avcodec/dcaenc: Initial implementation of ADPCM encoding for DCA encoder

8 years ago · b8c2b9c392
--- a/libavcodec/Makefile
+++ b/libavcodec/Makefile
@@ -244,7 +244,8 @@ OBJS-$(CONFIG_CYUV_DECODER)            += cyuv.o
 OBJS-$(CONFIG_DCA_DECODER)             += dcadec.o dca.o dcadata.o dcahuff.o \
                                          dca_core.o dca_exss.o dca_xll.o dca_lbr.o \
                                          dcadsp.o dcadct.o synth_filter.o
 OBJS-$(CONFIG_DCA_ENCODER)             += dcaenc.o dca.o dcadata.o dcahuff.o
 OBJS-$(CONFIG_DCA_ENCODER)             += dcaenc.o dca.o dcadata.o dcahuff.o \
                                          dcaadpcm.o
 OBJS-$(CONFIG_DDS_DECODER)             += dds.o
 OBJS-$(CONFIG_DIRAC_DECODER)           += diracdec.o dirac.o diracdsp.o diractab.o \
                                          dirac_arith.o dirac_dwt.o dirac_vlc.o
--- a/libavcodec/dca_core.c
+++ b/libavcodec/dca_core.c
@@ -18,6 +18,7 @@
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
 */
 #include "dcaadpcm.h"
 #include "dcadec.h"
 #include "dcadata.h"
 #include "dcahuff.h"
@@ -670,46 +671,21 @@ static inline int extract_audio(DCACoreDecoder *s, int32_t *audio, int abits, in
    return 0;
 }
 static inline void dequantize(int32_t *output, const int32_t *input,
                              int32_t step_size, int32_t scale, int residual)
 {
    // Account for quantizer step size
    int64_t step_scale = (int64_t)step_size * scale;
    int n, shift = 0;
    // Limit scale factor resolution to 22 bits
    if (step_scale > (1 << 23)) {
        shift = av_log2(step_scale >> 23) + 1;
        step_scale >>= shift;
    }
    // Scale the samples
    if (residual) {
        for (n = 0; n < DCA_SUBBAND_SAMPLES; n++)
            output[n] += clip23(norm__(input[n] * step_scale, 22 - shift));
    } else {
        for (n = 0; n < DCA_SUBBAND_SAMPLES; n++)
            output[n]  = clip23(norm__(input[n] * step_scale, 22 - shift));
    }
 }
 static inline void inverse_adpcm(int32_t **subband_samples,
                                 const int16_t *vq_index,
                                 const int8_t *prediction_mode,
                                 int sb_start, int sb_end,
                                 int ofs, int len)
 {
    int i, j, k;
    int i, j;
    for (i = sb_start; i < sb_end; i++) {
        if (prediction_mode[i]) {
            const int16_t *coeff = ff_dca_adpcm_vb[vq_index[i]];
            const int pred_id = vq_index[i];
            int32_t *ptr = subband_samples[i] + ofs;
            for (j = 0; j < len; j++) {
                int64_t err = 0;
                for (k = 0; k < DCA_ADPCM_COEFFS; k++)
                    err += (int64_t)ptr[j - k - 1] * coeff[k];
                ptr[j] = clip23(ptr[j] + clip23(norm13(err)));
                int32_t x = ff_dcaadpcm_predict(pred_id, ptr + j - DCA_ADPCM_COEFFS);
                ptr[j] = clip23(ptr[j] + x);
            }
        }
    }
@@ -817,8 +793,8 @@ static int parse_subframe_audio(DCACoreDecoder *s, int sf, enum HeaderType heade
                    scale = clip23(adj * scale >> 22);
                }
                dequantize(s->subband_samples[ch][band] + ofs,
                           audio, step_size, scale, 0);
                ff_dca_core_dequantize(s->subband_samples[ch][band] + ofs,
                           audio, step_size, scale, 0, DCA_SUBBAND_SAMPLES);
            }
        }
@@ -1146,8 +1122,8 @@ static int parse_xbr_subframe(DCACoreDecoder *s, int xbr_base_ch, int xbr_nchann
                else
                    scale = xbr_scale_factors[ch][band][1];
                dequantize(s->subband_samples[ch][band] + ofs,
