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|
/***
This file is part of PulseAudio.
Copyright 2018-2019 Pali Rohár <pali.rohar@gmail.com>
PulseAudio 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.
PulseAudio 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
General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with PulseAudio; if not, see <http://www.gnu.org/licenses/>.
***/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <pulsecore/core-util.h>
#include <pulsecore/log.h>
#include <pulsecore/macro.h>
#include <pulsecore/once.h>
#include <pulse/sample.h>
#include <pulse/xmalloc.h>
#include <arpa/inet.h>
#include <sbc/sbc.h>
#include "a2dp-codecs.h"
#include "a2dp-codec-api.h"
#include "rtp.h"
#define SBC_BITPOOL_DEC_LIMIT 32
#define SBC_BITPOOL_DEC_STEP 5
struct sbc_info {
sbc_t sbc; /* Codec data */
size_t codesize, frame_length; /* SBC Codesize, frame_length. We simply cache those values here */
uint16_t seq_num; /* Cumulative packet sequence */
uint8_t frequency;
uint8_t blocks;
uint8_t subbands;
uint8_t mode;
uint8_t allocation;
uint8_t initial_bitpool;
uint8_t min_bitpool;
uint8_t max_bitpool;
};
static bool can_accept_capabilities(const uint8_t *capabilities_buffer, uint8_t capabilities_size, bool for_encoding) {
const a2dp_sbc_t *capabilities = (const a2dp_sbc_t *) capabilities_buffer;
if (capabilities_size != sizeof(*capabilities))
return false;
if (!(capabilities->frequency & (SBC_SAMPLING_FREQ_16000 | SBC_SAMPLING_FREQ_32000 | SBC_SAMPLING_FREQ_44100 | SBC_SAMPLING_FREQ_48000)))
return false;
if (!(capabilities->channel_mode & (SBC_CHANNEL_MODE_MONO | SBC_CHANNEL_MODE_DUAL_CHANNEL | SBC_CHANNEL_MODE_STEREO | SBC_CHANNEL_MODE_JOINT_STEREO)))
return false;
if (!(capabilities->allocation_method & (SBC_ALLOCATION_SNR | SBC_ALLOCATION_LOUDNESS)))
return false;
if (!(capabilities->subbands & (SBC_SUBBANDS_4 | SBC_SUBBANDS_8)))
return false;
if (!(capabilities->block_length & (SBC_BLOCK_LENGTH_4 | SBC_BLOCK_LENGTH_8 | SBC_BLOCK_LENGTH_12 | SBC_BLOCK_LENGTH_16)))
return false;
return true;
}
static const char *choose_remote_endpoint(const pa_hashmap *capabilities_hashmap, const pa_sample_spec *default_sample_spec, bool for_encoding) {
const pa_a2dp_codec_capabilities *a2dp_capabilities;
const char *key;
void *state;
/* There is no preference, just choose random valid entry */
PA_HASHMAP_FOREACH_KV(key, a2dp_capabilities, capabilities_hashmap, state) {
if (can_accept_capabilities(a2dp_capabilities->buffer, a2dp_capabilities->size, for_encoding))
return key;
}
return NULL;
}
static uint8_t fill_capabilities(uint8_t capabilities_buffer[MAX_A2DP_CAPS_SIZE]) {
a2dp_sbc_t *capabilities = (a2dp_sbc_t *) capabilities_buffer;
pa_zero(*capabilities);
capabilities->channel_mode = SBC_CHANNEL_MODE_MONO | SBC_CHANNEL_MODE_DUAL_CHANNEL | SBC_CHANNEL_MODE_STEREO |
SBC_CHANNEL_MODE_JOINT_STEREO;
capabilities->frequency = SBC_SAMPLING_FREQ_16000 | SBC_SAMPLING_FREQ_32000 | SBC_SAMPLING_FREQ_44100 |
SBC_SAMPLING_FREQ_48000;
capabilities->allocation_method = SBC_ALLOCATION_SNR | SBC_ALLOCATION_LOUDNESS;
capabilities->subbands = SBC_SUBBANDS_4 | SBC_SUBBANDS_8;
capabilities->block_length = SBC_BLOCK_LENGTH_4 | SBC_BLOCK_LENGTH_8 | SBC_BLOCK_LENGTH_12 | SBC_BLOCK_LENGTH_16;
capabilities->min_bitpool = SBC_MIN_BITPOOL;
capabilities->max_bitpool = SBC_BITPOOL_HQ_JOINT_STEREO_44100;
return sizeof(*capabilities);
