================================================================
// A L S A
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//============================================================================
//----------------------------------------------------------------------------
// Alsa variables
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//----------------------------------------------------------------------------
static snd_pcm_t *AlsaPCMHandle; ///< alsa pcm handle
static char AlsaCanPause; ///< hw supports pause
static int AlsaUseMmap; ///< use mmap
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static snd_mixer_t *AlsaMixer; ///< alsa mixer handle
static snd_mixer_elem_t *AlsaMixerElem; ///< alsa pcm mixer element
static int AlsaRatio; ///< internal -> mixer ratio * 1000
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//----------------------------------------------------------------------------
// alsa pcm
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//----------------------------------------------------------------------------
/**
** Play samples from ringbuffer.
**
** Fill the kernel buffer, as much as possible.
**
** @retval 0 ok
** @retval 1 ring buffer empty
** @retval -1 underrun error
*/
static int AlsaPlayRingbuffer(void) {
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int first;
first = 1;
for (;;) { // loop for ring buffer wrap
int avail;
int n;
int err;
int frames;
const void *p;
// how many bytes can be written?
n = snd_pcm_avail_update(AlsaPCMHandle);
if (n < 0) {
if (n == -EAGAIN) {
continue;
}
Warning(_("audio/alsa: avail underrun error? '%s'\n"), snd_strerror(n));
err = snd_pcm_recover(AlsaPCMHandle, n, 0);
if (err >= 0) {
continue;
}
Error(_("audio/alsa: snd_pcm_avail_update(): %s\n"), snd_strerror(n));
return -1;
}
avail = snd_pcm_frames_to_bytes(AlsaPCMHandle, n);
if (avail < 256) { // too much overhead
if (first) {
// happens with broken alsa drivers
if (AudioThread) {
if (!AudioAlsaDriverBroken) {
Error(_("audio/alsa: broken driver %d state '%s'\n"), avail,
snd_pcm_state_name(snd_pcm_state(AlsaPCMHandle)));
}
// try to recover
if (snd_pcm_state(AlsaPCMHandle) == SND_PCM_STATE_PREPARED) {
if ((err = snd_pcm_start(AlsaPCMHandle)) < 0) {
Error(_("audio/alsa: snd_pcm_start(): %s\n"), snd_strerror(err));
}
}
usleep(5 * 1000);
}
}
Debug(4, "audio/alsa: break state '%s'\n", snd_pcm_state_name(snd_pcm_state(AlsaPCMHandle)));
break;
}
n = RingBufferGetReadPointer(AudioRing[AudioRingRead].RingBuffer, &p);
if (!n) { // ring buffer empty
if (first) { // only error on first loop
Debug(4, "audio/alsa: empty buffers %d\n", avail);
// ring buffer empty
// AlsaLowWaterMark = 1;
return 1;
}
return 0;
}
if (n < avail) { // not enough bytes in ring buffer
avail = n;
}
if (!avail) { // full or buffer empty
break;
}
// muting pass-through AC-3, can produce disturbance
if (AudioMute || (AudioSoftVolume && !AudioRing[AudioRingRead].Passthrough)) {
// FIXME: quick&dirty cast
AudioSoftAmplifier((int16_t *)p, avail);
// FIXME: if not all are written, we double amplify them
}
frames = snd_pcm_bytes_to_frames(AlsaPCMHandle, avail);
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#ifdef DEBUG
if (avail != snd_pcm_frames_to_bytes(AlsaPCMHandle, frames)) {
Error(_("audio/alsa: bytes lost -> out of sync\n"));
}
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#endif
for (;;) {
if (AlsaUseMmap) {
err = snd_pcm_mmap_writei(AlsaPCMHandle, p, frames);
} else {
err = snd_pcm_writei(AlsaPCMHandle, p, frames);
}
// Debug(3, "audio/alsa: wrote %d/%d frames\n", err, frames);
if (err != frames) {
if (err < 0) {
if (err == -EAGAIN) {
continue;
}
/*
if (err == -EBADFD) {
goto again;
}
*/
Warning(_("audio/alsa: writei underrun error? '%s'\n"), snd_strerror(err));
err = snd_pcm_recover(AlsaPCMHandle, err, 0);
if (err >= 0) {
continue;
}
Error(_("audio/alsa: snd_pcm_writei failed: %s\n"), snd_strerror(err));
return -1;
}
// this could happen, if underrun happened
Warning(_("audio/alsa: not all frames written\n"));
avail = snd_pcm_frames_to_bytes(AlsaPCMHandle, err);
}
break;
}
RingBufferReadAdvance(AudioRing[AudioRingRead].RingBuffer, avail);
first = 0;
}
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return 0;
}
/**
** Flush alsa buffers.
*/
static void AlsaFlushBuffers(void) {
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if (AlsaPCMHandle) {
int err;
snd_pcm_state_t state;
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state = snd_pcm_state(AlsaPCMHandle);
Debug(3, "audio/alsa: flush state %s\n", snd_pcm_state_name(state));
if (state != SND_PCM_STATE_OPEN) {
if ((err = snd_pcm_drop(AlsaPCMHandle)) < 0) {
Error(_("audio: snd_pcm_drop(): %s\n"), snd_strerror(err));
}
// ****ing alsa crash, when in open state here
if ((err = snd_pcm_prepare(AlsaPCMHandle)) < 0) {
Error(_("audio: snd_pcm_prepare(): %s\n"), snd_strerror(err));
}
}
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}
}
#ifdef USE_AUDIO_THREAD
//----------------------------------------------------------------------------
// thread playback
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//----------------------------------------------------------------------------
/**
** Alsa thread
**
** Play some samples and return.
**
** @retval -1 error
** @retval 0 underrun
** @retval 1 running
*/
static int AlsaThread(void) {
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int err;
if (!AlsaPCMHandle) {
usleep(24 * 1000);
return -1;
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}
for (;;) {
if (AudioPaused) {
return 1;
}
// wait for space in kernel buffers
if ((err = snd_pcm_wait(AlsaPCMHandle, 24)) < 0) {
Warning(_("audio/alsa: wait underrun error? '%s'\n"), snd_strerror(err));
err = snd_pcm_recover(AlsaPCMHandle, err, 0);
if (err >= 0) {
continue;
}
Error(_("audio/alsa: snd_pcm_wait(): %s\n"), snd_strerror(err));
usleep(24 * 1000);
return -1;
}
break;
}
if (!err || AudioPaused) { // timeout or some commands
return 1;
}
if ((err = AlsaPlayRingbuffer())) { // empty or error
snd_pcm_state_t state;
if (err < 0) { // underrun error
return -1;
}
state = snd_pcm_state(AlsaPCMHandle);
if (state != SND_PCM_STATE_RUNNING) {
Debug(3, "audio/alsa: stopping play '%s'\n", snd_pcm_state_name(state));
return 0;
}
usleep(24 * 1000); // let fill/empty the buffers
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}
return 1;
