1
0
mirror of https://github.com/FFmpeg/FFmpeg.git synced 2024-12-28 20:53:54 +02:00
FFmpeg/libavfilter/af_firequalizer.c
Andreas Rheinhardt 790f793844 avutil/common: Don't auto-include mem.h
There are lots of files that don't need it: The number of object
files that actually need it went down from 2011 to 884 here.

Keep it for external users in order to not cause breakages.

Also improve the other headers a bit while just at it.

Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@outlook.com>
2024-03-31 00:08:43 +01:00

968 lines
36 KiB
C

/*
* Copyright (c) 2016 Muhammad Faiz <mfcc64@gmail.com>
*
* 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/channel_layout.h"
#include "libavutil/file_open.h"
#include "libavutil/mem.h"
#include "libavutil/opt.h"
#include "libavutil/eval.h"
#include "libavutil/avassert.h"
#include "libavutil/tx.h"
#include "avfilter.h"
#include "internal.h"
#include "audio.h"
#define RDFT_BITS_MIN 4
#define RDFT_BITS_MAX 16
enum WindowFunc {
WFUNC_RECTANGULAR,
WFUNC_HANN,
WFUNC_HAMMING,
WFUNC_BLACKMAN,
WFUNC_NUTTALL3,
WFUNC_MNUTTALL3,
WFUNC_NUTTALL,
WFUNC_BNUTTALL,
WFUNC_BHARRIS,
WFUNC_TUKEY,
NB_WFUNC
};
enum Scale {
SCALE_LINLIN,
SCALE_LINLOG,
SCALE_LOGLIN,
SCALE_LOGLOG,
NB_SCALE
};
#define NB_GAIN_ENTRY_MAX 4096
typedef struct GainEntry {
double freq;
double gain;
} GainEntry;
typedef struct OverlapIndex {
int buf_idx;
int overlap_idx;
} OverlapIndex;
typedef struct FIREqualizerContext {
const AVClass *class;
AVTXContext *analysis_rdft;
av_tx_fn analysis_rdft_fn;
AVTXContext *analysis_irdft;
av_tx_fn analysis_irdft_fn;
AVTXContext *rdft;
av_tx_fn rdft_fn;
AVTXContext *irdft;
av_tx_fn irdft_fn;
AVTXContext *fft_ctx;
av_tx_fn fft_fn;
AVTXContext *cepstrum_rdft;
av_tx_fn cepstrum_rdft_fn;
AVTXContext *cepstrum_irdft;
av_tx_fn cepstrum_irdft_fn;
int analysis_rdft_len;
int rdft_len;
int cepstrum_len;
float *analysis_buf;
float *analysis_tbuf;
float *dump_buf;
float *kernel_tmp_buf;
float *kernel_tmp_tbuf;
float *kernel_buf;
float *tx_buf;
float *cepstrum_buf;
float *cepstrum_tbuf;
float *conv_buf;
OverlapIndex *conv_idx;
int fir_len;
int nsamples_max;
int64_t next_pts;
int frame_nsamples_max;
int remaining;
char *gain_cmd;
char *gain_entry_cmd;
const char *gain;
const char *gain_entry;
double delay;
double accuracy;
int wfunc;
int fixed;
int multi;
int zero_phase;
int scale;
char *dumpfile;
int dumpscale;
int fft2;
int min_phase;
int nb_gain_entry;
int gain_entry_err;
GainEntry gain_entry_tbl[NB_GAIN_ENTRY_MAX];
} FIREqualizerContext;
#define OFFSET(x) offsetof(FIREqualizerContext, x)
#define FLAGS AV_OPT_FLAG_AUDIO_PARAM|AV_OPT_FLAG_FILTERING_PARAM
#define TFLAGS AV_OPT_FLAG_AUDIO_PARAM|AV_OPT_FLAG_FILTERING_PARAM|AV_OPT_FLAG_RUNTIME_PARAM
static const AVOption firequalizer_options[] = {
{ "gain", "set gain curve", OFFSET(gain), AV_OPT_TYPE_STRING, { .str = "gain_interpolate(f)" }, 0, 0, TFLAGS },
{ "gain_entry", "set gain entry", OFFSET(gain_entry), AV_OPT_TYPE_STRING, { .str = NULL }, 0, 0, TFLAGS },
{ "delay", "set delay", OFFSET(delay), AV_OPT_TYPE_DOUBLE, { .dbl = 0.01 }, 0.0, 1e10, FLAGS },
{ "accuracy", "set accuracy", OFFSET(accuracy), AV_OPT_TYPE_DOUBLE, { .dbl = 5.0 }, 0.0, 1e10, FLAGS },
{ "wfunc", "set window function", OFFSET(wfunc), AV_OPT_TYPE_INT, { .i64 = WFUNC_HANN }, 0, NB_WFUNC-1, FLAGS, .unit = "wfunc" },
{ "rectangular", "rectangular window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_RECTANGULAR }, 0, 0, FLAGS, .unit = "wfunc" },
{ "hann", "hann window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_HANN }, 0, 0, FLAGS, .unit = "wfunc" },
{ "hamming", "hamming window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_HAMMING }, 0, 0, FLAGS, .unit = "wfunc" },
{ "blackman", "blackman window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_BLACKMAN }, 0, 0, FLAGS, .unit = "wfunc" },
{ "nuttall3", "3-term nuttall window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_NUTTALL3 }, 0, 0, FLAGS, .unit = "wfunc" },
