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FFmpeg/libavfilter/af_anequalizer.c

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  1. /*

  2.  * Copyright (c) 2001-2010 Krzysztof Foltman, Markus Schmidt, Thor Harald Johansen and others

  3.  * Copyright (c) 2015 Paul B Mahol

  4.  *

  5.  * This file is part of FFmpeg.

  6.  *

  7.  * FFmpeg is free software; you can redistribute it and/or

  8.  * modify it under the terms of the GNU Lesser General Public

  9.  * License as published by the Free Software Foundation; either

  10.  * version 2.1 of the License, or (at your option) any later version.

  11.  *

  12.  * FFmpeg is distributed in the hope that it will be useful,

  13.  * but WITHOUT ANY WARRANTY; without even the implied warranty of

  14.  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU

  15.  * Lesser General Public License for more details.

  16.  *

  17.  * You should have received a copy of the GNU Lesser General Public

  18.  * License along with FFmpeg; if not, write to the Free Software

  19.  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA

  20.  */

  21. 

  22. #include "libavutil/intreadwrite.h"

  23. #include "libavutil/avstring.h"

  24. #include "libavutil/ffmath.h"

  25. #include "libavutil/opt.h"

  26. #include "libavutil/parseutils.h"

  27. #include "avfilter.h"

  28. #include "internal.h"

  29. #include "audio.h"

  30. 

  31. #define FILTER_ORDER 4

  32. 

  33. enum FilterType {

  34.     BUTTERWORTH,

  35.     CHEBYSHEV1,

  36.     CHEBYSHEV2,

  37.     NB_TYPES

  38. };

  39. 

  40. typedef struct FoSection {

  41.     double a0, a1, a2, a3, a4;

  42.     double b0, b1, b2, b3, b4;

  43. 

  44.     double num[4];

  45.     double denum[4];

  46. } FoSection;

  47. 

  48. typedef struct EqualizatorFilter {

  49.     int ignore;

  50.     int channel;

  51.     int type;

  52. 

  53.     double freq;

  54.     double gain;

  55.     double width;

  56. 

  57.     FoSection section[2];

  58. } EqualizatorFilter;

  59. 

  60. typedef struct AudioNEqualizerContext {

  61.     const AVClass *class;

  62.     char *args;

  63.     char *colors;

  64.     int draw_curves;

  65.     int w, h;

  66. 

  67.     double mag;

  68.     int fscale;

  69.     int nb_filters;

  70.     int nb_allocated;

  71.     EqualizatorFilter *filters;

  72.     AVFrame *video;

  73. } AudioNEqualizerContext;

  74. 

  75. #define OFFSET(x) offsetof(AudioNEqualizerContext, x)

  76. #define A AV_OPT_FLAG_AUDIO_PARAM

  77. #define V AV_OPT_FLAG_VIDEO_PARAM

  78. #define F AV_OPT_FLAG_FILTERING_PARAM

  79. 

  80. static const AVOption anequalizer_options[] = {

  81.     { "params", NULL,                             OFFSET(args),        AV_OPT_TYPE_STRING,     {.str=""}, 0, 0, A|F },

  82.     { "curves", "draw frequency response curves", OFFSET(draw_curves), AV_OPT_TYPE_BOOL,       {.i64=0}, 0, 1, V|F },

  83.     { "size",   "set video size",                 OFFSET(w),           AV_OPT_TYPE_IMAGE_SIZE, {.str = "hd720"}, 0, 0, V|F },

  84.     { "mgain",  "set max gain",                   OFFSET(mag),         AV_OPT_TYPE_DOUBLE,     {.dbl=60}, -900, 900, V|F },

  85.     { "fscale", "set frequency scale",            OFFSET(fscale),      AV_OPT_TYPE_INT,        {.i64=1}, 0, 1, V|F, "fscale" },

  86.         { "lin",  "linear",                       0,                   AV_OPT_TYPE_CONST,      {.i64=0}, 0, 0, V|F, "fscale" },

  87.         { "log",  "logarithmic",                  0,                   AV_OPT_TYPE_CONST,      {.i64=1}, 0, 0, V|F, "fscale" },

  88.     { "colors", "set channels curves colors",     OFFSET(colors),      AV_OPT_TYPE_STRING,     {.str = "red|green|blue|yellow|orange|lime|pink|magenta|brown" }, 0, 0, V|F },

  89.     { NULL }

  90. };

  91. 

  92. AVFILTER_DEFINE_CLASS(anequalizer);

  93. 