}
#endif
//----------------------------------------------------------------------------
/**
** Open alsa pcm device.
**
** @param passthrough use pass-through (AC-3, ...) device
*/
static snd_pcm_t *AlsaOpenPCM(int passthrough) {
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const char *device;
snd_pcm_t *handle;
int err;
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char tmp[80];
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// &&|| hell
if (!(passthrough && ((device = AudioPassthroughDevice) || (device = getenv("ALSA_PASSTHROUGH_DEVICE")))) &&
!(device = AudioPCMDevice) && !(device = getenv("ALSA_DEVICE"))) {
device = "default";
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}
if (!AudioDoingInit) { // reduce blabla during init
Info(_("audio/alsa: using %sdevice '%s'\n"), passthrough ? "pass-through " : "", device);
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}
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//printf("audio/alsa: using %sdevice '%s'\n", passthrough ? "pass-through " : "", device);
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//
// for AC3 pass-through try to set the non-audio bit, use AES0=6
//
if (passthrough && AudioAppendAES) {
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if (!(strchr(device, ':'))) {
sprintf(tmp,
//"AES0=%d,AES1=%d,AES2=0,AES3=%d",
"%s:AES0=%d,AES1=%d,AES2=0",
device,
IEC958_AES0_NONAUDIO | IEC958_AES0_PRO_EMPHASIS_NONE,
IEC958_AES1_CON_ORIGINAL | IEC958_AES1_CON_PCM_CODER);
//map_iec958_srate(ao->samplerate));
}
else {
sprintf(tmp,
//"AES0=%d,AES1=%d,AES2=0,AES3=%d",
"%s,AES0=%d,AES1=%d,AES2=0",
device,
IEC958_AES0_NONAUDIO | IEC958_AES0_PRO_EMPHASIS_NONE,
IEC958_AES1_CON_ORIGINAL | IEC958_AES1_CON_PCM_CODER);
//map_iec958_srate(ao->samplerate));
}
printf( "opening device '%s' => '%s'\n", device, tmp);
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if ((err = snd_pcm_open(&handle, tmp, SND_PCM_STREAM_PLAYBACK, SND_PCM_NONBLOCK)) < 0 ) {
Error(_("audio/alsa: playback open '%s' error: %s\n"), device, snd_strerror(err));
return NULL;
}
} else {
// open none blocking; if device is already used, we don't want wait
if ((err = snd_pcm_open(&handle, device, SND_PCM_STREAM_PLAYBACK, SND_PCM_NONBLOCK)) < 0) {
Error(_("audio/alsa: playback open '%s' error: %s\n"), device, snd_strerror(err));
return NULL;
}
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}
if ((err = snd_pcm_nonblock(handle, 0)) < 0) {
Error(_("audio/alsa: can't set block mode: %s\n"), snd_strerror(err));
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}
return handle;
}
/**
** Initialize alsa pcm device.
**
** @see AudioPCMDevice
*/
static void AlsaInitPCM(void) {
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snd_pcm_t *handle;
snd_pcm_hw_params_t *hw_params;
int err;
if (!(handle = AlsaOpenPCM(0))) {
return;
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}
// FIXME: pass-through and pcm out can support different features
snd_pcm_hw_params_alloca(&hw_params);
// choose all parameters
if ((err = snd_pcm_hw_params_any(handle, hw_params)) < 0) {
Error(_("audio: snd_pcm_hw_params_any: no configurations available: %s\n"), snd_strerror(err));
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}
AlsaCanPause = snd_pcm_hw_params_can_pause(hw_params);
Info(_("audio/alsa: supports pause: %s\n"), AlsaCanPause ? "yes" : "no");
AlsaPCMHandle = handle;
}
//----------------------------------------------------------------------------
// Alsa Mixer
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//----------------------------------------------------------------------------
/**
** Set alsa mixer volume (0-1000)
**
** @param volume volume (0 .. 1000)
*/
static void AlsaSetVolume(int volume) {
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int v;
if (AlsaMixer && AlsaMixerElem) {
v = (volume * AlsaRatio) / (1000 * 1000);
snd_mixer_selem_set_playback_volume(AlsaMixerElem, 0, v);
snd_mixer_selem_set_playback_volume(AlsaMixerElem, 1, v);
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}
}
/**
** Initialize alsa mixer.
*/
static void AlsaInitMixer(void) {
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const char *device;
const char *channel;
snd_mixer_t *alsa_mixer;
snd_mixer_elem_t *alsa_mixer_elem;
long alsa_mixer_elem_min;
long alsa_mixer_elem_max;
if (!(device = AudioMixerDevice)) {
if (!(device = getenv("ALSA_MIXER"))) {
device = "default";
}
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}
if (!(channel = AudioMixerChannel)) {
if (!(channel = getenv("ALSA_MIXER_CHANNEL"))) {
channel = "PCM";
}
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}
Debug(3, "audio/alsa: mixer %s - %s open\n", device, channel);
snd_mixer_open(&alsa_mixer, 0);
if (alsa_mixer && snd_mixer_attach(alsa_mixer, device) >= 0 &&
snd_mixer_selem_register(alsa_mixer, NULL, NULL) >= 0 && snd_mixer_load(alsa_mixer) >= 0) {
const char *const alsa_mixer_elem_name = channel;
alsa_mixer_elem = snd_mixer_first_elem(alsa_mixer);
while (alsa_mixer_elem) {
const char *name;
name = snd_mixer_selem_get_name(alsa_mixer_elem);
if (!strcasecmp(name, alsa_mixer_elem_name)) {
snd_mixer_selem_get_playback_volume_range(alsa_mixer_elem, &alsa_mixer_elem_min, &alsa_mixer_elem_max);
AlsaRatio = 1000 * (alsa_mixer_elem_max - alsa_mixer_elem_min);
Debug(3, "audio/alsa: PCM mixer found %ld - %ld ratio %d\n", alsa_mixer_elem_min, alsa_mixer_elem_max,
AlsaRatio);
break;
}
alsa_mixer_elem = snd_mixer_elem_next(alsa_mixer_elem);
}
AlsaMixer = alsa_mixer;
AlsaMixerElem = alsa_mixer_elem;
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} else {
Error(_("audio/alsa: can't open mixer '%s'\n"), device);
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}
}
//----------------------------------------------------------------------------
// Alsa API
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//----------------------------------------------------------------------------
/**
** Get alsa audio delay in time-stamps.
**
** @returns audio delay in time-stamps.
**
** @todo FIXME: handle the case no audio running
*/
static int64_t AlsaGetDelay(void) {
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int err;
snd_pcm_sframes_t delay;
int64_t pts;
// setup error
if (!AlsaPCMHandle || !AudioRing[AudioRingRead].HwSampleRate) {
return 0L;
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}
// delay in frames in alsa + kernel buffers
if ((err = snd_pcm_delay(AlsaPCMHandle, &delay)) < 0) {
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// Debug(3, "audio/alsa: no hw delay\n");
delay = 0L;
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#ifdef DEBUG
} else if (snd_pcm_state(AlsaPCMHandle) != SND_PCM_STATE_RUNNING) {
// Debug(3, "audio/alsa: %ld frames delay ok, but not running\n", delay);
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#endif
}
Debug(4, "audio/alsa: %ld frames hw delay\n", delay);
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// delay can be negative, when underrun occur
if (delay < 0) {
delay = 0L;
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}
pts = ((int64_t)delay * 90 * 1000) / AudioRing[AudioRingRead].HwSampleRate;
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return pts;