                           audio, step_size, scale, 1);
                ff_dca_core_dequantize(s->subband_samples[ch][band] + ofs,
                           audio, step_size, scale, 1, DCA_SUBBAND_SAMPLES);
            }
        }
@@ -1326,8 +1302,8 @@ static int parse_x96_subframe_audio(DCACoreDecoder *s, int sf, int xch_base, int
                // Get the scale factor
                scale = s->scale_factors[ch][band >> 1][band & 1];
                dequantize(s->x96_subband_samples[ch][band] + ofs,
                           audio, step_size, scale, 0);
                ff_dca_core_dequantize(s->x96_subband_samples[ch][band] + ofs,
                           audio, step_size, scale, 0, DCA_SUBBAND_SAMPLES);
            }
        }
--- a/libavcodec/dca_core.h
+++ b/libavcodec/dca_core.h
@@ -33,6 +33,7 @@
 #include "dca_exss.h"
 #include "dcadsp.h"
 #include "dcadct.h"
 #include "dcamath.h"
 #include "dcahuff.h"
 #include "fft.h"
 #include "synth_filter.h"
@@ -43,7 +44,6 @@
 #define DCA_SUBFRAMES           16
 #define DCA_SUBBAND_SAMPLES     8
 #define DCA_PCMBLOCK_SAMPLES    32
 #define DCA_ADPCM_COEFFS        4
 #define DCA_LFE_HISTORY         8
 #define DCA_ABITS_MAX           26
@@ -195,6 +195,29 @@ static inline int ff_dca_core_map_spkr(DCACoreDecoder *core, int spkr)
    return -1;
 }
 static inline void ff_dca_core_dequantize(int32_t *output, const int32_t *input,
                                          int32_t step_size, int32_t scale, int residual, int len)
 {
    // Account for quantizer step size
    int64_t step_scale = (int64_t)step_size * scale;
    int n, shift = 0;
    // Limit scale factor resolution to 22 bits
    if (step_scale > (1 << 23)) {
        shift = av_log2(step_scale >> 23) + 1;
        step_scale >>= shift;
    }
    // Scale the samples
    if (residual) {
        for (n = 0; n < len; n++)
            output[n] += clip23(norm__(input[n] * step_scale, 22 - shift));
    } else {
        for (n = 0; n < len; n++)
            output[n]  = clip23(norm__(input[n] * step_scale, 22 - shift));
    }
 }
 int ff_dca_core_parse(DCACoreDecoder *s, uint8_t *data, int size);
 int ff_dca_core_parse_exss(DCACoreDecoder *s, uint8_t *data, DCAExssAsset *asset);
 int ff_dca_core_filter_fixed(DCACoreDecoder *s, int x96_synth);
--- a/libavcodec/dcaadpcm.c
+++ b/libavcodec/dcaadpcm.c
@@ -0,0 +1,228 @@
 /*
 * DCA ADPCM engine
 * Copyright (C) 2017 Daniil Cherednik
 *
 * 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 "dcaadpcm.h"
 #include "dcaenc.h"
 #include "dca_core.h"
 #include "mathops.h"
 typedef int32_t premultiplied_coeffs[10];
 //assume we have DCA_ADPCM_COEFFS values before x
 static inline int64_t calc_corr(const int32_t *x, int len, int j, int k)
 {
    int n;
    int64_t s = 0;
    for (n = 0; n < len; n++)
        s += MUL64(x[n-j], x[n-k]);
    return s;
 }
 static inline int64_t apply_filter(const int16_t a[DCA_ADPCM_COEFFS], const int64_t corr[15], const int32_t aa[10])
 {
    int64_t err = 0;
    int64_t tmp = 0;
    err = corr[0];
    tmp += MUL64(a[0], corr[1]);
    tmp += MUL64(a[1], corr[2]);
    tmp += MUL64(a[2], corr[3]);
    tmp += MUL64(a[3], corr[4]);
    tmp = norm__(tmp, 13);
    tmp += tmp;
    err -= tmp;
    tmp = 0;
    tmp += MUL64(corr[5], aa[0]);
    tmp += MUL64(corr[6], aa[1]);
    tmp += MUL64(corr[7], aa[2]);
    tmp += MUL64(corr[8], aa[3]);
    tmp += MUL64(corr[9], aa[4]);
    tmp += MUL64(corr[10], aa[5]);
    tmp += MUL64(corr[11], aa[6]);
    tmp += MUL64(corr[12], aa[7]);
    tmp += MUL64(corr[13], aa[8]);
    tmp += MUL64(corr[14], aa[9]);
    tmp = norm__(tmp, 26);
    err += tmp;
    return llabs(err);
 }
 static int64_t find_best_filter(const DCAADPCMEncContext *s, const int32_t *in, int len)
