/* quadruptwo Attractor PD External */ /* Copyright Michael McGonagle, from ??????, 2003 */ /* This program is distributed under the params of the GNU Public License */ /////////////////////////////////////////////////////////////////////////////////// /* This file is part of Chaos PD Externals. */ /* */ /* Chaos PD Externals are free software; you can redistribute them and/or modify */ /* them 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. */ /* */ /* Chaos PD Externals are distributed in the hope that they 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 the Chaos PD Externals; if not, write to the Free Software */ /* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ /////////////////////////////////////////////////////////////////////////////////// #include #include #include #include #include "chaos.h" #define M_a_lo -1000 #define M_a_hi 1000 #define M_b_lo -1000 #define M_b_hi 1000 #define M_c_lo -1000 #define M_c_hi 1000 #define M_a 0 #define M_b 1 #define M_c 2 #define M_x 0 #define M_y 1 #define M_param_count 3 #define M_var_count 2 #define M_search_count 3 #define M_failure_limit 1000 static char *version = "quadruptwo v0.0, by Michael McGonagle, from ??????, 2003"; t_class *quadruptwo_class; typedef struct quadruptwo_struct { t_object x_obj; double vars[M_var_count]; double vars_init[M_var_count]; t_atom vars_out[M_var_count]; t_outlet *vars_outlet; t_atom search_out[M_search_count]; t_outlet *search_outlet; double a, a_lo, a_hi, b, b_lo, b_hi, c, c_lo, c_hi; t_atom params_out[M_param_count]; t_outlet *params_outlet; double lyap_exp, lyap_lo, lyap_hi, lyap_limit, failure_ratio; t_outlet *outlets[M_var_count - 1]; } quadruptwo_struct; static void calc(quadruptwo_struct *quadruptwo, double *vars) { double x_0, y_0; x_0 =vars[M_y]-((vars[M_x]<0)?-1:1)*sin(log(abs(quadruptwo -> b*vars[M_x]-quadruptwo -> c)))*atan(pow(abs(quadruptwo -> c*vars[M_x]-quadruptwo -> b),2)); y_0 =quadruptwo -> a-vars[M_x]; vars[M_x] = x_0; vars[M_y] = y_0; } // end calc static void calculate(quadruptwo_struct *quadruptwo) { calc(quadruptwo, quadruptwo -> vars); outlet_float(quadruptwo -> x_obj.ob_outlet, quadruptwo -> vars[M_x]); outlet_float(quadruptwo -> outlets[M_y - 1], quadruptwo -> vars[M_y]); } // end calculate static void reset(quadruptwo_struct *quadruptwo, t_symbol *s, int argc, t_atom *argv) { if (argc == M_var_count) { quadruptwo -> vars[M_x] = (double) atom_getfloatarg(M_x, argc, argv); quadruptwo -> vars[M_y] = (double) atom_getfloatarg(M_y, argc, argv); } else { quadruptwo -> vars[M_x] = quadruptwo -> vars_init[M_x]; quadruptwo -> vars[M_y] = quadruptwo -> vars_init[M_y]; } // end if } // end reset static char *classify(quadruptwo_struct *quadruptwo) { static char buff[4]; char *c = "ABCDEFGHIJKLMNOPQRSTUVWXYZ"; buff[0] = c[(int) (((quadruptwo -> a - M_a_lo) * (1.0 / (M_a_hi - M_a_lo))) * 26)]; buff[1] = c[(int) (((quadruptwo -> b - M_b_lo) * (1.0 / (M_b_hi - M_b_lo))) * 26)]; buff[2] = c[(int) (((quadruptwo -> c - M_c_lo) * (1.0 / (M_c_hi - M_c_lo))) * 26)]; buff[3] = '\0'; return buff; } static void make_results(quadruptwo_struct *quadruptwo) { SETFLOAT(&quadruptwo -> search_out[0], quadruptwo -> lyap_exp); SETSYMBOL(&quadruptwo -> search_out[1], gensym(classify(quadruptwo))); SETFLOAT(&quadruptwo -> search_out[2], quadruptwo -> failure_ratio); SETFLOAT(&quadruptwo -> vars_out[M_x], quadruptwo -> vars[M_x]); SETFLOAT(&quadruptwo -> vars_out[M_y], quadruptwo -> vars[M_y]); SETFLOAT(&quadruptwo -> params_out[M_a], quadruptwo -> a); SETFLOAT(&quadruptwo -> params_out[M_b], quadruptwo -> b); SETFLOAT(&quadruptwo -> params_out[M_c], quadruptwo -> c); outlet_list(quadruptwo -> params_outlet, gensym("list"), M_param_count, quadruptwo -> params_out); outlet_list(quadruptwo -> vars_outlet, gensym("list"), M_var_count, quadruptwo -> vars_out); } static