}
/**
** Setup alsa audio for requested format.
**
** @param freq sample frequency
** @param channels number of channels
** @param passthrough use pass-through (AC-3, ...) device
**
** @retval 0 everything ok
** @retval 1 didn't support frequency/channels combination
** @retval -1 something gone wrong
**
** @todo FIXME: remove pointer for freq + channels
*/
static int AlsaSetup(int *freq, int *channels, int passthrough) {
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snd_pcm_uframes_t buffer_size;
snd_pcm_uframes_t period_size;
int err;
int delay;
if (!AlsaPCMHandle) { // alsa not running yet
// FIXME: if open fails for fe. pass-through, we never recover
return -1;
}
if (!AudioAlsaNoCloseOpen) { // close+open to fix HDMI no sound bug
snd_pcm_t *handle;
handle = AlsaPCMHandle;
// no lock needed, thread exit in main loop only
// Debug(3, "audio: %s [\n", __FUNCTION__);
AlsaPCMHandle = NULL; // other threads should check handle
snd_pcm_close(handle);
if (AudioAlsaCloseOpenDelay) {
usleep(50 * 1000); // 50ms delay for alsa recovery
}
// FIXME: can use multiple retries
if (!(handle = AlsaOpenPCM(passthrough))) {
return -1;
}
AlsaPCMHandle = handle;
// Debug(3, "audio: %s ]\n", __FUNCTION__);
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}
for (;;) {
if ((err = snd_pcm_set_params(AlsaPCMHandle, SND_PCM_FORMAT_S16,
AlsaUseMmap ? SND_PCM_ACCESS_MMAP_INTERLEAVED : SND_PCM_ACCESS_RW_INTERLEAVED,
*channels, *freq, 1, 96 * 1000))) {
// try reduced buffer size (needed for sunxi)
// FIXME: alternativ make this configurable
if ((err =
snd_pcm_set_params(AlsaPCMHandle, SND_PCM_FORMAT_S16,
AlsaUseMmap ? SND_PCM_ACCESS_MMAP_INTERLEAVED : SND_PCM_ACCESS_RW_INTERLEAVED,
*channels, *freq, 1, 72 * 1000))) {
/*
if ( err == -EBADFD ) {
snd_pcm_close(AlsaPCMHandle);
AlsaPCMHandle = NULL;
continue;
}
*/
if (!AudioDoingInit) {
Error(_("audio/alsa: set params error: %s\n"), snd_strerror(err));
}
// FIXME: must stop sound, AudioChannels ... invalid
return -1;
}
}
break;
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}
// this is disabled, no advantages!
if (0) { // no underruns allowed, play silence
snd_pcm_sw_params_t *sw_params;
snd_pcm_uframes_t boundary;
snd_pcm_sw_params_alloca(&sw_params);
err = snd_pcm_sw_params_current(AlsaPCMHandle, sw_params);
if (err < 0) {
Error(_("audio: snd_pcm_sw_params_current failed: %s\n"), snd_strerror(err));
}
if ((err = snd_pcm_sw_params_get_boundary(sw_params, &boundary)) < 0) {
Error(_("audio: snd_pcm_sw_params_get_boundary failed: %s\n"), snd_strerror(err));
}
Debug(4, "audio/alsa: boundary %lu frames\n", boundary);
if ((err = snd_pcm_sw_params_set_stop_threshold(AlsaPCMHandle, sw_params, boundary)) < 0) {
Error(_("audio: snd_pcm_sw_params_set_silence_size failed: %s\n"), snd_strerror(err));
}
if ((err = snd_pcm_sw_params_set_silence_size(AlsaPCMHandle, sw_params, boundary)) < 0) {
Error(_("audio: snd_pcm_sw_params_set_silence_size failed: %s\n"), snd_strerror(err));
}
if ((err = snd_pcm_sw_params(AlsaPCMHandle, sw_params)) < 0) {
Error(_("audio: snd_pcm_sw_params failed: %s\n"), snd_strerror(err));
}
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}
// update buffer
snd_pcm_get_params(AlsaPCMHandle, &buffer_size, &period_size);
Debug(3, "audio/alsa: buffer size %lu %zdms, period size %lu %zdms\n", buffer_size,
snd_pcm_frames_to_bytes(AlsaPCMHandle, buffer_size) * 1000 / (*freq * *channels * AudioBytesProSample),
period_size,
snd_pcm_frames_to_bytes(AlsaPCMHandle, period_size) * 1000 / (*freq * *channels * AudioBytesProSample));
Debug(3, "audio/alsa: state %s\n", snd_pcm_state_name(snd_pcm_state(AlsaPCMHandle)));
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AudioStartThreshold = snd_pcm_frames_to_bytes(AlsaPCMHandle, period_size);
// buffer time/delay in ms
delay = AudioBufferTime;
if (VideoAudioDelay > 0) {
delay += VideoAudioDelay / 90;
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}
if (AudioStartThreshold < (*freq * *channels * AudioBytesProSample * delay) / 1000U) {
AudioStartThreshold = (*freq * *channels * AudioBytesProSample * delay) / 1000U;
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}
// no bigger, than 1/3 the buffer
if (AudioStartThreshold > AudioRingBufferSize / 3) {
AudioStartThreshold = AudioRingBufferSize / 3;
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}
if (!AudioDoingInit) {
Info(_("audio/alsa: start delay %ums\n"),
(AudioStartThreshold * 1000) / (*freq * *channels * AudioBytesProSample));
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}
return 0;
}
/**
** Play audio.
*/
static void AlsaPlay(void) {
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int err;
if (AlsaCanPause) {
if ((err = snd_pcm_pause(AlsaPCMHandle, 0))) {
Error(_("audio/alsa: snd_pcm_pause(): %s\n"), snd_strerror(err));
}
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} else {
if ((err = snd_pcm_prepare(AlsaPCMHandle)) < 0) {
Error(_("audio/alsa: snd_pcm_prepare(): %s\n"), snd_strerror(err));
}
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}
#ifdef DEBUG
if (snd_pcm_state(AlsaPCMHandle) == SND_PCM_STATE_PAUSED) {
Error(_("audio/alsa: still paused\n"));
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}
#endif
}
/**
** Pause audio.
*/
static void AlsaPause(void) {
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int err;
if (AlsaCanPause) {
if ((err = snd_pcm_pause(AlsaPCMHandle, 1))) {
Error(_("snd_pcm_pause(): %s\n"), snd_strerror(err));
}
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} else {
if ((err = snd_pcm_drop(AlsaPCMHandle)) < 0) {
Error(_("snd_pcm_drop(): %s\n"), snd_strerror(err));
}
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}
}
/**
** Empty log callback
*/
static void AlsaNoopCallback(__attribute__((unused)) const char *file, __attribute__((unused)) int line,
__attribute__((unused)) const char *function, __attribute__((unused)) int err,
__attribute__((unused)) const char *fmt, ...) {}
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/**
** Initialize alsa audio output module.
*/
static void AlsaInit(void) {
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#ifdef DEBUG
(void)AlsaNoopCallback;
#else
// disable display of alsa error messages
snd_lib_error_set_handler(AlsaNoopCallback);
#endif
AlsaInitPCM();
AlsaInitMixer();
}
/**
** Cleanup alsa audio output module.
*/
static void AlsaExit(void) {
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if (AlsaPCMHandle) {
snd_pcm_close(AlsaPCMHandle);
AlsaPCMHandle = NULL;
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}
if (AlsaMixer) {
snd_mixer_close(AlsaMixer);
AlsaMixer = NULL;
AlsaMixerElem = NULL;
