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FFmpeg/libavcodec/aptx.c
Aurelien Jacobs a337b36b8b aptx: implement the aptX bluetooth codec
The encoder was reverse engineered from binary library and from
EP0398973B1 patent (long expired).
The decoder was simply deduced from the encoder.
2017-11-10 21:32:06 +00:00

861 lines
31 KiB
C

/*
* Audio Processing Technology codec for Bluetooth (aptX)
*
* Copyright (C) 2017 Aurelien Jacobs <aurel@gnuage.org>
*
* This file is part of FFmpeg.
*
* FFmpeg 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.
*
* FFmpeg is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with FFmpeg; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include "libavutil/intreadwrite.h"
#include "avcodec.h"
#include "internal.h"
#include "mathops.h"
#include "audio_frame_queue.h"
enum channels {
LEFT,
RIGHT,
NB_CHANNELS
};
enum subbands {
LF, // Low Frequency (0-5.5 kHz)
MLF, // Medium-Low Frequency (5.5-11kHz)
MHF, // Medium-High Frequency (11-16.5kHz)
HF, // High Frequency (16.5-22kHz)
NB_SUBBANDS
};
#define NB_FILTERS 2
#define FILTER_TAPS 16
typedef struct {
int pos;
int32_t buffer[2*FILTER_TAPS];
} FilterSignal;
typedef struct {
FilterSignal outer_filter_signal[NB_FILTERS];
FilterSignal inner_filter_signal[NB_FILTERS][NB_FILTERS];
} QMFAnalysis;
typedef struct {
int32_t quantized_sample;
int32_t quantized_sample_parity_change;
int32_t error;
} Quantize;
typedef struct {
int32_t quantization_factor;
int32_t factor_select;
int32_t reconstructed_difference;
} InvertQuantize;
typedef struct {
int32_t prev_sign[2];
int32_t s_weight[2];
int32_t d_weight[24];
int32_t pos;
int32_t reconstructed_differences[48];
int32_t previous_reconstructed_sample;
int32_t predicted_difference;
int32_t predicted_sample;
} Prediction;
typedef struct {
int32_t codeword_history;
int32_t dither_parity;
int32_t dither[NB_SUBBANDS];
QMFAnalysis qmf;
Quantize quantize[NB_SUBBANDS];
InvertQuantize invert_quantize[NB_SUBBANDS];
Prediction prediction[NB_SUBBANDS];
} Channel;
typedef struct {
int32_t sync_idx;
Channel channels[NB_CHANNELS];
AudioFrameQueue afq;
} AptXContext;
static const int32_t quantize_intervals_LF[65] = {
-9948, 9948, 29860, 49808, 69822, 89926, 110144, 130502,
151026, 171738, 192666, 213832, 235264, 256982, 279014, 301384,
324118, 347244, 370790, 394782, 419250, 444226, 469742, 495832,
522536, 549890, 577936, 606720, 636290, 666700, 698006, 730270,
763562, 797958, 833538, 870398, 908640, 948376, 989740, 1032874,
1077948, 1125150, 1174700, 1226850, 1281900, 1340196, 1402156, 1468282,
1539182, 1615610, 1698514, 1789098, 1888944, 2000168, 2125700, 2269750,
2438670, 2642660, 2899462, 3243240, 3746078, 4535138, 5664098, 7102424,
8897462,
};
static const int32_t invert_quantize_dither_factors_LF[65] = {
9948, 9948, 9962, 9988, 10026, 10078, 10142, 10218,
10306, 10408, 10520, 10646, 10784, 10934, 11098, 11274,
11462, 11664, 11880, 12112, 12358, 12618, 12898, 13194,
13510, 13844, 14202, 14582, 14988, 15422, 15884, 16380,
16912, 17484, 18098, 18762, 19480, 20258, 21106, 22030,
23044, 24158, 25390, 26760, 28290, 30008, 31954, 34172,
