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e58ee06492
toxcore/toxav/audio.c
iphydf 1859d0f44a
cleanup: Ensure we limit the system headers included in .h files. 
Most system headers contain functions (e.g. `memcpy` in `string.h`)
which aren't needed in our own header files. For the most part, our own
headers should only include types needed to declare our own types and
functions. We now enforce this so we think twice about which headers we
really need in the .h files.
2022-02-04 20:54:37 +00:00

518 lines
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/* SPDX-License-Identifier: GPL-3.0-or-later
* Copyright © 2016-2018 The TokTok team.
* Copyright © 2013-2015 Tox project.
*/
#include "audio.h"
#include <assert.h>
#include <stdlib.h>
#include <string.h>
#include "rtp.h"
#include "../toxcore/logger.h"
#include "../toxcore/mono_time.h"
static struct JitterBuffer *jbuf_new(uint32_t capacity);
static void jbuf_clear(struct JitterBuffer *q);
static void jbuf_free(struct JitterBuffer *q);
static int jbuf_write(const Logger *log, struct JitterBuffer *q, struct RTPMessage *m);
static struct RTPMessage *jbuf_read(struct JitterBuffer *q, int32_t *success);
static OpusEncoder *create_audio_encoder(const Logger *log, int32_t bit_rate, int32_t sampling_rate,
int32_t channel_count);
static bool reconfigure_audio_encoder(const Logger *log, OpusEncoder **e, int32_t new_br, int32_t new_sr,
uint8_t new_ch, int32_t *old_br, int32_t *old_sr, int32_t *old_ch);
static bool reconfigure_audio_decoder(ACSession *ac, int32_t sampling_rate, int8_t channels);
ACSession *ac_new(Mono_Time *mono_time, const Logger *log, ToxAV *av, uint32_t friend_number,
toxav_audio_receive_frame_cb *cb, void *cb_data)
{
ACSession *ac = (ACSession *)calloc(1, sizeof(ACSession));
if (!ac) {
LOGGER_WARNING(log, "Allocation failed! Application might misbehave!");
return nullptr;
}
if (create_recursive_mutex(ac->queue_mutex) != 0) {
LOGGER_WARNING(log, "Failed to create recursive mutex!");
free(ac);
return nullptr;
}
int status;
ac->decoder = opus_decoder_create(AUDIO_DECODER_START_SAMPLE_RATE, AUDIO_DECODER_START_CHANNEL_COUNT, &status);
if (status != OPUS_OK) {
LOGGER_ERROR(log, "Error while starting audio decoder: %s", opus_strerror(status));
goto BASE_CLEANUP;
}
ac->j_buf = jbuf_new(AUDIO_JITTERBUFFER_COUNT);
if (ac->j_buf == nullptr) {
LOGGER_WARNING(log, "Jitter buffer creaton failed!");
opus_decoder_destroy(ac->decoder);
goto BASE_CLEANUP;
}
ac->mono_time = mono_time;
ac->log = log;
/* Initialize encoders with default values */
ac->encoder = create_audio_encoder(log, AUDIO_START_BITRATE, AUDIO_START_SAMPLE_RATE, AUDIO_START_CHANNEL_COUNT);
if (ac->encoder == nullptr) {
goto DECODER_CLEANUP;
}
ac->le_bit_rate = AUDIO_START_BITRATE;
ac->le_sample_rate = AUDIO_START_SAMPLE_RATE;
ac->le_channel_count = AUDIO_START_CHANNEL_COUNT;
ac->ld_channel_count = AUDIO_DECODER_START_CHANNEL_COUNT;
ac->ld_sample_rate = AUDIO_DECODER_START_SAMPLE_RATE;
ac->ldrts = 0; /* Make it possible to reconfigure straight away */
/* These need to be set in order to properly
* do error correction with opus */
ac->lp_frame_duration = AUDIO_MAX_FRAME_DURATION_MS;
ac->lp_sampling_rate = AUDIO_DECODER_START_SAMPLE_RATE;
ac->lp_channel_count = AUDIO_DECODER_START_CHANNEL_COUNT;
ac->av = av;
ac->friend_number = friend_number;
ac->acb = cb;
ac->acb_user_data = cb_data;
return ac;
