doxygen/4.0/dcadsp_8c_source.html

 /*

  * Copyright (C) 2016 foo86

  *

  * 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/mem.h"


 #include "dcadsp.h"

 #include "dcamath.h"


 static void decode_hf_c(int32_t **dst,

                         const int32_t *vq_index,

                         const int8_t hf_vq[1024][32],

                         int32_t scale_factors[32][2],

                         ptrdiff_t sb_start, ptrdiff_t sb_end,

                         ptrdiff_t ofs, ptrdiff_t len)

 {

     int i, j;


     for (i = sb_start; i < sb_end; i++) {

         const int8_t *coeff = hf_vq[vq_index[i]];

         int32_t scale = scale_factors[i][0];

         for (j = 0; j < len; j++)

             dst[i][j + ofs] = clip23(coeff[j] * scale + (1 << 3) >> 4);

     }

 }


 static void decode_joint_c(int32_t **dst, int32_t **src,

                            const int32_t *scale_factors,

                            ptrdiff_t sb_start, ptrdiff_t sb_end,

                            ptrdiff_t ofs, ptrdiff_t len)

 {

     int i, j;


     for (i = sb_start; i < sb_end; i++) {

         int32_t scale = scale_factors[i];

         for (j = 0; j < len; j++)

             dst[i][j + ofs] = clip23(mul17(src[i][j + ofs], scale));

     }

 }


 static void lfe_fir_float_c(float *pcm_samples, int32_t *lfe_samples,

                             const float *filter_coeff, ptrdiff_t npcmblocks,

                             int dec_select)

 {

     // Select decimation factor

     int factor = 64 << dec_select;

     int ncoeffs = 8 >> dec_select;

     int nlfesamples = npcmblocks >> (dec_select + 1);

     int i, j, k;


     for (i = 0; i < nlfesamples; i++) {

         // One decimated sample generates 64 or 128 interpolated ones

         for (j = 0; j < factor / 2; j++) {

             float a = 0;

             float b = 0;


             for (k = 0; k < ncoeffs; k++) {

                 a += filter_coeff[      j * ncoeffs + k] * lfe_samples[-k];

                 b += filter_coeff[255 - j * ncoeffs - k] * lfe_samples[-k];

             }


             pcm_samples[             j] = a;

             pcm_samples[factor / 2 + j] = b;

         }


         lfe_samples++;

         pcm_samples += factor;

     }

 }


 static void lfe_fir0_float_c(float *pcm_samples, int32_t *lfe_samples,

                              const float *filter_coeff, ptrdiff_t npcmblocks)

 {

     lfe_fir_float_c(pcm_samples, lfe_samples, filter_coeff, npcmblocks, 0);

 }


 static void lfe_fir1_float_c(float *pcm_samples, int32_t *lfe_samples,

                              const float *filter_coeff, ptrdiff_t npcmblocks)

 {

     lfe_fir_float_c(pcm_samples, lfe_samples, filter_coeff, npcmblocks, 1);

 }


 static void lfe_x96_float_c(float *dst, const float *src,

                             float *hist, ptrdiff_t len)

 {

     float prev = *hist;

     int i;


     for (i = 0; i < len; i++) {

         float a = 0.25f * src[i] + 0.75f * prev;

         float b = 0.75f * src[i] + 0.25f * prev;

         prev = src[i];

         *dst++ = a;

         *dst++ = b;

     }


     *hist = prev;

 }


 static void sub_qmf32_float_c(SynthFilterContext *synth,

                               FFTContext *imdct,

                               float *pcm_samples,

                               int32_t **subband_samples_lo,

                               int32_t **subband_samples_hi,

                               float *hist1, int *offset, float *hist2,

                               const float *filter_coeff, ptrdiff_t npcmblocks,

                               float scale)

 {

     LOCAL_ALIGNED_32(float, input, [32]);

     int i, j;


     for (j = 0; j < npcmblocks; j++) {

         // Load in one sample from each subband

         for (i = 0; i < 32; i++) {

             if ((i - 1) & 2)

                 input[i] = -subband_samples_lo[i][j];

             else

                 input[i] =  subband_samples_lo[i][j];

