ref: 8f98f6ba0fb009ffe70c7c6d9be4e3fd9e80d72a
dir: /src/helpers/fir_resampler.c/
#include <stdlib.h> #include <string.h> #include <math.h> #include "internal/fir_resampler.h" enum { fir_width = 16 }; enum { fir_max_res = 1024 }; enum { fir_min_width = (fir_width < 4 ? 4 : fir_width) }; enum { fir_adj_width = fir_min_width / 4 * 4 + 2 }; enum { fir_stereo = 1 }; /* channel count, not boolean value */ enum { fir_write_offset = fir_adj_width * fir_stereo }; enum { fir_buffer_size = fir_width * 2 }; typedef short fir_impulse[fir_adj_width]; /* exp slope to 31/32 of ln(8) */ static const double fir_ratios[32] = { 1.000, 1.067, 1.139, 1.215, 1.297, 1.384, 1.477, 1.576, 1.682, 1.795, 1.915, 2.044, 2.181, 2.327, 2.484, 2.650, 2.828, 3.018, 3.221, 3.437, 3.668, 3.914, 4.177, 4.458, 4.757, 5.076, 5.417, 5.781, 6.169, 6.583, 7.025, 7.497 }; static fir_impulse fir_impulses[32][fir_max_res]; #undef PI #define PI 3.1415926535897932384626433832795029 static void gen_sinc( double rolloff, int width, double offset, double spacing, double scale, int count, short* out ) { double const maxh = 256; double const step = PI / maxh * spacing; double const to_w = maxh * 2 / width; double const pow_a_n = pow( rolloff, maxh ); double angle = (count / 2 - 1 + offset) * -step; scale /= maxh * 2; while ( count-- ) { double w; *out++ = 0; w = angle * to_w; if ( fabs( w ) < PI ) { double rolloff_cos_a = rolloff * cos( angle ); double num = 1 - rolloff_cos_a - pow_a_n * cos( maxh * angle ) + pow_a_n * rolloff * cos( (maxh - 1) * angle ); double den = 1 - rolloff_cos_a - rolloff_cos_a + rolloff * rolloff; double sinc = scale * num / den - scale; out [-1] = (short) (cos( w ) * sinc + sinc); } angle += step; } } typedef struct fir_resampler { int write_pos, write_filled; int read_pos, read_filled; unsigned short phase; unsigned int phase_inc; unsigned int ratio_set; int buffer_in[fir_buffer_size * 2]; int buffer_out[fir_buffer_size]; } fir_resampler; void * fir_resampler_create() { fir_resampler * r = ( fir_resampler * ) malloc( sizeof(fir_resampler) ); if ( !r ) return 0; r->write_pos = 0; r->write_filled = 0; r->read_pos = 0; r->read_filled = 0; r->phase = 0; r->phase_inc = 0; r->ratio_set = 0; memset( r->buffer_in, 0, sizeof(r->buffer_in) ); memset( r->buffer_out, 0, sizeof(r->buffer_out) ); return r; } void fir_resampler_delete(void * _r) { free( _r ); } void * fir_resampler_dup(void * _r) { fir_resampler * r_in = ( fir_resampler * ) _r; fir_resampler * r_out = ( fir_resampler * ) malloc( sizeof(fir_resampler) ); if ( !r_out ) return 0; r_out->write_pos = r_in->write_pos; r_out->write_filled = r_in->write_filled; r_out->read_pos = r_in->read_pos; r_out->read_filled = r_in->read_filled; r_out->phase = r_in->phase; r_out->phase_inc = r_in->phase_inc; r_out->ratio_set = r_in->ratio_set; memcpy( r_out->buffer_in, r_in->buffer_in, sizeof(r_in->buffer_in) ); memcpy( r_out->buffer_out, r_in->buffer_out, sizeof(r_in->buffer_out) ); return r_out; } int fir_resampler_get_free_count(void *_r) { fir_resampler * r = ( fir_resampler * ) _r; return fir_buffer_size - r->write_filled; } int fir_resampler_ready(void *_r) { fir_resampler * r = ( fir_resampler * ) _r; return