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/*
* copyright Steve Harris, Ben Saylor
* see GPL.txt
*/
#include <math.h>
#include <string.h>
#include "m_pd.h"
#ifdef NT
#define inline __inline
#define M_PI 3.14159265358979323846
#pragma warning( disable : 4244 )
#pragma warning( disable : 4305 )
#endif
// Number of filter oversamples
#define F_R 3
// Denormalise floats, only actually needed for PIII and very recent PowerPC
#define FLUSH_TO_ZERO(fv) (((*(unsigned int*)&(fv))&0x7f800000)==0)?0.0f:(fv)
/* pd's samplerate */
float fs;
static t_class *svf_class;
typedef struct _svf
{
t_object x_obj;
float f; // 2.0*sin(PI*fs/(fc*r));
float q; // 2.0*cos(pow(q, 0.1)*PI*0.5);
float qnrm; // sqrt(m/2.0f+0.01f);
float h; // high pass output
float b; // band pass output
float l; // low pass output
float p; // peaking output (allpass with resonance)
float n; // notch output
float *op; // pointer to output value
} t_svf;
/* Store data in SVF struct, takes the sampling frequency, cutoff frequency
and Q, and fills in the structure passed */
//static inline void setup_svf(sv_filter *sv, float fs, float fc, float q, int t) {
static inline void setup_svf(t_svf *sv, float fc, float q) {
sv->f = 2.0f * sin(M_PI * fc / (float)(fs * F_R));
sv->q = 2.0f * cos(pow(q, 0.1f) * M_PI * 0.5f);
sv->qnrm = sqrt(sv->q/2.0+0.01);
}
/* Run one sample through the SV filter. Filter is by andy@vellocet */
static inline float run_svf(t_svf *sv, float in) {
float out;
int i;
in = sv->qnrm * in ;
for (i=0; i < F_R; i++) {
// only needed for pentium chips
in = FLUSH_TO_ZERO(in);
sv->l = FLUSH_TO_ZERO(sv->l);
// very slight waveshape for extra stability
sv->b = sv->b - sv->b * sv->b * sv->b * 0.001f;
// regular state variable code here
// the notch and peaking outputs are optional
sv->h = in - sv->l - sv->q * sv->b;
sv->b = sv->b + sv->f * sv->h;
sv->l = sv->l + sv->f * sv->b;
sv->n = sv->l + sv->h;
sv->p = sv->l - sv->h;
out = *(sv->op);
in = out;
}
return out;
}
static void svf_setstate_LP(t_svf *sv)
{
sv->op = &(sv->l);
}
static void svf_setstate_HP(t_svf *sv)
{
sv->op = &(sv->h);
}
static void svf_setstate_BP(t_svf *sv)
{
sv->op = &(sv->b);
}
static void svf_setstate_BR(t_svf *sv)
{
sv->op = &(sv->n);
}
static void svf_setstate_AP(t_svf *sv)
{
sv->op = &(sv->p);
}
static t_int *svf_perform(t_int *w)
{
t_svf *obj = (t_svf *)(w[1]);
t_float *in = (t_float *)(w[2]);
t_float *freq = (t_float *)(w[3]);
t_float *q = (t_float *)(w[4]);
t_float *res = (t_float *)(w[5]);
t_float *out = (t_float *)(w[6]);
int n = (int)(w[7]);
while (n--) {
float f = *(in++);
setup_svf(obj, *(freq++), *(q++));
*(out++) = run_svf(obj, f + ((obj->b) * (*(res++))));
}
return (w+8);
}
static void svf_dsp(t_svf *x, t_signal **sp)
{
dsp_add(svf_perform, 7, x, sp[0]->s_vec, sp[1]->s_vec, sp[2]->s_vec, sp[3]->s_vec, sp[4]->s_vec, sp[0]->s_n);
}
static void *svf_new(t_symbol *s, int argc, t_atom *argv)
{
char string[11];
t_svf *x = (t_svf *)pd_new(svf_class);
svf_setstate_LP(x);
if (argc > 0) {
atom_string(argv, string, 10);
if (!strcmp(string, "high"))
svf_setstate_HP(x);
if (!strcmp(string, "band"))
svf_setstate_BP(x);
if (!strcmp(string, "notch"))
svf_setstate_BR(x);
if (!strcmp(string, "peak"))
svf_setstate_AP(x);
}
inlet_new(&x->x_obj, &x->x_obj.ob_pd, &s_signal, &s_signal);
inlet_new(&x->x_obj, &x->x_obj.ob_pd, &s_signal, &s_signal);
inlet_new(&x->x_obj, &x->x_obj.ob_pd, &s_signal, &s_signal);
outlet_new(&x->x_obj, gensym("signal"));
return (x);
}
void svf_tilde_setup(void)
{
fs = sys_getsr();
svf_class = class_new(gensym("svf~"), (t_newmethod)svf_new, 0, sizeof(t_svf), 0, A_GIMME, 0);
class_sethelpsymbol(svf_class, gensym("help-svf~.pd"));
class_addmethod(svf_class, nullfn, gensym("signal"), 0);
class_addmethod(svf_class, (t_method)svf_dsp, gensym("dsp"), 0);
class_addmethod(svf_class, (t_method)svf_setstate_LP, gensym("low"), 0);
class_addmethod(svf_class, (t_method)svf_setstate_HP, gensym("high"), 0);
class_addmethod(svf_class, (t_method)svf_setstate_BP, gensym("band"), 0);
class_addmethod(svf_class, (t_method)svf_setstate_BR, gensym("notch"), 0);
class_addmethod(svf_class, (t_method)svf_setstate_AP, gensym("peak"), 0);
}
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