         }


         // One subband sample generates 32 interpolated ones

         synth->synth_filter_float(imdct, hist1, offset,

                                   hist2, filter_coeff,

                                   pcm_samples, input, scale);

         pcm_samples += 32;

     }

 }


 static void sub_qmf64_float_c(SynthFilterContext *synth,

                               FFTContext *imdct,

                               float *pcm_samples,

                               int32_t **subband_samples_lo,

                               int32_t **subband_samples_hi,

                               float *hist1, int *offset, float *hist2,

                               const float *filter_coeff, ptrdiff_t npcmblocks,

                               float scale)

 {

     LOCAL_ALIGNED_32(float, input, [64]);

     int i, j;


     if (!subband_samples_hi)

         memset(&input[32], 0, sizeof(input[0]) * 32);


     for (j = 0; j < npcmblocks; j++) {

         // Load in one sample from each subband

         if (subband_samples_hi) {

             // Full 64 subbands, first 32 are residual coded

             for (i =  0; i < 32; i++) {

                 if ((i - 1) & 2)

                     input[i] = -subband_samples_lo[i][j] - subband_samples_hi[i][j];

                 else

                     input[i] =  subband_samples_lo[i][j] + subband_samples_hi[i][j];

             }

             for (i = 32; i < 64; i++) {

                 if ((i - 1) & 2)

                     input[i] = -subband_samples_hi[i][j];

                 else

                     input[i] =  subband_samples_hi[i][j];

             }

         } else {

             // Only first 32 subbands

             for (i =  0; i < 32; i++) {

                 if ((i - 1) & 2)

                     input[i] = -subband_samples_lo[i][j];

                 else

                     input[i] =  subband_samples_lo[i][j];

             }

         }


         // One subband sample generates 64 interpolated ones

         synth->synth_filter_float_64(imdct, hist1, offset,

                                      hist2, filter_coeff,

                                      pcm_samples, input, scale);

         pcm_samples += 64;

     }

 }


 static void lfe_fir_fixed_c(int32_t *pcm_samples, int32_t *lfe_samples,

                             const int32_t *filter_coeff, ptrdiff_t npcmblocks)

 {

     // Select decimation factor

     int nlfesamples = npcmblocks >> 1;

     int i, j, k;


     for (i = 0; i < nlfesamples; i++) {

         // One decimated sample generates 64 interpolated ones

         for (j = 0; j < 32; j++) {

             int64_t a = 0;

             int64_t b = 0;


             for (k = 0; k < 8; k++) {

                 a += (int64_t)filter_coeff[      j * 8 + k] * lfe_samples[-k];

                 b += (int64_t)filter_coeff[255 - j * 8 - k] * lfe_samples[-k];

             }


             pcm_samples[     j] = clip23(norm23(a));

             pcm_samples[32 + j] = clip23(norm23(b));

         }


         lfe_samples++;

         pcm_samples += 64;

     }

 }


 static void lfe_x96_fixed_c(int32_t *dst, const int32_t *src,

                             int32_t *hist, ptrdiff_t len)

 {

     int32_t prev = *hist;

     int i;


     for (i = 0; i < len; i++) {

         int64_t a = INT64_C(2097471) * src[i] + INT64_C(6291137) * prev;

         int64_t b = INT64_C(6291137) * src[i] + INT64_C(2097471) * prev;

         prev = src[i];

         *dst++ = clip23(norm23(a));

         *dst++ = clip23(norm23(b));

     }


     *hist = prev;

 }


 static void sub_qmf32_fixed_c(SynthFilterContext *synth,

                               DCADCTContext *imdct,

                               int32_t *pcm_samples,

                               int32_t **subband_samples_lo,

                               int32_t **subband_samples_hi,

                               int32_t *hist1, int *offset, int32_t *hist2,

                               const int32_t *filter_coeff, ptrdiff_t npcmblocks)

 {

     LOCAL_ALIGNED_32(int32_t, input, [32]);

     int i, j;


     for (j = 0; j < npcmblocks; j++) {

         // Load in one sample from each subband

         for (i = 0; i < 32; i++)

             input[i] = subband_samples_lo[i][j];


         // One subband sample generates 32 interpolated ones

         synth->synth_filter_fixed(imdct, hist1, offset,

                                   hist2, filter_coeff,

                                   pcm_samples, input);

         pcm_samples += 32;

