ref: f140e52941bed2b902411f6eab0804c81fd4a072
dir: /src/rate_poly_fir.h/
/* Effect: change sample rate Copyright (c) 2008,12 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 */ /* Resample using an interpolated poly-phase FIR with length LEN.*/ /* Input must be followed by LEN-1 samples. */ #define a (coef(p->shared->poly_fir_coefs, COEF_INTERP, FIR_LENGTH, phase, 0,j)) #define b (coef(p->shared->poly_fir_coefs, COEF_INTERP, FIR_LENGTH, phase, 1,j)) #define c (coef(p->shared->poly_fir_coefs, COEF_INTERP, FIR_LENGTH, phase, 2,j)) #define d (coef(p->shared->poly_fir_coefs, COEF_INTERP, FIR_LENGTH, phase, 3,j)) #if COEF_INTERP == 0 #define _ sum += a *in[j], ++j; #elif COEF_INTERP == 1 #define _ sum += (b *x + a)*in[j], ++j; #elif COEF_INTERP == 2 #define _ sum += ((c *x + b)*x + a)*in[j], ++j; #elif COEF_INTERP == 3 #define _ sum += (((d*x + c)*x + b)*x + a)*in[j], ++j; #else #error COEF_INTERP #endif static void FUNCTION(stage_t * p, fifo_t * output_fifo) { sample_t const * input = stage_read_p(p); int i, num_in = stage_occupancy(p), max_num_out = 1 + num_in*p->out_in_ratio; sample_t * output = fifo_reserve(output_fifo, max_num_out); #if defined HI_PREC_CLOCK if (p->use_hi_prec_clock) { hi_prec_clock_t at = p->at.hi_prec_clock; for (i = 0; (int)at < num_in; ++i, at += p->step.hi_prec_clock) { sample_t const * in = input + (int)at; hi_prec_clock_t fraction = at - (int)at; int phase = fraction * (1 << PHASE_BITS); #if COEF_INTERP > 0 sample_t x = fraction * (1 << PHASE_BITS) - phase; #endif sample_t sum = 0; int j = 0; CONVOLVE output[i] = sum; } fifo_read(&p->fifo, (int)at, NULL); p->at.hi_prec_clock = at - (int)at; } else #endif { for (i = 0; p->at.parts.integer < num_in; ++i, p->at.all += p->step.all) { sample_t const * in = input + p->at.parts.integer; uint32_t fraction = p->at.parts.fraction; int phase = fraction >> (32 - PHASE_BITS); /* high-order bits */ #if COEF_INTERP > 0 /* low-order bits, scaled to [0,1) */ sample_t x = (sample_t) (fraction << PHASE_BITS) * (1 / MULT32); #endif sample_t sum = 0; int j = 0; CONVOLVE output[i] = sum; } fifo_read(&p->fifo, p->at.parts.integer, NULL); p->at.parts.integer = 0; } assert(max_num_out - i >= 0); fifo_trim_by(output_fifo, max_num_out - i); } #undef _ #undef a #undef b #undef c #undef d #undef COEF_INTERP #undef CONVOLVE #undef FIR_LENGTH #undef FUNCTION #undef PHASE_BITS