 {
    const premultiplied_coeffs *precalc_data = s->private_data;
    int i, j, k = 0;
    int vq;
    int64_t err;
    int64_t min_err = 1ll << 62;
    int64_t corr[15];
    for (i = 0; i <= DCA_ADPCM_COEFFS; i++)
        for (j = i; j <= DCA_ADPCM_COEFFS; j++)
            corr[k++] = calc_corr(in+4, len, i, j);
    for (i = 0; i < DCA_ADPCM_VQCODEBOOK_SZ; i++) {
        err = apply_filter(ff_dca_adpcm_vb[i], corr, *precalc_data);
        if (err < min_err) {
            min_err = err;
            vq = i;
        }
        precalc_data++;
    }
    return vq;
 }
 static inline int64_t calc_prediction_gain(int pred_vq, const int32_t *in, int32_t *out, int len)
 {
    int i;
    int32_t error;
    int64_t signal_energy = 0;
    int64_t error_energy = 0;
    for (i = 0; i < len; i++) {
        error = in[DCA_ADPCM_COEFFS + i] - ff_dcaadpcm_predict(pred_vq, in + i);
        out[i] = error;
        signal_energy += MUL64(in[DCA_ADPCM_COEFFS + i], in[DCA_ADPCM_COEFFS + i]);
        error_energy += MUL64(error, error);
    }
    if (!error_energy)
        return -1;
    return signal_energy / error_energy;
 }
 int ff_dcaadpcm_subband_analysis(const DCAADPCMEncContext *s, const int32_t *in, int len, int *diff)
 {
    int pred_vq, i;
    int32_t input_buffer[16 + DCA_ADPCM_COEFFS];
    int32_t input_buffer2[16 + DCA_ADPCM_COEFFS];
    int32_t max = 0;
    int shift_bits;
    uint64_t pg = 0;
    for (i = 0; i < len + DCA_ADPCM_COEFFS; i++)
        max |= FFABS(in[i]);
    // normalize input to simplify apply_filter
    shift_bits = av_log2(max) - 11;
    for (i = 0; i < len + DCA_ADPCM_COEFFS; i++) {
        input_buffer[i] = norm__(in[i], 7);
        input_buffer2[i] = norm__(in[i], shift_bits);
    }
    pred_vq = find_best_filter(s, input_buffer2, len);
    if (pred_vq < 0)
        return -1;
    pg = calc_prediction_gain(pred_vq, input_buffer, diff, len);
    // Greater than 10db (10*log(10)) prediction gain to use ADPCM.
    // TODO: Tune it.
    if (pg < 10)
        return -1;
    for (i = 0; i < len; i++)
        diff[i] <<= 7;
    return pred_vq;
 }
 static void precalc(premultiplied_coeffs *data)
 {
    int i, j, k;
    for (i = 0; i < DCA_ADPCM_VQCODEBOOK_SZ; i++) {
        int id = 0;
        int32_t t = 0;
        for (j = 0; j < DCA_ADPCM_COEFFS; j++) {
            for (k = j; k < DCA_ADPCM_COEFFS; k++) {
                t = (int32_t)ff_dca_adpcm_vb[i][j] * (int32_t)ff_dca_adpcm_vb[i][k];
                if (j != k)
                    t *= 2;
                (*data)[id++] = t;
             }
        }
        data++;
    }
 }
 int ff_dcaadpcm_do_real(int pred_vq_index,
                        softfloat quant, int32_t scale_factor, int32_t step_size,
                        const int32_t *prev_hist, const int32_t *in, int32_t *next_hist, int32_t *out,
                        int len, int32_t peak)
 {
    int i;
    int64_t delta;
    int32_t dequant_delta;
    int32_t work_bufer[16 + DCA_ADPCM_COEFFS];
    memcpy(work_bufer, prev_hist, sizeof(int32_t) * DCA_ADPCM_COEFFS);
    for (i = 0; i < len; i++) {
        work_bufer[DCA_ADPCM_COEFFS + i] = ff_dcaadpcm_predict(pred_vq_index, &work_bufer[i]);
        delta = (int64_t)in[i] - ((int64_t)work_bufer[DCA_ADPCM_COEFFS + i] << 7);
        out[i] = quantize_value(av_clip64(delta, -peak, peak), quant);
        ff_dca_core_dequantize(&dequant_delta, &out[i], step_size, scale_factor, 0, 1);
        work_bufer[DCA_ADPCM_COEFFS+i] += dequant_delta;
    }
    memcpy(next_hist, &work_bufer[len], sizeof(int32_t) * DCA_ADPCM_COEFFS);
    return 0;
 }
 av_cold int ff_dcaadpcm_init(DCAADPCMEncContext *s)
 {
    if (!s)
        return -1;