     }

 }


 static void sub_qmf64_fixed_c(SynthFilterContext *synth,

                               DCADCTContext *imdct,

                               int32_t *pcm_samples,

                               int32_t **subband_samples_lo,

                               int32_t **subband_samples_hi,

                               int32_t *hist1, int *offset, int32_t *hist2,

                               const int32_t *filter_coeff, ptrdiff_t npcmblocks)

 {

     LOCAL_ALIGNED_32(int32_t, input, [64]);

     int i, j;


     if (!subband_samples_hi)

         memset(&input[32], 0, sizeof(input[0]) * 32);


     for (j = 0; j < npcmblocks; j++) {

         // Load in one sample from each subband

         if (subband_samples_hi) {

             // Full 64 subbands, first 32 are residual coded

             for (i =  0; i < 32; i++)

                 input[i] = subband_samples_lo[i][j] + subband_samples_hi[i][j];

             for (i = 32; i < 64; i++)

                 input[i] = subband_samples_hi[i][j];

         } else {

             // Only first 32 subbands

             for (i =  0; i < 32; i++)

                 input[i] = subband_samples_lo[i][j];

         }


         // One subband sample generates 64 interpolated ones

         synth->synth_filter_fixed_64(imdct, hist1, offset,

                                      hist2, filter_coeff,

                                      pcm_samples, input);

         pcm_samples += 64;

     }

 }


 static void decor_c(int32_t *dst, const int32_t *src, int coeff, ptrdiff_t len)

 {

     int i;


     for (i = 0; i < len; i++)

         dst[i] += (SUINT)((int)(src[i] * (SUINT)coeff + (1 << 2)) >> 3);

 }


 static void dmix_sub_xch_c(int32_t *dst1, int32_t *dst2,

                            const int32_t *src, ptrdiff_t len)

 {

     int i;


     for (i = 0; i < len; i++) {

         int32_t cs = mul23(src[i], 5931520 /* M_SQRT1_2 * (1 << 23) */);

         dst1[i] -= cs;

         dst2[i] -= cs;

     }

 }


 static void dmix_sub_c(int32_t *dst, const int32_t *src, int coeff, ptrdiff_t len)

 {

     int i;


     for (i = 0; i < len; i++)

         dst[i] -= (unsigned)mul15(src[i], coeff);

 }


 static void dmix_add_c(int32_t *dst, const int32_t *src, int coeff, ptrdiff_t len)

 {

     int i;


     for (i = 0; i < len; i++)

         dst[i] += mul15(src[i], coeff);

 }


 static void dmix_scale_c(int32_t *dst, int scale, ptrdiff_t len)

 {

     int i;


     for (i = 0; i < len; i++)

         dst[i] = mul15(dst[i], scale);

 }


 static void dmix_scale_inv_c(int32_t *dst, int scale_inv, ptrdiff_t len)

 {

     int i;


     for (i = 0; i < len; i++)

         dst[i] = mul16(dst[i], scale_inv);

 }


 static void filter0(SUINT32 *dst, const int32_t *src, int32_t coeff, ptrdiff_t len)

 {

     int i;


     for (i = 0; i < len; i++)

         dst[i] -= mul22(src[i], coeff);

 }


 static void filter1(SUINT32 *dst, const int32_t *src, int32_t coeff, ptrdiff_t len)

 {

     int i;


     for (i = 0; i < len; i++)

         dst[i] -= mul23(src[i], coeff);

 }


 static void assemble_freq_bands_c(int32_t *dst, int32_t *src0, int32_t *src1,

                                   const int32_t *coeff, ptrdiff_t len)

 {

     int i;


     filter0(src0, src1, coeff[0], len);

     filter0(src1, src0, coeff[1], len);

     filter0(src0, src1, coeff[2], len);

     filter0(src1, src0, coeff[3], len);


     for (i = 0; i < 8; i++, src0--) {

         filter1(src0, src1, coeff[i +  4], len);

         filter1(src1, src0, coeff[i + 12], len);

         filter1(src0, src1, coeff[i +  4], len);

     }


     for (i = 0; i < len; i++) {

         *dst++ = *src1++;

         *dst++ = *++src0;