}
static bool is_configuration_valid(const uint8_t *config_buffer, uint8_t config_size) {
const a2dp_sbc_t *config = (const a2dp_sbc_t *) config_buffer;
if (config_size != sizeof(*config)) {
pa_log_error("Invalid size of config buffer");
return false;
}
if (config->frequency != SBC_SAMPLING_FREQ_16000 && config->frequency != SBC_SAMPLING_FREQ_32000 &&
config->frequency != SBC_SAMPLING_FREQ_44100 && config->frequency != SBC_SAMPLING_FREQ_48000) {
pa_log_error("Invalid sampling frequency in configuration");
return false;
}
if (config->channel_mode != SBC_CHANNEL_MODE_MONO && config->channel_mode != SBC_CHANNEL_MODE_DUAL_CHANNEL &&
config->channel_mode != SBC_CHANNEL_MODE_STEREO && config->channel_mode != SBC_CHANNEL_MODE_JOINT_STEREO) {
pa_log_error("Invalid channel mode in configuration");
return false;
}
if (config->allocation_method != SBC_ALLOCATION_SNR && config->allocation_method != SBC_ALLOCATION_LOUDNESS) {
pa_log_error("Invalid allocation method in configuration");
return false;
}
if (config->subbands != SBC_SUBBANDS_4 && config->subbands != SBC_SUBBANDS_8) {
pa_log_error("Invalid SBC subbands in configuration");
return false;
}
if (config->block_length != SBC_BLOCK_LENGTH_4 && config->block_length != SBC_BLOCK_LENGTH_8 &&
config->block_length != SBC_BLOCK_LENGTH_12 && config->block_length != SBC_BLOCK_LENGTH_16) {
pa_log_error("Invalid block length in configuration");
return false;
}
if (config->min_bitpool > config->max_bitpool) {
pa_log_error("Invalid bitpool in configuration");
return false;
}
return true;
}
static uint8_t default_bitpool(uint8_t freq, uint8_t mode) {
/* These bitpool values were chosen based on the A2DP spec recommendation */
switch (freq) {
case SBC_SAMPLING_FREQ_16000:
case SBC_SAMPLING_FREQ_32000:
switch (mode) {
case SBC_CHANNEL_MODE_MONO:
case SBC_CHANNEL_MODE_DUAL_CHANNEL:
case SBC_CHANNEL_MODE_STEREO:
case SBC_CHANNEL_MODE_JOINT_STEREO:
return SBC_BITPOOL_HQ_JOINT_STEREO_44100;
}
break;
case SBC_SAMPLING_FREQ_44100:
switch (mode) {
case SBC_CHANNEL_MODE_MONO:
case SBC_CHANNEL_MODE_DUAL_CHANNEL:
return SBC_BITPOOL_HQ_MONO_44100;
case SBC_CHANNEL_MODE_STEREO:
case SBC_CHANNEL_MODE_JOINT_STEREO:
return SBC_BITPOOL_HQ_JOINT_STEREO_44100;
}
break;
case SBC_SAMPLING_FREQ_48000:
switch (mode) {
case SBC_CHANNEL_MODE_MONO:
case SBC_CHANNEL_MODE_DUAL_CHANNEL:
return SBC_BITPOOL_HQ_MONO_48000;
case SBC_CHANNEL_MODE_STEREO:
case SBC_CHANNEL_MODE_JOINT_STEREO:
return SBC_BITPOOL_HQ_JOINT_STEREO_48000;
}
break;
}
pa_assert_not_reached();
}
static uint8_t fill_preferred_configuration(const pa_sample_spec *default_sample_spec, const uint8_t *capabilities_buffer, uint8_t capabilities_size, uint8_t config_buffer[MAX_A2DP_CAPS_SIZE]) {
a2dp_sbc_t *config = (a2dp_sbc_t *) config_buffer;
const a2dp_sbc_t *capabilities = (const a2dp_sbc_t *) capabilities_buffer;
int i;
static const struct {
uint32_t rate;
uint8_t cap;
} freq_table[] = {
{ 16000U, SBC_SAMPLING_FREQ_16000 },
{ 32000U, SBC_SAMPLING_FREQ_32000 },
{ 44100U, SBC_SAMPLING_FREQ_44100 },
{ 48000U, SBC_SAMPLING_FREQ_48000 }
};
if (capabilities_size != sizeof(*capabilities)) {
pa_log_error("Invalid size of capabilities buffer");
return 0;
}
pa_zero(*config);
/* Find the lowest freq that is at least as high as the requested sampling rate */
for (i = 0; (unsigned) i < PA_ELEMENTSOF(freq_table); i++)
if (freq_table[i].rate >= default_sample_spec->rate && (capabilities->frequency & freq_table[i].cap)) {