    s->private_data = av_malloc(sizeof(premultiplied_coeffs) * DCA_ADPCM_VQCODEBOOK_SZ);
    precalc(s->private_data);
    return 0;
 }
 av_cold void ff_dcaadpcm_free(DCAADPCMEncContext *s)
 {
    if (!s)
        return;
    av_freep(&s->private_data);
 }
--- a/libavcodec/dcaadpcm.h
+++ b/libavcodec/dcaadpcm.h
@@ -0,0 +1,54 @@
 /*
 * DCA ADPCM engine
 * Copyright (C) 2017 Daniil Cherednik
 *
 * 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
 */
 #ifndef AVCODEC_DCAADPCM_H
 #define AVCODEC_DCAADPCM_H
 #include "dcamath.h"
 #include "dcadata.h"
 #include "dcaenc.h"
 typedef struct DCAADPCMEncContext {
    void *private_data;
 } DCAADPCMEncContext;
 static inline int64_t ff_dcaadpcm_predict(int pred_vq_index, const int32_t *input)
 {
    int i;
    const int16_t *coeff = ff_dca_adpcm_vb[pred_vq_index];
    int64_t pred = 0;
    for (i = 0; i < DCA_ADPCM_COEFFS; i++)
        pred += (int64_t)input[DCA_ADPCM_COEFFS - 1 - i] * coeff[i];
    return clip23(norm13(pred));
 }
 int ff_dcaadpcm_subband_analysis(const DCAADPCMEncContext *s, const int32_t *input, int len, int *diff);
 int ff_dcaadpcm_do_real(int pred_vq_index,
                        softfloat quant, int32_t scale_factor, int32_t step_size,
                        const int32_t *prev_hist, const int32_t *in, int32_t *next_hist, int32_t *out,
                        int len, int32_t peak);
 av_cold int ff_dcaadpcm_init(DCAADPCMEncContext *s);
 av_cold void ff_dcaadpcm_free(DCAADPCMEncContext *s);
 #endif /* AVCODEC_DCAADPCM_H */
--- a/libavcodec/dcadata.c
+++ b/libavcodec/dcadata.c
@@ -61,7 +61,7 @@ const uint8_t ff_dca_quant_index_group_size[DCA_CODE_BOOKS] = {
 /* ADPCM data */
 /* 16 bits signed fractional Q13 binary codes */
 const int16_t ff_dca_adpcm_vb[4096][4] = {
 const int16_t ff_dca_adpcm_vb[DCA_ADPCM_VQCODEBOOK_SZ][DCA_ADPCM_COEFFS] = {
    {   9928,  -2618,  -1093, -1263 },
    {  11077,  -2876,  -1747,  -308 },
    {  10503,  -1082,  -1426, -1167 },
--- a/libavcodec/dcadata.h
+++ b/libavcodec/dcadata.h
@@ -25,6 +25,9 @@
 #include "dcahuff.h"
 #define DCA_ADPCM_COEFFS        4
 #define DCA_ADPCM_VQCODEBOOK_SZ 4096
 extern const uint32_t ff_dca_bit_rates[32];
 extern const uint8_t ff_dca_channels[16];
@@ -36,7 +39,7 @@ extern const uint8_t ff_dca_dmix_primary_nch[8];
 extern const uint8_t ff_dca_quant_index_sel_nbits[DCA_CODE_BOOKS];
 extern const uint8_t ff_dca_quant_index_group_size[DCA_CODE_BOOKS];
 extern const int16_t ff_dca_adpcm_vb[4096][4];
 extern const int16_t ff_dca_adpcm_vb[DCA_ADPCM_VQCODEBOOK_SZ][DCA_ADPCM_COEFFS];
 extern const uint32_t ff_dca_scale_factor_quant6[64];
 extern const uint32_t ff_dca_scale_factor_quant7[128];
--- a/libavcodec/dcaenc.c
+++ b/libavcodec/dcaenc.c
@@ -25,8 +25,12 @@
 #include "libavutil/channel_layout.h"
 #include "libavutil/common.h"
 #include "libavutil/ffmath.h"
 #include "libavutil/opt.h"
 #include "avcodec.h"
 #include "dca.h"
 #include "dcaadpcm.h"
 #include "dcamath.h"
 #include "dca_core.h"
 #include "dcadata.h"
 #include "dcaenc.h"
 #include "internal.h"
@@ -44,8 +48,15 @@
 #define SUBBAND_SAMPLES (SUBFRAMES * SUBSUBFRAMES * 8)
 #define AUBANDS 25
 typedef struct CompressionOptions {
    int adpcm_mode;
 } CompressionOptions;
 typedef struct DCAEncContext {
    AVClass *class;
    PutBitContext pb;
    DCAADPCMEncContext adpcm_ctx;
    CompressionOptions options;
    int frame_size;
    int frame_bits;
    int fullband_channels;
@@ -61,10 +72,13 @@ typedef struct DCAEncContext {
    int32_t lfe_peak_cb;
    const int8_t *channel_order_tab;  ///< channel reordering table, lfe and non lfe
    int32_t prediction_mode[MAX_CHANNELS][DCAENC_SUBBANDS];
    int32_t adpcm_history[MAX_CHANNELS][DCAENC_SUBBANDS][DCA_ADPCM_COEFFS * 2];
