/* ------------------------- rewrap ------------------------------------------ */ /* */ /* rewraps input to lie within an output range. */ /* Written by Olaf Matthes */ /* Get source at http://www.akustische-kunst.org/puredata/maxlib/ */ /* */ /* This program is free software; you can redistribute it and/or */ /* modify it under the terms of the GNU General Public License */ /* as published by the Free Software Foundation; either version 2 */ /* of the License, or (at your option) any later version. */ /* */ /* This program is distributed in the hope that it will be useful, */ /* but WITHOUT ANY WARRANTY; without even the implied warranty of */ /* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the */ /* GNU General Public License for more details. */ /* */ /* You should have received a copy of the GNU General Public License */ /* along with this program; if not, write to the Free Software */ /* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* */ /* Based on PureData by Miller Puckette and others. */ /* */ /* ---------------------------------------------------------------------------- */ #include "m_pd.h" #include #include static char *version = "rewrap v0.1, written by Olaf Matthes "; typedef struct rewrap { t_object x_ob; t_float x_min; /* low border of input range */ t_float x_max; /* high border of input range */ t_outlet *x_outlet1; /* path-through outlet */ t_outlet *x_outlet2; /* rewrap outlet */ } t_rewrap; static void rewrap_float(t_rewrap *x, t_floatarg f) { t_float min = x->x_min; t_float max = x->x_max; t_float range = 2.0f * (max - min); t_int i; if(range == 0.0f) { f = min; outlet_float(x->x_outlet2, 0); } else if(f < min) { float diff = min - f; float n = ceil(diff / range); f += n * range; if(f >= max) { f = 2 * max - f; n -= 0.5; } outlet_float(x->x_outlet2, (t_int)(-2.0f * n)); } else if (f >= max) { float diff = f - max; float n = floor(diff / range) + 1.0f; f -= n * range; if(f < min) { f = 2 * min - f; n -= 0.5; } outlet_float(x->x_outlet2, (t_int)(2.0f * n)); } else outlet_float(x->x_outlet2, 0.0f); outlet_float(x->x_outlet1, f); } static void rewrap_a(t_rewrap *x, t_floatarg a) { t_float max = x->x_max; if(a <= max) x->x_min = a; else { x->x_min = max; x->x_max = a; } } static void rewrap_b(t_rewrap *x, t_floatarg b) { t_float min = x->x_min; if(b >= min) x->x_max = b; else { x->x_max = min; x->x_min = b; } } static t_class *rewrap_class; static void *rewrap_new(t_floatarg fmin, t_floatarg fmax) { t_rewrap *x = (t_rewrap *)pd_new(rewrap_class); inlet_new(&x->x_ob, &x->x_ob.ob_pd, gensym("float"), gensym("a")); inlet_new(&x->x_ob, &x->x_ob.ob_pd, gensym("float"), gensym("b")); x->x_outlet1 = outlet_new(&x->x_ob, gensym("float")); x->x_outlet2 = outlet_new(&x->x_ob, gensym("float")); x->x_min = fmin; rewrap_b(x, fmax); return (void *)x; } #ifndef MAXLIB void rewrap_setup(void) { rewrap_class = class_new(gensym("rewrap"), (t_newmethod)rewrap_new, 0, sizeof(t_rewrap), 0, A_DEFFLOAT, A_DEFFLOAT, 0); class_addfloat(rewrap_class, rewrap_float); class_addmethod(rewrap_class, (t_method)rewrap_a, gensym("a"), A_FLOAT, 0); class_addmethod(rewrap_class, (t_method)rewrap_b, gensym("b"), A_FLOAT, 0); logpost(NULL, 4, version); } #else void maxlib_rewrap_setup(void) { rewrap_class = class_new(gensym("maxlib_rewrap"), (t_newmethod)rewrap_new, 0, sizeof(t_rewrap), 0, A_DEFFLOAT, A_DEFFLOAT, 0); class_addcreator((t_newmethod)rewrap_new, gensym("rewrap"), A_DEFFLOAT, A_DEFFLOAT, 0); class_addfloat(rewrap_class, rewrap_float); class_addmethod(rewrap_class, (t_method)rewrap_a, gensym("a"), A_FLOAT, 0); class_addmethod(rewrap_class, (t_method)rewrap_b, gensym("b"), A_FLOAT, 0); class_sethelpsymbol(rewrap_class, gensym("maxlib/rewrap-help.pd")); } #endif