config->frequency = freq_table[i].cap;
break;
}
if ((unsigned) i == PA_ELEMENTSOF(freq_table)) {
for (--i; i >= 0; i--) {
if (capabilities->frequency & freq_table[i].cap) {
config->frequency = freq_table[i].cap;
break;
}
}
if (i < 0) {
pa_log_error("Not suitable sample rate");
return 0;
}
}
pa_assert((unsigned) i < PA_ELEMENTSOF(freq_table));
if (default_sample_spec->channels <= 1) {
if (capabilities->channel_mode & SBC_CHANNEL_MODE_MONO)
config->channel_mode = SBC_CHANNEL_MODE_MONO;
else if (capabilities->channel_mode & SBC_CHANNEL_MODE_JOINT_STEREO)
config->channel_mode = SBC_CHANNEL_MODE_JOINT_STEREO;
else if (capabilities->channel_mode & SBC_CHANNEL_MODE_STEREO)
config->channel_mode = SBC_CHANNEL_MODE_STEREO;
else if (capabilities->channel_mode & SBC_CHANNEL_MODE_DUAL_CHANNEL)
config->channel_mode = SBC_CHANNEL_MODE_DUAL_CHANNEL;
else {
pa_log_error("No supported channel modes");
return 0;
}
} else {
if (capabilities->channel_mode & SBC_CHANNEL_MODE_JOINT_STEREO)
config->channel_mode = SBC_CHANNEL_MODE_JOINT_STEREO;
else if (capabilities->channel_mode & SBC_CHANNEL_MODE_STEREO)
config->channel_mode = SBC_CHANNEL_MODE_STEREO;
else if (capabilities->channel_mode & SBC_CHANNEL_MODE_DUAL_CHANNEL)
config->channel_mode = SBC_CHANNEL_MODE_DUAL_CHANNEL;
else if (capabilities->channel_mode & SBC_CHANNEL_MODE_MONO)
config->channel_mode = SBC_CHANNEL_MODE_MONO;
else {
pa_log_error("No supported channel modes");
return 0;
}
}
if (capabilities->block_length & SBC_BLOCK_LENGTH_16)
config->block_length = SBC_BLOCK_LENGTH_16;
else if (capabilities->block_length & SBC_BLOCK_LENGTH_12)
config->block_length = SBC_BLOCK_LENGTH_12;
else if (capabilities->block_length & SBC_BLOCK_LENGTH_8)
config->block_length = SBC_BLOCK_LENGTH_8;
else if (capabilities->block_length & SBC_BLOCK_LENGTH_4)
config->block_length = SBC_BLOCK_LENGTH_4;
else {
pa_log_error("No supported block lengths");
return 0;
}
if (capabilities->subbands & SBC_SUBBANDS_8)
config->subbands = SBC_SUBBANDS_8;
else if (capabilities->subbands & SBC_SUBBANDS_4)
config->subbands = SBC_SUBBANDS_4;
else {
pa_log_error("No supported subbands");
return 0;
}
if (capabilities->allocation_method & SBC_ALLOCATION_LOUDNESS)
config->allocation_method = SBC_ALLOCATION_LOUDNESS;
else if (capabilities->allocation_method & SBC_ALLOCATION_SNR)
config->allocation_method = SBC_ALLOCATION_SNR;
else {
pa_log_error("No supported allocation method");
return 0;
}
config->min_bitpool = (uint8_t) PA_MAX(SBC_MIN_BITPOOL, capabilities->min_bitpool);
config->max_bitpool = (uint8_t) PA_MIN(default_bitpool(config->frequency, config->channel_mode), capabilities->max_bitpool);
if (config->min_bitpool > config->max_bitpool) {
pa_log_error("No supported bitpool");
return 0;
}
return sizeof(*config);
}
static void set_params(struct sbc_info *sbc_info) {
sbc_info->sbc.frequency = sbc_info->frequency;
sbc_info->sbc.blocks = sbc_info->blocks;
sbc_info->sbc.subbands = sbc_info->subbands;
sbc_info->sbc.mode = sbc_info->mode;
sbc_info->sbc.allocation = sbc_info->allocation;
sbc_info->sbc.bitpool = sbc_info->initial_bitpool;
sbc_info->sbc.endian = SBC_LE;
sbc_info->codesize = sbc_get_codesize(&sbc_info->sbc);
sbc_info->frame_length = sbc_get_frame_length(&sbc_info->sbc);
}
static void *init(bool for_encoding, bool for_backchannel, const uint8_t *config_buffer, uint8_t config_size, pa_sample_spec *sample_spec) {