36728, 39700, 43202, 47382, 52462, 58762, 66770, 77280,
91642, 112348, 144452, 199326, 303512, 485546, 643414, 794914,
1000124,
};
static const int32_t quantize_dither_factors_LF[65] = {
0, 4, 7, 10, 13, 16, 19, 22,
26, 28, 32, 35, 38, 41, 44, 47,
51, 54, 58, 62, 65, 70, 74, 79,
84, 90, 95, 102, 109, 116, 124, 133,
143, 154, 166, 180, 195, 212, 231, 254,
279, 308, 343, 383, 430, 487, 555, 639,
743, 876, 1045, 1270, 1575, 2002, 2628, 3591,
5177, 8026, 13719, 26047, 45509, 39467, 37875, 51303,
0,
};
static const int16_t quantize_factor_select_offset_LF[65] = {
0, -21, -19, -17, -15, -12, -10, -8,
-6, -4, -1, 1, 3, 6, 8, 10,
13, 15, 18, 20, 23, 26, 29, 31,
34, 37, 40, 43, 47, 50, 53, 57,
60, 64, 68, 72, 76, 80, 85, 89,
94, 99, 105, 110, 116, 123, 129, 136,
144, 152, 161, 171, 182, 194, 207, 223,
241, 263, 291, 328, 382, 467, 522, 522,
522,
};
static const int32_t quantize_intervals_MLF[9] = {
-89806, 89806, 278502, 494338, 759442, 1113112, 1652322, 2720256, 5190186,
};
static const int32_t invert_quantize_dither_factors_MLF[9] = {
89806, 89806, 98890, 116946, 148158, 205512, 333698, 734236, 1735696,
};
static const int32_t quantize_dither_factors_MLF[9] = {
0, 2271, 4514, 7803, 14339, 32047, 100135, 250365, 0,
};
static const int16_t quantize_factor_select_offset_MLF[9] = {
0, -14, 6, 29, 58, 96, 154, 270, 521,
};
static const int32_t quantize_intervals_MHF[3] = {
-194080, 194080, 890562,
};
static const int32_t invert_quantize_dither_factors_MHF[3] = {
194080, 194080, 502402,
};
static const int32_t quantize_dither_factors_MHF[3] = {
0, 77081, 0,
};
static const int16_t quantize_factor_select_offset_MHF[3] = {
0, -33, 136,
};
static const int32_t quantize_intervals_HF[5] = {
-163006, 163006, 542708, 1120554, 2669238,
};
static const int32_t invert_quantize_dither_factors_HF[5] = {
163006, 163006, 216698, 361148, 1187538,
};
static const int32_t quantize_dither_factors_HF[5] = {
0, 13423, 36113, 206598, 0,
};
static const int16_t quantize_factor_select_offset_HF[5] = {
0, -8, 33, 95, 262,
};
typedef const struct {
const int32_t *quantize_intervals;
const int32_t *invert_quantize_dither_factors;
const int32_t *quantize_dither_factors;
const int16_t *quantize_factor_select_offset;
int tables_size;
int32_t quantized_bits;
int32_t prediction_order;
} ConstTables;
static ConstTables tables[NB_SUBBANDS] = {
[LF] = { quantize_intervals_LF,
invert_quantize_dither_factors_LF,
quantize_dither_factors_LF,
quantize_factor_select_offset_LF,
FF_ARRAY_ELEMS(quantize_intervals_LF),
7, 24 },
[MLF] = { quantize_intervals_MLF,
invert_quantize_dither_factors_MLF,
quantize_dither_factors_MLF,
quantize_factor_select_offset_MLF,
FF_ARRAY_ELEMS(quantize_intervals_MLF),
4, 12 },
[MHF] = { quantize_intervals_MHF,
invert_quantize_dither_factors_MHF,
quantize_dither_factors_MHF,
quantize_factor_select_offset_MHF,
FF_ARRAY_ELEMS(quantize_intervals_MHF),
2, 6 },
[HF] = { quantize_intervals_HF,
invert_quantize_dither_factors_HF,
quantize_dither_factors_HF,
quantize_factor_select_offset_HF,
FF_ARRAY_ELEMS(quantize_intervals_HF),
3, 12 },
};
static const int16_t quantization_factors[32] = {