     }

 }


 static void lbr_bank_c(float output[32][4], float **input,

                        const float *coeff, ptrdiff_t ofs, ptrdiff_t len)

 {

     float SW0 = coeff[0];

     float SW1 = coeff[1];

     float SW2 = coeff[2];

     float SW3 = coeff[3];


     float C1  = coeff[4];

     float C2  = coeff[5];

     float C3  = coeff[6];

     float C4  = coeff[7];


     float AL1 = coeff[8];

     float AL2 = coeff[9];


     int i;


     // Short window and 8 point forward MDCT

     for (i = 0; i < len; i++) {

         float *src = input[i] + ofs;


         float a = src[-4] * SW0 - src[-1] * SW3;

         float b = src[-3] * SW1 - src[-2] * SW2;

         float c = src[ 2] * SW1 + src[ 1] * SW2;

         float d = src[ 3] * SW0 + src[ 0] * SW3;


         output[i][0] = C1 * b - C2 * c + C4 * a - C3 * d;

         output[i][1] = C1 * d - C2 * a - C4 * b - C3 * c;

         output[i][2] = C3 * b + C2 * d - C4 * c + C1 * a;

         output[i][3] = C3 * a - C2 * b + C4 * d - C1 * c;

     }


     // Aliasing cancellation for high frequencies

     for (i = 12; i < len - 1; i++) {

         float a = output[i  ][3] * AL1;

         float b = output[i+1][0] * AL1;

         output[i  ][3] += b - a;

         output[i+1][0] -= b + a;

         a = output[i  ][2] * AL2;

         b = output[i+1][1] * AL2;

         output[i  ][2] += b - a;

         output[i+1][1] -= b + a;

     }

 }


 static void lfe_iir_c(float *output, const float *input,

                       const float iir[5][4], float hist[5][2],

                       ptrdiff_t factor)

 {

     float res, tmp;

     int i, j, k;


     for (i = 0; i < 64; i++) {

         res = *input++;


         for (j = 0; j < factor; j++) {

             for (k = 0; k < 5; k++) {

                 tmp = hist[k][0] * iir[k][0] + hist[k][1] * iir[k][1] + res;

                 res = hist[k][0] * iir[k][2] + hist[k][1] * iir[k][3] + tmp;


                 hist[k][0] = hist[k][1];

                 hist[k][1] = tmp;

             }


             *output++ = res;

             res = 0;

         }

     }

 }


 av_cold void ff_dcadsp_init(DCADSPContext *s)

 {

     s->decode_hf     = decode_hf_c;

     s->decode_joint  = decode_joint_c;


     s->lfe_fir_float[0] = lfe_fir0_float_c;

     s->lfe_fir_float[1] = lfe_fir1_float_c;

     s->lfe_x96_float    = lfe_x96_float_c;

     s->sub_qmf_float[0] = sub_qmf32_float_c;

     s->sub_qmf_float[1] = sub_qmf64_float_c;


     s->lfe_fir_fixed    = lfe_fir_fixed_c;

     s->lfe_x96_fixed    = lfe_x96_fixed_c;

     s->sub_qmf_fixed[0] = sub_qmf32_fixed_c;

     s->sub_qmf_fixed[1] = sub_qmf64_fixed_c;


     s->decor   = decor_c;


     s->dmix_sub_xch   = dmix_sub_xch_c;

     s->dmix_sub       = dmix_sub_c;

     s->dmix_add       = dmix_add_c;

     s->dmix_scale     = dmix_scale_c;

     s->dmix_scale_inv = dmix_scale_inv_c;


     s->assemble_freq_bands = assemble_freq_bands_c;


     s->lbr_bank = lbr_bank_c;

     s->lfe_iir = lfe_iir_c;


     if (ARCH_X86)

         ff_dcadsp_init_x86(s);

