ref: 0a5f275112d871f18435dbe76294c11d5f99ecf9
dir: /modules/wpkorg35.c/
/* * WPKorg35 * * This is a filter based off of an implemenation the Korg35 filter by Will * Pirke. It has been ported from the CCRMA chugin by the same name. * */ #include <stdlib.h> #include <math.h> #include "soundpipe.h" #ifndef M_PI #define M_PI 3.14159265358979323846 #endif static void update(sp_data *sp, sp_wpkorg35 *wpk) { /* prewarp for BZT */ SPFLOAT wd = 2*M_PI*wpk->cutoff; SPFLOAT T = 1.0/(SPFLOAT)sp->sr; SPFLOAT wa = (2/T)*tan(wd*T/2); SPFLOAT g = wa*T/2.0; /* the feedforward coeff in the VA One Pole */ SPFLOAT G = g/(1.0 + g); /* set alphas */ wpk->lpf1_a = G; wpk->lpf2_a = G; wpk->hpf_a = G; /* set betas */ wpk->lpf2_b = (wpk->res - wpk->res*G)/(1.0 + g); wpk->hpf_b = -1.0/(1.0 + g); wpk->alpha = 1.0/(1.0 - wpk->res*G + wpk->res*G*G); ; } SPFLOAT wpk_doFilter(sp_wpkorg35 *wpk) { return 0.0; } int sp_wpkorg35_create(sp_wpkorg35 **p) { *p = malloc(sizeof(sp_wpkorg35)); return SP_OK; } int sp_wpkorg35_destroy(sp_wpkorg35 **p) { free(*p); return SP_OK; } int sp_wpkorg35_init(sp_data *sp, sp_wpkorg35 *p) { p->alpha = 0.0; p->pcutoff = p->cutoff = 1000; p->pres = p->res = 1.0; /* reset memory for filters */ p->lpf1_z = 0; p->lpf2_z = 0; p->hpf_z = 0; /* initialize LPF1 */ p->lpf1_a = 1.0; p->lpf1_z = 0.0; /* initialize LPF2 */ p->lpf2_a = 1.0; p->lpf2_b = 1.0; p->lpf2_z = 0.0; p->nonlinear = 0; p->saturation = 0; /* update filters */ update(sp, p); return SP_OK; } int sp_wpkorg35_compute(sp_data *sp, sp_wpkorg35 *p, SPFLOAT *in, SPFLOAT *out) { /* initialize variables */ SPFLOAT y1; SPFLOAT S35; SPFLOAT u; SPFLOAT y; SPFLOAT vn; if(p->pcutoff != p->cutoff || p->pres != p->res) update(sp, p); y1 = 0.0; S35 = 0.0; u = 0.0; y = 0.0; vn = 0.0; /* process input through LPF1 */ vn = (*in - p->lpf1_z) * p->lpf1_a; y1 = vn + p->lpf1_z; p->lpf1_z = y1 + vn; /* form feedback value */ S35 = (p->hpf_z * p->hpf_b) + (p->lpf2_z * p->lpf2_b); /* Calculate u */ u = p->alpha * (y1 + S35); /* Naive NLP */ if(p->saturation > 0) { u = tanh(p->saturation * u); } /* Feed it to LPF2 */ vn = (u - p->lpf2_z) * p->lpf2_a; y = (vn + p->lpf2_z); p->lpf2_z = y + vn; y *= p->res; /* Feed y to HPF2 */ vn = (y - p->hpf_z) * p->hpf_a; p->hpf_z = vn + (vn + p->hpf_z); /* Auto-normalize */ if(p->res > 0) { y *= 1.0 / p->res; } *out = y; p->pcutoff = p->cutoff; p->pres = p->res; return SP_OK; }