  94. static void draw_curves(AVFilterContext *ctx, AVFilterLink *inlink, AVFrame *out)

  95. {

  96.     AudioNEqualizerContext *s = ctx->priv;

  97.     char *colors, *color, *saveptr = NULL;

  98.     int ch, i, n;

  99. 

  100.     colors = av_strdup(s->colors);

  101.     if (!colors)

  102.         return;

  103. 

  104.     memset(out->data[0], 0, s->h * out->linesize[0]);

  105. 

  106.     for (ch = 0; ch < inlink->channels; ch++) {

  107.         uint8_t fg[4] = { 0xff, 0xff, 0xff, 0xff };

  108.         int prev_v = -1;

  109.         double f;

  110. 

  111.         color = av_strtok(ch == 0 ? colors : NULL, " |", &saveptr);

  112.         if (color)

  113.             av_parse_color(fg, color, -1, ctx);

  114. 

  115.         for (f = 0; f < s->w; f++) {

  116.             double zr, zi, zr2, zi2;

  117.             double Hr, Hi;

  118.             double Hmag = 1;

  119.             double w;

  120.             int v, y, x;

  121. 

  122.             w = M_PI * (s->fscale ? pow(s->w - 1, f / s->w) : f) / (s->w - 1);

  123.             zr = cos(w);

  124.             zr2 = zr * zr;

  125.             zi = -sin(w);

  126.             zi2 = zi * zi;

  127. 

  128.             for (n = 0; n < s->nb_filters; n++) {

  129.                 if (s->filters[n].channel != ch ||

  130.                     s->filters[n].ignore)

  131.                     continue;

  132. 

  133.                 for (i = 0; i < FILTER_ORDER / 2; i++) {

  134.                     FoSection *S = &s->filters[n].section[i];

  135. 

  136.                     /* H *= (((((S->b4 * z + S->b3) * z + S->b2) * z + S->b1) * z + S->b0) /

  137.                           ((((S->a4 * z + S->a3) * z + S->a2) * z + S->a1) * z + S->a0)); */

  138. 

  139.                     Hr = S->b4*(1-8*zr2*zi2) + S->b2*(zr2-zi2) + zr*(S->b1+S->b3*(zr2-3*zi2))+ S->b0;

  140.                     Hi = zi*(S->b3*(3*zr2-zi2) + S->b1 + 2*zr*(2*S->b4*(zr2-zi2) + S->b2));

  141.                     Hmag *= hypot(Hr, Hi);

  142.                     Hr = S->a4*(1-8*zr2*zi2) + S->a2*(zr2-zi2) + zr*(S->a1+S->a3*(zr2-3*zi2))+ S->a0;

  143.                     Hi = zi*(S->a3*(3*zr2-zi2) + S->a1 + 2*zr*(2*S->a4*(zr2-zi2) + S->a2));

  144.                     Hmag /= hypot(Hr, Hi);

  145.                 }

  146.             }

  147. 

  148.             v = av_clip((1. + -20 * log10(Hmag) / s->mag) * s->h / 2, 0, s->h - 1);

  149.             x = lrint(f);

  150.             if (prev_v == -1)

  151.                 prev_v = v;

  152.             if (v <= prev_v) {

  153.                 for (y = v; y <= prev_v; y++)

  154.                     AV_WL32(out->data[0] + y * out->linesize[0] + x * 4, AV_RL32(fg));

  155.             } else {

  156.                 for (y = prev_v; y <= v; y++)

  157.                     AV_WL32(out->data[0] + y * out->linesize[0] + x * 4, AV_RL32(fg));

  158.             }

  159. 

  160.             prev_v = v;

  161.         }

  162.     }

  163. 

  164.     av_free(colors);

  165. }

  166. 

  167. static int config_video(AVFilterLink *outlink)

  168. {

  169.     AVFilterContext *ctx = outlink->src;

  170.     AudioNEqualizerContext *s = ctx->priv;

  171.     AVFilterLink *inlink = ctx->inputs[0];

  172.     AVFrame *out;

  173. 

  174.     outlink->w = s->w;

  175.     outlink->h = s->h;

  176. 

  177.     av_frame_free(&s->video);

  178.     s->video = out = ff_get_video_buffer(outlink, outlink->w, outlink->h);

  179.     if (!out)

  180.         return AVERROR(ENOMEM);

  181.     outlink->sample_aspect_ratio = (AVRational){1,1};

  182. 

  183.     draw_curves(ctx, inlink, out);

  184. 

  185.     return 0;

  186. }

  187. 

  188. static av_cold int init(AVFilterContext *ctx)

  189. {

  190.     AudioNEqualizerContext *s = ctx->priv;

  191.     AVFilterPad pad, vpad;

  192.     int ret;

  193. 