 }

DCADSPContext::lfe_fir_fixed
void(* lfe_fir_fixed)(int32_t *pcm_samples, int32_t *lfe_samples, const int32_t *filter_coeff, ptrdiff_t npcmblocks)
Definition: dcadsp.h:58

s
const char * s
Definition: avisynth_c.h:768

lfe_fir_float_c
static void lfe_fir_float_c(float *pcm_samples, int32_t *lfe_samples, const float *filter_coeff, ptrdiff_t npcmblocks, int dec_select)
Definition: dcadsp.c:57

mul22
static int32_t mul22(int32_t a, int32_t b)
Definition: dcamath.h:49

sub_qmf32_fixed_c
static void sub_qmf32_fixed_c(SynthFilterContext *synth, DCADCTContext *imdct, int32_t *pcm_samples, int32_t **subband_samples_lo, int32_t **subband_samples_hi, int32_t *hist1, int *offset, int32_t *hist2, const int32_t *filter_coeff, ptrdiff_t npcmblocks)
Definition: dcadsp.c:238

assemble_freq_bands_c
static void assemble_freq_bands_c(int32_t *dst, int32_t *src0, int32_t *src1, const int32_t *coeff, ptrdiff_t len)
Definition: dcadsp.c:366

DCADSPContext::sub_qmf_float
void(* sub_qmf_float[2])(SynthFilterContext *synth, FFTContext *imdct, float *pcm_samples, int32_t **subband_samples_lo, int32_t **subband_samples_hi, float *hist1, int *offset, float *hist2, const float *filter_coeff, ptrdiff_t npcmblocks, float scale)
Definition: dcadsp.h:49

dmix_scale_c
static void dmix_scale_c(int32_t *dst, int scale, ptrdiff_t len)
Definition: dcadsp.c:334

mem.h
Memory handling functions.

sub_qmf64_fixed_c
static void sub_qmf64_fixed_c(SynthFilterContext *synth, DCADCTContext *imdct, int32_t *pcm_samples, int32_t **subband_samples_lo, int32_t **subband_samples_hi, int32_t *hist1, int *offset, int32_t *hist2, const int32_t *filter_coeff, ptrdiff_t npcmblocks)
Definition: dcadsp.c:262

b
const char * b
Definition: vf_curves.c:113

lfe_fir0_float_c
static void lfe_fir0_float_c(float *pcm_samples, int32_t *lfe_samples, const float *filter_coeff, ptrdiff_t npcmblocks)
Definition: dcadsp.c:87

mul15
static int32_t mul15(int32_t a, int32_t b)
Definition: dcamath.h:46

DCADSPContext::dmix_scale_inv
void(* dmix_scale_inv)(int32_t *dst, int scale_inv, ptrdiff_t len)
Definition: dcadsp.h:83

SUINT
#define SUINT
Definition: dct32_template.c:30

SynthFilterContext::synth_filter_float_64
void(* synth_filter_float_64)(FFTContext *imdct, float *synth_buf_ptr, int *synth_buf_offset, float synth_buf2[64], const float window[1024], float out[64], const float in[64], float scale)
Definition: synth_filter.h:33

src
#define src
Definition: vp8dsp.c:254

lfe_fir_fixed_c
static void lfe_fir_fixed_c(int32_t *pcm_samples, int32_t *lfe_samples, const int32_t *filter_coeff, ptrdiff_t npcmblocks)
Definition: dcadsp.c:194

C3
#define C3
Definition: simple_idct_mmi.c:31

SynthFilterContext::synth_filter_fixed_64
void(* synth_filter_fixed_64)(DCADCTContext *imdct, int32_t *synth_buf_ptr, int *synth_buf_offset, int32_t synth_buf2[64], const int32_t window[1024], int32_t out[64], const int32_t in[64])
Definition: synth_filter.h:41

filter0
static void filter0(SUINT32 *dst, const int32_t *src, int32_t coeff, ptrdiff_t len)
Definition: dcadsp.c:350

clip23
static int32_t clip23(int32_t a)
Definition: dcamath.h:54

mul23
static int32_t mul23(int32_t a, int32_t b)
Definition: dcamath.h:50

mul16
static int32_t mul16(int32_t a, int32_t b)
Definition: dcamath.h:47

av_cold
#define av_cold
Definition: attributes.h:82

lfe_iir_c
static void lfe_iir_c(float *output, const float *input, const float iir[5][4], float hist[5][2], ptrdiff_t factor)
Definition: dcadsp.c:434

ff_dcadsp_init_x86
av_cold void ff_dcadsp_init_x86(DCADSPContext *s)
Definition: dcadsp_init.c:36