2048, 2093, 2139, 2186, 2233, 2282, 2332, 2383,
2435, 2489, 2543, 2599, 2656, 2714, 2774, 2834,
2896, 2960, 3025, 3091, 3158, 3228, 3298, 3371,
3444, 3520, 3597, 3676, 3756, 3838, 3922, 4008,
};
/* Rounded right shift with optionnal clipping */
#define RSHIFT_SIZE(size) \
av_always_inline \
static int##size##_t rshift##size(int##size##_t value, int shift) \
{ \
int##size##_t rounding = (int##size##_t)1 << (shift - 1); \
int##size##_t mask = ((int##size##_t)1 << (shift + 1)) - 1; \
return ((value + rounding) >> shift) - ((value & mask) == rounding); \
} \
av_always_inline \
static int##size##_t rshift##size##_clip24(int##size##_t value, int shift) \
{ \
return av_clip_intp2(rshift##size(value, shift), 23); \
}
RSHIFT_SIZE(32)
RSHIFT_SIZE(64)
av_always_inline
static void aptx_update_codeword_history(Channel *channel)
{
int32_t cw = ((channel->quantize[0].quantized_sample & 3) << 0) +
((channel->quantize[1].quantized_sample & 2) << 1) +
((channel->quantize[2].quantized_sample & 1) << 3);
channel->codeword_history = (cw << 8) + (channel->codeword_history << 4);
}
static void aptx_generate_dither(Channel *channel)
{
int subband;
int64_t m;
int32_t d;
aptx_update_codeword_history(channel);
m = (int64_t)5184443 * (channel->codeword_history >> 7);
d = (m << 2) + (m >> 22);
for (subband = 0; subband < NB_SUBBANDS; subband++)
channel->dither[subband] = d << (23 - 5*subband);
channel->dither_parity = (d >> 25) & 1;
}
/*
* Convolution filter coefficients for the outer QMF of the QMF tree.
* The 2 sets are a mirror of each other.
*/
static const int32_t aptx_qmf_outer_coeffs[NB_FILTERS][FILTER_TAPS] = {
{
730, -413, -9611, 43626, -121026, 269973, -585547, 2801966,
697128, -160481, 27611, 8478, -10043, 3511, 688, -897,
},
{
-897, 688, 3511, -10043, 8478, 27611, -160481, 697128,
2801966, -585547, 269973, -121026, 43626, -9611, -413, 730,
},
};
/*
* Convolution filter coefficients for the inner QMF of the QMF tree.
* The 2 sets are a mirror of each other.
*/
static const int32_t aptx_qmf_inner_coeffs[NB_FILTERS][FILTER_TAPS] = {
{
1033, -584, -13592, 61697, -171156, 381799, -828088, 3962579,
985888, -226954, 39048, 11990, -14203, 4966, 973, -1268,
},
{
-1268, 973, 4966, -14203, 11990, 39048, -226954, 985888,
3962579, -828088, 381799, -171156, 61697, -13592, -584, 1033,
},
};
/*
* Push one sample into a circular signal buffer.
*/
av_always_inline
static void aptx_qmf_filter_signal_push(FilterSignal *signal, int32_t sample)
{
signal->buffer[signal->pos ] = sample;
signal->buffer[signal->pos+FILTER_TAPS] = sample;
signal->pos = (signal->pos + 1) & (FILTER_TAPS - 1);
}
/*
* Compute the convolution of the signal with the coefficients, and reduce
* to 24 bits by applying the specified right shifting.
*/
av_always_inline
static int32_t aptx_qmf_convolution(FilterSignal *signal,
const int32_t coeffs[FILTER_TAPS],
int shift)
{
int32_t *sig = &signal->buffer[signal->pos];
int64_t e = 0;
int i;
for (i = 0; i < FILTER_TAPS; i++)
e += MUL64(sig[i], coeffs[i]);
return rshift64_clip24(e, shift);
}
/*
* Half-band QMF analysis filter realized with a polyphase FIR filter.
* Split into 2 subbands and downsample by 2.