  194.     pad = (AVFilterPad){

  195.         .name         = av_strdup("out0"),

  196.         .type         = AVMEDIA_TYPE_AUDIO,

  197.     };

  198. 

  199.     if (!pad.name)

  200.         return AVERROR(ENOMEM);

  201. 

  202.     if (s->draw_curves) {

  203.         vpad = (AVFilterPad){

  204.             .name         = av_strdup("out1"),

  205.             .type         = AVMEDIA_TYPE_VIDEO,

  206.             .config_props = config_video,

  207.         };

  208.         if (!vpad.name) {

  209.             av_freep(&pad.name);

  210.             return AVERROR(ENOMEM);

  211.         }

  212.     }

  213. 

  214.     ret = ff_insert_outpad(ctx, 0, &pad);

  215.     if (ret < 0) {

  216.         av_freep(&pad.name);

  217.         return ret;

  218.     }

  219. 

  220.     if (s->draw_curves) {

  221.         ret = ff_insert_outpad(ctx, 1, &vpad);

  222.         if (ret < 0) {

  223.             av_freep(&vpad.name);

  224.             return ret;

  225.         }

  226.     }

  227. 

  228.     return 0;

  229. }

  230. 

  231. static int query_formats(AVFilterContext *ctx)

  232. {

  233.     AVFilterLink *inlink = ctx->inputs[0];

  234.     AVFilterLink *outlink = ctx->outputs[0];

  235.     AudioNEqualizerContext *s = ctx->priv;

  236.     AVFilterFormats *formats;

  237.     AVFilterChannelLayouts *layouts;

  238.     static const enum AVPixelFormat pix_fmts[] = { AV_PIX_FMT_RGBA, AV_PIX_FMT_NONE };

  239.     static const enum AVSampleFormat sample_fmts[] = {

  240.         AV_SAMPLE_FMT_DBLP,

  241.         AV_SAMPLE_FMT_NONE

  242.     };

  243.     int ret;

  244. 

  245.     if (s->draw_curves) {

  246.         AVFilterLink *videolink = ctx->outputs[1];

  247.         formats = ff_make_format_list(pix_fmts);

  248.         if ((ret = ff_formats_ref(formats, &videolink->in_formats)) < 0)

  249.             return ret;

  250.     }

  251. 

  252.     formats = ff_make_format_list(sample_fmts);

  253.     if ((ret = ff_formats_ref(formats, &inlink->out_formats)) < 0 ||

  254.         (ret = ff_formats_ref(formats, &outlink->in_formats)) < 0)

  255.         return ret;

  256. 

  257.     layouts = ff_all_channel_counts();

  258.     if ((ret = ff_channel_layouts_ref(layouts, &inlink->out_channel_layouts)) < 0 ||

  259.         (ret = ff_channel_layouts_ref(layouts, &outlink->in_channel_layouts)) < 0)

  260.         return ret;

  261. 

  262.     formats = ff_all_samplerates();

  263.     if ((ret = ff_formats_ref(formats, &inlink->out_samplerates)) < 0 ||

  264.         (ret = ff_formats_ref(formats, &outlink->in_samplerates)) < 0)

  265.         return ret;

  266. 

  267.     return 0;

  268. }

  269. 

  270. static av_cold void uninit(AVFilterContext *ctx)

  271. {

  272.     AudioNEqualizerContext *s = ctx->priv;

  273. 

  274.     for (int i = 0; i < ctx->nb_outputs; i++)

  275.         av_freep(&ctx->output_pads[i].name);

  276.     av_frame_free(&s->video);

  277.     av_freep(&s->filters);

  278.     s->nb_filters = 0;

  279.     s->nb_allocated = 0;

  280. }

  281. 

  282. static void butterworth_fo_section(FoSection *S, double beta,

  283.                                    double si, double g, double g0,

  284.                                    double D, double c0)

  285. {

  286.     if (c0 == 1 || c0 == -1) {

  287.         S->b0 = (g*g*beta*beta + 2*g*g0*si*beta + g0*g0)/D;

  288.         S->b1 = 2*c0*(g*g*beta*beta - g0*g0)/D;

  289.         S->b2 = (g*g*beta*beta - 2*g0*g*beta*si + g0*g0)/D;

  290.         S->b3 = 0;

  291.         S->b4 = 0;

  292. 