{ "mnuttall3", "minimum 3-term nuttall window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_MNUTTALL3 }, 0, 0, FLAGS, .unit = "wfunc" },
{ "nuttall", "nuttall window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_NUTTALL }, 0, 0, FLAGS, .unit = "wfunc" },
{ "bnuttall", "blackman-nuttall window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_BNUTTALL }, 0, 0, FLAGS, .unit = "wfunc" },
{ "bharris", "blackman-harris window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_BHARRIS }, 0, 0, FLAGS, .unit = "wfunc" },
{ "tukey", "tukey window", 0, AV_OPT_TYPE_CONST, { .i64 = WFUNC_TUKEY }, 0, 0, FLAGS, .unit = "wfunc" },
{ "fixed", "set fixed frame samples", OFFSET(fixed), AV_OPT_TYPE_BOOL, { .i64 = 0 }, 0, 1, FLAGS },
{ "multi", "set multi channels mode", OFFSET(multi), AV_OPT_TYPE_BOOL, { .i64 = 0 }, 0, 1, FLAGS },
{ "zero_phase", "set zero phase mode", OFFSET(zero_phase), AV_OPT_TYPE_BOOL, { .i64 = 0 }, 0, 1, FLAGS },
{ "scale", "set gain scale", OFFSET(scale), AV_OPT_TYPE_INT, { .i64 = SCALE_LINLOG }, 0, NB_SCALE-1, FLAGS, .unit = "scale" },
{ "linlin", "linear-freq linear-gain", 0, AV_OPT_TYPE_CONST, { .i64 = SCALE_LINLIN }, 0, 0, FLAGS, .unit = "scale" },
{ "linlog", "linear-freq logarithmic-gain", 0, AV_OPT_TYPE_CONST, { .i64 = SCALE_LINLOG }, 0, 0, FLAGS, .unit = "scale" },
{ "loglin", "logarithmic-freq linear-gain", 0, AV_OPT_TYPE_CONST, { .i64 = SCALE_LOGLIN }, 0, 0, FLAGS, .unit = "scale" },
{ "loglog", "logarithmic-freq logarithmic-gain", 0, AV_OPT_TYPE_CONST, { .i64 = SCALE_LOGLOG }, 0, 0, FLAGS, .unit = "scale" },
{ "dumpfile", "set dump file", OFFSET(dumpfile), AV_OPT_TYPE_STRING, { .str = NULL }, 0, 0, FLAGS },
{ "dumpscale", "set dump scale", OFFSET(dumpscale), AV_OPT_TYPE_INT, { .i64 = SCALE_LINLOG }, 0, NB_SCALE-1, FLAGS, .unit = "scale" },
{ "fft2", "set 2-channels fft", OFFSET(fft2), AV_OPT_TYPE_BOOL, { .i64 = 0 }, 0, 1, FLAGS },
{ "min_phase", "set minimum phase mode", OFFSET(min_phase), AV_OPT_TYPE_BOOL, { .i64 = 0 }, 0, 1, FLAGS },
{ NULL }
};
AVFILTER_DEFINE_CLASS(firequalizer);
static void common_uninit(FIREqualizerContext *s)
{
av_tx_uninit(&s->analysis_rdft);
av_tx_uninit(&s->analysis_irdft);
av_tx_uninit(&s->rdft);
av_tx_uninit(&s->irdft);
av_tx_uninit(&s->fft_ctx);
av_tx_uninit(&s->cepstrum_rdft);
av_tx_uninit(&s->cepstrum_irdft);
s->analysis_rdft = s->analysis_irdft = s->rdft = s->irdft = NULL;
s->fft_ctx = NULL;
s->cepstrum_rdft = NULL;
s->cepstrum_irdft = NULL;
av_freep(&s->analysis_buf);
av_freep(&s->analysis_tbuf);
av_freep(&s->dump_buf);
av_freep(&s->kernel_tmp_buf);
av_freep(&s->kernel_tmp_tbuf);
av_freep(&s->kernel_buf);
av_freep(&s->tx_buf);
av_freep(&s->cepstrum_buf);
av_freep(&s->cepstrum_tbuf);
av_freep(&s->conv_buf);
av_freep(&s->conv_idx);
}
static av_cold void uninit(AVFilterContext *ctx)
{
FIREqualizerContext *s = ctx->priv;
common_uninit(s);
av_freep(&s->gain_cmd);
av_freep(&s->gain_entry_cmd);
}
static void fast_convolute(FIREqualizerContext *restrict s, const float *restrict kernel_buf, float *restrict conv_buf,
OverlapIndex *restrict idx, float *restrict data, int nsamples)
{
if (nsamples <= s->nsamples_max) {
float *buf = conv_buf + idx->buf_idx * s->rdft_len;
float *obuf = conv_buf + !idx->buf_idx * s->rdft_len + idx->overlap_idx;
float *tbuf = s->tx_buf;
int center = s->fir_len/2;
int k;
memset(buf, 0, center * sizeof(*data));
memcpy(buf + center, data, nsamples * sizeof(*data));
memset(buf + center + nsamples, 0, (s->rdft_len - nsamples - center) * sizeof(*data));
s->rdft_fn(s->rdft, tbuf, buf, sizeof(float));
for (k = 0; k <= s->rdft_len/2; k++) {
tbuf[2*k] *= kernel_buf[k];
tbuf[2*k+1] *= kernel_buf[k];
}
s->irdft_fn(s->irdft, buf, tbuf, sizeof(AVComplexFloat));
for (k = 0; k < s->rdft_len - idx->overlap_idx; k++)
buf[k] += obuf[k];
memcpy(data, buf, nsamples * sizeof(*data));
idx->buf_idx = !idx->buf_idx;