    int32_t history[MAX_CHANNELS][512]; /* This is a circular buffer */
    int32_t subband[MAX_CHANNELS][DCAENC_SUBBANDS][SUBBAND_SAMPLES];
    int32_t *subband[MAX_CHANNELS][DCAENC_SUBBANDS];
    int32_t quantized[MAX_CHANNELS][DCAENC_SUBBANDS][SUBBAND_SAMPLES];
    int32_t peak_cb[MAX_CHANNELS][DCAENC_SUBBANDS];
    int32_t diff_peak_cb[MAX_CHANNELS][DCAENC_SUBBANDS]; ///< expected peak of residual signal
    int32_t downsampled_lfe[DCA_LFE_SAMPLES];
    int32_t masking_curve_cb[SUBSUBFRAMES][256];
    int32_t bit_allocation_sel[MAX_CHANNELS];
@@ -77,6 +91,7 @@ typedef struct DCAEncContext {
    int32_t worst_quantization_noise;
    int32_t worst_noise_ever;
    int consumed_bits;
    int consumed_adpcm_bits; ///< Number of bits to transmit ADPCM related info
 } DCAEncContext;
 static int32_t cos_table[2048];
@@ -107,18 +122,52 @@ static double gammafilter(int i, double f)
    return 20 * log10(h);
 }
 static int subband_bufer_alloc(DCAEncContext *c)
 {
    int ch, band;
    int32_t *bufer = av_calloc(MAX_CHANNELS * DCAENC_SUBBANDS *
                               (SUBBAND_SAMPLES + DCA_ADPCM_COEFFS),
                               sizeof(int32_t));
    if (!bufer)
        return -1;
    /* we need a place for DCA_ADPCM_COEFF samples from previous frame
     * to calc prediction coefficients for each subband */
    for (ch = 0; ch < MAX_CHANNELS; ch++) {
        for (band = 0; band < DCAENC_SUBBANDS; band++) {
            c->subband[ch][band] = bufer +
                                   ch * DCAENC_SUBBANDS * (SUBBAND_SAMPLES + DCA_ADPCM_COEFFS) +
                                   band * (SUBBAND_SAMPLES + DCA_ADPCM_COEFFS) + DCA_ADPCM_COEFFS;
        }
    }
    return 0;
 }
 static void subband_bufer_free(DCAEncContext *c)
 {
    int32_t *bufer = c->subband[0][0] - DCA_ADPCM_COEFFS;
    av_freep(&bufer);
 }
 static int encode_init(AVCodecContext *avctx)
 {
    DCAEncContext *c = avctx->priv_data;
    uint64_t layout = avctx->channel_layout;
    int i, j, min_frame_bits;
    if (subband_bufer_alloc(c))
        return AVERROR(ENOMEM);
    c->fullband_channels = c->channels = avctx->channels;
    c->lfe_channel = (avctx->channels == 3 || avctx->channels == 6);
    c->band_interpolation = band_interpolation[1];
    c->band_spectrum = band_spectrum[1];
    c->worst_quantization_noise = -2047;
    c->worst_noise_ever = -2047;
    c->consumed_adpcm_bits = 0;
    if (ff_dcaadpcm_init(&c->adpcm_ctx))
        return AVERROR(ENOMEM);
    if (!layout) {
        av_log(avctx, AV_LOG_WARNING, "No channel layout specified. The "
@@ -150,6 +199,12 @@ static int encode_init(AVCodecContext *avctx)
        }
        /* 6 - no Huffman */
        c->bit_allocation_sel[i] = 6;
        for (j = 0; j < DCAENC_SUBBANDS; j++) {
            /* -1 - no ADPCM */
            c->prediction_mode[i][j] = -1;
            memset(c->adpcm_history[i][j], 0, sizeof(int32_t)*DCA_ADPCM_COEFFS);
        }
    }
    for (i = 0; i < 9; i++) {
@@ -238,6 +293,16 @@ static int encode_init(AVCodecContext *avctx)
    return 0;
 }
 static av_cold int encode_close(AVCodecContext *avctx)
 {
    if (avctx->priv_data) {
        DCAEncContext *c = avctx->priv_data;
        subband_bufer_free(c);
        ff_dcaadpcm_free(&c->adpcm_ctx);
    }
    return 0;
 }
 static inline int32_t cos_t(int x)
 {
    return cos_table[x & 2047];
@@ -253,12 +318,6 @@ static inline int32_t half32(int32_t a)
    return (a + 1) >> 1;
 }
 static inline int32_t mul32(int32_t a, int32_t b)
 {
    int64_t r = (int64_t)a * b + 0x80000000ULL;
    return r >> 32;
 }
 static void subband_transform(DCAEncContext *c, const int32_t *input)
 {
    int ch, subs, i, k, j;
@@ -545,31 +604,53 @@ static void calc_masking(DCAEncContext *c, const int32_t *input)