* So for each pair of samples that goes in, one sample goes out,
* split into 2 separate subbands.
*/
av_always_inline
static void aptx_qmf_polyphase_analysis(FilterSignal signal[NB_FILTERS],
const int32_t coeffs[NB_FILTERS][FILTER_TAPS],
int shift,
int32_t samples[NB_FILTERS],
int32_t *low_subband_output,
int32_t *high_subband_output)
{
int32_t subbands[NB_FILTERS];
int i;
for (i = 0; i < NB_FILTERS; i++) {
aptx_qmf_filter_signal_push(&signal[i], samples[NB_FILTERS-1-i]);
subbands[i] = aptx_qmf_convolution(&signal[i], coeffs[i], shift);
}
*low_subband_output = av_clip_intp2(subbands[0] + subbands[1], 23);
*high_subband_output = av_clip_intp2(subbands[0] - subbands[1], 23);
}
/*
* Two stage QMF analysis tree.
* Split 4 input samples into 4 subbands and downsample by 4.
* So for each group of 4 samples that goes in, one sample goes out,
* split into 4 separate subbands.
*/
static void aptx_qmf_tree_analysis(QMFAnalysis *qmf,
int32_t samples[4],
int32_t subband_samples[4])
{
int32_t intermediate_samples[4];
int i;
/* Split 4 input samples into 2 intermediate subbands downsampled to 2 samples */
for (i = 0; i < 2; i++)
aptx_qmf_polyphase_analysis(qmf->outer_filter_signal,
aptx_qmf_outer_coeffs, 23,
&samples[2*i],
&intermediate_samples[0+i],
&intermediate_samples[2+i]);
/* Split 2 intermediate subband samples into 4 final subbands downsampled to 1 sample */
for (i = 0; i < 2; i++)
aptx_qmf_polyphase_analysis(qmf->inner_filter_signal[i],
aptx_qmf_inner_coeffs, 23,
&intermediate_samples[2*i],
&subband_samples[2*i+0],
&subband_samples[2*i+1]);
}
/*
* Half-band QMF synthesis filter realized with a polyphase FIR filter.
* Join 2 subbands and upsample by 2.
* So for each 2 subbands sample that goes in, a pair of samples goes out.
*/
av_always_inline
static void aptx_qmf_polyphase_synthesis(FilterSignal signal[NB_FILTERS],
const int32_t coeffs[NB_FILTERS][FILTER_TAPS],
int shift,
int32_t low_subband_input,
int32_t high_subband_input,
int32_t samples[NB_FILTERS])
{
int32_t subbands[NB_FILTERS];
int i;
subbands[0] = low_subband_input + high_subband_input;
subbands[1] = low_subband_input - high_subband_input;
for (i = 0; i < NB_FILTERS; i++) {
aptx_qmf_filter_signal_push(&signal[i], subbands[1-i]);
samples[i] = aptx_qmf_convolution(&signal[i], coeffs[i], shift);
}
}
/*
* Two stage QMF synthesis tree.
* Join 4 subbands and upsample by 4.
* So for each 4 subbands sample that goes in, a group of 4 samples goes out.