idx->overlap_idx = nsamples;
} else {
while (nsamples > s->nsamples_max * 2) {
fast_convolute(s, kernel_buf, conv_buf, idx, data, s->nsamples_max);
data += s->nsamples_max;
nsamples -= s->nsamples_max;
}
fast_convolute(s, kernel_buf, conv_buf, idx, data, nsamples/2);
fast_convolute(s, kernel_buf, conv_buf, idx, data + nsamples/2, nsamples - nsamples/2);
}
}
static void fast_convolute_nonlinear(FIREqualizerContext *restrict s, const float *restrict kernel_buf,
float *restrict conv_buf, OverlapIndex *restrict idx,
float *restrict data, int nsamples)
{
if (nsamples <= s->nsamples_max) {
float *buf = conv_buf + idx->buf_idx * s->rdft_len;
float *obuf = conv_buf + !idx->buf_idx * s->rdft_len + idx->overlap_idx;
float *tbuf = s->tx_buf;
int k;
memcpy(buf, data, nsamples * sizeof(*data));
memset(buf + nsamples, 0, (s->rdft_len - nsamples) * sizeof(*data));
s->rdft_fn(s->rdft, tbuf, buf, sizeof(float));
for (k = 0; k < s->rdft_len + 2; k += 2) {
float re, im;
re = tbuf[k] * kernel_buf[k] - tbuf[k+1] * kernel_buf[k+1];
im = tbuf[k] * kernel_buf[k+1] + tbuf[k+1] * kernel_buf[k];
tbuf[k] = re;
tbuf[k+1] = im;
}
s->irdft_fn(s->irdft, buf, tbuf, sizeof(AVComplexFloat));
for (k = 0; k < s->rdft_len - idx->overlap_idx; k++)
buf[k] += obuf[k];
memcpy(data, buf, nsamples * sizeof(*data));
idx->buf_idx = !idx->buf_idx;
idx->overlap_idx = nsamples;
} else {
while (nsamples > s->nsamples_max * 2) {
fast_convolute_nonlinear(s, kernel_buf, conv_buf, idx, data, s->nsamples_max);
data += s->nsamples_max;
nsamples -= s->nsamples_max;
}
fast_convolute_nonlinear(s, kernel_buf, conv_buf, idx, data, nsamples/2);
fast_convolute_nonlinear(s, kernel_buf, conv_buf, idx, data + nsamples/2, nsamples - nsamples/2);
}
}
static void fast_convolute2(FIREqualizerContext *restrict s, const float *restrict kernel_buf, AVComplexFloat *restrict conv_buf,
OverlapIndex *restrict idx, float *restrict data0, float *restrict data1, int nsamples)
{
if (nsamples <= s->nsamples_max) {
AVComplexFloat *buf = conv_buf + idx->buf_idx * s->rdft_len;
AVComplexFloat *obuf = conv_buf + !idx->buf_idx * s->rdft_len + idx->overlap_idx;
AVComplexFloat *tbuf = (AVComplexFloat *)s->tx_buf;
int center = s->fir_len/2;
int k;
float tmp;
memset(buf, 0, center * sizeof(*buf));
for (k = 0; k < nsamples; k++) {
buf[center+k].re = data0[k];
buf[center+k].im = data1[k];
}
memset(buf + center + nsamples, 0, (s->rdft_len - nsamples - center) * sizeof(*buf));
s->fft_fn(s->fft_ctx, tbuf, buf, sizeof(AVComplexFloat));
/* swap re <-> im, do backward fft using forward fft_ctx */
/* normalize with 0.5f */
tmp = tbuf[0].re;
tbuf[0].re = 0.5f * kernel_buf[0] * tbuf[0].im;
tbuf[0].im = 0.5f * kernel_buf[0] * tmp;
for (k = 1; k < s->rdft_len/2; k++) {
int m = s->rdft_len - k;
tmp = tbuf[k].re;
tbuf[k].re = 0.5f * kernel_buf[k] * tbuf[k].im;
tbuf[k].im = 0.5f * kernel_buf[k] * tmp;
tmp = tbuf[m].re;
tbuf[m].re = 0.5f * kernel_buf[k] * tbuf[m].im;
tbuf[m].im = 0.5f * kernel_buf[k] * tmp;
}
tmp = tbuf[k].re;
tbuf[k].re = 0.5f * kernel_buf[k] * tbuf[k].im;
tbuf[k].im = 0.5f * kernel_buf[k] * tmp;
s->fft_fn(s->fft_ctx, buf, tbuf, sizeof(AVComplexFloat));
for (k = 0; k < s->rdft_len - idx->overlap_idx; k++) {
buf[k].re += obuf[k].re;
buf[k].im += obuf[k].im;
}
/* swapped re <-> im */
for (k = 0; k < nsamples; k++) {
data0[k] = buf[k].im;
data1[k] = buf[k].re;
}
idx->buf_idx = !idx->buf_idx;
idx->overlap_idx = nsamples;
} else {
while (nsamples > s->nsamples_max * 2) {
fast_convolute2(s, kernel_buf, conv_buf, idx, data0, data1, s->nsamples_max);
data0 += s->nsamples_max;
data1 += s->nsamples_max;
nsamples -= s->nsamples_max;
}
fast_convolute2(s, kernel_buf, conv_buf, idx, data0, data1, nsamples/2);
fast_convolute2(s, kernel_buf, conv_buf, idx, data0 + nsamples/2, data1 + nsamples/2, nsamples - nsamples/2);
}
}
static void dump_fir(AVFilterContext *ctx, FILE *fp, int ch)
{
FIREqualizerContext *s = ctx->priv;
