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/*
* HOWTO write an External for Pure data
* (c) 2001-2006 IOhannes m zmölnig zmoelnig[AT]iem.at
*
* this is the source-code for the fourth example in the HOWTO
* it creates a simple dsp-object:
* 2 input signals are mixed into 1 output signal
* the mixing-factor can be set via the 3rd inlet
*
* for legal issues please see the file LICENSE.txt
*/
/**
* include the interface to Pd
*/
#include "m_pd.h"
/**
* define a new "class"
*/
static t_class *pan_tilde_class;
/**
* this is the dataspace of our new object
* the first element is the mandatory "t_object"
* f_pan denotes the mixing-factor
* "f" is a dummy and is used to be able to send floats AS signals.
*/
typedef struct _pan_tilde {
t_object x_obj;
t_sample f_pan;
t_sample f;
} t_pan_tilde;
/**
* this is the core of the object
* this perform-routine is called for each signal block
* the name of this function is arbitrary and is registered to Pd in the
* pan_tilde_dsp() function, each time the DSP is turned on
*
* the argument to this function is just a pointer within an array
* we have to know for ourselves how many elements inthis array are
* reserved for us (hint: we declare the number of used elements in the
* pan_tilde_dsp() at registration
*
* since all elements are of type "t_int" we have to cast them to whatever
* we think is apropriate; "apropriate" is how we registered this function
* in pan_tilde_dsp()
*/
t_int *pan_tilde_perform(t_int *w)
{
/* the first element is a pointer to the dataspace of this object */
t_pan_tilde *x = (t_pan_tilde *)(w[1]);
/* here is a pointer to the t_sample arrays that hold the 2 input signals */
t_sample *in1 = (t_sample *)(w[2]);
t_sample *in2 = (t_sample *)(w[3]);
/* here comes the signalblock that will hold the output signal */
t_sample *out = (t_sample *)(w[4]);
/* all signalblocks are of the same length */
int n = (int)(w[5]);
/* get (and clip) the mixing-factor */
t_sample f_pan = (x->f_pan<0)?0.0:(x->f_pan>1)?1.0:x->f_pan;
/* just a counter */
int i;
/* this is the main routine:
* mix the 2 input signals into the output signal
*/
for(i=0; i<n; i++)
{
out[i]=in1[i]*(1-f_pan)+in2[i]*f_pan;
}
/* return a pointer to the dataspace for the next dsp-object */
return (w+6);
}
/**
* register a special perform-routine at the dsp-engine
* this function gets called whenever the DSP is turned ON
* the name of this function is registered in pan_tilde_setup()
*/
void pan_tilde_dsp(t_pan_tilde *x, t_signal **sp)
{
/* add pan_tilde_perform() to the DSP-tree;
* the pan_tilde_perform() will expect "5" arguments (packed into an
* t_int-array), which are:
* the objects data-space, 3 signal vectors (which happen to be
* 2 input signals and 1 output signal) and the length of the
* signal vectors (all vectors are of the same length)
*/
dsp_add(pan_tilde_perform, 5, x,
sp[0]->s_vec, sp[1]->s_vec, sp[2]->s_vec, sp[0]->s_n);
}
/**
* this is the "constructor" of the class
* the argument is the initial mixing-factir
*/
void *pan_tilde_new(t_floatarg f)
{
t_pan_tilde *x = (t_pan_tilde *)pd_new(pan_tilde_class);
/* save the mixing factor in our dataspace */
x->f_pan = f;
/* create a new signal-inlet */
inlet_new(&x->x_obj, &x->x_obj.ob_pd, &s_signal, &s_signal);
/* create a new passive inlet for the mixing-factor */
floatinlet_new (&x->x_obj, &x->f_pan);
/* create a new signal-outlet */
outlet_new(&x->x_obj, &s_signal);
return (void *)x;
}
/**
* define the function-space of the class
* within a single-object external the name of this function is very special
*/
void pan_tilde_setup(void) {
pan_tilde_class = class_new(gensym("pan~"),
(t_newmethod)pan_tilde_new,
0, sizeof(t_pan_tilde),
CLASS_DEFAULT,
A_DEFFLOAT, 0);
/* whenever the audio-engine is turned on, the "pan_tilde_dsp()"
* function will get called
*/
class_addmethod(pan_tilde_class,
(t_method)pan_tilde_dsp, gensym("dsp"), 0);
/* if no signal is connected to the first inlet, we can as well
* connect a number box to it and use it as "signal"
*/
CLASS_MAINSIGNALIN(pan_tilde_class, t_pan_tilde, f);
}
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