    }
 }
 static inline int32_t find_peak(const int32_t *in, int len) {
    int sample;
    int32_t m = 0;
    for (sample = 0; sample < len; sample++) {
        int32_t s = abs(in[sample]);
        if (m < s) {
            m = s;
        }
    }
    return get_cb(m);
 }
 static void find_peaks(DCAEncContext *c)
 {
    int band, ch;
    for (ch = 0; ch < c->fullband_channels; ch++)
    for (ch = 0; ch < c->fullband_channels; ch++) {
        for (band = 0; band < 32; band++) {
            int sample;
            int32_t m = 0;
            for (sample = 0; sample < SUBBAND_SAMPLES; sample++) {
                int32_t s = abs(c->subband[ch][band][sample]);
                if (m < s)
                    m = s;
            }
            c->peak_cb[ch][band] = get_cb(m);
            c->peak_cb[ch][band] = find_peak(c->subband[ch][band], SUBBAND_SAMPLES);
        }
    }
    if (c->lfe_channel) {
        int sample;
        int32_t m = 0;
        c->lfe_peak_cb = find_peak(c->downsampled_lfe, DCA_LFE_SAMPLES);
    }
 }
 static void adpcm_analysis(DCAEncContext *c)
 {
    int ch, band;
    int pred_vq_id;
    int32_t *samples;
    int32_t estimated_diff[SUBBAND_SAMPLES];
        for (sample = 0; sample < DCA_LFE_SAMPLES; sample++)
            if (m < abs(c->downsampled_lfe[sample]))
                m = abs(c->downsampled_lfe[sample]);
        c->lfe_peak_cb = get_cb(m);
    c->consumed_adpcm_bits = 0;
    for (ch = 0; ch < c->fullband_channels; ch++) {
        for (band = 0; band < 32; band++) {
            samples = c->subband[ch][band] - DCA_ADPCM_COEFFS;
            pred_vq_id = ff_dcaadpcm_subband_analysis(&c->adpcm_ctx, samples, SUBBAND_SAMPLES, estimated_diff);
            if (pred_vq_id >= 0) {
                c->prediction_mode[ch][band] = pred_vq_id;
                c->consumed_adpcm_bits += 12; //12 bits to transmit prediction vq index
                c->diff_peak_cb[ch][band] = find_peak(estimated_diff, 16);
            } else {
                c->prediction_mode[ch][band] = -1;
            }
        }
    }
 }
@@ -578,13 +659,16 @@ static const int snr_fudge = 128;
 #define USED_NABITS 2
 #define USED_26ABITS 4
 static int32_t quantize_value(int32_t value, softfloat quant)
 static inline int32_t get_step_size(const DCAEncContext *c, int ch, int band)
 {
    int32_t offset = 1 << (quant.e - 1);
    int32_t step_size;
    value = mul32(value, quant.m) + offset;
    value = value >> quant.e;
    return value;
    if (c->bitrate_index == 3)
        step_size = ff_dca_lossless_quant[c->abits[ch][band]];
    else
        step_size = ff_dca_lossy_quant[c->abits[ch][band]];
    return step_size;
 }
 static int calc_one_scale(int32_t peak_cb, int abits, softfloat *quant)
@@ -619,14 +703,40 @@ static int calc_one_scale(int32_t peak_cb, int abits, softfloat *quant)
    return our_nscale;
 }
 static void quantize_all(DCAEncContext *c)
 static inline void quantize_adpcm_subband(DCAEncContext *c, int ch, int band)
 {
    int32_t step_size;
    int32_t diff_peak_cb = c->diff_peak_cb[ch][band];
    c->scale_factor[ch][band] = calc_one_scale(diff_peak_cb,
                                               c->abits[ch][band],
                                               &c->quant[ch][band]);
    step_size = get_step_size(c, ch, band);
    ff_dcaadpcm_do_real(c->prediction_mode[ch][band],
                        c->quant[ch][band], ff_dca_scale_factor_quant7[c->scale_factor[ch][band]], step_size,
                        c->adpcm_history[ch][band], c->subband[ch][band], c->adpcm_history[ch][band]+4, c->quantized[ch][band],
                        SUBBAND_SAMPLES, cb_to_level[-diff_peak_cb]);
 }
 static void quantize_adpcm(DCAEncContext *c)