int rate = ctx->inputs[0]->sample_rate;
int xlog = s->dumpscale == SCALE_LOGLIN || s->dumpscale == SCALE_LOGLOG;
int ylog = s->dumpscale == SCALE_LINLOG || s->dumpscale == SCALE_LOGLOG;
int x;
int center = s->fir_len / 2;
double delay = s->zero_phase ? 0.0 : (double) center / rate;
double vx, ya, yb;
if (!s->min_phase) {
s->analysis_buf[0] *= s->rdft_len/2;
for (x = 1; x <= center; x++) {
s->analysis_buf[x] *= s->rdft_len/2;
s->analysis_buf[s->analysis_rdft_len - x] *= s->rdft_len/2;
}
} else {
for (x = 0; x < s->fir_len; x++)
s->analysis_buf[x] *= s->rdft_len/2;
}
if (ch)
fprintf(fp, "\n\n");
fprintf(fp, "# time[%d] (time amplitude)\n", ch);
if (!s->min_phase) {
for (x = center; x > 0; x--)
fprintf(fp, "%15.10f %15.10f\n", delay - (double) x / rate, (double) s->analysis_buf[s->analysis_rdft_len - x]);
for (x = 0; x <= center; x++)
fprintf(fp, "%15.10f %15.10f\n", delay + (double)x / rate , (double) s->analysis_buf[x]);
} else {
for (x = 0; x < s->fir_len; x++)
fprintf(fp, "%15.10f %15.10f\n", (double)x / rate, (double) s->analysis_buf[x]);
}
s->analysis_rdft_fn(s->analysis_rdft, s->analysis_tbuf, s->analysis_buf, sizeof(float));
fprintf(fp, "\n\n# freq[%d] (frequency desired_gain actual_gain)\n", ch);
for (x = 0; x <= s->analysis_rdft_len/2; x++) {
int i = 2 * x;
vx = (double)x * rate / s->analysis_rdft_len;
if (xlog)
vx = log2(0.05*vx);
ya = s->dump_buf[i];
yb = s->min_phase ? hypotf(s->analysis_tbuf[i], s->analysis_tbuf[i+1]) : s->analysis_tbuf[i];
if (s->min_phase)
yb = fabs(yb);
if (ylog) {
ya = 20.0 * log10(fabs(ya));
yb = 20.0 * log10(fabs(yb));
}
fprintf(fp, "%17.10f %17.10f %17.10f\n", vx, ya, yb);
}
}
static double entry_func(void *p, double freq, double gain)
{
AVFilterContext *ctx = p;
FIREqualizerContext *s = ctx->priv;
if (s->nb_gain_entry >= NB_GAIN_ENTRY_MAX) {
av_log(ctx, AV_LOG_ERROR, "entry table overflow.\n");
s->gain_entry_err = AVERROR(EINVAL);
return 0;
}
if (isnan(freq)) {
av_log(ctx, AV_LOG_ERROR, "nan frequency (%g, %g).\n", freq, gain);
s->gain_entry_err = AVERROR(EINVAL);
return 0;
}
if (s->nb_gain_entry > 0 && freq <= s->gain_entry_tbl[s->nb_gain_entry - 1].freq) {
av_log(ctx, AV_LOG_ERROR, "unsorted frequency (%g, %g).\n", freq, gain);
s->gain_entry_err = AVERROR(EINVAL);
return 0;
}
s->gain_entry_tbl[s->nb_gain_entry].freq = freq;
s->gain_entry_tbl[s->nb_gain_entry].gain = gain;
s->nb_gain_entry++;
return 0;
}
static int gain_entry_compare(const void *key, const void *memb)
{
const double *freq = key;
const GainEntry *entry = memb;
if (*freq < entry[0].freq)
return -1;
if (*freq > entry[1].freq)
return 1;
return 0;
}
static double gain_interpolate_func(void *p, double freq)
{
AVFilterContext *ctx = p;
FIREqualizerContext *s = ctx->priv;
GainEntry *res;
double d0, d1, d;
if (isnan(freq))
return freq;
if (!s->nb_gain_entry)
return 0;
if (freq <= s->gain_entry_tbl[0].freq)
return s->gain_entry_tbl[0].gain;
if (freq >= s->gain_entry_tbl[s->nb_gain_entry-1].freq)
return s->gain_entry_tbl[s->nb_gain_entry-1].gain;
res = bsearch(&freq, &s->gain_entry_tbl, s->nb_gain_entry - 1, sizeof(*res), gain_entry_compare);
av_assert0(res);
d = res[1].freq - res[0].freq;
d0 = freq - res[0].freq;
d1 = res[1].freq - freq;
if (d0 && d1)
return (d0 * res[1].gain + d1 * res[0].gain) / d;
if (d0)
return res[1].gain;
return res[0].gain;
}
static double cubic_interpolate_func(void *p, double freq)
{
AVFilterContext *ctx = p;
FIREqualizerContext *s = ctx->priv;
GainEntry *res;
double x, x2, x3;
double a, b, c, d;
double m0, m1, m2, msum, unit;
if (!s->nb_gain_entry)
return 0;
if (freq <= s->gain_entry_tbl[0].freq)
return s->gain_entry_tbl[0].gain;
if (freq >= s->gain_entry_tbl[s->nb_gain_entry-1].freq)
return s->gain_entry_tbl[s->nb_gain_entry-1].gain;
res = bsearch(&freq, &s->gain_entry_tbl, s->nb_gain_entry - 1, sizeof(*res), gain_entry_compare);
av_assert0(res);
unit = res[1].freq - res[0].freq;
m0 = res != s->gain_entry_tbl ?