struct sbc_info *sbc_info;
const a2dp_sbc_t *config = (const a2dp_sbc_t *) config_buffer;
int ret;
pa_assert(config_size == sizeof(*config));
pa_assert(!for_backchannel);
sbc_info = pa_xnew0(struct sbc_info, 1);
ret = sbc_init(&sbc_info->sbc, 0);
if (ret != 0) {
pa_xfree(sbc_info);
pa_log_error("SBC initialization failed: %d", ret);
return NULL;
}
sample_spec->format = PA_SAMPLE_S16LE;
switch (config->frequency) {
case SBC_SAMPLING_FREQ_16000:
sbc_info->frequency = SBC_FREQ_16000;
sample_spec->rate = 16000U;
break;
case SBC_SAMPLING_FREQ_32000:
sbc_info->frequency = SBC_FREQ_32000;
sample_spec->rate = 32000U;
break;
case SBC_SAMPLING_FREQ_44100:
sbc_info->frequency = SBC_FREQ_44100;
sample_spec->rate = 44100U;
break;
case SBC_SAMPLING_FREQ_48000:
sbc_info->frequency = SBC_FREQ_48000;
sample_spec->rate = 48000U;
break;
default:
pa_assert_not_reached();
}
switch (config->channel_mode) {
case SBC_CHANNEL_MODE_MONO:
sbc_info->mode = SBC_MODE_MONO;
sample_spec->channels = 1;
break;
case SBC_CHANNEL_MODE_DUAL_CHANNEL:
sbc_info->mode = SBC_MODE_DUAL_CHANNEL;
sample_spec->channels = 2;
break;
case SBC_CHANNEL_MODE_STEREO:
sbc_info->mode = SBC_MODE_STEREO;
sample_spec->channels = 2;
break;
case SBC_CHANNEL_MODE_JOINT_STEREO:
sbc_info->mode = SBC_MODE_JOINT_STEREO;
sample_spec->channels = 2;
break;
default:
pa_assert_not_reached();
}
switch (config->allocation_method) {
case SBC_ALLOCATION_SNR:
sbc_info->allocation = SBC_AM_SNR;
break;
case SBC_ALLOCATION_LOUDNESS:
sbc_info->allocation = SBC_AM_LOUDNESS;
break;
default:
pa_assert_not_reached();
}
switch (config->subbands) {
case SBC_SUBBANDS_4:
sbc_info->subbands = SBC_SB_4;
break;
case SBC_SUBBANDS_8:
sbc_info->subbands = SBC_SB_8;
break;
default:
pa_assert_not_reached();
}
switch (config->block_length) {
case SBC_BLOCK_LENGTH_4:
sbc_info->blocks = SBC_BLK_4;
break;
case SBC_BLOCK_LENGTH_8:
sbc_info->blocks = SBC_BLK_8;
break;
case SBC_BLOCK_LENGTH_12:
sbc_info->blocks = SBC_BLK_12;
break;
case SBC_BLOCK_LENGTH_16:
sbc_info->blocks = SBC_BLK_16;
break;
default:
pa_assert_not_reached();
}
sbc_info->min_bitpool = config->min_bitpool;
sbc_info->max_bitpool = config->max_bitpool;
/* Set minimum bitpool for source to get the maximum possible block_size
* in get_block_size() function. This block_size is length of buffer used
* for decoded audio data and so is inversely proportional to frame length
* which depends on bitpool value. Bitpool is controlled by other side from
* range [min_bitpool, max_bitpool]. */
sbc_info->initial_bitpool = for_encoding ? sbc_info->max_bitpool : sbc_info->min_bitpool;
set_params(sbc_info);
pa_log_info("SBC parameters: allocation=%s, subbands=%u, blocks=%u, mode=%s bitpool=%u codesize=%u frame_length=%u",
sbc_info->sbc.allocation ? "SNR" : "Loudness", sbc_info->sbc.subbands ? 8 : 4,
(sbc_info->sbc.blocks+1)*4, sbc_info->sbc.mode == SBC_MODE_MONO ? "Mono" :
sbc_info->sbc.mode == SBC_MODE_DUAL_CHANNEL ? "DualChannel" :
sbc_info->sbc.mode == SBC_MODE_STEREO ? "Stereo" : "JointStereo",
sbc_info->sbc.bitpool, (unsigned)sbc_info->codesize, (unsigned)sbc_info->frame_length);
return sbc_info;
}
static void deinit(void *codec_info) {
struct sbc_info *sbc_info = (struct sbc_info *) codec_info;
sbc_finish(&sbc_info->sbc);
pa_xfree(sbc_info);
}
static void set_bitpool(struct sbc_info *sbc_info, uint8_t bitpool) {