DECODER_CLEANUP:
opus_decoder_destroy(ac->decoder);
jbuf_free((struct JitterBuffer *)ac->j_buf);
BASE_CLEANUP:
pthread_mutex_destroy(ac->queue_mutex);
free(ac);
return nullptr;
}
void ac_kill(ACSession *ac)
{
if (!ac) {
return;
}
opus_encoder_destroy(ac->encoder);
opus_decoder_destroy(ac->decoder);
jbuf_free((struct JitterBuffer *)ac->j_buf);
pthread_mutex_destroy(ac->queue_mutex);
LOGGER_DEBUG(ac->log, "Terminated audio handler: %p", (void *)ac);
free(ac);
}
void ac_iterate(ACSession *ac)
{
if (!ac) {
return;
}
/* TODO: fix this and jitter buffering */
/* Enough space for the maximum frame size (120 ms 48 KHz stereo audio) */
int16_t *temp_audio_buffer = (int16_t *)malloc(AUDIO_MAX_BUFFER_SIZE_PCM16 * AUDIO_MAX_CHANNEL_COUNT * sizeof(int16_t));
if (temp_audio_buffer == nullptr) {
LOGGER_ERROR(ac->log, "Failed to allocate memory for audio buffer");
return;
}
pthread_mutex_lock(ac->queue_mutex);
struct JitterBuffer *const j_buf = (struct JitterBuffer *)ac->j_buf;
int rc = 0;
for (struct RTPMessage *msg = jbuf_read(j_buf, &rc); msg != nullptr || rc == 2; msg = jbuf_read(j_buf, &rc)) {
pthread_mutex_unlock(ac->queue_mutex);
if (rc == 2) {
LOGGER_DEBUG(ac->log, "OPUS correction");
int fs = (ac->lp_sampling_rate * ac->lp_frame_duration) / 1000;
rc = opus_decode(ac->decoder, nullptr, 0, temp_audio_buffer, fs, 1);
} else {
/* Get values from packet and decode. */
/* NOTE: This didn't work very well */
#if 0
rc = convert_bw_to_sampling_rate(opus_packet_get_bandwidth(msg->data));
if (rc != -1) {
cs->last_packet_sampling_rate = rc;
} else {
LOGGER_WARNING(ac->log, "Failed to load packet values!");
free(msg);
pthread_mutex_lock(ac->queue_mutex);
continue;
}
#endif
assert(msg->len > 4);
/* Pick up sampling rate from packet */
memcpy(&ac->lp_sampling_rate, msg->data, 4);
ac->lp_sampling_rate = net_ntohl(ac->lp_sampling_rate);
ac->lp_channel_count = opus_packet_get_nb_channels(msg->data + 4);
/* NOTE: even though OPUS supports decoding mono frames with stereo decoder and vice versa,
* it didn't work quite well.
*/
if (!reconfigure_audio_decoder(ac, ac->lp_sampling_rate, ac->lp_channel_count)) {
LOGGER_WARNING(ac->log, "Failed to reconfigure decoder!");
free(msg);
pthread_mutex_lock(ac->queue_mutex);
continue;
}
/*
* frame_size = opus_decode(dec, packet, len, decoded, max_size, 0);
* where
* packet is the byte array containing the compressed data
* len is the exact number of bytes contained in the packet
* decoded is the decoded audio data in opus_int16 (or float for opus_decode_float())
* max_size is the max duration of the frame in samples (per channel) that can fit
* into the decoded_frame array
*/
rc = opus_decode(ac->decoder, msg->data + 4, msg->len - 4, temp_audio_buffer, 5760, 0);
free(msg);
}
if (rc < 0) {
LOGGER_WARNING(ac->log, "Decoding error: %s", opus_strerror(rc));
} else if (ac->acb) {
ac->lp_frame_duration = (rc * 1000) / ac->lp_sampling_rate;
ac->acb(ac->av, ac->friend_number, temp_audio_buffer, rc, ac->lp_channel_count,
ac->lp_sampling_rate, ac->acb_user_data);
}
free(temp_audio_buffer);
return;
}
pthread_mutex_unlock(ac->queue_mutex);
free(temp_audio_buffer);
}
int ac_queue_message(Mono_Time *mono_time, void *acp, struct RTPMessage *msg)
{
if (!acp || !msg) {
free(msg);
return -1;
}
ACSession *ac = (ACSession *)acp;
if ((msg->header.pt & 0x7f) == (RTP_TYPE_AUDIO + 2) % 128) {
LOGGER_WARNING(ac->log, "Got dummy!");