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}
}
/**
** Alsa module.
*/
static const AudioModule AlsaModule = {
.Name = "alsa",
#ifdef USE_AUDIO_THREAD
.Thread = AlsaThread,
#endif
.FlushBuffers = AlsaFlushBuffers,
.GetDelay = AlsaGetDelay,
.SetVolume = AlsaSetVolume,
.Setup = AlsaSetup,
.Play = AlsaPlay,
.Pause = AlsaPause,
.Init = AlsaInit,
.Exit = AlsaExit,
};
//============================================================================
// Noop
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//============================================================================
/**
** Get audio delay in time stamps.
**
** @returns audio delay in time stamps.
*/
static int64_t NoopGetDelay(void) { return 0L; }
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/**
** Set mixer volume (0-1000)
**
** @param volume volume (0 .. 1000)
*/
static void NoopSetVolume(__attribute__((unused)) int volume) {}
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/**
** Noop setup.
**
** @param freq sample frequency
** @param channels number of channels
** @param passthrough use pass-through (AC-3, ...) device
*/
static int NoopSetup(__attribute__((unused)) int *channels, __attribute__((unused)) int *freq,
__attribute__((unused)) int passthrough) {
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return -1;
}
/**
** Noop void
*/
static void NoopVoid(void) {}
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/**
** Noop module.
*/
static const AudioModule NoopModule = {
.Name = "noop",
.FlushBuffers = NoopVoid,
.GetDelay = NoopGetDelay,
.SetVolume = NoopSetVolume,
.Setup = NoopSetup,
.Play = NoopVoid,
.Pause = NoopVoid,
.Init = NoopVoid,
.Exit = NoopVoid,
};
//----------------------------------------------------------------------------
// thread playback
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//----------------------------------------------------------------------------
#ifdef USE_AUDIO_THREAD
/**
** Prepare next ring buffer.
*/
static int AudioNextRing(void) {
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int passthrough;
int sample_rate;
int channels;
size_t used;
// update audio format
// not always needed, but check if needed is too complex
passthrough = AudioRing[AudioRingRead].Passthrough;
sample_rate = AudioRing[AudioRingRead].HwSampleRate;
channels = AudioRing[AudioRingRead].HwChannels;
if (AudioUsedModule->Setup(&sample_rate, &channels, passthrough)) {
Error(_("audio: can't set channels %d sample-rate %dHz\n"), channels, sample_rate);
// FIXME: handle error
AudioRing[AudioRingRead].HwSampleRate = 0;
AudioRing[AudioRingRead].InSampleRate = 0;
return -1;
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}
AudioSetVolume(AudioVolume); // update channel delta
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AudioResetCompressor();
AudioResetNormalizer();
Debug(3, "audio: a/v next buf(%d,%4zdms)\n", atomic_read(&AudioRingFilled),
(RingBufferUsedBytes(AudioRing[AudioRingRead].RingBuffer) * 1000) /
(AudioRing[AudioRingWrite].HwSampleRate * AudioRing[AudioRingWrite].HwChannels * AudioBytesProSample));
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// stop, if not enough in next buffer
used = RingBufferUsedBytes(AudioRing[AudioRingRead].RingBuffer);
if (AudioStartThreshold * 4 < used || (AudioVideoIsReady && AudioStartThreshold < used)) {
return 0;
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}
return 1;
}
/**
** Audio play thread.
**
** @param dummy unused thread argument
*/
static void *AudioPlayHandlerThread(void *dummy) {
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Debug(3, "audio: play thread started\n");
prctl(PR_SET_NAME, "cuvid audio", 0, 0, 0);
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for (;;) {
// check if we should stop the thread
if (AudioThreadStop) {
Debug(3, "audio: play thread stopped\n");
return PTHREAD_CANCELED;
}
Debug(3, "audio: wait on start condition\n");
pthread_mutex_lock(&AudioMutex);
AudioRunning = 0;
do {
pthread_cond_wait(&AudioStartCond, &AudioMutex);
// cond_wait can return, without signal!
} while (!AudioRunning);
pthread_mutex_unlock(&AudioMutex);
Debug(
3, "audio: ----> %dms %d start\n",
(AudioUsedBytes() * 1000) /
(!AudioRing[AudioRingWrite].HwSampleRate + !AudioRing[AudioRingWrite].HwChannels +
AudioRing[AudioRingWrite].HwSampleRate * AudioRing[AudioRingWrite].HwChannels * AudioBytesProSample),
AudioUsedBytes());
do {
int filled;
int read;
int flush;
int err;
int i;
// check if we should stop the thread
if (AudioThreadStop) {
Debug(3, "audio: play thread stopped\n");
return PTHREAD_CANCELED;
}
// look if there is a flush command in the queue
flush = 0;
filled = atomic_read(&AudioRingFilled);
read = AudioRingRead;
i = filled;
while (i--) {
read = (read + 1) % AUDIO_RING_MAX;
if (AudioRing[read].FlushBuffers) {
AudioRing[read].FlushBuffers = 0;
AudioRingRead = read;
// handle all flush in queue
flush = filled - i;
}
}
if (flush) {
Debug(3, "audio: flush %d ring buffer(s)\n", flush);
AudioUsedModule->FlushBuffers();
atomic_sub(flush, &AudioRingFilled);
if (AudioNextRing()) {
break;
}
}
// try to play some samples
err = 0;
if (RingBufferUsedBytes(AudioRing[AudioRingRead].RingBuffer)) {
err = AudioUsedModule->Thread();
}
// underrun, check if new ring buffer is available
if (!err) {
int passthrough;
int sample_rate;
int channels;
int old_passthrough;
int old_sample_rate;
int old_channels;
// underrun, and no new ring buffer, goto sleep.
if (!atomic_read(&AudioRingFilled)) {
Debug(3, "audio: HandlerThread Underrun with no new data\n");
break;
}
Debug(3, "audio: next ring buffer\n");
old_passthrough = AudioRing[AudioRingRead].Passthrough;
old_sample_rate = AudioRing[AudioRingRead].HwSampleRate;
old_channels = AudioRing[AudioRingRead].HwChannels;
atomic_dec(&AudioRingFilled);
AudioRingRead = (AudioRingRead + 1) % AUDIO_RING_MAX;
passthrough = AudioRing[AudioRingRead].Passthrough;
sample_rate = AudioRing[AudioRingRead].HwSampleRate;
channels = AudioRing[AudioRingRead].HwChannels;
Debug(3, "audio: thread channels %d frequency %dHz %s\n", channels, sample_rate,
passthrough ? "pass-through" : "");
// audio config changed?