unit * (res[0].gain - res[-1].gain) / (res[0].freq - res[-1].freq) : 0;
m1 = res[1].gain - res[0].gain;
m2 = res != s->gain_entry_tbl + s->nb_gain_entry - 2 ?
unit * (res[2].gain - res[1].gain) / (res[2].freq - res[1].freq) : 0;
msum = fabs(m0) + fabs(m1);
m0 = msum > 0 ? (fabs(m0) * m1 + fabs(m1) * m0) / msum : 0;
msum = fabs(m1) + fabs(m2);
m1 = msum > 0 ? (fabs(m1) * m2 + fabs(m2) * m1) / msum : 0;
d = res[0].gain;
c = m0;
b = 3 * res[1].gain - m1 - 2 * c - 3 * d;
a = res[1].gain - b - c - d;
x = (freq - res[0].freq) / unit;
x2 = x * x;
x3 = x2 * x;
return a * x3 + b * x2 + c * x + d;
}
static const char *const var_names[] = {
"f",
"sr",
"ch",
"chid",
"chs",
"chlayout",
NULL
};
enum VarOffset {
VAR_F,
VAR_SR,
VAR_CH,
VAR_CHID,
VAR_CHS,
VAR_CHLAYOUT,
VAR_NB
};
static void generate_min_phase_kernel(FIREqualizerContext *s, float *rdft_buf)
{
int k, cepstrum_len = s->cepstrum_len, rdft_len = s->rdft_len;
double norm = 2.0 / cepstrum_len;
double minval = 1e-7 / rdft_len;
memset(s->cepstrum_buf, 0, cepstrum_len * sizeof(*s->cepstrum_buf));
memset(s->cepstrum_tbuf, 0, (cepstrum_len + 2) * sizeof(*s->cepstrum_tbuf));
memcpy(s->cepstrum_buf, rdft_buf, rdft_len/2 * sizeof(*rdft_buf));
memcpy(s->cepstrum_buf + cepstrum_len - rdft_len/2, rdft_buf + rdft_len/2, rdft_len/2 * sizeof(*rdft_buf));
s->cepstrum_rdft_fn(s->cepstrum_rdft, s->cepstrum_tbuf, s->cepstrum_buf, sizeof(float));
for (k = 0; k < cepstrum_len + 2; k += 2) {
s->cepstrum_tbuf[k] = log(FFMAX(s->cepstrum_tbuf[k], minval));
s->cepstrum_tbuf[k+1] = 0;
}
s->cepstrum_irdft_fn(s->cepstrum_irdft, s->cepstrum_buf, s->cepstrum_tbuf, sizeof(AVComplexFloat));
memset(s->cepstrum_buf + cepstrum_len/2 + 1, 0, (cepstrum_len/2 - 1) * sizeof(*s->cepstrum_buf));
for (k = 1; k <= cepstrum_len/2; k++)
s->cepstrum_buf[k] *= 2;
s->cepstrum_rdft_fn(s->cepstrum_rdft, s->cepstrum_tbuf, s->cepstrum_buf, sizeof(float));
for (k = 0; k < cepstrum_len + 2; k += 2) {
double mag = exp(s->cepstrum_tbuf[k] * norm) * norm;
double ph = s->cepstrum_tbuf[k+1] * norm;
s->cepstrum_tbuf[k] = mag * cos(ph);
s->cepstrum_tbuf[k+1] = mag * sin(ph);
}
s->cepstrum_irdft_fn(s->cepstrum_irdft, s->cepstrum_buf, s->cepstrum_tbuf, sizeof(AVComplexFloat));
memset(rdft_buf, 0, s->rdft_len * sizeof(*rdft_buf));
memcpy(rdft_buf, s->cepstrum_buf, s->fir_len * sizeof(*rdft_buf));
if (s->dumpfile) {
memset(s->analysis_buf, 0, (s->analysis_rdft_len + 2) * sizeof(*s->analysis_buf));
memcpy(s->analysis_buf, s->cepstrum_buf, s->fir_len * sizeof(*s->analysis_buf));
}
}
static int generate_kernel(AVFilterContext *ctx, const char *gain, const char *gain_entry)
{
FIREqualizerContext *s = ctx->priv;
AVFilterLink *inlink = ctx->inputs[0];
const char *gain_entry_func_names[] = { "entry", NULL };
const char *gain_func_names[] = { "gain_interpolate", "cubic_interpolate", NULL };
double (*gain_entry_funcs[])(void *, double, double) = { entry_func, NULL };
double (*gain_funcs[])(void *, double) = { gain_interpolate_func, cubic_interpolate_func, NULL };
double vars[VAR_NB];
AVExpr *gain_expr;
int ret, k, center, ch;
int xlog = s->scale == SCALE_LOGLIN || s->scale == SCALE_LOGLOG;
int ylog = s->scale == SCALE_LINLOG || s->scale == SCALE_LOGLOG;
FILE *dump_fp = NULL;
s->nb_gain_entry = 0;
s->gain_entry_err = 0;
if (gain_entry) {
double result = 0.0;
ret = av_expr_parse_and_eval(&result, gain_entry, NULL, NULL, NULL, NULL,
gain_entry_func_names, gain_entry_funcs, ctx, 0, ctx);
if (ret < 0)
return ret;
if (s->gain_entry_err < 0)
return s->gain_entry_err;
}
av_log(ctx, AV_LOG_DEBUG, "nb_gain_entry = %d.\n", s->nb_gain_entry);
ret = av_expr_parse(&gain_expr, gain, var_names,
gain_func_names, gain_funcs, NULL, NULL, 0, ctx);
if (ret < 0)
return ret;
if (s->dumpfile && (!s->dump_buf || !s->analysis_rdft || !(dump_fp = avpriv_fopen_utf8(s->dumpfile, "w"))))
av_log(ctx, AV_LOG_WARNING, "dumping failed.\n");
vars[VAR_CHS] = inlink->ch_layout.nb_channels;
vars[VAR_CHLAYOUT] = inlink->ch_layout.order == AV_CHANNEL_ORDER_NATIVE ?