  293.         S->a0 = 1;

  294.         S->a1 = 2*c0*(beta*beta - 1)/D;

  295.         S->a2 = (beta*beta - 2*beta*si + 1)/D;

  296.         S->a3 = 0;

  297.         S->a4 = 0;

  298.     } else {

  299.         S->b0 = (g*g*beta*beta + 2*g*g0*si*beta + g0*g0)/D;

  300.         S->b1 = -4*c0*(g0*g0 + g*g0*si*beta)/D;

  301.         S->b2 = 2*(g0*g0*(1 + 2*c0*c0) - g*g*beta*beta)/D;

  302.         S->b3 = -4*c0*(g0*g0 - g*g0*si*beta)/D;

  303.         S->b4 = (g*g*beta*beta - 2*g*g0*si*beta + g0*g0)/D;

  304. 

  305.         S->a0 = 1;

  306.         S->a1 = -4*c0*(1 + si*beta)/D;

  307.         S->a2 = 2*(1 + 2*c0*c0 - beta*beta)/D;

  308.         S->a3 = -4*c0*(1 - si*beta)/D;

  309.         S->a4 = (beta*beta - 2*si*beta + 1)/D;

  310.     }

  311. }

  312. 

  313. static void butterworth_bp_filter(EqualizatorFilter *f,

  314.                                   int N, double w0, double wb,

  315.                                   double G, double Gb, double G0)

  316. {

  317.     double g, c0, g0, beta;

  318.     double epsilon;

  319.     int r =  N % 2;

  320.     int L = (N - r) / 2;

  321.     int i;

  322. 

  323.     if (G == 0 && G0 == 0) {

  324.         f->section[0].a0 = 1;

  325.         f->section[0].b0 = 1;

  326.         f->section[1].a0 = 1;

  327.         f->section[1].b0 = 1;

  328.         return;

  329.     }

  330. 

  331.     G  = ff_exp10(G/20);

  332.     Gb = ff_exp10(Gb/20);

  333.     G0 = ff_exp10(G0/20);

  334. 

  335.     epsilon = sqrt((G * G - Gb * Gb) / (Gb * Gb - G0 * G0));

  336.     g  = pow(G,  1.0 / N);

  337.     g0 = pow(G0, 1.0 / N);

  338.     beta = pow(epsilon, -1.0 / N) * tan(wb/2);

  339.     c0 = cos(w0);

  340. 

  341.     for (i = 1; i <= L; i++) {

  342.         double ui = (2.0 * i - 1) / N;

  343.         double si = sin(M_PI * ui / 2.0);

  344.         double Di = beta * beta + 2 * si * beta + 1;

  345. 

  346.         butterworth_fo_section(&f->section[i - 1], beta, si, g, g0, Di, c0);

  347.     }

  348. }

  349. 

  350. static void chebyshev1_fo_section(FoSection *S, double a,

  351.                                   double c, double tetta_b,

  352.                                   double g0, double si, double b,

  353.                                   double D, double c0)

  354. {

  355.     if (c0 == 1 || c0 == -1) {

  356.         S->b0 = (tetta_b*tetta_b*(b*b+g0*g0*c*c) + 2*g0*b*si*tetta_b*tetta_b + g0*g0)/D;

  357.         S->b1 = 2*c0*(tetta_b*tetta_b*(b*b+g0*g0*c*c) - g0*g0)/D;

  358.         S->b2 = (tetta_b*tetta_b*(b*b+g0*g0*c*c) - 2*g0*b*si*tetta_b + g0*g0)/D;

  359.         S->b3 = 0;

  360.         S->b4 = 0;

  361. 

  362.         S->a0 = 1;

  363.         S->a1 = 2*c0*(tetta_b*tetta_b*(a*a+c*c) - 1)/D;

  364.         S->a2 = (tetta_b*tetta_b*(a*a+c*c) - 2*a*si*tetta_b + 1)/D;

  365.         S->a3 = 0;

  366.         S->a4 = 0;

  367.     } else {

  368.         S->b0 = ((b*b + g0*g0*c*c)*tetta_b*tetta_b + 2*g0*b*si*tetta_b + g0*g0)/D;

  369.         S->b1 = -4*c0*(g0*g0 + g0*b*si*tetta_b)/D;

  370.         S->b2 = 2*(g0*g0*(1 + 2*c0*c0) - (b*b + g0*g0*c*c)*tetta_b*tetta_b)/D;

  371.         S->b3 = -4*c0*(g0*g0 - g0*b*si*tetta_b)/D;

  372.         S->b4 = ((b*b + g0*g0*c*c)*tetta_b*tetta_b - 2*g0*b*si*tetta_b + g0*g0)/D;

  373. 