 {
    int band, ch;
    for (ch = 0; ch < c->fullband_channels; ch++)
        for (band = 0; band < 32; band++)
            if (c->prediction_mode[ch][band] >= 0)
                quantize_adpcm_subband(c, ch, band);
 }
 static void quantize_pcm(DCAEncContext *c)
 {
    int sample, band, ch;
    for (ch = 0; ch < c->fullband_channels; ch++)
        for (band = 0; band < 32; band++)
            for (sample = 0; sample < SUBBAND_SAMPLES; sample++)
                c->quantized[ch][band][sample] = quantize_value(c->subband[ch][band][sample], c->quant[ch][band]);
            if (c->prediction_mode[ch][band] == -1)
                for (sample = 0; sample < SUBBAND_SAMPLES; sample++)
                    c->quantized[ch][band][sample] = quantize_value(c->subband[ch][band][sample], c->quant[ch][band]);
 }
 static void accumulate_huff_bit_consumption(int abits, int32_t *quantized, uint32_t *result)
@@ -710,6 +820,7 @@ static int init_quantization_noise(DCAEncContext *c, int noise)
    uint32_t bits_counter = 0;
    c->consumed_bits = 132 + 333 * c->fullband_channels;
    c->consumed_bits += c->consumed_adpcm_bits;
    if (c->lfe_channel)
        c->consumed_bits += 72;
@@ -740,12 +851,15 @@ static int init_quantization_noise(DCAEncContext *c, int noise)
    /* TODO: May be cache scaled values */
    for (ch = 0; ch < c->fullband_channels; ch++) {
        for (band = 0; band < 32; band++) {
            c->scale_factor[ch][band] = calc_one_scale(c->peak_cb[ch][band],
                                                       c->abits[ch][band],
                                                       &c->quant[ch][band]);
            if (c->prediction_mode[ch][band] == -1) {
                c->scale_factor[ch][band] = calc_one_scale(c->peak_cb[ch][band],
                                                           c->abits[ch][band],
                                                           &c->quant[ch][band]);
            }
        }
    }
    quantize_all(c);
    quantize_adpcm(c);
    quantize_pcm(c);
    memset(huff_bit_count_accum, 0, MAX_CHANNELS * DCA_CODE_BOOKS * 7 * sizeof(uint32_t));
    memset(clc_bit_count_accum, 0, MAX_CHANNELS * DCA_CODE_BOOKS * sizeof(uint32_t));
@@ -819,6 +933,41 @@ static void shift_history(DCAEncContext *c, const int32_t *input)
        }
 }
 static void fill_in_adpcm_bufer(DCAEncContext *c)
 {
     int ch, band;
     int32_t step_size;
     /* We fill in ADPCM work buffer for subbands which hasn't been ADPCM coded
      * in current frame - we need this data if subband of next frame is
      * ADPCM
      */
     for (ch = 0; ch < c->channels; ch++) {
        for (band = 0; band < 32; band++) {
            int32_t *samples = c->subband[ch][band] - DCA_ADPCM_COEFFS;
            if (c->prediction_mode[ch][band] == -1) {
                step_size = get_step_size(c, ch, band);
                ff_dca_core_dequantize(c->adpcm_history[ch][band],
                                       c->quantized[ch][band]+12, step_size, ff_dca_scale_factor_quant7[c->scale_factor[ch][band]], 0, 4);
            } else {
                AV_COPY128U(c->adpcm_history[ch][band], c->adpcm_history[ch][band]+4);
            }
            /* Copy dequantized values for LPC analysis.
             * It reduces artifacts in case of extreme quantization,
             * example: in current frame abits is 1 and has no prediction flag,
             * but end of this frame is sine like signal. In this case, if LPC analysis uses
             * original values, likely LPC analysis returns good prediction gain, and sets prediction flag.
             * But there are no proper value in decoder history, so likely result will be no good.