inlink->ch_layout.u.mask : 0;
vars[VAR_SR] = inlink->sample_rate;
for (ch = 0; ch < inlink->ch_layout.nb_channels; ch++) {
float *rdft_buf = s->kernel_tmp_buf + ch * (s->rdft_len * 2);
float *rdft_tbuf = s->kernel_tmp_tbuf;
double result;
vars[VAR_CH] = ch;
vars[VAR_CHID] = av_channel_layout_channel_from_index(&inlink->ch_layout, ch);
for (k = 0; k <= s->analysis_rdft_len/2; k++) {
vars[VAR_F] = k * ((double)inlink->sample_rate /(double)s->analysis_rdft_len);
if (xlog)
vars[VAR_F] = log2(0.05 * vars[VAR_F]);
result = av_expr_eval(gain_expr, vars, ctx);
s->analysis_tbuf[2*k] = ylog ? pow(10.0, 0.05 * result) : s->min_phase ? fabs(result) : result;
s->analysis_tbuf[2*k+1] = 0.0;
}
if (s->dump_buf)
memcpy(s->dump_buf, s->analysis_tbuf, (s->analysis_rdft_len + 2) * sizeof(*s->analysis_tbuf));
s->analysis_irdft_fn(s->analysis_irdft, s->analysis_buf, s->analysis_tbuf, sizeof(AVComplexFloat));
center = s->fir_len / 2;
for (k = 0; k <= center; k++) {
double u = k * (M_PI/center);
double win;
switch (s->wfunc) {
case WFUNC_RECTANGULAR:
win = 1.0;
break;
case WFUNC_HANN:
win = 0.5 + 0.5 * cos(u);
break;
case WFUNC_HAMMING:
win = 0.53836 + 0.46164 * cos(u);
break;
case WFUNC_BLACKMAN:
win = 0.42 + 0.5 * cos(u) + 0.08 * cos(2*u);
break;
case WFUNC_NUTTALL3:
win = 0.40897 + 0.5 * cos(u) + 0.09103 * cos(2*u);
break;
case WFUNC_MNUTTALL3:
win = 0.4243801 + 0.4973406 * cos(u) + 0.0782793 * cos(2*u);
break;
case WFUNC_NUTTALL:
win = 0.355768 + 0.487396 * cos(u) + 0.144232 * cos(2*u) + 0.012604 * cos(3*u);
break;
case WFUNC_BNUTTALL:
win = 0.3635819 + 0.4891775 * cos(u) + 0.1365995 * cos(2*u) + 0.0106411 * cos(3*u);
break;
case WFUNC_BHARRIS:
win = 0.35875 + 0.48829 * cos(u) + 0.14128 * cos(2*u) + 0.01168 * cos(3*u);
break;
case WFUNC_TUKEY:
win = (u <= 0.5 * M_PI) ? 1.0 : (0.5 + 0.5 * cos(2*u - M_PI));
break;
default:
av_assert0(0);
}
s->analysis_buf[k] *= (2.0/s->analysis_rdft_len) * (2.0/s->rdft_len) * win;
if (k)
s->analysis_buf[s->analysis_rdft_len - k] = s->analysis_buf[k];
}
memset(s->analysis_buf + center + 1, 0, (s->analysis_rdft_len - s->fir_len) * sizeof(*s->analysis_buf));
memcpy(rdft_tbuf, s->analysis_buf, s->rdft_len/2 * sizeof(*s->analysis_buf));
memcpy(rdft_tbuf + s->rdft_len/2, s->analysis_buf + s->analysis_rdft_len - s->rdft_len/2, s->rdft_len/2 * sizeof(*s->analysis_buf));
if (s->min_phase)
generate_min_phase_kernel(s, rdft_tbuf);
s->rdft_fn(s->rdft, rdft_buf, rdft_tbuf, sizeof(float));
for (k = 0; k < s->rdft_len + 2; k++) {
if (isnan(rdft_buf[k]) || isinf(rdft_buf[k])) {
av_log(ctx, AV_LOG_ERROR, "filter kernel contains nan or infinity.\n");
av_expr_free(gain_expr);
if (dump_fp)
fclose(dump_fp);
return AVERROR(EINVAL);
}
}
if (!s->min_phase) {
for (k = 0; k <= s->rdft_len/2; k++)
rdft_buf[k] = rdft_buf[2*k];
}
if (dump_fp)
dump_fir(ctx, dump_fp, ch);
if (!s->multi)
break;
}
memcpy(s->kernel_buf, s->kernel_tmp_buf, (s->multi ? inlink->ch_layout.nb_channels : 1) * (s->rdft_len * 2) * sizeof(*s->kernel_buf));
av_expr_free(gain_expr);
if (dump_fp)
fclose(dump_fp);
return 0;
}
#define SELECT_GAIN(s) (s->gain_cmd ? s->gain_cmd : s->gain)
#define SELECT_GAIN_ENTRY(s) (s->gain_entry_cmd ? s->gain_entry_cmd : s->gain_entry)
static int config_input(AVFilterLink *inlink)
{
AVFilterContext *ctx = inlink->dst;
FIREqualizerContext *s = ctx->priv;
float iscale, scale = 1.f;
int rdft_bits, ret;
common_uninit(s);
s->next_pts = 0;
s->frame_nsamples_max = 0;
s->fir_len = FFMAX(2 * (int)(inlink->sample_rate * s->delay) + 1, 3);
s->remaining = s->fir_len - 1;
for (rdft_bits = RDFT_BITS_MIN; rdft_bits <= RDFT_BITS_MAX; rdft_bits++) {
s->rdft_len = 1 << rdft_bits;
s->nsamples_max = s->rdft_len - s->fir_len + 1;