  374.         S->a0 = 1;

  375.         S->a1 = -4*c0*(1 + a*si*tetta_b)/D;

  376.         S->a2 = 2*(1 + 2*c0*c0 - (a*a + c*c)*tetta_b*tetta_b)/D;

  377.         S->a3 = -4*c0*(1 - a*si*tetta_b)/D;

  378.         S->a4 = ((a*a + c*c)*tetta_b*tetta_b - 2*a*si*tetta_b + 1)/D;

  379.     }

  380. }

  381. 

  382. static void chebyshev1_bp_filter(EqualizatorFilter *f,

  383.                                  int N, double w0, double wb,

  384.                                  double G, double Gb, double G0)

  385. {

  386.     double a, b, c0, g0, alfa, beta, tetta_b;

  387.     double epsilon;

  388.     int r =  N % 2;

  389.     int L = (N - r) / 2;

  390.     int i;

  391. 

  392.     if (G == 0 && G0 == 0) {

  393.         f->section[0].a0 = 1;

  394.         f->section[0].b0 = 1;

  395.         f->section[1].a0 = 1;

  396.         f->section[1].b0 = 1;

  397.         return;

  398.     }

  399. 

  400.     G  = ff_exp10(G/20);

  401.     Gb = ff_exp10(Gb/20);

  402.     G0 = ff_exp10(G0/20);

  403. 

  404.     epsilon = sqrt((G*G - Gb*Gb) / (Gb*Gb - G0*G0));

  405.     g0 = pow(G0,1.0/N);

  406.     alfa = pow(1.0/epsilon    + sqrt(1 + 1/(epsilon*epsilon)), 1.0/N);

  407.     beta = pow(G/epsilon + Gb * sqrt(1 + 1/(epsilon*epsilon)), 1.0/N);

  408.     a = 0.5 * (alfa - 1.0/alfa);

  409.     b = 0.5 * (beta - g0*g0*(1/beta));

  410.     tetta_b = tan(wb/2);

  411.     c0 = cos(w0);

  412. 

  413.     for (i = 1; i <= L; i++) {

  414.         double ui = (2.0*i-1.0)/N;

  415.         double ci = cos(M_PI*ui/2.0);

  416.         double si = sin(M_PI*ui/2.0);

  417.         double Di = (a*a + ci*ci)*tetta_b*tetta_b + 2.0*a*si*tetta_b + 1;

  418. 

  419.         chebyshev1_fo_section(&f->section[i - 1], a, ci, tetta_b, g0, si, b, Di, c0);

  420.     }

  421. }

  422. 

  423. static void chebyshev2_fo_section(FoSection *S, double a,

  424.                                   double c, double tetta_b,

  425.                                   double g, double si, double b,

  426.                                   double D, double c0)

  427. {

  428.     if (c0 == 1 || c0 == -1) {

  429.         S->b0 = (g*g*tetta_b*tetta_b + 2*tetta_b*g*b*si + b*b + g*g*c*c)/D;

  430.         S->b1 = 2*c0*(g*g*tetta_b*tetta_b - b*b - g*g*c*c)/D;

  431.         S->b2 = (g*g*tetta_b*tetta_b - 2*tetta_b*g*b*si + b*b + g*g*c*c)/D;

  432.         S->b3 = 0;

  433.         S->b4 = 0;

  434. 

  435.         S->a0 = 1;

  436.         S->a1 = 2*c0*(tetta_b*tetta_b - a*a - c*c)/D;

  437.         S->a2 = (tetta_b*tetta_b - 2*tetta_b*a*si + a*a + c*c)/D;

  438.         S->a3 = 0;

  439.         S->a4 = 0;

  440.     } else {

  441.         S->b0 = (g*g*tetta_b*tetta_b + 2*g*b*si*tetta_b + b*b + g*g*c*c)/D;

  442.         S->b1 = -4*c0*(b*b + g*g*c*c + g*b*si*tetta_b)/D;

  443.         S->b2 = 2*((b*b + g*g*c*c)*(1 + 2*c0*c0) - g*g*tetta_b*tetta_b)/D;

  444.         S->b3 = -4*c0*(b*b + g*g*c*c - g*b*si*tetta_b)/D;

  445.         S->b4 = (g*g*tetta_b*tetta_b - 2*g*b*si*tetta_b + b*b + g*g*c*c)/D;

  446. 