if (old_passthrough != passthrough || old_sample_rate != sample_rate || old_channels != channels) {
// FIXME: wait for buffer drain
if (AudioNextRing()) {
Debug(3, "audio: HandlerThread break on nextring");
break;
}
} else {
AudioResetCompressor();
AudioResetNormalizer();
}
}
// FIXME: check AudioPaused ...Thread()
if (AudioPaused) {
Debug(3, "audio: HandlerThread break on paused");
break;
}
} while (AudioRing[AudioRingRead].HwSampleRate);
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}
return dummy;
}
/**
** Initialize audio thread.
*/
static void AudioInitThread(void) {
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AudioThreadStop = 0;
pthread_mutex_init(&AudioMutex, NULL);
pthread_cond_init(&AudioStartCond, NULL);
pthread_create(&AudioThread, NULL, AudioPlayHandlerThread, NULL);
pthread_setname_np(AudioThread, "softhddev audio");
}
/**
** Cleanup audio thread.
*/
static void AudioExitThread(void) {
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void *retval;
Debug(3, "audio: %s\n", __FUNCTION__);
if (AudioThread) {
AudioThreadStop = 1;
AudioRunning = 1; // wakeup thread, if needed
pthread_cond_signal(&AudioStartCond);
if (pthread_join(AudioThread, &retval) || retval != PTHREAD_CANCELED) {
Error(_("audio: can't cancel play thread\n"));
}
pthread_cond_destroy(&AudioStartCond);
pthread_mutex_destroy(&AudioMutex);
AudioThread = 0;
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}
}
#endif
//----------------------------------------------------------------------------
//----------------------------------------------------------------------------
/**
** Table of all audio modules.
*/
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static const AudioModule *AudioModules[] = {
&AlsaModule,
&NoopModule,
};
void AudioDelayms(int delayms) {
int count;
unsigned char *p;
#ifdef DEBUG
printf("Try Delay Audio for %d ms Samplerate %d Channels %d bps %d\n", delayms,
AudioRing[AudioRingWrite].HwSampleRate, AudioRing[AudioRingWrite].HwChannels, AudioBytesProSample);
#endif
count = delayms * AudioRing[AudioRingWrite].HwSampleRate * AudioRing[AudioRingWrite].HwChannels *
AudioBytesProSample / 1000;
if (delayms < 5000 && delayms > 0) { // not more than 5seconds
p = calloc(1, count);
RingBufferWrite(AudioRing[AudioRingWrite].RingBuffer, p, count);
free(p);
}
}
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/**
** Place samples in audio output queue.
**
** @param samples sample buffer
** @param count number of bytes in sample buffer
*/
void AudioEnqueue(const void *samples, int count) {
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size_t n;
int16_t *buffer;
#ifdef noDEBUG
static uint32_t last_tick;
uint32_t tick;
tick = GetMsTicks();
if (tick - last_tick > 101) {
Debug(3, "audio: enqueue %4d %dms\n", count, tick - last_tick);
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}
last_tick = tick;
#endif
if (!AudioRing[AudioRingWrite].HwSampleRate) {
Debug(3, "audio: enqueue not ready\n");
return; // no setup yet
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}
// save packet size
if (!AudioRing[AudioRingWrite].PacketSize) {
AudioRing[AudioRingWrite].PacketSize = count;
Debug(3, "audio: a/v packet size %d bytes\n", count);
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}
// audio sample modification allowed and needed?
buffer = (void *)samples;
if (!AudioRing[AudioRingWrite].Passthrough &&
(AudioCompression || AudioNormalize ||
AudioRing[AudioRingWrite].InChannels != AudioRing[AudioRingWrite].HwChannels)) {
int frames;
// resample into ring-buffer is too complex in the case of a roundabout
// just use a temporary buffer
frames = count / (AudioRing[AudioRingWrite].InChannels * AudioBytesProSample);
buffer = alloca(frames * AudioRing[AudioRingWrite].HwChannels * AudioBytesProSample);
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#ifdef USE_AUDIO_MIXER
// Convert / resample input to hardware format
AudioResample(samples, AudioRing[AudioRingWrite].InChannels, frames, buffer,
AudioRing[AudioRingWrite].HwChannels);
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#else
#ifdef DEBUG
if (AudioRing[AudioRingWrite].InChannels != AudioRing[AudioRingWrite].HwChannels) {
Debug(3, "audio: internal failure channels mismatch\n");
return;
}
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#endif
memcpy(buffer, samples, count);
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#endif
count = frames * AudioRing[AudioRingWrite].HwChannels * AudioBytesProSample;
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if (AudioCompression) { // in place operation
AudioCompressor(buffer, count);
}
if (AudioNormalize) { // in place operation
AudioNormalizer(buffer, count);
}
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}
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n = RingBufferWrite(AudioRing[AudioRingWrite].RingBuffer, buffer, count);
if (n != (size_t)count) {
Error(_("audio: can't place %d samples in ring buffer\n"), count);
// too many bytes are lost
// FIXME: caller checks buffer full.
// FIXME: should skip more, longer skip, but less often?
// FIXME: round to channel + sample border
}
if (!AudioRunning) { // check, if we can start the thread
int skip;
n = RingBufferUsedBytes(AudioRing[AudioRingWrite].RingBuffer);
skip = AudioSkip;
// FIXME: round to packet size
Debug(4, "audio: start? %4zdms skip %dms\n",
(n * 1000) / (AudioRing[AudioRingWrite].HwSampleRate * AudioRing[AudioRingWrite].HwChannels *
AudioBytesProSample),
(skip * 1000) / (AudioRing[AudioRingWrite].HwSampleRate * AudioRing[AudioRingWrite].HwChannels *
AudioBytesProSample));
if (skip) {
if (n < (unsigned)skip) {
skip = n;
}
AudioSkip -= skip;
RingBufferReadAdvance(AudioRing[AudioRingWrite].RingBuffer, skip);
n = RingBufferUsedBytes(AudioRing[AudioRingWrite].RingBuffer);
}
// forced start or enough video + audio buffered
// for some exotic channels * 4 too small
if (AudioStartThreshold * 4 < n || (AudioVideoIsReady
// if ((AudioVideoIsReady
&& AudioStartThreshold < n)) {
// restart play-back
// no lock needed, can wakeup next time
AudioRunning = 1;
pthread_cond_signal(&AudioStartCond);
Debug(3, "Start on AudioEnque Threshold %d n %d\n", AudioStartThreshold, n);
}
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}
// Update audio clock (stupid gcc developers thinks INT64_C is unsigned)
if (AudioRing[AudioRingWrite].PTS != (int64_t)AV_NOPTS_VALUE) {
AudioRing[AudioRingWrite].PTS +=
((int64_t)count * 90 * 1000) /
(AudioRing[AudioRingWrite].HwSampleRate * AudioRing[AudioRingWrite].HwChannels * AudioBytesProSample);