r->write_filled > fir_adj_width; } void fir_resampler_clear(void *_r) { fir_resampler * r = ( fir_resampler * ) _r; r->write_pos = 0; r->write_filled = 0; r->read_pos = 0; r->read_filled = 0; r->phase = 0; memset( r->buffer_in, 0, sizeof(r->buffer_in) ); } void fir_resampler_set_rate(void *_r, double new_factor) { fir_resampler * r = ( fir_resampler * ) _r; r->phase_inc = (int)( new_factor * 65536.0 ); r->ratio_set = 0; while ( r->ratio_set < 31 && new_factor > fir_ratios[ r->ratio_set ] ) r->ratio_set++; } void fir_resampler_write_sample(void *_r, short s) { fir_resampler * r = ( fir_resampler * ) _r; if ( r->write_filled < fir_buffer_size ) { int s32 = s; r->buffer_in[ r->write_pos ] = s32; r->buffer_in[ r->write_pos + fir_buffer_size ] = s32; ++r->write_filled; r->write_pos = ( r->write_pos + 1 ) % fir_buffer_size; } } void fir_init() { double const rolloff = 0.999; double const gain = 1.0; int const res = fir_max_res; int i; for (i = 0; i < 32; i++) { double const ratio_ = fir_ratios[ i ]; double fraction = 1.0 / (double)fir_max_res; double const filter = (ratio_ < 1.0) ? 1.0 : 1.0 / ratio_; double pos = 0.0; short* out = (short*) fir_impulses[ i ]; int n; for ( n = res; --n >= 0; ) { gen_sinc( rolloff, (int) (fir_adj_width * filter + 1) & ~1, pos, filter, (double) (0x7FFF * gain * filter), (int) fir_adj_width, out ); out += fir_adj_width; pos += fraction; } } } int fir_resampler_run(void *_r, int ** out_, int * out_end) { fir_resampler * r = ( fir_resampler * ) _r; int in_size = r->write_filled; int const* in_ = r->buffer_in + fir_buffer_size + r->write_pos - r->write_filled; int used = 0; in_size -= fir_write_offset; if ( in_size > 0 ) { int* out = *out_; int const* in = in_; int const* const in_end = in + in_size; int phase = r->phase; int phase_inc = r->phase_inc; int ratio_set = r->ratio_set; do { // accumulate in extended precision short const* imp = fir_impulses[ratio_set][(phase & 0xFFC0) >> 6]; int pt = imp [0]; int s = pt * in [0]; int n; if ( out >= out_end ) break; for ( n = (fir_adj_width - 2) / 2; n; --n ) { pt = imp [1]; s += pt * in [1]; // pre-increment more efficient on some RISC processors imp += 2; pt = imp [0]; in += 2; s += pt * in [0]; } pt = imp [1]; s += pt * in [1]; phase += phase_inc; in += (phase >> 16) - fir_adj_width + 2; phase &= 65535; *out++ = (int) (s >> 7); } while ( in < in_end ); r->phase = phase; *out_ = out; used = in - in_; r->write_filled -= used; } return used; } int fir_resampler_get_sample(void *_r) { fir_resampler * r = ( fir_resampler * ) _r; if ( r->read_filled < 1 ) { int write_pos = ( r->read_pos + r->read_filled ) % fir_buffer_size; int write_size = fir_buffer_size - write_pos; int * out = r->buffer_out + write_pos; if ( write_size > ( fir_buffer_size - r->read_filled ) ) write_size = fir_buffer_size - r->read_filled; fir_resampler_run( r, &out, out + write_size ); r->read_filled += out - r->buffer_out - write_pos; } if ( r->read_filled < 1 ) return 0; return r->buffer_out[ r->read_pos ]; } void fir_resampler_remove_sample(void *_r) { fir_resampler * r = ( fir_resampler * ) _r; if ( r->read_filled > 0 ) { --r->read_filled; r->read_pos = ( r->read_pos + 1 ) % fir_buffer_size; } }