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189 lines
4.0 KiB
189 lines
4.0 KiB
15 years ago
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/*
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// Copyright (C) 2000 Julien Carme
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// Copyright (C) 2001 Neil Stevens <neil@qualityassistant.com>
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//
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// This program is free software; you can redistribute it and/or modify
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// it under the terms of the GNU General Public License version 2, as
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// published by the Free Software Foundation.
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//
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// This program is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU General Public License for more details.
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//
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// You should have received a copy of the GNU General Public License
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// along with this program; if not, write to the Free Software
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// Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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*/
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#include <math.h>
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#include "renderer.h"
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#include "compute.h"
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#define PI 3.14159
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t_complex fct(t_complex a,int n,int p1,int p2) /*p1 et p2:0-4 */
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{
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t_complex b;
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float fact;
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float an;
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float circle_size;
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float speed;
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float co,si;
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a.x-=scr_par.width/2;
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a.y-=scr_par.height/2;
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switch (n) {
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case 0:
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an=0.025*(p1-2)+0.002;
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co=cos(an);
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si=sin(an);
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circle_size=scr_par.height*0.25;
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speed=2000+p2*500;
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b.x=(co*a.x-si*a.y);
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b.y=(si*a.x+co*a.y);
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fact=-(sqrt(b.x*b.x+b.y*b.y)-circle_size)/speed+1;
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b.x=(b.x*fact);
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b.y=(b.y*fact);
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break;
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case 1:
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an=0.015*(p1-2)+0.002;
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co=cos(an);
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si=sin(an);
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circle_size=scr_par.height*0.45;
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speed=4000+p2*1000;
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b.x=(co*a.x-si*a.y);
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b.y=(si*a.x+co*a.y);
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fact=(sqrt(b.x*b.x+b.y*b.y)-circle_size)/speed+1;
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b.x=(b.x*fact);
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b.y=(b.y*fact);
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break;
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case 2:
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an=0.002;
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co=cos(an);
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si=sin(an);
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circle_size=scr_par.height*0.25;
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speed=400+p2*100;
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b.x=(co*a.x-si*a.y);
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b.y=(si*a.x+co*a.y);
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fact=-(sqrt(b.x*b.x+b.y*b.y)-circle_size)/speed+1;
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b.x=(b.x*fact);
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b.y=(b.y*fact);
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break;
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case 3:
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an=(sin(sqrt(a.x*a.x+a.y*a.y)/20)/20)+0.002;
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co=cos(an);
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si=sin(an);
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circle_size=scr_par.height*0.25;
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speed=4000;
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b.x=(co*a.x-si*a.y);
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b.y=(si*a.x+co*a.y);
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fact=-(sqrt(b.x*b.x+b.y*b.y)-circle_size)/speed+1;
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b.x=(b.x*fact);
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b.y=(b.y*fact);
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break;
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case 4:
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an=0.002;
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co=cos(an);
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si=sin(an);
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circle_size=scr_par.height*0.25;
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speed=sin(sqrt(a.x*a.x+a.y*a.y)/5)*3000+4000;
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b.x=(co*a.x-si*a.y);
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b.y=(si*a.x+co*a.y);
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fact=-(sqrt(b.x*b.x+b.y*b.y)-circle_size)/speed+1;
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b.x=(b.x*fact);
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b.y=(b.y*fact);
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break;
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case 5:
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b.x=a.x*1.02;
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b.y=a.y*1.02;
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break;
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case 6:
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an=0.002;
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co=cos(an);
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si=sin(an);
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circle_size=scr_par.height*0.25;
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fact=1+cos(atan(a.x/(a.y+0.00001))*6)*0.02;
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b.x=(co*a.x-si*a.y);
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b.y=(si*a.x+co*a.y);
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b.x=(b.x*fact);
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b.y=(b.y*fact);
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break;
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}
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b.x+=scr_par.width/2;
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b.y+=scr_par.height/2;
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if (b.x<0)
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b.x=0;
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if (b.y<0)
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b.y=0;
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if (b.x>scr_par.width-1)
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b.x=scr_par.width-1;
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if (b.y>scr_par.height-1)
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b.y=scr_par.height-1;
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return b;
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}
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void generate_sector(int g,int f,int p1,int p2,int debut,int step,t_interpol* vector_field);
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void generate_sector(int g,int f,int p1,int p2,int debut,int step,t_interpol* vector_field)
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{
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int fin=debut+step;
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const int prop_transmitted=249;
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const int b_add=g*scr_par.width*scr_par.height;
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t_coord c;
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if (fin>scr_par.height)
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fin=scr_par.height;
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for (c.y=debut;c.y<fin;c.y++)
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for (c.x=0;c.x<scr_par.width;c.x++) {
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t_complex a;
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float fpy;
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int rw,lw,add;
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unsigned int w1,w2,w3,w4;
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unsigned int x,y;
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a.x=(float)c.x;
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a.y=(float)c.y;
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a=fct(a,f,p1,p2);
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add=c.x+c.y*scr_par.width;
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x=(int)(a.x);
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y=(int)(a.y);
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vector_field[b_add+add].coord=(x<<16)|y;
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fpy=a.y-floor(a.y);
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rw=(int)((a.x-floor(a.x))*prop_transmitted);
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lw=prop_transmitted-rw;
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w4=(int)(fpy*rw);
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w2=rw-w4;
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w3=(int)(fpy*lw);
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w1=lw-w3;
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vector_field[b_add+add].weight=(w1<<24)|(w2<<16)|(w3<<8)|w4;
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}
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}
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void generate_vector_field(t_interpol* vector_field)
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{
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int f;
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int i,p1,p2;
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for (f=0;f<NB_FCT;f++) {
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p1=2;
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p2=2;
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for (i=0;i<scr_par.height;i+=10)
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generate_sector(f,f,p1,p2,i,10,vector_field);
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}
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}
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