*/
static void aptx_qmf_tree_synthesis(QMFAnalysis *qmf,
int32_t subband_samples[4],
int32_t samples[4])
{
int32_t intermediate_samples[4];
int i;
/* Join 4 subbands into 2 intermediate subbands upsampled to 2 samples. */
for (i = 0; i < 2; i++)
aptx_qmf_polyphase_synthesis(qmf->inner_filter_signal[i],
aptx_qmf_inner_coeffs, 22,
subband_samples[2*i+0],
subband_samples[2*i+1],
&intermediate_samples[2*i]);
/* Join 2 samples from intermediate subbands upsampled to 4 samples. */
for (i = 0; i < 2; i++)
aptx_qmf_polyphase_synthesis(qmf->outer_filter_signal,
aptx_qmf_outer_coeffs, 21,
intermediate_samples[0+i],
intermediate_samples[2+i],
&samples[2*i]);
}
av_always_inline
static int32_t aptx_bin_search(int32_t value, int32_t factor,
const int32_t *intervals, int32_t nb_intervals)
{
int32_t idx = 0;
int i;
for (i = nb_intervals >> 1; i > 0; i >>= 1)
if (MUL64(factor, intervals[idx + i]) <= ((int64_t)value << 24))
idx += i;
return idx;
}
static void aptx_quantize_difference(Quantize *quantize,
int32_t sample_difference,
int32_t dither,
int32_t quantization_factor,
ConstTables *tables)
{
const int32_t *intervals = tables->quantize_intervals;
int32_t quantized_sample, dithered_sample, parity_change;
int32_t d, mean, interval, inv;
int64_t error;
quantized_sample = aptx_bin_search(FFABS(sample_difference) >> 4,
quantization_factor,
intervals, tables->tables_size);
d = rshift32_clip24(MULH(dither, dither), 7) - (1 << 23);
d = rshift64(MUL64(d, tables->quantize_dither_factors[quantized_sample]), 23);
intervals += quantized_sample;
mean = (intervals[1] + intervals[0]) / 2;
interval = (intervals[1] - intervals[0]) * (-(sample_difference < 0) | 1);
dithered_sample = rshift64_clip24(MUL64(dither, interval) + ((int64_t)(mean + d) << 32), 32);
error = ((int64_t)FFABS(sample_difference) << 20) - MUL64(dithered_sample, quantization_factor);
quantize->error = FFABS(rshift64(error, 23));
parity_change = quantized_sample;
if (error < 0)
quantized_sample--;
else
parity_change--;
inv = -(sample_difference < 0);
quantize->quantized_sample = quantized_sample ^ inv;
quantize->quantized_sample_parity_change = parity_change ^ inv;
}
static void aptx_encode_channel(Channel *channel, int32_t samples[4])
{
int32_t subband_samples[4];
int subband;
aptx_qmf_tree_analysis(&channel->qmf, samples, subband_samples);
aptx_generate_dither(channel);
for (subband = 0; subband < NB_SUBBANDS; subband++) {
int32_t diff = av_clip_intp2(subband_samples[subband] - channel->prediction[subband].predicted_sample, 23);
aptx_quantize_difference(&channel->quantize[subband], diff,
channel->dither[subband],
channel->invert_quantize[subband].quantization_factor,
&tables[subband]);
}
}
static void aptx_decode_channel(Channel *channel, int32_t samples[4])
{
int32_t subband_samples[4];
int subband;
for (subband = 0; subband < NB_SUBBANDS; subband++)
subband_samples[subband] = channel->prediction[subband].previous_reconstructed_sample;
aptx_qmf_tree_synthesis(&channel->qmf, subband_samples, samples);
}
static void aptx_invert_quantization(InvertQuantize *invert_quantize,
int32_t quantized_sample, int32_t dither,
ConstTables *tables)
{
int32_t qr, idx, shift, factor_select;
idx = (quantized_sample ^ -(quantized_sample < 0)) + 1;
qr = tables->quantize_intervals[idx] / 2;
if (quantized_sample < 0)
qr = -qr;
qr = rshift64_clip24(((int64_t)qr<<32) + MUL64(dither, tables->invert_quantize_dither_factors[idx]), 32);
