ref: 0ac9f7f715bc5740ba06adcfc69eadf2f85457b1
dir: /src/mcompand_xover.h/
/* libSoX Compander Crossover Filter (c) 2008 robs@users.sourceforge.net * * 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 2.1 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #define N 4 /* 4th order Linkwitz-Riley IIRs */ #define CONVOLVE _ _ _ _ typedef struct {double in, out_low, out_high;} previous_t[N * 2]; typedef struct { previous_t * previous; size_t pos; double coefs[3 *(N+1)]; } crossover_t; static void square_quadratic(char const * name, double const * x, double * y) { assert(N == 4); y[0] = x[0] * x[0]; y[1] = 2 * x[0] * x[1]; y[2] = 2 * x[0] * x[2] + x[1] * x[1]; y[3] = 2 * x[1] * x[2]; y[4] = x[2] * x[2]; lsx_debug("%s=[%.16g %.16g %.16g %.16g %.16g];", name, y[0], y[1], y[2], y[3], y[4]); } static int crossover_setup(sox_effect_t * effp, crossover_t * p, double frequency) { double w0 = 2 * M_PI * frequency / effp->in_signal.rate; double Q = sqrt(.5), alpha = sin(w0)/(2*Q); double x[9], norm; int i; if (w0 > M_PI) { lsx_fail("frequency must not exceed half the sample-rate (Nyquist rate)"); return SOX_EOF; } x[0] = (1 - cos(w0))/2; /* Cf. filter_LPF in biquads.c */ x[1] = 1 - cos(w0); x[2] = (1 - cos(w0))/2; x[3] = (1 + cos(w0))/2; /* Cf. filter_HPF in biquads.c */ x[4] = -(1 + cos(w0)); x[5] = (1 + cos(w0))/2; x[6] = 1 + alpha; x[7] = -2*cos(w0); x[8] = 1 - alpha; for (norm = x[6], i = 0; i < 9; ++i) x[i] /= norm; square_quadratic("lb", x , p->coefs); square_quadratic("hb", x + 3, p->coefs + 5); square_quadratic("a" , x + 6, p->coefs + 10); p->previous = lsx_calloc(effp->in_signal.channels, sizeof(*p->previous)); return SOX_SUCCESS; } static int crossover_flow(sox_effect_t * effp, crossover_t * p, sox_sample_t *ibuf, sox_sample_t *obuf_low, sox_sample_t *obuf_high, size_t len0) { double out_low, out_high; size_t c, len = len0 / effp->in_signal.channels; assert(len * effp->in_signal.channels == len0); while (len--) { p->pos = p->pos? p->pos - 1 : N - 1; for (c = 0; c < effp->in_signal.channels; ++c) { #define _ out_low += p->coefs[j] * p->previous[c][p->pos + j].in \ - p->coefs[2*N+2 + j] * p->previous[c][p->pos + j].out_low, ++j; { int j = 1; out_low = p->coefs[0] * *ibuf; CONVOLVE assert(j == N+1); *obuf_low++ = SOX_ROUND_CLIP_COUNT(out_low, effp->clips); } #undef _ #define _ out_high += p->coefs[j+N+1] * p->previous[c][p->pos + j].in \ - p->coefs[2*N+2 + j] * p->previous[c][p->pos + j].out_high, ++j; { int j = 1; out_high = p->coefs[N+1] * *ibuf; CONVOLVE assert(j == N+1); *obuf_high++ = SOX_ROUND_CLIP_COUNT(out_high, effp->clips); } p->previous[c][p->pos + N].in = p->previous[c][p->pos].in = *ibuf++; p->previous[c][p->pos + N].out_low = p->previous[c][p->pos].out_low = out_low; p->previous[c][p->pos + N].out_high = p->previous[c][p->pos].out_high = out_high; } } return SOX_SUCCESS; }