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}
}
/**
** Video is ready.
**
** @param pts video presentation timestamp
*/
void AudioVideoReady(int64_t pts) {
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int64_t audio_pts;
size_t used;
if (pts == (int64_t)AV_NOPTS_VALUE) {
Debug(3, "audio: a/v start, no valid video\n");
return;
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}
// no valid audio known
if (!AudioRing[AudioRingWrite].HwSampleRate || !AudioRing[AudioRingWrite].HwChannels ||
AudioRing[AudioRingWrite].PTS == (int64_t)AV_NOPTS_VALUE) {
Debug(3, "audio: a/v start, no valid audio\n");
AudioVideoIsReady = 1;
return;
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}
// Audio.PTS = next written sample time stamp
used = RingBufferUsedBytes(AudioRing[AudioRingWrite].RingBuffer);
audio_pts = AudioRing[AudioRingWrite].PTS -
(used * 90 * 1000) / (AudioRing[AudioRingWrite].HwSampleRate * AudioRing[AudioRingWrite].HwChannels *
AudioBytesProSample);
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Debug(3, "audio: a/v sync buf(%d,%4zdms) %s | %s = %dms %s\n", atomic_read(&AudioRingFilled),
(used * 1000) /
(AudioRing[AudioRingWrite].HwSampleRate * AudioRing[AudioRingWrite].HwChannels * AudioBytesProSample),
Timestamp2String(pts), Timestamp2String(audio_pts), (int)(pts - audio_pts) / 90,
AudioRunning ? "running" : "ready");
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if (!AudioRunning) {
int skip;
// buffer ~15 video frames
// FIXME: HDTV can use smaller video buffer
skip = pts - 0 * 20 * 90 - AudioBufferTime * 90 - audio_pts + VideoAudioDelay;
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#ifdef DEBUG
// fprintf(stderr, "a/v-diff %dms a/v-delay %dms skip %dms Audiobuffer
//%d\n", (int)(pts - audio_pts) / 90, VideoAudioDelay / 90, skip /
// 90,AudioBufferTime);
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#endif
// guard against old PTS
if (skip > 0 && skip < 4000 * 90) {
skip = (((int64_t)skip * AudioRing[AudioRingWrite].HwSampleRate) / (1000 * 90)) *
AudioRing[AudioRingWrite].HwChannels * AudioBytesProSample;
// FIXME: round to packet size
if ((unsigned)skip > used) {
AudioSkip = skip - used;
skip = used;
}
Debug(3, "audio: sync advance %dms %d/%zd Rest %d\n",
(skip * 1000) / (AudioRing[AudioRingWrite].HwSampleRate * AudioRing[AudioRingWrite].HwChannels *
AudioBytesProSample),
skip, used, AudioSkip);
RingBufferReadAdvance(AudioRing[AudioRingWrite].RingBuffer, skip);
used = RingBufferUsedBytes(AudioRing[AudioRingWrite].RingBuffer);
} else {
Debug(3, "No audio skip -> should skip %d\n", skip / 90);
}
// FIXME: skip<0 we need bigger audio buffer
// enough video + audio buffered
if (AudioStartThreshold < used) {
AudioRunning = 1;
pthread_cond_signal(&AudioStartCond);
Debug(3, "Start on AudioVideoReady\n");
}
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}
AudioVideoIsReady = 1;
}
/**
** Flush audio buffers.
*/
void AudioFlushBuffers(void) {
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int old;
int i;
if (atomic_read(&AudioRingFilled) >= AUDIO_RING_MAX) {
// wait for space in ring buffer, should never happen
for (i = 0; i < 24 * 2; ++i) {
if (atomic_read(&AudioRingFilled) < AUDIO_RING_MAX) {
break;
}
Debug(3, "audio: flush out of ring buffers\n");
usleep(1 * 1000); // avoid hot polling
}
if (atomic_read(&AudioRingFilled) >= AUDIO_RING_MAX) {
// FIXME: We can set the flush flag in the last wrote ring buffer
Error(_("audio: flush out of ring buffers\n"));
return;
}
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}
old = AudioRingWrite;
AudioRingWrite = (AudioRingWrite + 1) % AUDIO_RING_MAX;
AudioRing[AudioRingWrite].FlushBuffers = 1;
AudioRing[AudioRingWrite].Passthrough = AudioRing[old].Passthrough;
AudioRing[AudioRingWrite].HwSampleRate = AudioRing[old].HwSampleRate;
AudioRing[AudioRingWrite].HwChannels = AudioRing[old].HwChannels;
AudioRing[AudioRingWrite].InSampleRate = AudioRing[old].InSampleRate;
AudioRing[AudioRingWrite].InChannels = AudioRing[old].InChannels;
AudioRing[AudioRingWrite].PTS = AV_NOPTS_VALUE;
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RingBufferReadAdvance(AudioRing[AudioRingWrite].RingBuffer,
RingBufferUsedBytes(AudioRing[AudioRingWrite].RingBuffer));
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Debug(3, "audio: reset video ready\n");
AudioVideoIsReady = 0;
AudioSkip = 0;
atomic_inc(&AudioRingFilled);
// FIXME: wait for flush complete needed?
for (i = 0; i < 24 * 2; ++i) {
if (!AudioRunning) { // wakeup thread to flush buffers
AudioRunning = 1;
pthread_cond_signal(&AudioStartCond);
Debug(3, "Start on Flush\n");
}
// FIXME: waiting on zero isn't correct, but currently works
if (!atomic_read(&AudioRingFilled)) {
break;
}
usleep(1 * 1000); // avoid hot polling
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}
Debug(3, "audio: audio flush %dms\n", i);
}
/**
** Call back to play audio polled.
*/
void AudioPoller(void) {
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// FIXME: write poller
}
/**
** Get free bytes in audio output.
*/
int AudioFreeBytes(void) {
return AudioRing[AudioRingWrite].RingBuffer ? RingBufferFreeBytes(AudioRing[AudioRingWrite].RingBuffer)
: INT32_MAX;
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}
/**
** Get used bytes in audio output.
*/
int AudioUsedBytes(void) {
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// FIXME: not correct, if multiple buffer are in use
return AudioRing[AudioRingWrite].RingBuffer ? RingBufferUsedBytes(AudioRing[AudioRingWrite].RingBuffer) : 0;
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}
/**
** Get audio delay in time stamps.
**
** @returns audio delay in time stamps.
*/
int64_t AudioGetDelay(void) {
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int64_t pts;
if (!AudioRunning) {
return 0L; // audio not running
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}
if (!AudioRing[AudioRingRead].HwSampleRate) {
return 0L; // audio not setup
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}
if (atomic_read(&AudioRingFilled)) {
return 0L; // multiple buffers, invalid delay
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}
pts = AudioUsedModule->GetDelay();
pts += ((int64_t)RingBufferUsedBytes(AudioRing[AudioRingRead].RingBuffer) * 90 * 1000) /
(AudioRing[AudioRingRead].HwSampleRate * AudioRing[AudioRingRead].HwChannels * AudioBytesProSample);
Debug(4, "audio: hw+sw delay %zd %" PRId64 "ms\n", RingBufferUsedBytes(AudioRing[AudioRingRead].RingBuffer),
pts / 90);
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return pts;
}
/**
** Set audio clock base.
**
** @param pts audio presentation timestamp
*/
void AudioSetClock(int64_t pts) {
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if (AudioRing[AudioRingWrite].PTS != pts) {
Debug(4, "audio: set clock %s -> %s pts\n", Timestamp2String(AudioRing[AudioRingWrite].PTS),
Timestamp2String(pts));
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}
// printf("Audiosetclock pts %#012" PRIx64 "
// %d\n",pts,RingBufferUsedBytes(AudioRing[AudioRingWrite].RingBuffer));
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AudioRing[AudioRingWrite].PTS = pts;
}
/**
** Get current audio clock.
**
** @returns the audio clock in time stamps.
*/
int64_t AudioGetClock(void) {
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// (cast) needed for the evil gcc
if (AudioRing[AudioRingRead].PTS != (int64_t)AV_NOPTS_VALUE) {
int64_t delay;
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// delay zero, if no valid time stamp
if ((delay = AudioGetDelay())) {
if (AudioRing[AudioRingRead].Passthrough) {
return AudioRing[AudioRingRead].PTS + 0 * 90 - delay;
}
return AudioRing[AudioRingRead].PTS + 0 * 90 - delay;
}
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}
return AV_NOPTS_VALUE;
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}
/**
** Set mixer volume (0-1000)
**
** @param volume volume (0 .. 1000)
*/
void AudioSetVolume(int volume) {
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AudioVolume = volume;
AudioMute = !volume;
// reduce loudness for stereo output
if (AudioStereoDescent && AudioRing[AudioRingRead].InChannels == 2 && !AudioRing[AudioRingRead].Passthrough) {
volume -= AudioStereoDescent;
if (volume < 0) {
volume = 0;
} else if (volume > 1000) {
volume = 1000;
}
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}
AudioAmplifier = volume;
if (!AudioSoftVolume) {
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AudioUsedModule->SetVolume(volume);