invert_quantize->reconstructed_difference = MUL64(invert_quantize->quantization_factor, qr) >> 19;
shift = 24 - tables->quantized_bits;
/* update factor_select */
factor_select = 32620 * invert_quantize->factor_select;
factor_select = rshift32(factor_select + (tables->quantize_factor_select_offset[idx] << 15), 15);
invert_quantize->factor_select = av_clip(factor_select, 0, (shift << 8) | 0xFF);
/* update quantization factor */
idx = (invert_quantize->factor_select & 0xFF) >> 3;
shift -= invert_quantize->factor_select >> 8;
invert_quantize->quantization_factor = (quantization_factors[idx] << 11) >> shift;
}
static int32_t *aptx_reconstructed_differences_update(Prediction *prediction,
int32_t reconstructed_difference,
int order)
{
int32_t *rd1 = prediction->reconstructed_differences, *rd2 = rd1 + order;
int p = prediction->pos;
rd1[p] = rd2[p];
prediction->pos = p = (p + 1) % order;
rd2[p] = reconstructed_difference;
return &rd2[p];
}
static void aptx_prediction_filtering(Prediction *prediction,
int32_t reconstructed_difference,
int order)
{
int32_t reconstructed_sample, predictor, srd0;
int32_t *reconstructed_differences;
int64_t predicted_difference = 0;
int i;
reconstructed_sample = av_clip_intp2(reconstructed_difference + prediction->predicted_sample, 23);
predictor = av_clip_intp2((MUL64(prediction->s_weight[0], prediction->previous_reconstructed_sample)
+ MUL64(prediction->s_weight[1], reconstructed_sample)) >> 22, 23);
prediction->previous_reconstructed_sample = reconstructed_sample;
reconstructed_differences = aptx_reconstructed_differences_update(prediction, reconstructed_difference, order);
srd0 = FFDIFFSIGN(reconstructed_difference, 0) << 23;
for (i = 0; i < order; i++) {
int32_t srd = FF_SIGNBIT(reconstructed_differences[-i-1]) | 1;
prediction->d_weight[i] -= rshift32(prediction->d_weight[i] - srd*srd0, 8);
predicted_difference += MUL64(reconstructed_differences[-i], prediction->d_weight[i]);
}
prediction->predicted_difference = av_clip_intp2(predicted_difference >> 22, 23);
prediction->predicted_sample = av_clip_intp2(predictor + prediction->predicted_difference, 23);
}
static void aptx_process_subband(InvertQuantize *invert_quantize,
Prediction *prediction,
int32_t quantized_sample, int32_t dither,
ConstTables *tables)
{
int32_t sign, same_sign[2], weight[2], sw1, range;
aptx_invert_quantization(invert_quantize, quantized_sample, dither, tables);
sign = FFDIFFSIGN(invert_quantize->reconstructed_difference,
-prediction->predicted_difference);
same_sign[0] = sign * prediction->prev_sign[0];
same_sign[1] = sign * prediction->prev_sign[1];
prediction->prev_sign[0] = prediction->prev_sign[1];
prediction->prev_sign[1] = sign | 1;
range = 0x100000;
sw1 = rshift32(-same_sign[1] * prediction->s_weight[1], 1);
sw1 = (av_clip(sw1, -range, range) & ~0xF) << 4;
range = 0x300000;
weight[0] = 254 * prediction->s_weight[0] + 0x800000*same_sign[0] + sw1;
prediction->s_weight[0] = av_clip(rshift32(weight[0], 8), -range, range);
range = 0x3C0000 - prediction->s_weight[0];
weight[1] = 255 * prediction->s_weight[1] + 0xC00000*same_sign[1];
prediction->s_weight[1] = av_clip(rshift32(weight[1], 8), -range, range);
aptx_prediction_filtering(prediction,
invert_quantize->reconstructed_difference,
tables->prediction_order);
}
static void aptx_invert_quantize_and_prediction(Channel *channel)
{
int subband;
for (subband = 0; subband < NB_SUBBANDS; subband++)