free(msg);
return 0;
}
if ((msg->header.pt & 0x7f) != RTP_TYPE_AUDIO % 128) {
LOGGER_WARNING(ac->log, "Invalid payload type!");
free(msg);
return -1;
}
pthread_mutex_lock(ac->queue_mutex);
int rc = jbuf_write(ac->log, (struct JitterBuffer *)ac->j_buf, msg);
pthread_mutex_unlock(ac->queue_mutex);
if (rc == -1) {
LOGGER_WARNING(ac->log, "Could not queue the message!");
free(msg);
return -1;
}
return 0;
}
int ac_reconfigure_encoder(ACSession *ac, int32_t bit_rate, int32_t sampling_rate, uint8_t channels)
{
if (!ac || !reconfigure_audio_encoder(ac->log, &ac->encoder, bit_rate,
sampling_rate, channels,
&ac->le_bit_rate,
&ac->le_sample_rate,
&ac->le_channel_count)) {
return -1;
}
return 0;
}
struct JitterBuffer {
struct RTPMessage **queue;
uint32_t size;
uint32_t capacity;
uint16_t bottom;
uint16_t top;
};
static struct JitterBuffer *jbuf_new(uint32_t capacity)
{
unsigned int size = 1;
while (size <= (capacity * 4)) {
size *= 2;
}
struct JitterBuffer *q = (struct JitterBuffer *)calloc(1, sizeof(struct JitterBuffer));
if (!q) {
return nullptr;
}
q->queue = (struct RTPMessage **)calloc(size, sizeof(struct RTPMessage *));
if (!q->queue) {
free(q);
return nullptr;
}
q->size = size;
q->capacity = capacity;
return q;
}
static void jbuf_clear(struct JitterBuffer *q)
{
while (q->bottom != q->top) {
free(q->queue[q->bottom % q->size]);
q->queue[q->bottom % q->size] = nullptr;
++q->bottom;
}
}
static void jbuf_free(struct JitterBuffer *q)
{
if (!q) {
return;
}
jbuf_clear(q);
free(q->queue);
free(q);
}
static int jbuf_write(const Logger *log, struct JitterBuffer *q, struct RTPMessage *m)
{
uint16_t sequnum = m->header.sequnum;
unsigned int num = sequnum % q->size;
if ((uint32_t)(sequnum - q->bottom) > q->size) {
LOGGER_DEBUG(log, "Clearing filled jitter buffer: %p", (void *)q);
jbuf_clear(q);
q->bottom = sequnum - q->capacity;
q->queue[num] = m;
q->top = sequnum + 1;
return 0;
}
if (q->queue[num]) {
return -1;
}
q->queue[num] = m;
if ((sequnum - q->bottom) >= (q->top - q->bottom)) {
q->top = sequnum + 1;
}
return 0;
}
static struct RTPMessage *jbuf_read(struct JitterBuffer *q, int32_t *success)
{
if (q->top == q->bottom) {
*success = 0;
return nullptr;
}
unsigned int num = q->bottom % q->size;
if (q->queue[num]) {
struct RTPMessage *ret = q->queue[num];
q->queue[num] = nullptr;
++q->bottom;
*success = 1;
return ret;
}
if ((uint32_t)(q->top - q->bottom) > q->capacity) {
++q->bottom;
*success = 2;
return nullptr;
}
*success = 0;
return nullptr;
}
static OpusEncoder *create_audio_encoder(const Logger *log, int32_t bit_rate, int32_t sampling_rate,
int32_t channel_count)
{
int status = OPUS_OK;
/*
* OPUS_APPLICATION_VOIP Process signal for improved speech intelligibility
* OPUS_APPLICATION_AUDIO Favor faithfulness to the original input
* OPUS_APPLICATION_RESTRICTED_LOWDELAY Configure the minimum possible coding delay
*/
OpusEncoder *rc = opus_encoder_create(sampling_rate, channel_count, OPUS_APPLICATION_VOIP, &status);
if (status != OPUS_OK) {
LOGGER_ERROR(log, "Error while starting audio encoder: %s", opus_strerror(status));
return nullptr;
}
/*
* Rates from 500 to 512000 bits per second are meaningful as well as the special
* values OPUS_BITRATE_AUTO and OPUS_BITRATE_MAX. The value OPUS_BITRATE_MAX can
* be used to cause the codec to use as much rate as it can, which is useful for
* controlling the rate by adjusting the output buffer size.