DCADSPContext::dmix_add
void(* dmix_add)(int32_t *dst, const int32_t *src, int coeff, ptrdiff_t len)
Definition: dcadsp.h:79

ff_dcadsp_init
av_cold void ff_dcadsp_init(DCADSPContext *s)
Definition: dcadsp.c:459

SynthFilterContext
Definition: synth_filter.h:27

filter1
static void filter1(SUINT32 *dst, const int32_t *src, int32_t coeff, ptrdiff_t len)
Definition: dcadsp.c:358

lfe_x96_fixed_c
static void lfe_x96_fixed_c(int32_t *dst, const int32_t *src, int32_t *hist, ptrdiff_t len)
Definition: dcadsp.c:221

decor_c
static void decor_c(int32_t *dst, const int32_t *src, int coeff, ptrdiff_t len)
Definition: dcadsp.c:298

C1
#define C1
Definition: simple_idct_mmi.c:29

DCADSPContext::lfe_fir_float
void(* lfe_fir_float[2])(float *pcm_samples, int32_t *lfe_samples, const float *filter_coeff, ptrdiff_t npcmblocks)
Definition: dcadsp.h:43

DCADSPContext::lfe_iir
void(* lfe_iir)(float *output, const float *input, const float iir[5][4], float hist[5][2], ptrdiff_t factor)
Definition: dcadsp.h:91

lfe_fir1_float_c
static void lfe_fir1_float_c(float *pcm_samples, int32_t *lfe_samples, const float *filter_coeff, ptrdiff_t npcmblocks)
Definition: dcadsp.c:93

decode_hf_c
static void decode_hf_c(int32_t **dst, const int32_t *vq_index, const int8_t hf_vq[1024][32], int32_t scale_factors[32][2], ptrdiff_t sb_start, ptrdiff_t sb_end, ptrdiff_t ofs, ptrdiff_t len)
Definition: dcadsp.c:26

DCADSPContext::assemble_freq_bands
void(* assemble_freq_bands)(int32_t *dst, int32_t *src0, int32_t *src1, const int32_t *coeff, ptrdiff_t len)
Definition: dcadsp.h:85

C2
#define C2
Definition: simple_idct_mmi.c:30

offset
static const uint8_t offset[127][2]
Definition: vf_spp.c:92

FFTContext
Definition: fft.h:88

dmix_sub_xch_c
static void dmix_sub_xch_c(int32_t *dst1, int32_t *dst2, const int32_t *src, ptrdiff_t len)
Definition: dcadsp.c:306

lbr_bank_c
static void lbr_bank_c(float output[32][4], float **input, const float *coeff, ptrdiff_t ofs, ptrdiff_t len)
Definition: dcadsp.c:388

dcamath.h

SUINT32
#define SUINT32
Definition: dct32_template.c:31

DCADSPContext::dmix_scale
void(* dmix_scale)(int32_t *dst, int scale, ptrdiff_t len)
Definition: dcadsp.h:81

int32_t
int32_t
Definition: audio_convert.c:194

DCADSPContext::lfe_x96_float
void(* lfe_x96_float)(float *dst, const float *src, float *hist, ptrdiff_t len)
Definition: dcadsp.h:46

dcadsp.h

DCADSPContext::lbr_bank
void(* lbr_bank)(float output[32][4], float **input, const float *coeff, ptrdiff_t ofs, ptrdiff_t len)
Definition: dcadsp.h:88

C4
#define C4
Definition: simple_idct_mmi.c:32

dmix_add_c
static void dmix_add_c(int32_t *dst, const int32_t *src, int coeff, ptrdiff_t len)
Definition: dcadsp.c:326

DCADSPContext::decode_hf
void(* decode_hf)(int32_t **dst, const int32_t *vq_index, const int8_t hf_vq[1024][32], int32_t scale_factors[32][2], ptrdiff_t sb_start, ptrdiff_t sb_end, ptrdiff_t ofs, ptrdiff_t len)
Definition: dcadsp.h:31

src1
#define src1
Definition: h264pred.c:139

DCADSPContext::decode_joint
void(* decode_joint)(int32_t **dst, int32_t **src, const int32_t *scale_factors, ptrdiff_t sb_start, ptrdiff_t sb_end, ptrdiff_t ofs, ptrdiff_t len)
Definition: dcadsp.h:38