if (bitpool > sbc_info->max_bitpool)
bitpool = sbc_info->max_bitpool;
else if (bitpool < sbc_info->min_bitpool)
bitpool = sbc_info->min_bitpool;
sbc_info->sbc.bitpool = bitpool;
sbc_info->codesize = sbc_get_codesize(&sbc_info->sbc);
sbc_info->frame_length = sbc_get_frame_length(&sbc_info->sbc);
pa_log_debug("Bitpool has changed to %u", sbc_info->sbc.bitpool);
}
static int reset(void *codec_info) {
struct sbc_info *sbc_info = (struct sbc_info *) codec_info;
int ret;
ret = sbc_reinit(&sbc_info->sbc, 0);
if (ret != 0) {
pa_log_error("SBC reinitialization failed: %d", ret);
return -1;
}
/* sbc_reinit() sets also default parameters, so reset them back */
set_params(sbc_info);
sbc_info->seq_num = 0;
return 0;
}
static size_t get_block_size(void *codec_info, size_t link_mtu) {
struct sbc_info *sbc_info = (struct sbc_info *) codec_info;
size_t rtp_size = sizeof(struct rtp_header) + sizeof(struct rtp_sbc_payload);
size_t frame_count = (link_mtu - rtp_size) / sbc_info->frame_length;
/* frame_count is only 4 bit number */
if (frame_count > 15)
frame_count = 15;
return frame_count * sbc_info->codesize;
}
static size_t reduce_encoder_bitrate(void *codec_info, size_t write_link_mtu) {
struct sbc_info *sbc_info = (struct sbc_info *) codec_info;
uint8_t bitpool;
/* Check if bitpool is already at its limit */
if (sbc_info->sbc.bitpool <= SBC_BITPOOL_DEC_LIMIT)
return 0;
bitpool = sbc_info->sbc.bitpool - SBC_BITPOOL_DEC_STEP;
if (bitpool < SBC_BITPOOL_DEC_LIMIT)
bitpool = SBC_BITPOOL_DEC_LIMIT;
if (sbc_info->sbc.bitpool == bitpool)
return 0;
set_bitpool(sbc_info, bitpool);
return get_block_size(codec_info, write_link_mtu);
}
static size_t encode_buffer(void *codec_info, uint32_t timestamp, const uint8_t *input_buffer, size_t input_size, uint8_t *output_buffer, size_t output_size, size_t *processed) {
struct sbc_info *sbc_info = (struct sbc_info *) codec_info;
struct rtp_header *header;
struct rtp_sbc_payload *payload;
uint8_t *d;
const uint8_t *p;
size_t to_write, to_encode;
uint8_t frame_count;
header = (struct rtp_header*) output_buffer;
payload = (struct rtp_sbc_payload*) (output_buffer + sizeof(*header));
frame_count = 0;
p = input_buffer;
to_encode = input_size;
d = output_buffer + sizeof(*header) + sizeof(*payload);
to_write = output_size - sizeof(*header) - sizeof(*payload);
/* frame_count is only 4 bit number */
while (PA_LIKELY(to_encode > 0 && to_write > 0 && frame_count < 15)) {
ssize_t written;
ssize_t encoded;
encoded = sbc_encode(&sbc_info->sbc,
p, to_encode,
d, to_write,
&written);
if (PA_UNLIKELY(encoded <= 0)) {
pa_log_error("SBC encoding error (%li)", (long) encoded);
break;
}
if (PA_UNLIKELY(written < 0)) {
pa_log_error("SBC encoding error (%li)", (long) written);
break;
}
pa_assert_fp((size_t) encoded <= to_encode);
pa_assert_fp((size_t) encoded == sbc_info->codesize);
pa_assert_fp((size_t) written <= to_write);
pa_assert_fp((size_t) written == sbc_info->frame_length);
p += encoded;
to_encode -= encoded;
d += written;
to_write -= written;
frame_count++;
}
PA_ONCE_BEGIN {
pa_log_debug("Using SBC codec implementation: %s", pa_strnull(sbc_get_implementation_info(&sbc_info->sbc)));
} PA_ONCE_END;
if (PA_UNLIKELY(frame_count == 0)) {
*processed = 0;
return 0;
}
/* write it to the fifo */
pa_memzero(output_buffer, sizeof(*header) + sizeof(*payload));
header->v = 2;
/* A2DP spec: "A payload type in the RTP dynamic range shall be chosen".