*
* Parameters:
* `[in]` `x` `opus_int32`: bitrate in bits per second.
*/
status = opus_encoder_ctl(rc, OPUS_SET_BITRATE(bit_rate));
if (status != OPUS_OK) {
LOGGER_ERROR(log, "Error while setting encoder ctl: %s", opus_strerror(status));
goto FAILURE;
}
/*
* Configures the encoder's use of inband forward error correction.
* Note:
* This is only applicable to the LPC layer
* Parameters:
* `[in]` `x` `int`: FEC flag, 0 (disabled) is default
*/
/* Enable in-band forward error correction in codec */
status = opus_encoder_ctl(rc, OPUS_SET_INBAND_FEC(1));
if (status != OPUS_OK) {
LOGGER_ERROR(log, "Error while setting encoder ctl: %s", opus_strerror(status));
goto FAILURE;
}
/*
* Configures the encoder's expected packet loss percentage.
* Higher values with trigger progressively more loss resistant behavior in
* the encoder at the expense of quality at a given bitrate in the lossless case,
* but greater quality under loss.
* Parameters:
* `[in]` `x` `int`: Loss percentage in the range 0-100, inclusive.
*/
/* Make codec resistant to up to 10% packet loss
* NOTE This could also be adjusted on the fly, rather than hard-coded,
* with feedback from the receiving client.
*/
status = opus_encoder_ctl(rc, OPUS_SET_PACKET_LOSS_PERC(AUDIO_OPUS_PACKET_LOSS_PERC));
if (status != OPUS_OK) {
LOGGER_ERROR(log, "Error while setting encoder ctl: %s", opus_strerror(status));
goto FAILURE;
}
/*
* Configures the encoder's computational complexity.
*
* The supported range is 0-10 inclusive with 10 representing the highest complexity.
* The default value is 10.
*
* Parameters:
* `[in]` `x` `int`: 0-10, inclusive
*/
/* Set algorithm to the highest complexity, maximizing compression */
status = opus_encoder_ctl(rc, OPUS_SET_COMPLEXITY(AUDIO_OPUS_COMPLEXITY));
if (status != OPUS_OK) {
LOGGER_ERROR(log, "Error while setting encoder ctl: %s", opus_strerror(status));
goto FAILURE;
}
return rc;
FAILURE:
opus_encoder_destroy(rc);
return nullptr;
}
static bool reconfigure_audio_encoder(const Logger *log, OpusEncoder **e, int32_t new_br, int32_t new_sr,
uint8_t new_ch, int32_t *old_br, int32_t *old_sr, int32_t *old_ch)
{
/* Values are checked in toxav.c */
if (*old_sr != new_sr || *old_ch != new_ch) {
OpusEncoder *new_encoder = create_audio_encoder(log, new_br, new_sr, new_ch);
if (new_encoder == nullptr) {
return false;
}
opus_encoder_destroy(*e);
*e = new_encoder;
} else if (*old_br == new_br) {
return true; /* Nothing changed */
}
int status = opus_encoder_ctl(*e, OPUS_SET_BITRATE(new_br));
if (status != OPUS_OK) {
LOGGER_ERROR(log, "Error while setting encoder ctl: %s", opus_strerror(status));
return false;
}
*old_br = new_br;
*old_sr = new_sr;
*old_ch = new_ch;
LOGGER_DEBUG(log, "Reconfigured audio encoder br: %d sr: %d cc:%d", new_br, new_sr, new_ch);
return true;
}
static bool reconfigure_audio_decoder(ACSession *ac, int32_t sampling_rate, int8_t channels)
{
if (sampling_rate != ac->ld_sample_rate || channels != ac->ld_channel_count) {
if (current_time_monotonic(ac->mono_time) - ac->ldrts < 500) {
return false;
}
int status;
OpusDecoder *new_dec = opus_decoder_create(sampling_rate, channels, &status);
if (status != OPUS_OK) {
LOGGER_ERROR(ac->log, "Error while starting audio decoder(%d %d): %s", sampling_rate, channels, opus_strerror(status));
return false;
}
ac->ld_sample_rate = sampling_rate;
ac->ld_channel_count = channels;
ac->ldrts = current_time_monotonic(ac->mono_time);
opus_decoder_destroy(ac->decoder);
ac->decoder = new_dec;
LOGGER_DEBUG(ac->log, "Reconfigured audio decoder sr: %d cc: %d", sampling_rate, channels);
}
return true;
}
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