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/* 1903:forum::für::umläute:2005 */
/*
* mulitplex : zpack a specified input to the output
*
* THINK: should the selector-inlet be the first or the last ???
* pros/cons:
* the 1st inlet being the selector is not consistant with pd (hot/cold)
* but as it since the hot inlet is selectable, the whole object is not really consitant
* numbering would have to start with 1 (for the 1st not-leftmost inlet)
* if the selector is rightmost this would mean: cold is right(most), hot is (somewhere) left
* numbering would be ok
*
* conclusio: make the selector rightmost
*
*/
#include "zexy.h"
#include <stdio.h>
/* ------------------------- zpack ------------------------------- */
/*
a zpacker
*/
static t_class *zpack_class;
static t_class *zpackproxy_class;
typedef struct _zpack
{
t_object x_obj;
struct _zpackproxy **x_proxy;
t_inlet **in;
t_atom*x_argv;
int x_argc;
} t_zpack;
typedef struct _zpackproxy
{
t_pd p_pd;
t_zpack *p_master;
int id;
} t_zpackproxy;
static void setatom(t_zpack *x, t_atom*from, int to) {
x->x_argv[to].a_type=from->a_type;
x->x_argv[to].a_w =from->a_w;
}
static void zpack_bang(t_zpack*x) {
outlet_list(x->x_obj.ob_outlet, gensym("list"), x->x_argc, x->x_argv);
}
static void zpack_list0(t_zpack*x, t_symbol *s, int argc, t_atom *argv) {
if(argc>0)
setatom(x, argv, 0);
zpack_bang(x);
}
static void zpack_list(t_zpackproxy *y, t_symbol *s, int argc, t_atom *argv)
{
if(argc>0)
setatom(y->p_master, argv, y->id);
}
static void *zpack_new(t_symbol *s, int argc, t_atom *argv)
{
t_zpack *x = (t_zpack *)pd_new(zpack_class);
int n =0;
x->x_argc = (argc < 1)?2:argc;
if(argc<1) {
x->x_argv=(t_atom*)getbytes(2*sizeof(t_atom));
SETFLOAT(x->x_argv+0, 0.f);
SETFLOAT(x->x_argv+1, 0.f);
} else {
int i=0;
x->x_argv=(t_atom*)getbytes(x->x_argc*sizeof(t_atom));
for(i=0; i<x->x_argc; i++)
setatom(x, argv+i, i);
}
x->in = (t_inlet **)getbytes(x->x_argc * sizeof(t_inlet *));
x->x_proxy = (t_zpackproxy**)getbytes(x->x_argc * sizeof(t_zpackproxy*));
x->in[0] =0;
x->x_proxy[0]=0;
for (n = 1; n<x->x_argc; n++) {
x->x_proxy[n]=(t_zpackproxy*)pd_new(zpackproxy_class);
x->x_proxy[n]->p_master = x;
x->x_proxy[n]->id=n;
x->in[n] = inlet_new ((t_object*)x, (t_pd*)x->x_proxy[n], 0,0);
}
outlet_new(&x->x_obj, 0);
return (x);
}
static void zpack_free(t_zpack*x){
const int count = x->x_argc;
if(x->in && x->x_proxy){
int n=0;
for(n=0; n<count; n++){
if(x->in[n]){
inlet_free(x->in[n]);
}
x->in[n]=0;
if(x->x_proxy[n]){
t_zpackproxy *y=x->x_proxy[n];
y->p_master=0;
y->id=0;
pd_free(&y->p_pd);
}
x->x_proxy[n]=0;
}
freebytes(x->in, x->x_argc * sizeof(t_inlet *));
freebytes(x->x_proxy, x->x_argc * sizeof(t_zpackproxy*));
}
}
void zpack_setup(void)
{
zpack_class = class_new(gensym("pack"), (t_newmethod)zpack_new,
(t_method)zpack_free, sizeof(t_zpack), 0, A_GIMME, 0);
class_addcreator((t_newmethod)zpack_new, gensym("zexy/pack"), A_GIMME, 0);
class_addbang(zpack_class, zpack_bang);
class_addlist(zpack_class, zpack_list0);
zpackproxy_class = class_new(gensym("zpack proxy"), 0, 0,
sizeof(t_zpackproxy),
CLASS_PD | CLASS_NOINLET, 0);
class_addlist(zpackproxy_class, zpack_list);
zexy_register("pack");
}
void pack_setup(void)
{
zpack_setup();
}
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