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}
}
/**
** Setup audio for requested format.
**
** @param freq sample frequency
** @param channels number of channels
** @param passthrough use pass-through (AC-3, ...) device
**
** @retval 0 everything ok
** @retval 1 didn't support frequency/channels combination
** @retval -1 something gone wrong
**
** @todo add support to report best fitting format.
*/
int AudioSetup(int *freq, int *channels, int passthrough) {
Debug(3, "audio: setup channels %d frequency %dHz %s\n", *channels, *freq, passthrough ? "pass-through" : "");
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// invalid parameter
if (!freq || !channels || !*freq || !*channels) {
Debug(3, "audio: bad channels or frequency parameters\n");
// FIXME: set flag invalid setup
return -1;
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}
return AudioRingAdd(*freq, *channels, passthrough);
}
/**
** Play audio.
*/
void AudioPlay(void) {
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if (!AudioPaused) {
Debug(3, "audio: not paused, check the code\n");
return;
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}
Debug(3, "audio: resumed\n");
AudioPaused = 0;
AudioEnqueue(NULL, 0); // wakeup thread
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}
/**
** Pause audio.
*/
void AudioPause(void) {
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if (AudioPaused) {
Debug(3, "audio: already paused, check the code\n");
return;
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}
Debug(3, "audio: paused\n");
AudioPaused = 1;
}
/**
** Set audio buffer time.
**
** PES audio packets have a max distance of 300 ms.
** TS audio packet have a max distance of 100 ms.
** The period size of the audio buffer is 24 ms.
** With streamdev sometimes extra +100ms are needed.
*/
void AudioSetBufferTime(int delay) {
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if (!delay) {
delay = 336;
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}
AudioBufferTime = delay;
}
/**
** Enable/disable software volume.
**
** @param onoff -1 toggle, true turn on, false turn off
*/
void AudioSetSoftvol(int onoff) {
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if (onoff < 0) {
AudioSoftVolume ^= 1;
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} else {
AudioSoftVolume = onoff;
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}
}
/**
** Set normalize volume parameters.
**
** @param onoff -1 toggle, true turn on, false turn off
** @param maxfac max. factor of normalize /1000
*/
void AudioSetNormalize(int onoff, int maxfac) {
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if (onoff < 0) {
AudioNormalize ^= 1;
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} else {
AudioNormalize = onoff;
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}
AudioMaxNormalize = maxfac;
}
/**
** Set volume compression parameters.
**
** @param onoff -1 toggle, true turn on, false turn off
** @param maxfac max. factor of compression /1000
*/
void AudioSetCompression(int onoff, int maxfac) {
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if (onoff < 0) {
AudioCompression ^= 1;
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} else {
AudioCompression = onoff;
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}
AudioMaxCompression = maxfac;
if (!AudioCompressionFactor) {
AudioCompressionFactor = 1000;
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}
if (AudioCompressionFactor > AudioMaxCompression) {
AudioCompressionFactor = AudioMaxCompression;
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}
}
/**
** Set stereo loudness descent.
**
** @param delta value (/1000) to reduce stereo volume
*/
void AudioSetStereoDescent(int delta) {
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AudioStereoDescent = delta;
AudioSetVolume(AudioVolume); // update channel delta
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}
/**
** Set pcm audio device.
**
** @param device name of pcm device (fe. "hw:0,9" or "/dev/dsp")
**
** @note this is currently used to select alsa/OSS output module.
*/
void AudioSetDevice(const char *device) {
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if (!AudioModuleName) {
AudioModuleName = "alsa"; // detect alsa/OSS
if (!device[0]) {
AudioModuleName = "noop";
} else if (device[0] == '/') {
AudioModuleName = "oss";
}
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}
AudioPCMDevice = device;
}
/**
** Set pass-through audio device.
**
** @param device name of pass-through device (fe. "hw:0,1")
**
** @note this is currently usable with alsa only.
*/
void AudioSetPassthroughDevice(const char *device) {
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if (!AudioModuleName) {
AudioModuleName = "alsa"; // detect alsa/OSS
if (!device[0]) {
AudioModuleName = "noop";
} else if (device[0] == '/') {
AudioModuleName = "oss";
}
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}
AudioPassthroughDevice = device;
}
/**
** Set pcm audio mixer channel.
**
** @param channel name of the mixer channel (fe. PCM or Master)
**
** @note this is currently used to select alsa/OSS output module.
*/
void AudioSetChannel(const char *channel) { AudioMixerChannel = channel; }
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/**
** Set automatic AES flag handling.
**
** @param onoff turn setting AES flag on or off
*/
void AudioSetAutoAES(int onoff) {
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if (onoff < 0) {
AudioAppendAES ^= 1;
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} else {
AudioAppendAES = onoff;
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}
}
/**
** Initialize audio output module.
**
** @todo FIXME: make audio output module selectable.
*/
void AudioInit(void) {
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unsigned u;
const char *name;
int freq;
int chan;
name = "noop";
name = "alsa";
if (AudioModuleName) {
name = AudioModuleName;
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}
//
// search selected audio module.