  447.         S->a0 = 1;

  448.         S->a1 = -4*c0*(a*a + c*c + a*si*tetta_b)/D;

  449.         S->a2 = 2*((a*a + c*c)*(1 + 2*c0*c0) - tetta_b*tetta_b)/D;

  450.         S->a3 = -4*c0*(a*a + c*c - a*si*tetta_b)/D;

  451.         S->a4 = (tetta_b*tetta_b - 2*a*si*tetta_b + a*a + c*c)/D;

  452.     }

  453. }

  454. 

  455. static void chebyshev2_bp_filter(EqualizatorFilter *f,

  456.                                  int N, double w0, double wb,

  457.                                  double G, double Gb, double G0)

  458. {

  459.     double a, b, c0, tetta_b;

  460.     double epsilon, g, eu, ew;

  461.     int r =  N % 2;

  462.     int L = (N - r) / 2;

  463.     int i;

  464. 

  465.     if (G == 0 && G0 == 0) {

  466.         f->section[0].a0 = 1;

  467.         f->section[0].b0 = 1;

  468.         f->section[1].a0 = 1;

  469.         f->section[1].b0 = 1;

  470.         return;

  471.     }

  472. 

  473.     G  = ff_exp10(G/20);

  474.     Gb = ff_exp10(Gb/20);

  475.     G0 = ff_exp10(G0/20);

  476. 

  477.     epsilon = sqrt((G*G - Gb*Gb) / (Gb*Gb - G0*G0));

  478.     g  = pow(G, 1.0 / N);

  479.     eu = pow(epsilon + sqrt(1 + epsilon*epsilon), 1.0/N);

  480.     ew = pow(G0*epsilon + Gb*sqrt(1 + epsilon*epsilon), 1.0/N);

  481.     a = (eu - 1.0/eu)/2.0;

  482.     b = (ew - g*g/ew)/2.0;

  483.     tetta_b = tan(wb/2);

  484.     c0 = cos(w0);

  485. 

  486.     for (i = 1; i <= L; i++) {

  487.         double ui = (2.0 * i - 1.0)/N;

  488.         double ci = cos(M_PI * ui / 2.0);

  489.         double si = sin(M_PI * ui / 2.0);

  490.         double Di = tetta_b*tetta_b + 2*a*si*tetta_b + a*a + ci*ci;

  491. 

  492.         chebyshev2_fo_section(&f->section[i - 1], a, ci, tetta_b, g, si, b, Di, c0);

  493.     }

  494. }

  495. 

  496. static double butterworth_compute_bw_gain_db(double gain)

  497. {

  498.     double bw_gain = 0;

  499. 

  500.     if (gain <= -6)

  501.         bw_gain = gain + 3;

  502.     else if(gain > -6 && gain < 6)

  503.         bw_gain = gain * 0.5;

  504.     else if(gain >= 6)

  505.         bw_gain = gain - 3;

  506. 

  507.     return bw_gain;

  508. }

  509. 

  510. static double chebyshev1_compute_bw_gain_db(double gain)

  511. {

  512.     double bw_gain = 0;

  513. 

  514.     if (gain <= -6)

  515.         bw_gain = gain + 1;

  516.     else if(gain > -6 && gain < 6)

  517.         bw_gain = gain * 0.9;

  518.     else if(gain >= 6)

  519.         bw_gain = gain - 1;

  520. 

  521.     return bw_gain;

  522. }

  523. 

  524. static double chebyshev2_compute_bw_gain_db(double gain)

  525. {

  526.     double bw_gain = 0;

  527. 

  528.     if (gain <= -6)

  529.         bw_gain = -3;

  530.     else if(gain > -6 && gain < 6)

  531.         bw_gain = gain * 0.3;

  532.     else if(gain >= 6)

  533.         bw_gain = 3;

  534. 

  535.     return bw_gain;

  536. }

  537. 

  538. static inline double hz_2_rad(double x, double fs)

  539. {

  540.     return 2 * M_PI * x / fs;

  541. }

  542. 

  543. static void equalizer(EqualizatorFilter *f, double sample_rate)

  544. {

  545.     double w0 = hz_2_rad(f->freq,  sample_rate);

  546.     double wb = hz_2_rad(f->width, sample_rate);

  547.     double bw_gain;

  548. 

  549.     switch (f->type) {

  550.     case BUTTERWORTH:

  551.         bw_gain = butterworth_compute_bw_gain_db(f->gain);

  552.         butterworth_bp_filter(f, FILTER_ORDER, w0, wb, f->gain, bw_gain, 0);

  553.         break;

  554.     case CHEBYSHEV1:

  555.         bw_gain = chebyshev1_compute_bw_gain_db(f->gain);

  556.         chebyshev1_bp_filter(f, FILTER_ORDER, w0, wb, f->gain, bw_gain, 0);

  557.         break;

  558.     case CHEBYSHEV2:

  559.         bw_gain = chebyshev2_compute_bw_gain_db(f->gain);

  560.         chebyshev2_bp_filter(f, FILTER_ORDER, w0, wb, f->gain, bw_gain, 0);

  561.         break;

  562.     }

  563. 