aptx_process_subband(&channel->invert_quantize[subband],
&channel->prediction[subband],
channel->quantize[subband].quantized_sample,
channel->dither[subband],
&tables[subband]);
}
static int32_t aptx_quantized_parity(Channel *channel)
{
int32_t parity = channel->dither_parity;
int subband;
for (subband = 0; subband < NB_SUBBANDS; subband++)
parity ^= channel->quantize[subband].quantized_sample;
return parity & 1;
}
/* For each sample, ensure that the parity of all subbands of all channels
* is 0 except once every 8 samples where the parity is forced to 1. */
static int aptx_check_parity(Channel channels[NB_CHANNELS], int32_t *idx)
{
int32_t parity = aptx_quantized_parity(&channels[LEFT])
^ aptx_quantized_parity(&channels[RIGHT]);
int eighth = *idx == 7;
*idx = (*idx + 1) & 7;
return parity ^ eighth;
}
static void aptx_insert_sync(Channel channels[NB_CHANNELS], int32_t *idx)
{
if (aptx_check_parity(channels, idx)) {
int i;
Channel *c;
static const int map[] = { 1, 2, 0, 3 };
Quantize *min = &channels[NB_CHANNELS-1].quantize[map[0]];
for (c = &channels[NB_CHANNELS-1]; c >= channels; c--)
for (i = 0; i < NB_SUBBANDS; i++)
if (c->quantize[map[i]].error < min->error)
min = &c->quantize[map[i]];
/* Forcing the desired parity is done by offsetting by 1 the quantized
* sample from the subband featuring the smallest quantization error. */
min->quantized_sample = min->quantized_sample_parity_change;
}
}
static uint16_t aptx_pack_codeword(Channel *channel)
{
int32_t parity = aptx_quantized_parity(channel);
return (((channel->quantize[3].quantized_sample & 0x06) | parity) << 13)
| (((channel->quantize[2].quantized_sample & 0x03) ) << 11)
| (((channel->quantize[1].quantized_sample & 0x0F) ) << 7)
| (((channel->quantize[0].quantized_sample & 0x7F) ) << 0);
}
static void aptx_unpack_codeword(Channel *channel, uint16_t codeword)
{
channel->quantize[0].quantized_sample = sign_extend(codeword >> 0, 7);
channel->quantize[1].quantized_sample = sign_extend(codeword >> 7, 4);
channel->quantize[2].quantized_sample = sign_extend(codeword >> 11, 2);
channel->quantize[3].quantized_sample = sign_extend(codeword >> 13, 3);
channel->quantize[3].quantized_sample = (channel->quantize[3].quantized_sample & ~1)
| aptx_quantized_parity(channel);
}
static void aptx_encode_samples(AptXContext *ctx,
int32_t samples[NB_CHANNELS][4],
uint8_t output[2*NB_CHANNELS])
{
int channel;
for (channel = 0; channel < NB_CHANNELS; channel++)
aptx_encode_channel(&ctx->channels[channel], samples[channel]);
aptx_insert_sync(ctx->channels, &ctx->sync_idx);
for (channel = 0; channel < NB_CHANNELS; channel++) {
aptx_invert_quantize_and_prediction(&ctx->channels[channel]);
AV_WB16(output + 2*channel, aptx_pack_codeword(&ctx->channels[channel]));
}
}
static int aptx_decode_samples(AptXContext *ctx,
const uint8_t input[2*NB_CHANNELS],
int32_t samples[NB_CHANNELS][4])
{
int channel, ret;
for (channel = 0; channel < NB_CHANNELS; channel++) {
uint16_t codeword;
aptx_generate_dither(&ctx->channels[channel]);
codeword = AV_RB16(input + 2*channel);
aptx_unpack_codeword(&ctx->channels[channel], codeword);
aptx_invert_quantize_and_prediction(&ctx->channels[channel]);
}
ret = aptx_check_parity(ctx->channels, &ctx->sync_idx);
for (channel = 0; channel < NB_CHANNELS; channel++)
aptx_decode_channel(&ctx->channels[channel], samples[channel]);
return ret;
}
static av_cold int aptx_init(AVCodecContext *avctx)
{
AptXContext *s = avctx->priv_data;
