ref: 8dfc09d5e2ca3e9dfa06d251ec58fbd1d6b5d6dd
dir: /src/equalizer.c/
/* Equalizer filter effect file for SoX Copyright (C) 2006 Pascal Giard <evilynux@gmail.com> This library 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 of the License, or (at your option) any later version. This library 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 this library; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA Code based on the biquad filters described in Cookbook formulae for audio EQ biquad filter coefficients by Robert Bristow-Johnson <rbj@audioimagination.com> Theory: y[n] = (a0/b0)*x[n] + (b1/a0)*x[n-1] + (b2/a0)*x[n-2] - (a1/a0)*y[n-1] - (a2/a0)*y[n-2] Where: w0 = 2*M_PI*cfreq/srate A = 10^(gain/40) alpha = sin(w0)/( 2*Q ) For a PeakingEQ filter: b0 = 1 + alpha*A b1 = -2*cos(w0) b2 = 1 - alpha*A a0 = 1 + alpha/A a1 = -2*cos(w0) a2 = 1 - alpha/A Reminder: Q = sqrt(2^n)/(2^n - 1) where n is bandwidth in octave n = log2(bw) where bw is bandwidth in Hz Transfer function is: (a0/b0) + (b1/a0)z^-1 + (b2/a0)z^-2 H(z) = ----------------------------------- 1 + (a1/a0)z^-1 + (a2/a0)z^-2 */ #include <math.h> #include "st_i.h" static st_effect_t st_equalizer_effect; /* Filter parameters */ typedef struct filterparams { float rate; // Sample rate float Q; // Q-factor float cfreq; // Central frequency (Hz) float gain; // Gain (dB) double x[3]; // In where x[2] <=> x[ n - 2 ] double y[3]; // Out double b[3]; // From this point, equation constants... double a[3]; } *equalizer_t; int st_equalizer_getopts(eff_t effp, int n, char **argv) { equalizer_t eq = (equalizer_t) effp->priv; int i; if (n < 3) { st_fail("Usage: equalizer center-freq Q gain"); return (ST_EOF); } i = 0; sscanf(argv[i++], "%f", &eq->cfreq); sscanf(argv[i++], "%f", &eq->Q); sscanf(argv[i++], "%f", &eq->gain); // TODO: Would be nice to validate the params.. return (ST_SUCCESS); } // Set the filter constants int st_equalizer_start(eff_t effp) { equalizer_t eq = (equalizer_t) effp->priv; double w0; double amp; double alpha; // Sample rate eq->rate = effp->ininfo.rate; w0 = 2*M_PI*eq->cfreq/eq->rate; amp = pow( 10, eq->gain/40 ); alpha = sin(w0)/( 2*eq->Q ); st_report("Debug: cfreq: %fHz", eq->cfreq); st_report("Debug: Q: %f", eq->Q); st_report("Debug: gain: %fdB", eq->gain); st_report("Debug: rate: %f", eq->rate); st_report("Debug: w0: %f", w0); st_report("Debug: amp: %f", amp); st_report("Debug: alpha: %f", alpha); // Initialisation eq->b[0] = 1 + alpha*amp; eq->b[1] = -2*cos(w0); eq->b[2] = 1 - alpha*amp; eq->a[0] = 1 + alpha/amp; eq->a[1] = -2*cos(w0); eq->a[2] = 1 - alpha/amp; eq->x[0] = 0; // x[n] eq->x[1] = 0; // x[n-1] eq->x[2] = 0; // x[n-2] eq->y[0] = 0; // y[n] eq->y[1] = 0; // y[n-1] eq->y[2] = 0; // y[n-2] if (effp->globalinfo.octave_plot_effect) { printf( "title('SoX effect: %s gain=%g centre=%g Q=%g (rate=%u)')\n" "xlabel('Frequency (Hz)')\n" "ylabel('Amplitude Response (dB)')\n" "Fs=%u;minF=10;maxF=Fs/2;\n" "axis([minF maxF -25 25])\n" "sweepF=logspace(log10(minF),log10(maxF),200);\n" "grid on\n" "[h,w]=freqz([%f %f %f],[%f %f %f],sweepF,Fs);\n" "semilogx(w,20*log10(h),'b')\n" "pause\n" , effp->name, eq->gain, eq->cfreq, eq->Q , effp->ininfo.rate, effp->ininfo.rate , eq->b[0], eq->b[1], eq->b[2], eq->a[0], eq->a[1], eq->a[2] ); exit(0); } return (ST_SUCCESS); } int st_equalizer_flow(eff_t effp, st_sample_t *ibuf, st_sample_t *obuf, st_size_t *isamp, st_size_t *osamp) { equalizer_t eq = (equalizer_t) effp->priv; st_size_t len, done; double out; len = ((*isamp > *osamp) ? *osamp : *isamp); for(done = 0; done < len; done++) { eq->x[2] = eq->x[1]; eq->x[1] = eq->x[0]; eq->x[0] = *ibuf++; eq->y[2] = eq->y[1]; eq->y[1] = eq->y[0]; out = ( (eq->b[0]/eq->a[0])*eq->x[0] + (eq->b[1]/eq->a[0])*eq->x[1] + (eq->b[2]/eq->a[0])*eq->x[2] - (eq->a[1]/eq->a[0])*eq->y[1] - (eq->a[2]/eq->a[0])*eq->y[2] ); eq->y[0] = out; if (out < ST_SAMPLE_MIN) { out = ST_SAMPLE_MIN; } else if (out > ST_SAMPLE_MAX) { out = ST_SAMPLE_MAX; } *obuf++ = out; } *isamp = len; *osamp = len; return (ST_SUCCESS); } static st_effect_t st_equalizer_effect = { "equalizer", "Usage: equalizer central-frequency Q gain", 0, st_equalizer_getopts, st_equalizer_start, st_equalizer_flow, st_effect_nothing_drain, st_effect_nothing }; const st_effect_t *st_equalizer_effect_fn(void) { return &st_equalizer_effect; }