  564. }

  565. 

  566. static int add_filter(AudioNEqualizerContext *s, AVFilterLink *inlink)

  567. {

  568.     equalizer(&s->filters[s->nb_filters], inlink->sample_rate);

  569.     if (s->nb_filters >= s->nb_allocated) {

  570.         EqualizatorFilter *filters;

  571. 

  572.         filters = av_calloc(s->nb_allocated, 2 * sizeof(*s->filters));

  573.         if (!filters)

  574.             return AVERROR(ENOMEM);

  575.         memcpy(filters, s->filters, sizeof(*s->filters) * s->nb_allocated);

  576.         av_free(s->filters);

  577.         s->filters = filters;

  578.         s->nb_allocated *= 2;

  579.     }

  580.     s->nb_filters++;

  581. 

  582.     return 0;

  583. }

  584. 

  585. static int config_input(AVFilterLink *inlink)

  586. {

  587.     AVFilterContext *ctx = inlink->dst;

  588.     AudioNEqualizerContext *s = ctx->priv;

  589.     char *args = av_strdup(s->args);

  590.     char *saveptr = NULL;

  591.     int ret = 0;

  592. 

  593.     if (!args)

  594.         return AVERROR(ENOMEM);

  595. 

  596.     s->nb_allocated = 32 * inlink->channels;

  597.     s->filters = av_calloc(inlink->channels, 32 * sizeof(*s->filters));

  598.     if (!s->filters) {

  599.         s->nb_allocated = 0;

  600.         av_free(args);

  601.         return AVERROR(ENOMEM);

  602.     }

  603. 

  604.     while (1) {

  605.         char *arg = av_strtok(s->nb_filters == 0 ? args : NULL, "|", &saveptr);

  606. 

  607.         if (!arg)

  608.             break;

  609. 

  610.         s->filters[s->nb_filters].type = 0;

  611.         if (sscanf(arg, "c%d f=%lf w=%lf g=%lf t=%d", &s->filters[s->nb_filters].channel,

  612.                                                      &s->filters[s->nb_filters].freq,

  613.                                                      &s->filters[s->nb_filters].width,

  614.                                                      &s->filters[s->nb_filters].gain,

  615.                                                      &s->filters[s->nb_filters].type) != 5 &&

  616.             sscanf(arg, "c%d f=%lf w=%lf g=%lf", &s->filters[s->nb_filters].channel,

  617.                                                 &s->filters[s->nb_filters].freq,

  618.                                                 &s->filters[s->nb_filters].width,

  619.                                                 &s->filters[s->nb_filters].gain) != 4 ) {

  620.             av_free(args);

  621.             return AVERROR(EINVAL);

  622.         }

  623. 

  624.         if (s->filters[s->nb_filters].freq < 0 ||

  625.             s->filters[s->nb_filters].freq > inlink->sample_rate / 2.0)

  626.             s->filters[s->nb_filters].ignore = 1;

  627. 

  628.         if (s->filters[s->nb_filters].channel < 0 ||

  629.             s->filters[s->nb_filters].channel >= inlink->channels)

  630.             s->filters[s->nb_filters].ignore = 1;

  631. 

  632.         s->filters[s->nb_filters].type = av_clip(s->filters[s->nb_filters].type, 0, NB_TYPES - 1);

  633.         ret = add_filter(s, inlink);

  634.         if (ret < 0)

  635.             break;

  636.     }

  637. 

  638.     av_free(args);

  639. 

  640.     return ret;

  641. }

  642. 

  643. static int process_command(AVFilterContext *ctx, const char *cmd, const char *args,

  644.                            char *res, int res_len, int flags)

  645. {

  646.     AudioNEqualizerContext *s = ctx->priv;

  647.     AVFilterLink *inlink = ctx->inputs[0];

  648.     int ret = AVERROR(ENOSYS);

  649. 

  650.     if (!strcmp(cmd, "change")) {

  651.         double freq, width, gain;

  652.         int filter;

  653. 

  654.         if (sscanf(args, "%d|f=%lf|w=%lf|g=%lf", &filter, &freq, &width, &gain) != 4)

  655.             return AVERROR(EINVAL);

  656. 