int chan, subband;
if (avctx->frame_size == 0)
avctx->frame_size = 1024;
if (avctx->frame_size & 3) {
av_log(avctx, AV_LOG_ERROR, "Frame size must be a multiple of 4 samples\n");
return AVERROR(EINVAL);
}
for (chan = 0; chan < NB_CHANNELS; chan++) {
Channel *channel = &s->channels[chan];
for (subband = 0; subband < NB_SUBBANDS; subband++) {
Prediction *prediction = &channel->prediction[subband];
prediction->prev_sign[0] = 1;
prediction->prev_sign[1] = 1;
}
}
ff_af_queue_init(avctx, &s->afq);
return 0;
}
static int aptx_decode_frame(AVCodecContext *avctx, void *data,
int *got_frame_ptr, AVPacket *avpkt)
{
AptXContext *s = avctx->priv_data;
AVFrame *frame = data;
int pos, channel, sample, ret;
if (avpkt->size < 4) {
av_log(avctx, AV_LOG_ERROR, "Packet is too small\n");
return AVERROR_INVALIDDATA;
}
/* get output buffer */
frame->channels = NB_CHANNELS;
frame->format = AV_SAMPLE_FMT_S32P;
frame->nb_samples = avpkt->size & ~3;
if ((ret = ff_get_buffer(avctx, frame, 0)) < 0)
return ret;
for (pos = 0; pos < frame->nb_samples; pos += 4) {
int32_t samples[NB_CHANNELS][4];
if (aptx_decode_samples(s, &avpkt->data[pos], samples)) {
av_log(avctx, AV_LOG_ERROR, "Synchronization error\n");
return AVERROR_INVALIDDATA;
}
for (channel = 0; channel < NB_CHANNELS; channel++)
for (sample = 0; sample < 4; sample++)
AV_WN32A(&frame->data[channel][4*(sample+pos)],
samples[channel][sample] << 8);
}
*got_frame_ptr = 1;
return frame->nb_samples;
}
static int aptx_encode_frame(AVCodecContext *avctx, AVPacket *avpkt,
const AVFrame *frame, int *got_packet_ptr)
{
AptXContext *s = avctx->priv_data;
int pos, channel, sample, ret;
if ((ret = ff_af_queue_add(&s->afq, frame)) < 0)
return ret;
if ((ret = ff_alloc_packet2(avctx, avpkt, frame->nb_samples, 0)) < 0)
return ret;
for (pos = 0; pos < frame->nb_samples; pos += 4) {
int32_t samples[NB_CHANNELS][4];
for (channel = 0; channel < NB_CHANNELS; channel++)
for (sample = 0; sample < 4; sample++)
samples[channel][sample] = (int32_t)AV_RN32A(&frame->data[channel][4*(sample+pos)]) >> 8;
aptx_encode_samples(s, samples, avpkt->data + pos);
}
ff_af_queue_remove(&s->afq, frame->nb_samples, &avpkt->pts, &avpkt->duration);
*got_packet_ptr = 1;
return 0;
}
static av_cold int aptx_close(AVCodecContext *avctx)
{
AptXContext *s = avctx->priv_data;
ff_af_queue_close(&s->afq);
return 0;
}
#if CONFIG_APTX_DECODER
AVCodec ff_aptx_decoder = {
.name = "aptx",
.long_name = NULL_IF_CONFIG_SMALL("aptX (Audio Processing Technology for Bluetooth)"),
.type = AVMEDIA_TYPE_AUDIO,
.id = AV_CODEC_ID_APTX,
.priv_data_size = sizeof(AptXContext),
.init = aptx_init,
.decode = aptx_decode_frame,
.close = aptx_close,
.capabilities = AV_CODEC_CAP_DR1,
.channel_layouts = (const uint64_t[]) { AV_CH_LAYOUT_STEREO, 0},
.sample_fmts = (const enum AVSampleFormat[]) { AV_SAMPLE_FMT_S32P,
AV_SAMPLE_FMT_NONE },
};
#endif
#if CONFIG_APTX_ENCODER
AVCodec ff_aptx_encoder = {
.name = "aptx",
.long_name = NULL_IF_CONFIG_SMALL("aptX (Audio Processing Technology for Bluetooth)"),
.type = AVMEDIA_TYPE_AUDIO,
.id = AV_CODEC_ID_APTX,
.priv_data_size = sizeof(AptXContext),
.init = aptx_init,
.encode2 = aptx_encode_frame,
.close = aptx_close,
.channel_layouts = (const uint64_t[]) { AV_CH_LAYOUT_STEREO, 0},
.sample_fmts = (const enum AVSampleFormat[]) { AV_SAMPLE_FMT_S32P,
AV_SAMPLE_FMT_NONE },
.supported_samplerates = (const int[]) {8000, 16000, 24000, 32000, 44100, 48000, 0},
};
#endif