DCADSPContext
Definition: dcadsp.h:30

decode_joint_c
static void decode_joint_c(int32_t **dst, int32_t **src, const int32_t *scale_factors, ptrdiff_t sb_start, ptrdiff_t sb_end, ptrdiff_t ofs, ptrdiff_t len)
Definition: dcadsp.c:43

sub_qmf64_float_c
static void sub_qmf64_float_c(SynthFilterContext *synth, FFTContext *imdct, float *pcm_samples, int32_t **subband_samples_lo, int32_t **subband_samples_hi, float *hist1, int *offset, float *hist2, const float *filter_coeff, ptrdiff_t npcmblocks, float scale)
Definition: dcadsp.c:145

src0
#define src0
Definition: h264pred.c:138

factor
static const int factor[16]
Definition: vf_pp7.c:75

dmix_scale_inv_c
static void dmix_scale_inv_c(int32_t *dst, int scale_inv, ptrdiff_t len)
Definition: dcadsp.c:342

LOCAL_ALIGNED_32
#define LOCAL_ALIGNED_32(t, v,...)
Definition: internal.h:137

DCADSPContext::sub_qmf_fixed
void(* sub_qmf_fixed[2])(SynthFilterContext *synth, DCADCTContext *imdct, int32_t *pcm_samples, int32_t **subband_samples_lo, int32_t **subband_samples_hi, int32_t *hist1, int *offset, int32_t *hist2, const int32_t *filter_coeff, ptrdiff_t npcmblocks)
Definition: dcadsp.h:64

SynthFilterContext::synth_filter_float
void(* synth_filter_float)(FFTContext *imdct, float *synth_buf_ptr, int *synth_buf_offset, float synth_buf2[32], const float window[512], float out[32], const float in[32], float scale)
Definition: synth_filter.h:28

int
int
Definition: ffmpeg_filter.c:190

c
static double c[64]
Definition: vsrc_mptestsrc.c:87

DCADSPContext::dmix_sub_xch
void(* dmix_sub_xch)(int32_t *dst1, int32_t *dst2, const int32_t *src, ptrdiff_t len)
Definition: dcadsp.h:74

len
int len
Definition: vorbis_enc_data.h:452

mul17
static int32_t mul17(int32_t a, int32_t b)
Definition: dcamath.h:48

DCADSPContext::dmix_sub
void(* dmix_sub)(int32_t *dst, const int32_t *src, int coeff, ptrdiff_t len)
Definition: dcadsp.h:77

SynthFilterContext::synth_filter_fixed
void(* synth_filter_fixed)(DCADCTContext *imdct, int32_t *synth_buf_ptr, int *synth_buf_offset, int32_t synth_buf2[32], const int32_t window[512], int32_t out[32], const int32_t in[32])
Definition: synth_filter.h:37

coeff
static const double coeff[2][5]
Definition: vf_owdenoise.c:72

DCADCTContext
Definition: dcadct.h:26

norm23
static int32_t norm23(int64_t a)
Definition: dcamath.h:44

DCADSPContext::lfe_x96_fixed
void(* lfe_x96_fixed)(int32_t *dst, const int32_t *src, int32_t *hist, ptrdiff_t len)
Definition: dcadsp.h:61

dmix_sub_c
static void dmix_sub_c(int32_t *dst, const int32_t *src, int coeff, ptrdiff_t len)
Definition: dcadsp.c:318

DCADSPContext::decor
void(* decor)(int32_t *dst, const int32_t *src, int coeff, ptrdiff_t len)
Definition: dcadsp.h:72

sub_qmf32_float_c
static void sub_qmf32_float_c(SynthFilterContext *synth, FFTContext *imdct, float *pcm_samples, int32_t **subband_samples_lo, int32_t **subband_samples_hi, float *hist1, int *offset, float *hist2, const float *filter_coeff, ptrdiff_t npcmblocks, float scale)
Definition: dcadsp.c:116

lfe_x96_float_c
static void lfe_x96_float_c(float *dst, const float *src, float *hist, ptrdiff_t len)
Definition: dcadsp.c:99

a
a
Definition: h264pred_template.c:468

tmp
static uint8_t tmp[11]
Definition: aes_ctr.c:26