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/* Copyright (c) 2003-2005 krzYszcz and others.
* For information on usage and redistribution, and for a DISCLAIMER OF ALL
* WARRANTIES, see the file, "LICENSE.txt," in this distribution. */
/* Based on Chamberlin's prototype from "Musical Applications of
Microprocessors" (csound's svfilter). Slightly distorted,
no upsampling. */
/* CHECKED scalar case: input preserved (not coefs) after changing mode */
/* CHECKME if creation args (or defaults) restored after signal disconnection */
#include <math.h>
#include "m_pd.h"
#include "shared.h"
#include "sickle/sic.h"
#if defined(NT) || defined(MACOSX)
/* cf pd/src/x_arithmetic.c */
#define sinf sin
#endif
#define SVF_HZ 0
#define SVF_LINEAR 1
#define SVF_RADIANS 2
#define SVF_DRIVE .0001
#define SVF_QSTRETCH 1.2 /* CHECKED */
#define SVF_MINR 0. /* CHECKME */
#define SVF_MAXR 1.2 /* CHECKME */
#define SVF_MINOMEGA 0. /* CHECKME */
#define SVF_MAXOMEGA (SHARED_PI * .5) /* CHECKME */
#define SVF_DEFFREQ 0.
#define SVF_DEFQ .01 /* CHECKME */
typedef struct _svf
{
t_sic x_sic;
int x_mode;
float x_srcoef;
float x_band;
float x_low;
} t_svf;
static t_class *svf_class;
static t_symbol *ps_hz;
static t_symbol *ps_linear;
static t_symbol *ps_radians;
static void svf_clear(t_svf *x)
{
x->x_band = x->x_low = 0.;
}
static void svf_hz(t_svf *x)
{
x->x_mode = SVF_HZ;
}
static void svf_linear(t_svf *x)
{
x->x_mode = SVF_LINEAR;
}
static void svf_radians(t_svf *x)
{
x->x_mode = SVF_RADIANS;
}
/* LATER make ready for optional audio-rate modulation
(separate scalar case routines, use sic_makecostable(), etc.) */
static t_int *svf_perform(t_int *w)
{
t_svf *x = (t_svf *)(w[1]);
int nblock = (int)(w[2]);
t_float *xin = (t_float *)(w[3]);
t_float fin0 = *(t_float *)(w[4]);
t_float rin0 = *(t_float *)(w[5]);
t_float *lout = (t_float *)(w[6]);
t_float *hout = (t_float *)(w[7]);
t_float *bout = (t_float *)(w[8]);
t_float *nout = (t_float *)(w[9]);
float band = x->x_band;
float low = x->x_low;
/* CHECKME sampled once per block */
float c1, c2;
float r = (1. - rin0) * SVF_QSTRETCH; /* CHECKED */
if (r < SVF_MINR)
r = SVF_MINR;
else if (r > SVF_MAXR)
r = SVF_MAXR;
c2 = r * r;
if (x->x_mode == SVF_HZ)
{
float omega = fin0 * x->x_srcoef;
if (omega < SVF_MINOMEGA)
omega = SVF_MINOMEGA;
else if (omega > SVF_MAXOMEGA)
omega = SVF_MAXOMEGA;
c1 = sinf(omega);
/* CHECKED irs slightly drift apart at high omega, LATER investigate */
}
else if (x->x_mode == SVF_LINEAR)
c1 = sinf(fin0 * (SHARED_PI * .5)); /* CHECKME actual range of fin0 */
else
c1 = fin0; /* CHECKME range */
while (nblock--)
{
float high, xn = *xin++;
*lout++ = low = low + c1 * band;
*hout++ = high = xn - low - c2 * band;
*bout++ = band = c1 * high + band;
*nout++ = low + high;
band -= band * band * band * SVF_DRIVE;
}
/* LATER rethink */
x->x_band = (PD_BADFLOAT(band) ? 0. : band);
x->x_low = (PD_BADFLOAT(low) ? 0. : low);
return (w + 10);
}
static void svf_dsp(t_svf *x, t_signal **sp)
{
x->x_srcoef = SHARED_2PI / sp[0]->s_sr;
svf_clear(x);
dsp_add(svf_perform, 9, x, sp[0]->s_n,
sp[0]->s_vec, sp[1]->s_vec, sp[2]->s_vec, sp[3]->s_vec,
sp[4]->s_vec, sp[5]->s_vec, sp[6]->s_vec);
}
static void *svf_new(t_symbol *s, int ac, t_atom *av)
{
t_svf *x = (t_svf *)pd_new(svf_class);
t_float freq = SVF_DEFFREQ, qcoef = SVF_DEFQ;
t_symbol *modesym = 0;
int i;
for (i = 0; i < ac; i++) if (av[i].a_type == A_SYMBOL)
{
modesym = av[i].a_w.w_symbol;
break;
}
while (ac && av->a_type != A_FLOAT) ac--, av++;
if (ac)
{
freq = av->a_w.w_float;
ac--; av++;
while (ac && av->a_type != A_FLOAT) ac--, av++;
if (ac)
qcoef = av->a_w.w_float;
}
x->x_srcoef = SHARED_PI / sys_getsr();
sic_newinlet((t_sic *)x, freq);
sic_newinlet((t_sic *)x, qcoef);
outlet_new((t_object *)x, &s_signal);
outlet_new((t_object *)x, &s_signal);
outlet_new((t_object *)x, &s_signal);
outlet_new((t_object *)x, &s_signal);
svf_clear(x);
if (modesym == ps_linear)
x->x_mode = SVF_LINEAR;
else if (modesym == ps_radians)
x->x_mode = SVF_RADIANS;
else
{
x->x_mode = SVF_HZ;
if (modesym && modesym != &s_ &&
modesym != ps_hz && modesym != gensym("Hz"))
{
/* CHECKED no warning */
}
}
return (x);
}
void svf_tilde_setup(void)
{
ps_hz = gensym("hz");
ps_linear = gensym("linear");
ps_radians = gensym("radians");
svf_class = class_new(gensym("svf~"),
(t_newmethod)svf_new, 0,
sizeof(t_svf), 0, A_GIMME, 0);
sic_setup(svf_class, svf_dsp, SIC_FLOATTOSIGNAL);
class_addmethod(svf_class, (t_method)svf_clear, gensym("clear"), 0);
class_addmethod(svf_class, (t_method)svf_hz, ps_hz, 0);
class_addmethod(svf_class, (t_method)svf_hz, gensym("Hz"), 0);
class_addmethod(svf_class, (t_method)svf_linear, ps_linear, 0);
class_addmethod(svf_class, (t_method)svf_radians, ps_radians, 0);
}
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