* RFC3551 defines the dynamic range to span from 96 to 127, and 96 appears
* to be the most common choice in A2DP implementations. */
header->pt = 96;
header->sequence_number = htons(sbc_info->seq_num++);
header->timestamp = htonl(timestamp);
header->ssrc = htonl(1);
payload->frame_count = frame_count;
*processed = p - input_buffer;
return d - output_buffer;
}
static size_t decode_buffer(void *codec_info, const uint8_t *input_buffer, size_t input_size, uint8_t *output_buffer, size_t output_size, size_t *processed) {
struct sbc_info *sbc_info = (struct sbc_info *) codec_info;
struct rtp_header *header;
struct rtp_sbc_payload *payload;
const uint8_t *p;
uint8_t *d;
size_t to_write, to_decode;
uint8_t frame_count;
header = (struct rtp_header *) input_buffer;
payload = (struct rtp_sbc_payload*) (input_buffer + sizeof(*header));
frame_count = payload->frame_count;
/* TODO: Add support for decoding fragmented SBC frames */
if (payload->is_fragmented) {
pa_log_error("Unsupported fragmented SBC frame");
*processed = 0;
return 0;
}
p = input_buffer + sizeof(*header) + sizeof(*payload);
to_decode = input_size - sizeof(*header) - sizeof(*payload);
d = output_buffer;
to_write = output_size;
while (PA_LIKELY(to_decode > 0 && to_write > 0 && frame_count > 0)) {
size_t written;
ssize_t decoded;
decoded = sbc_decode(&sbc_info->sbc,
p, to_decode,
d, to_write,
&written);
if (PA_UNLIKELY(decoded <= 0)) {
pa_log_error("SBC decoding error (%li)", (long) decoded);
break;
}
/* Reset frame length, it can be changed due to bitpool change */
sbc_info->frame_length = sbc_get_frame_length(&sbc_info->sbc);
pa_assert_fp((size_t) decoded <= to_decode);
pa_assert_fp((size_t) decoded == sbc_info->frame_length);
pa_assert_fp((size_t) written <= to_write);
pa_assert_fp((size_t) written == sbc_info->codesize);
p += decoded;
to_decode -= decoded;
d += written;
to_write -= written;
frame_count--;
}
*processed = p - input_buffer;
return d - output_buffer;
}
const pa_a2dp_codec pa_a2dp_codec_sbc = {
.name = "sbc",
.description = "SBC",
.id = { A2DP_CODEC_SBC, 0, 0 },
.support_backchannel = false,
.can_accept_capabilities = can_accept_capabilities,
.choose_remote_endpoint = choose_remote_endpoint,
.fill_capabilities = fill_capabilities,
.is_configuration_valid = is_configuration_valid,
.fill_preferred_configuration = fill_preferred_configuration,
.init = init,
.deinit = deinit,
.reset = reset,
.get_read_block_size = get_block_size,
.get_write_block_size = get_block_size,
.reduce_encoder_bitrate = reduce_encoder_bitrate,
.encode_buffer = encode_buffer,
.decode_buffer = decode_buffer,
};
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