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//
for (u = 0; u < sizeof(AudioModules) / sizeof(*AudioModules); ++u) {
if (!strcasecmp(name, AudioModules[u]->Name)) {
AudioUsedModule = AudioModules[u];
Info(_("audio: '%s' output module used\n"), AudioUsedModule->Name);
goto found;
}
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}
Error(_("audio: '%s' output module isn't supported\n"), name);
AudioUsedModule = &NoopModule;
return;
found:
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AudioDoingInit = 1;
AudioRingInit();
AudioUsedModule->Init();
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#if 0
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for (u = 0; u < AudioRatesMax; ++u) {
AudioChannelMatrix[u][1]=AudioChannelMatrix[u][2]=AudioChannelMatrix[u][3]=AudioChannelMatrix[u][4]=\
AudioChannelMatrix[u][5]=AudioChannelMatrix[u][6]=AudioChannelMatrix[u][7]=AudioChannelMatrix[u][8]=2;
printf("audio: %6dHz supports %d %d %d %d %d %d %d %d channels\n", AudioRatesTable[u],
AudioChannelMatrix[u][1], AudioChannelMatrix[u][2], AudioChannelMatrix[u][3], AudioChannelMatrix[u][4],
AudioChannelMatrix[u][5], AudioChannelMatrix[u][6], AudioChannelMatrix[u][7], AudioChannelMatrix[u][8]);
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}
AudioChannelsInHw[1]=AudioChannelsInHw[3]=AudioChannelsInHw[4]=AudioChannelsInHw[5]=AudioChannelsInHw[6]=AudioChannelsInHw[7]=AudioChannelsInHw[8]=0;
AudioChannelsInHw[2]=2;
#else
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//
// Check which channels/rates/formats are supported
// FIXME: we force 44.1Khz and 48Khz must be supported equal
// FIXME: should use bitmap of channels supported in RatesInHw
// FIXME: use loop over sample-rates
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freq = 44100;
AudioRatesInHw[Audio44100] = 0;
for (chan = 1; chan < 9; ++chan) {
int tchan;
int tfreq;
tchan = chan;
tfreq = freq;
if (AudioUsedModule->Setup(&tfreq, &tchan, 0)) {
AudioChannelsInHw[chan] = 0;
} else {
AudioChannelsInHw[chan] = chan;
AudioRatesInHw[Audio44100] |= (1 << chan);
}
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}
freq = 48000;
AudioRatesInHw[Audio48000] = 0;
for (chan = 1; chan < 9; ++chan) {
int tchan;
int tfreq;
if (!AudioChannelsInHw[chan]) {
continue;
}
tchan = chan;
tfreq = freq;
if (AudioUsedModule->Setup(&tfreq, &tchan, 0)) {
// AudioChannelsInHw[chan] = 0;
} else {
AudioChannelsInHw[chan] = chan;
AudioRatesInHw[Audio48000] |= (1 << chan);
}
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}
freq = 192000;
AudioRatesInHw[Audio192000] = 0;
for (chan = 1; chan < 9; ++chan) {
int tchan;
int tfreq;
if (!AudioChannelsInHw[chan]) {
continue;
}
tchan = chan;
tfreq = freq;
if (AudioUsedModule->Setup(&tfreq, &tchan, 0)) {
// AudioChannelsInHw[chan] = 0;
} else {
AudioChannelsInHw[chan] = chan;
AudioRatesInHw[Audio192000] |= (1 << chan);
}
}
// build channel support and conversion table
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for (u = 0; u < AudioRatesMax; ++u) {
for (chan = 1; chan < 9; ++chan) {
AudioChannelMatrix[u][chan] = 0;
if (!AudioRatesInHw[u]) { // rate unsupported
continue;
}
if (AudioChannelsInHw[chan]) {
AudioChannelMatrix[u][chan] = chan;
} else {
switch (chan) {
case 1:
if (AudioChannelsInHw[2]) {
AudioChannelMatrix[u][chan] = 2;
}
break;
case 2:
case 3:
if (AudioChannelsInHw[4]) {
AudioChannelMatrix[u][chan] = 4;
break;
}
case 4:
if (AudioChannelsInHw[5]) {
AudioChannelMatrix[u][chan] = 5;
break;
}
case 5:
if (AudioChannelsInHw[6]) {
AudioChannelMatrix[u][chan] = 6;
break;
}
case 6:
if (AudioChannelsInHw[7]) {
AudioChannelMatrix[u][chan] = 7;
break;
}
case 7:
if (AudioChannelsInHw[8]) {
AudioChannelMatrix[u][chan] = 8;
break;
}
case 8:
if (AudioChannelsInHw[6]) {
AudioChannelMatrix[u][chan] = 6;
break;
}
if (AudioChannelsInHw[2]) {
AudioChannelMatrix[u][chan] = 2;
break;
}
if (AudioChannelsInHw[1]) {
AudioChannelMatrix[u][chan] = 1;
break;
}
break;
}
}
}
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}
for (u = 0; u < AudioRatesMax; ++u) {
Debug(3,"audio: %6dHz supports %d %d %d %d %d %d %d %d channels\n", AudioRatesTable[u],
AudioChannelMatrix[u][1], AudioChannelMatrix[u][2], AudioChannelMatrix[u][3], AudioChannelMatrix[u][4],
AudioChannelMatrix[u][5], AudioChannelMatrix[u][6], AudioChannelMatrix[u][7], AudioChannelMatrix[u][8]);
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}
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#endif
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#ifdef USE_AUDIO_THREAD
if (AudioUsedModule->Thread) { // supports threads
AudioInitThread();
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}
#endif
AudioDoingInit = 0;
}
/**
** Cleanup audio output module.
*/
void AudioExit(void) {
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const AudioModule *module;
Debug(3, "audio: %s\n", __FUNCTION__);
#ifdef USE_AUDIO_THREAD
if (AudioUsedModule->Thread) { // supports threads
AudioExitThread();
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}
#endif
module = AudioUsedModule;
AudioUsedModule = &NoopModule;
module->Exit();
AudioRingExit();
AudioRunning = 0;
AudioPaused = 0;
}
#ifdef AUDIO_TEST
//----------------------------------------------------------------------------
// Test
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//----------------------------------------------------------------------------
void AudioTest(void) {
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for (;;) {
unsigned u;
uint8_t buffer[16 * 1024]; // some random data
int i;
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for (u = 0; u < sizeof(buffer); u++) {
buffer[u] = random() & 0xffff;
}
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Debug(3, "audio/test: loop\n");
for (i = 0; i < 100; ++i) {
while (RingBufferFreeBytes(AlsaRingBuffer) > sizeof(buffer)) {
AlsaEnqueue(buffer, sizeof(buffer));
}
usleep(20 * 1000);
}
break;
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}
}
#include <getopt.h>
int SysLogLevel; ///< show additional debug informations
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/**
** Print version.
*/
static void PrintVersion(void) {
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printf("audio_test: audio tester Version " VERSION
#ifdef GIT_REV
"(GIT-" GIT_REV ")"
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#endif
",\n\t(c) 2009 - 2013 by Johns\n"
"\tLicense AGPLv3: GNU Affero General Public License version 3\n");
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}
/**
** Print usage.
*/
static void PrintUsage(void) {
printf("Usage: audio_test [-?dhv]\n"
"\t-d\tenable debug, more -d increase the verbosity\n"
"\t-? -h\tdisplay this message\n"
"\t-v\tdisplay version information\n"
"Only idiots print usage on stderr!\n");
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}
/**
** Main entry point.
**
** @param argc number of arguments
** @param argv arguments vector
**
** @returns -1 on failures, 0 clean exit.
*/
int main(int argc, char *const argv[]) {
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SysLogLevel = 0;
//
// Parse command line arguments
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//
for (;;) {
switch (getopt(argc, argv, "hv?-c:d")) {
case 'd': // enabled debug
++SysLogLevel;
continue;
case EOF:
break;
case 'v': // print version
PrintVersion();
return 0;
case '?':
case 'h': // help usage
PrintVersion();
PrintUsage();
return 0;
case '-':
PrintVersion();
PrintUsage();
fprintf(stderr, "\nWe need no long options\n");
return -1;
case ':':
PrintVersion();
fprintf(stderr, "Missing argument for option '%c'\n", optopt);
return -1;
default:
PrintVersion();
fprintf(stderr, "Unknown option '%c'\n", optopt);
return -1;
}
break;
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}
if (optind < argc) {
PrintVersion();
while (optind < argc) {
fprintf(stderr, "Unhandled argument '%s'\n", argv[optind++]);
}
return -1;
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}
//
// main loop
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//
AudioInit();
for (;;) {
unsigned u;
uint8_t buffer[16 * 1024]; // some random data
for (u = 0; u < sizeof(buffer); u++) {
buffer[u] = random() & 0xffff;
}
Debug(3, "audio/test: loop\n");
for (;;) {
while (RingBufferFreeBytes(AlsaRingBuffer) > sizeof(buffer)) {
AlsaEnqueue(buffer, sizeof(buffer));
}
}
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}
AudioExit();
return 0;
}
#endif