void show(quadruptwo_struct *quadruptwo) { make_results(quadruptwo); outlet_anything(quadruptwo -> search_outlet, gensym("show"), M_search_count, quadruptwo -> search_out); } static void param(quadruptwo_struct *quadruptwo, t_symbol *s, int argc, t_atom *argv) { if (argc != 3) { post("Incorrect number of arguments for quadruptwo fractal. Expecting 3 arguments."); return; } quadruptwo -> a = (double) atom_getfloatarg(0, argc, argv); quadruptwo -> b = (double) atom_getfloatarg(1, argc, argv); quadruptwo -> c = (double) atom_getfloatarg(2, argc, argv); } static void seed(quadruptwo_struct *quadruptwo, t_symbol *s, int argc, t_atom *argv) { if (argc > 0) { srand48(((unsigned int)time(0))|1); } else { srand48((unsigned int) atom_getfloatarg(0, argc, argv)); } } static void lyap(quadruptwo_struct *quadruptwo, t_floatarg l, t_floatarg h, t_floatarg lim) { quadruptwo -> lyap_lo = l; quadruptwo -> lyap_hi = h; quadruptwo -> lyap_limit = (double) ((int) lim); } static void elyap(quadruptwo_struct *quadruptwo) { double results[M_var_count]; int i; if (lyapunov_full((void *) quadruptwo, (t_gotfn) calc, M_var_count, quadruptwo -> vars, results) != NULL) { post("elyapunov:"); for(i = 0; i < M_var_count; i++) { post("%d: %3.80f", i, results[i]); } } } static void limiter(quadruptwo_struct *quadruptwo) { if (quadruptwo -> a_lo < M_a_lo) { quadruptwo -> a_lo = M_a_lo; } if (quadruptwo -> a_lo > M_a_hi) { quadruptwo -> a_lo = M_a_hi; } if (quadruptwo -> a_hi < M_a_lo) { quadruptwo -> a_hi = M_a_lo; } if (quadruptwo -> a_hi > M_a_hi) { quadruptwo -> a_hi = M_a_hi; } if (quadruptwo -> b_lo < M_b_lo) { quadruptwo -> b_lo = M_b_lo; } if (quadruptwo -> b_lo > M_b_hi) { quadruptwo -> b_lo = M_b_hi; } if (quadruptwo -> b_hi < M_b_lo) { quadruptwo -> b_hi = M_b_lo; } if (quadruptwo -> b_hi > M_b_hi) { quadruptwo -> b_hi = M_b_hi; } if (quadruptwo -> c_lo < M_c_lo) { quadruptwo -> c_lo = M_c_lo; } if (quadruptwo -> c_lo > M_c_hi) { quadruptwo -> c_lo = M_c_hi; } if (quadruptwo -> c_hi < M_c_lo) { quadruptwo -> c_hi = M_c_lo; } if (quadruptwo -> c_hi > M_c_hi) { quadruptwo -> c_hi = M_c_hi; } } static void constrain(quadruptwo_struct *quadruptwo, t_symbol *s, int argc, t_atom *argv) { int i; t_atom *arg = argv; if (argc == 0) { // reset to full limits of search ranges quadruptwo -> a_lo = M_a_lo; quadruptwo -> a_hi = M_a_hi; quadruptwo -> b_lo = M_b_lo; quadruptwo -> b_hi = M_b_hi; quadruptwo -> c_lo = M_c_lo; quadruptwo -> c_hi = M_c_hi; return; } if (argc == 1) { // set the ranges based on percentage of full range double percent = atom_getfloat(arg); double a_spread = ((M_a_hi - M_a_lo) * percent) / 2; double b_spread = ((M_b_hi - M_b_lo) * percent) / 2; double c_spread = ((M_c_hi - M_c_lo) * percent) / 2; quadruptwo -> a_lo = quadruptwo -> a - a_spread; quadruptwo -> a_hi = quadruptwo -> a + a_spread; quadruptwo -> b_lo = quadruptwo -> b - b_spread; quadruptwo -> b_hi = quadruptwo -> b + b_spread; quadruptwo -> c_lo = quadruptwo -> c - c_spread; quadruptwo -> c_hi = quadruptwo -> c + c_spread; limiter(quadruptwo); return; } if (argc != M_param_count * 2) { post("Invalid number of arguments for quadruptwo constraints, requires 6 values, got %d", argc); return; } quadruptwo -> a_lo = atom_getfloat(arg++); quadruptwo -> a_hi = atom_getfloat(arg++); quadruptwo -> b_lo = atom_getfloat(arg++); quadruptwo -> b_hi = atom_getfloat(arg++); quadruptwo -> c_lo = atom_getfloat(arg++); quadruptwo -> c_hi = atom_getfloat(arg++); limiter(quadruptwo); } static void search(quadruptwo_struct *quadruptwo, t_symbol *s, int argc, t_atom *argv) { int not_found, not_expired = quadruptwo -> lyap_limit; int jump, i, iterations; t_atom vars[M_var_count]; double temp_a = quadruptwo -> a; double temp_b = quadruptwo -> b; double temp_c = quadruptwo -> c; if (argc > 0) { for (i = 0; i < M_var_count; i++) { SETFLOAT(&vars[i], atom_getfloatarg(i, argc, argv)); } } else { for (i = 0; i < M_var_count; i++) { SETFLOAT(&vars[i], quadruptwo -> vars_init[i]); } } do { jump = 500; not_found = 0; iterations = 10000; bad_params: quadruptwo -> a = (drand48() * (quadruptwo -> a_hi - quadruptwo -> a_lo)) + quadruptwo -> a_lo; quadruptwo -> b = (drand48() * (quadruptwo -> b_hi - quadruptwo -> b_lo)) + quadruptwo -> b_lo; quadruptwo -> c = (drand48() * (quadruptwo -> c_hi - quadruptwo -> c_lo)) + quadruptwo -> c_lo; // put any preliminary checks specific to this fractal to eliminate bad_params reset(quadruptwo, NULL, argc, vars); do { calc(quadruptwo, quadruptwo -> vars); } while(jump--); quadruptwo -> lyap_exp = lyapunov((void *) quadruptwo, (t_gotfn) calc, M_var_count, (double *) quadruptwo -> vars); if (isnan(quadruptwo -> lyap_exp)) { not_found = 1; } if (quadruptwo -> lyap_exp < quadruptwo -> lyap_lo || quadruptwo -> lyap_exp > quadruptwo -> lyap_hi) { not_found = 1; } not_expired--; } while(not_found && not_expired); reset(quadruptwo, NULL, argc, vars); if (!not_expired) { post("Could not find a fractal after %d attempts.", (int) quadruptwo -> lyap_limit); post("Try using wider constraints."); quadruptwo -> a = temp_a; quadruptwo -> b = temp_b; quadruptwo -> c = temp_c; outlet_anything(quadruptwo -> search_outlet, gensym("invalid"), 0, NULL); } else { quadruptwo -> failure_ratio = (quadruptwo -> lyap_limit - not_expired) / quadruptwo -> lyap_limit; make_results(quadruptwo); outlet_anything(quadruptwo -> search_outlet, gensym("search"), M_search_count, quadruptwo -> search_out); } } void *quadruptwo_new(t_symbol *s, int argc, t_atom *argv) { quadruptwo_struct *quadruptwo = (quadruptwo_struct *) pd_new(quadruptwo_class); if (quadruptwo != NULL) { outlet_new(&quadruptwo -> x_obj, &s_float); quadruptwo -> outlets[0] = outlet_new(&quadruptwo -> x_obj, &s_float); quadruptwo -> search_outlet = outlet_new(&quadruptwo -> x_obj, &s_list); quadruptwo -> vars_outlet = outlet_new(&quadruptwo -> x_obj, &s_list); quadruptwo -> params_outlet = outlet_new(&quadruptwo -> x_obj, &s_list); if (argc == M_param_count + M_var_count) { quadruptwo -> vars_init[M_x] = quadruptwo -> vars[M_x] = (double) atom_getfloatarg(0, argc, argv); quadruptwo -> vars_init[M_y] = quadruptwo -> vars[M_y] = (double) atom_getfloatarg(1, argc, argv); quadruptwo -> a = (double) atom_getfloatarg(2, argc, argv); quadruptwo -> b = (double) atom_getfloatarg(3, argc, argv); quadruptwo -> c = (double) atom_getfloatarg(4, argc, argv); } else { if (argc != 0 && argc != M_param_count + M_var_count) { post("Incorrect number of arguments for quadruptwo fractal. Expecting 5 arguments."); } quadruptwo -> vars_init[M_x] = 0; quadruptwo -> vars_init[M_y] = 0; quadruptwo -> a = 34; quadruptwo -> b = 1; quadruptwo -> c = 5; } constrain(quadruptwo, NULL, 0, NULL); lyap(quadruptwo, -1000000.0, 1000000.0, M_failure_limit); } return (void *)quadruptwo; } void quadruptwo_setup(void) { quadruptwo_class = class_new(gensym("quadruptwo"), (t_newmethod) quadruptwo_new, 0, sizeof(quadruptwo_struct), 0, A_GIMME, 0); class_addbang(quadruptwo_class, (t_method) calculate); class_addmethod(quadruptwo_class, (t_method) reset, gensym("reset"), A_GIMME, 0); class_addmethod(quadruptwo_class, (t_method) show, gensym("show"), 0); class_addmethod(quadruptwo_class, (t_method) param, gensym("param"), A_GIMME, 0); class_addmethod(quadruptwo_class, (t_method) seed, gensym("seed"), A_GIMME, 0); class_addmethod(quadruptwo_class, (t_method) lyap, gensym("lyapunov"), A_DEFFLOAT, A_DEFFLOAT, A_DEFFLOAT, 0); class_addmethod(quadruptwo_class, (t_method) elyap, gensym("elyapunov"), 0); class_addmethod(quadruptwo_class, (t_method) search, gensym("search"), A_GIMME, 0); class_addmethod(quadruptwo_class, (t_method) constrain, gensym("constrain"), A_GIMME, 0); }