             * Bitstream has "Predictor history flag switch", but this flag disables history for all subbands
             */
            samples[0] = c->adpcm_history[ch][band][0] << 7;
            samples[1] = c->adpcm_history[ch][band][1] << 7;
            samples[2] = c->adpcm_history[ch][band][2] << 7;
            samples[3] = c->adpcm_history[ch][band][3] << 7;
        }
     }
 }
 static void calc_lfe_scales(DCAEncContext *c)
 {
    if (c->lfe_channel)
@@ -1001,9 +1150,14 @@ static void put_subframe(DCAEncContext *c, int subframe)
    /* Prediction mode: no ADPCM, in each channel and subband */
    for (ch = 0; ch < c->fullband_channels; ch++)
        for (band = 0; band < DCAENC_SUBBANDS; band++)
            put_bits(&c->pb, 1, 0);
            put_bits(&c->pb, 1, !(c->prediction_mode[ch][band] == -1));
    /* Prediction VQ address */
    for (ch = 0; ch < c->fullband_channels; ch++)
        for (band = 0; band < DCAENC_SUBBANDS; band++)
            if (c->prediction_mode[ch][band] >= 0)
                put_bits(&c->pb, 12, c->prediction_mode[ch][band]);
    /* Prediction VQ address: not transmitted */
    /* Bit allocation index */
    for (ch = 0; ch < c->fullband_channels; ch++) {
        if (c->bit_allocation_sel[ch] == 6) {
@@ -1068,12 +1222,15 @@ static int encode_frame(AVCodecContext *avctx, AVPacket *avpkt,
        lfe_downsample(c, samples);
    calc_masking(c, samples);
    if (c->options.adpcm_mode)
        adpcm_analysis(c);
    find_peaks(c);
    assign_bits(c);
    calc_lfe_scales(c);
    shift_history(c, samples);
    init_put_bits(&c->pb, avpkt->data, avpkt->size);
    fill_in_adpcm_bufer(c);
    put_frame_header(c);
    put_primary_audio_header(c);
    for (i = 0; i < SUBFRAMES; i++)
@@ -1092,6 +1249,20 @@ static int encode_frame(AVCodecContext *avctx, AVPacket *avpkt,
    return 0;
 }
 #define DCAENC_FLAGS AV_OPT_FLAG_ENCODING_PARAM | AV_OPT_FLAG_AUDIO_PARAM
 static const AVOption options[] = {
    { "dca_adpcm", "Use ADPCM encoding", offsetof(DCAEncContext, options.adpcm_mode), AV_OPT_TYPE_BOOL, {.i64 = 0}, 0, 1, DCAENC_FLAGS },
    { NULL },
 };
 static const AVClass dcaenc_class = {
    .class_name = "DCA (DTS Coherent Acoustics)",
    .item_name = av_default_item_name,
    .option = options,
    .version = LIBAVUTIL_VERSION_INT,
 };
 static const AVCodecDefault defaults[] = {
    { "b",          "1411200" },
    { NULL },
@@ -1104,6 +1275,7 @@ AVCodec ff_dca_encoder = {
    .id                    = AV_CODEC_ID_DTS,
    .priv_data_size        = sizeof(DCAEncContext),
    .init                  = encode_init,
    .close                 = encode_close,
    .encode2               = encode_frame,
    .capabilities          = AV_CODEC_CAP_EXPERIMENTAL,
    .sample_fmts           = (const enum AVSampleFormat[]){ AV_SAMPLE_FMT_S32,
@@ -1116,4 +1288,5 @@ AVCodec ff_dca_encoder = {
                                                  AV_CH_LAYOUT_5POINT1,
                                                  0 },
    .defaults              = defaults,
    .priv_class            = &dcaenc_class,
 };
--- a/libavcodec/dcaenc.h
+++ b/libavcodec/dcaenc.h
@@ -24,6 +24,8 @@
 #include <stdint.h>
 #include "dcamath.h"
 typedef struct {
    int32_t m;
    int32_t e;
@@ -144,4 +146,13 @@ static const int8_t channel_reorder_nolfe[16][9] = {
    { 3,  2,  4,  0,  1,  5,  7,  6, -1 },
 };
 static inline int32_t quantize_value(int32_t value, softfloat quant)
 {
    int32_t offset = 1 << (quant.e - 1);
    value = mul32(value, quant.m) + offset;
    value = value >> quant.e;
    return value;
 }
 #endif /* AVCODEC_DCAENC_H */
--- a/libavcodec/dcamath.h
+++ b/libavcodec/dcamath.h
@@ -49,6 +49,7 @@ static inline int32_t mul17(int32_t a, int32_t b) { return mul__(a, b, 17); }
 static inline int32_t mul22(int32_t a, int32_t b) { return mul__(a, b, 22); }
 static inline int32_t mul23(int32_t a, int32_t b) { return mul__(a, b, 23); }
 static inline int32_t mul31(int32_t a, int32_t b) { return mul__(a, b, 31); }
 static inline int32_t mul32(int32_t a, int32_t b) { return mul__(a, b, 32); }
 static inline int32_t clip23(int32_t a) { return av_clip_intp2(a, 23); }