  657.         if (filter < 0 || filter >= s->nb_filters)

  658.             return AVERROR(EINVAL);

  659. 

  660.         if (freq < 0 || freq > inlink->sample_rate / 2.0)

  661.             return AVERROR(EINVAL);

  662. 

  663.         s->filters[filter].freq  = freq;

  664.         s->filters[filter].width = width;

  665.         s->filters[filter].gain  = gain;

  666.         equalizer(&s->filters[filter], inlink->sample_rate);

  667.         if (s->draw_curves)

  668.             draw_curves(ctx, inlink, s->video);

  669. 

  670.         ret = 0;

  671.     }

  672. 

  673.     return ret;

  674. }

  675. 

  676. static inline double section_process(FoSection *S, double in)

  677. {

  678.     double out;

  679. 

  680.     out = S->b0 * in;

  681.     out+= S->b1 * S->num[0] - S->denum[0] * S->a1;

  682.     out+= S->b2 * S->num[1] - S->denum[1] * S->a2;

  683.     out+= S->b3 * S->num[2] - S->denum[2] * S->a3;

  684.     out+= S->b4 * S->num[3] - S->denum[3] * S->a4;

  685. 

  686.     S->num[3] = S->num[2];

  687.     S->num[2] = S->num[1];

  688.     S->num[1] = S->num[0];

  689.     S->num[0] = in;

  690. 

  691.     S->denum[3] = S->denum[2];

  692.     S->denum[2] = S->denum[1];

  693.     S->denum[1] = S->denum[0];

  694.     S->denum[0] = out;

  695. 

  696.     return out;

  697. }

  698. 

  699. static double process_sample(FoSection *s1, double in)

  700. {

  701.     double p0 = in, p1;

  702.     int i;

  703. 

  704.     for (i = 0; i < FILTER_ORDER / 2; i++) {

  705.         p1 = section_process(&s1[i], p0);

  706.         p0 = p1;

  707.     }

  708. 

  709.     return p1;

  710. }

  711. 

  712. static int filter_frame(AVFilterLink *inlink, AVFrame *buf)

  713. {

  714.     AVFilterContext *ctx = inlink->dst;

  715.     AudioNEqualizerContext *s = ctx->priv;

  716.     AVFilterLink *outlink = ctx->outputs[0];

  717.     double *bptr;

  718.     int i, n;

  719. 

  720.     for (i = 0; i < s->nb_filters; i++) {

  721.         EqualizatorFilter *f = &s->filters[i];

  722. 

  723.         if (f->gain == 0. || f->ignore)

  724.             continue;

  725. 

  726.         bptr = (double *)buf->extended_data[f->channel];

  727.         for (n = 0; n < buf->nb_samples; n++) {

  728.             double sample = bptr[n];

  729. 

  730.             sample  = process_sample(f->section, sample);

  731.             bptr[n] = sample;

  732.         }

  733.     }

  734. 

  735.     if (s->draw_curves) {

  736.         AVFrame *clone;

  737. 

  738.         const int64_t pts = buf->pts +

  739.             av_rescale_q(buf->nb_samples, (AVRational){ 1, inlink->sample_rate },

  740.                          outlink->time_base);

  741.         int ret;

  742. 

  743.         s->video->pts = pts;

  744.         clone = av_frame_clone(s->video);

  745.         if (!clone)

  746.             return AVERROR(ENOMEM);

  747.         ret = ff_filter_frame(ctx->outputs[1], clone);

  748.         if (ret < 0)

  749.             return ret;

  750.     }

  751. 

  752.     return ff_filter_frame(outlink, buf);

  753. }

  754. 

  755. static const AVFilterPad inputs[] = {

  756.     {

  757.         .name           = "default",

  758.         .type           = AVMEDIA_TYPE_AUDIO,

  759.         .config_props   = config_input,

  760.         .filter_frame   = filter_frame,

  761.         .needs_writable = 1,

  762.     },

  763.     { NULL }

  764. };

  765. 

  766. AVFilter ff_af_anequalizer = {

  767.     .name          = "anequalizer",

  768.     .description   = NULL_IF_CONFIG_SMALL("Apply high-order audio parametric multi band equalizer."),

  769.     .priv_size     = sizeof(AudioNEqualizerContext),

  770.     .priv_class    = &anequalizer_class,

  771.     .init          = init,

  772.     .uninit        = uninit,

  773.     .query_formats = query_formats,

  774.     .inputs        = inputs,

  775.     .outputs       = NULL,

  776.     .flags         = AVFILTER_FLAG_DYNAMIC_OUTPUTS,

  777.     .process_command = process_command,

  778. };