if (s->nsamples_max * 2 >= s->fir_len)
break;
}
if (rdft_bits > RDFT_BITS_MAX) {
av_log(ctx, AV_LOG_ERROR, "too large delay, please decrease it.\n");
return AVERROR(EINVAL);
}
iscale = 0.5f;
if (((ret = av_tx_init(&s->rdft, &s->rdft_fn, AV_TX_FLOAT_RDFT, 0, 1 << rdft_bits, &scale, 0)) < 0) ||
((ret = av_tx_init(&s->irdft, &s->irdft_fn, AV_TX_FLOAT_RDFT, 1, 1 << rdft_bits, &iscale, 0)) < 0))
return ret;
scale = 1.f;
if (s->fft2 && !s->multi && inlink->ch_layout.nb_channels > 1 &&
((ret = av_tx_init(&s->fft_ctx, &s->fft_fn, AV_TX_FLOAT_FFT, 0, 1 << rdft_bits, &scale, 0)) < 0))
return ret;
if (s->min_phase) {
int cepstrum_bits = rdft_bits + 2;
if (cepstrum_bits > RDFT_BITS_MAX) {
av_log(ctx, AV_LOG_ERROR, "too large delay, please decrease it.\n");
return AVERROR(EINVAL);
}
cepstrum_bits = FFMIN(RDFT_BITS_MAX, cepstrum_bits + 1);
scale = 1.f;
ret = av_tx_init(&s->cepstrum_rdft, &s->cepstrum_rdft_fn, AV_TX_FLOAT_RDFT, 0, 1 << cepstrum_bits, &scale, 0);
if (ret < 0)
return ret;
iscale = 0.5f;
ret = av_tx_init(&s->cepstrum_irdft, &s->cepstrum_irdft_fn, AV_TX_FLOAT_RDFT, 1, 1 << cepstrum_bits, &iscale, 0);
if (ret < 0)
return ret;
s->cepstrum_len = 1 << cepstrum_bits;
s->cepstrum_buf = av_malloc_array(s->cepstrum_len, sizeof(*s->cepstrum_buf));
if (!s->cepstrum_buf)
return AVERROR(ENOMEM);
s->cepstrum_tbuf = av_malloc_array(s->cepstrum_len + 2, sizeof(*s->cepstrum_tbuf));
if (!s->cepstrum_tbuf)
return AVERROR(ENOMEM);
}
for ( ; rdft_bits <= RDFT_BITS_MAX; rdft_bits++) {
s->analysis_rdft_len = 1 << rdft_bits;
if (inlink->sample_rate <= s->accuracy * s->analysis_rdft_len)
break;
}
if (rdft_bits > RDFT_BITS_MAX) {
av_log(ctx, AV_LOG_ERROR, "too small accuracy, please increase it.\n");
return AVERROR(EINVAL);
}
iscale = 0.5f;
if ((ret = av_tx_init(&s->analysis_irdft, &s->analysis_irdft_fn, AV_TX_FLOAT_RDFT, 1, 1 << rdft_bits, &iscale, 0)) < 0)
return ret;
if (s->dumpfile) {
scale = 1.f;
if ((ret = av_tx_init(&s->analysis_rdft, &s->analysis_rdft_fn, AV_TX_FLOAT_RDFT, 0, 1 << rdft_bits, &scale, 0)) < 0)
return ret;
s->dump_buf = av_malloc_array(s->analysis_rdft_len + 2, sizeof(*s->dump_buf));
}
s->analysis_buf = av_malloc_array((s->analysis_rdft_len + 2), sizeof(*s->analysis_buf));
s->analysis_tbuf = av_malloc_array(s->analysis_rdft_len + 2, sizeof(*s->analysis_tbuf));
s->kernel_tmp_buf = av_malloc_array((s->rdft_len * 2) * (s->multi ? inlink->ch_layout.nb_channels : 1), sizeof(*s->kernel_tmp_buf));
s->kernel_tmp_tbuf = av_malloc_array(s->rdft_len, sizeof(*s->kernel_tmp_tbuf));
s->kernel_buf = av_malloc_array((s->rdft_len * 2) * (s->multi ? inlink->ch_layout.nb_channels : 1), sizeof(*s->kernel_buf));
s->tx_buf = av_malloc_array(2 * (s->rdft_len + 2), sizeof(*s->kernel_buf));
s->conv_buf = av_calloc(2 * s->rdft_len * inlink->ch_layout.nb_channels, sizeof(*s->conv_buf));
s->conv_idx = av_calloc(inlink->ch_layout.nb_channels, sizeof(*s->conv_idx));
if (!s->analysis_buf || !s->analysis_tbuf || !s->kernel_tmp_buf || !s->kernel_buf || !s->conv_buf || !s->conv_idx || !s->kernel_tmp_tbuf || !s->tx_buf)
return AVERROR(ENOMEM);
av_log(ctx, AV_LOG_DEBUG, "sample_rate = %d, channels = %d, analysis_rdft_len = %d, rdft_len = %d, fir_len = %d, nsamples_max = %d.\n",
inlink->sample_rate, inlink->ch_layout.nb_channels, s->analysis_rdft_len, s->rdft_len, s->fir_len, s->nsamples_max);
if (s->fixed)
inlink->min_samples = inlink->max_samples = s->nsamples_max;
return generate_kernel(ctx, SELECT_GAIN(s), SELECT_GAIN_ENTRY(s));
}
static int filter_frame(AVFilterLink *inlink, AVFrame *frame)
{
AVFilterContext *ctx = inlink->dst;
FIREqualizerContext *s = ctx->priv;
int ch;
if (!s->min_phase) {
for (ch = 0; ch + 1 < inlink->ch_layout.nb_channels && s->fft_ctx; ch += 2) {
fast_convolute2(s, s->kernel_buf, (AVComplexFloat *)(s->conv_buf + 2 * ch * s->rdft_len),
s->conv_idx + ch, (float *) frame->extended_data[ch],
(float *) frame->extended_data[ch+1], frame->nb_samples);
}
for ( ; ch < inlink->ch_layout.nb_channels; ch++) {
fast_convolute(s, s->kernel_buf + (s->multi ? ch * (s->rdft_len * 2) : 0),
s->conv_buf + 2 * ch * s->rdft_len, s->conv_idx + ch,
(float *) frame->extended_data[ch], frame->nb_samples);
}
} else {
for (ch = 0; ch < inlink->ch_layout.nb_channels; ch++) {
fast_convolute_nonlinear(s, s->kernel_buf + (s->multi ? ch * (s->rdft_len * 2) : 0),
s->conv_buf + 2 * ch * s->rdft_len, s->conv_idx + ch,
(float *) frame->extended_data[ch], frame->nb_samples);
}
}
s->next_pts = AV_NOPTS_VALUE;
if (frame->pts != AV_NOPTS_VALUE) {
s->next_pts = frame->pts + av_rescale_q(frame->nb_samples, av_make_q(1, inlink->sample_rate), inlink->time_base);
if (s->zero_phase && !s->min_phase)
frame->pts -= av_rescale_q(s->fir_len/2, av_make_q(1, inlink->sample_rate), inlink->time_base);
}
s->frame_nsamples_max = FFMAX(s->frame_nsamples_max, frame->nb_samples);
return ff_filter_frame(ctx->outputs[0], frame);
}
static int request_frame(AVFilterLink *outlink)
{
AVFilterContext *ctx = outlink->src;
FIREqualizerContext *s= ctx->priv;
int ret;
ret = ff_request_frame(ctx->inputs[0]);
if (ret == AVERROR_EOF && s->remaining > 0 && s->frame_nsamples_max > 0) {
AVFrame *frame = ff_get_audio_buffer(outlink, FFMIN(s->remaining, s->frame_nsamples_max));
if (!frame)
return AVERROR(ENOMEM);
av_samples_set_silence(frame->extended_data, 0, frame->nb_samples, outlink->ch_layout.nb_channels, frame->format);
frame->pts = s->next_pts;
s->remaining -= frame->nb_samples;
ret = filter_frame(ctx->inputs[0], frame);
}
return ret;
}
static int process_command(AVFilterContext *ctx, const char *cmd, const char *args,
char *res, int res_len, int flags)
{
FIREqualizerContext *s = ctx->priv;
int ret = AVERROR(ENOSYS);
if (!strcmp(cmd, "gain")) {
char *gain_cmd;
if (SELECT_GAIN(s) && !strcmp(SELECT_GAIN(s), args)) {
av_log(ctx, AV_LOG_DEBUG, "equal gain, do not rebuild.\n");
return 0;
}
gain_cmd = av_strdup(args);
if (!gain_cmd)
return AVERROR(ENOMEM);
ret = generate_kernel(ctx, gain_cmd, SELECT_GAIN_ENTRY(s));
if (ret >= 0) {
av_freep(&s->gain_cmd);
s->gain_cmd = gain_cmd;
} else {
av_freep(&gain_cmd);
}
} else if (!strcmp(cmd, "gain_entry")) {
char *gain_entry_cmd;
if (SELECT_GAIN_ENTRY(s) && !strcmp(SELECT_GAIN_ENTRY(s), args)) {
av_log(ctx, AV_LOG_DEBUG, "equal gain_entry, do not rebuild.\n");
return 0;
}
gain_entry_cmd = av_strdup(args);
if (!gain_entry_cmd)
return AVERROR(ENOMEM);
ret = generate_kernel(ctx, SELECT_GAIN(s), gain_entry_cmd);
if (ret >= 0) {
av_freep(&s->gain_entry_cmd);
s->gain_entry_cmd = gain_entry_cmd;
} else {
av_freep(&gain_entry_cmd);
}
}
return ret;
}
static const AVFilterPad firequalizer_inputs[] = {
{
.name = "default",
.flags = AVFILTERPAD_FLAG_NEEDS_WRITABLE,
.config_props = config_input,
.filter_frame = filter_frame,
.type = AVMEDIA_TYPE_AUDIO,
},
};
static const AVFilterPad firequalizer_outputs[] = {
{
.name = "default",
.request_frame = request_frame,
.type = AVMEDIA_TYPE_AUDIO,
},
};
const AVFilter ff_af_firequalizer = {
.name = "firequalizer",
.description = NULL_IF_CONFIG_SMALL("Finite Impulse Response Equalizer."),
.uninit = uninit,
.process_command = process_command,
.priv_size = sizeof(FIREqualizerContext),
FILTER_INPUTS(firequalizer_inputs),
FILTER_OUTPUTS(firequalizer_outputs),
FILTER_SINGLE_SAMPLEFMT(AV_SAMPLE_FMT_FLTP),
.priv_class = &firequalizer_class,
};