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Diffstat (limited to 'xc/extras/Mesa/demos/morph3d.c')
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diff --git a/xc/extras/Mesa/demos/morph3d.c b/xc/extras/Mesa/demos/morph3d.c new file mode 100644 index 000000000..954d9bb53 --- /dev/null +++ b/xc/extras/Mesa/demos/morph3d.c @@ -0,0 +1,906 @@ +/* $Id: morph3d.c,v 1.1.1.1 2000/12/05 16:38:38 dawes Exp $ */ + +/* + * $Log: morph3d.c,v $ + * Revision 1.1.1.1 2000/12/05 16:38:38 dawes + * Import of XFree86 4.0.1g + * + * Revision 1.4 2000/06/27 17:04:43 brianp + * fixed compiler warnings + * + * Revision 1.3 1999/12/15 13:00:45 brianp + * moved #define to column 0 + * + * Revision 1.2 1999/09/17 12:27:01 brianp + * silenced some warnings + * + * Revision 1.1.1.1 1999/08/19 00:55:40 jtg + * Imported sources + * + * Revision 3.1 1998/06/29 02:37:30 brianp + * minor changes for Windows (Ted Jump) + * + * Revision 3.0 1998/02/14 18:42:29 brianp + * initial rev + * + */ + + +/*- + * morph3d.c - Shows 3D morphing objects + * + * Converted to GLUT by brianp on 1/1/98 + * + * This program was inspired on a WindowsNT(R)'s screen saver. It was written + * from scratch and it was not based on any other source code. + * + * Porting it to xlock (the final objective of this code since the moment I + * decided to create it) was possible by comparing the original Mesa's gear + * demo with it's ported version, so thanks for Danny Sung for his indirect + * help (look at gear.c in xlock source tree). NOTE: At the moment this code + * was sent to Brian Paul for package inclusion, the XLock Version was not + * available. In fact, I'll wait it to appear on the next Mesa release (If you + * are reading this, it means THIS release) to send it for xlock package + * inclusion). It will probably there be a GLUT version too. + * + * Thanks goes also to Brian Paul for making it possible and inexpensive + * to use OpenGL at home. + * + * Since I'm not a native english speaker, my apologies for any gramatical + * mistake. + * + * My e-mail addresses are + * + * vianna@cat.cbpf.br + * and + * marcelo@venus.rdc.puc-rio.br + * + * Marcelo F. Vianna (Feb-13-1997) + */ + +/* +This document is VERY incomplete, but tries to describe the mathematics used +in the program. At this moment it just describes how the polyhedra are +generated. On futhurer versions, this document will be probabbly improved. + +Since I'm not a native english speaker, my apologies for any gramatical +mistake. + +Marcelo Fernandes Vianna +- Undergraduate in Computer Engeneering at Catholic Pontifical University +- of Rio de Janeiro (PUC-Rio) Brasil. +- e-mail: vianna@cat.cbpf.br or marcelo@venus.rdc.puc-rio.br +- Feb-13-1997 + +POLYHEDRA GENERATION + +For the purpose of this program it's not sufficient to know the polyhedra +vertexes coordinates. Since the morphing algorithm applies a nonlinear +transformation over the surfaces (faces) of the polyhedron, each face has +to be divided into smaller ones. The morphing algorithm needs to transform +each vertex of these smaller faces individually. It's a very time consoming +task. + +In order to reduce calculation overload, and since all the macro faces of +the polyhedron are transformed by the same way, the generation is made by +creating only one face of the polyhedron, morphing it and then rotating it +around the polyhedron center. + +What we need to know is the face radius of the polyhedron (the radius of +the inscribed sphere) and the angle between the center of two adjacent +faces using the center of the sphere as the angle's vertex. + +The face radius of the regular polyhedra are known values which I decided +to not waste my time calculating. Following is a table of face radius for +the regular polyhedra with edge length = 1: + + TETRAHEDRON : 1/(2*sqrt(2))/sqrt(3) + CUBE : 1/2 + OCTAHEDRON : 1/sqrt(6) + DODECAHEDRON : T^2 * sqrt((T+2)/5) / 2 -> where T=(sqrt(5)+1)/2 + ICOSAHEDRON : (3*sqrt(3)+sqrt(15))/12 + +I've not found any reference about the mentioned angles, so I needed to +calculate them, not a trivial task until I figured out how :) +Curiously these angles are the same for the tetrahedron and octahedron. +A way to obtain this value is inscribing the tetrahedron inside the cube +by matching their vertexes. So you'll notice that the remaining unmatched +vertexes are in the same straight line starting in the cube/tetrahedron +center and crossing the center of each tetrahedron's face. At this point +it's easy to obtain the bigger angle of the isosceles triangle formed by +the center of the cube and two opposite vertexes on the same cube face. +The edges of this triangle have the following lenghts: sqrt(2) for the base +and sqrt(3)/2 for the other two other edges. So the angle we want is: + +-----------------------------------------------------------+ + | 2*ARCSIN(sqrt(2)/sqrt(3)) = 109.47122063449069174 degrees | + +-----------------------------------------------------------+ +For the cube this angle is obvious, but just for formality it can be +easily obtained because we also know it's isosceles edge lenghts: +sqrt(2)/2 for the base and 1/2 for the other two edges. So the angle we +want is: + +-----------------------------------------------------------+ + | 2*ARCSIN((sqrt(2)/2)/1) = 90.000000000000000000 degrees | + +-----------------------------------------------------------+ +For the octahedron we use the same idea used for the tetrahedron, but now +we inscribe the cube inside the octahedron so that all cubes's vertexes +matches excatly the center of each octahedron's face. It's now clear that +this angle is the same of the thetrahedron one: + +-----------------------------------------------------------+ + | 2*ARCSIN(sqrt(2)/sqrt(3)) = 109.47122063449069174 degrees | + +-----------------------------------------------------------+ +For the dodecahedron it's a little bit harder because it's only relationship +with the cube is useless to us. So we need to solve the problem by another +way. The concept of Face radius also exists on 2D polygons with the name +Edge radius: + Edge Radius For Pentagon (ERp) + ERp = (1/2)/TAN(36 degrees) * VRp = 0.6881909602355867905 + (VRp is the pentagon's vertex radio). + Face Radius For Dodecahedron + FRd = T^2 * sqrt((T+2)/5) / 2 = 1.1135163644116068404 +Why we need ERp? Well, ERp and FRd segments forms a 90 degrees angle, +completing this triangle, the lesser angle is a half of the angle we are +looking for, so this angle is: + +-----------------------------------------------------------+ + | 2*ARCTAN(ERp/FRd) = 63.434948822922009981 degrees | + +-----------------------------------------------------------+ +For the icosahedron we can use the same method used for dodecahedron (well +the method used for dodecahedron may be used for all regular polyhedra) + Edge Radius For Triangle (this one is well known: 1/3 of the triangle height) + ERt = sin(60)/3 = sqrt(3)/6 = 0.2886751345948128655 + Face Radius For Icosahedron + FRi= (3*sqrt(3)+sqrt(15))/12 = 0.7557613140761707538 +So the angle is: + +-----------------------------------------------------------+ + | 2*ARCTAN(ERt/FRi) = 41.810314895778596167 degrees | + +-----------------------------------------------------------+ + +*/ + + +#include <stdio.h> +#include <stdlib.h> +#ifndef _WIN32 +#include <unistd.h> +#endif +#include <GL/glut.h> +#include <math.h> +#include <string.h> + +#define Scale 0.3 + +#define VectMul(X1,Y1,Z1,X2,Y2,Z2) (Y1)*(Z2)-(Z1)*(Y2),(Z1)*(X2)-(X1)*(Z2),(X1)*(Y2)-(Y1)*(X2) +#define sqr(A) ((A)*(A)) + +/* Increasing this values produces better image quality, the price is speed. */ +/* Very low values produces erroneous/incorrect plotting */ +#define tetradivisions 23 +#define cubedivisions 20 +#define octadivisions 21 +#define dodecadivisions 10 +#define icodivisions 15 + +#define tetraangle 109.47122063449069174 +#define cubeangle 90.000000000000000000 +#define octaangle 109.47122063449069174 +#define dodecaangle 63.434948822922009981 +#define icoangle 41.810314895778596167 + +#ifndef Pi +#define Pi 3.1415926535897932385 +#endif +#define SQRT2 1.4142135623730951455 +#define SQRT3 1.7320508075688771932 +#define SQRT5 2.2360679774997898051 +#define SQRT6 2.4494897427831778813 +#define SQRT15 3.8729833462074170214 +#define cossec36_2 0.8506508083520399322 +#define cos72 0.3090169943749474241 +#define sin72 0.9510565162951535721 +#define cos36 0.8090169943749474241 +#define sin36 0.5877852522924731292 + +/*************************************************************************/ + +static int mono=0; +static int smooth=1; +static GLint WindH, WindW; +static GLfloat step=0; +static GLfloat seno; +static int object; +static int edgedivisions; +static void (*draw_object)( void ); +static float Magnitude; +static float *MaterialColor[20]; + +static float front_shininess[] = {60.0}; +static float front_specular[] = { 0.7, 0.7, 0.7, 1.0 }; +static float ambient[] = { 0.0, 0.0, 0.0, 1.0 }; +static float diffuse[] = { 1.0, 1.0, 1.0, 1.0 }; +static float position0[] = { 1.0, 1.0, 1.0, 0.0 }; +static float position1[] = {-1.0,-1.0, 1.0, 0.0 }; +static float lmodel_ambient[] = { 0.5, 0.5, 0.5, 1.0 }; +static float lmodel_twoside[] = {GL_TRUE}; + +static float MaterialRed[] = { 0.7, 0.0, 0.0, 1.0 }; +static float MaterialGreen[] = { 0.1, 0.5, 0.2, 1.0 }; +static float MaterialBlue[] = { 0.0, 0.0, 0.7, 1.0 }; +static float MaterialCyan[] = { 0.2, 0.5, 0.7, 1.0 }; +static float MaterialYellow[] = { 0.7, 0.7, 0.0, 1.0 }; +static float MaterialMagenta[] = { 0.6, 0.2, 0.5, 1.0 }; +static float MaterialWhite[] = { 0.7, 0.7, 0.7, 1.0 }; +static float MaterialGray[] = { 0.2, 0.2, 0.2, 1.0 }; + +#define TRIANGLE(Edge, Amp, Divisions, Z) \ +{ \ + GLfloat Xf,Yf,Xa,Yb,Xf2,Yf2; \ + GLfloat Factor,Factor1,Factor2; \ + GLfloat VertX,VertY,VertZ,NeiAX,NeiAY,NeiAZ,NeiBX,NeiBY,NeiBZ; \ + GLfloat Ax,Ay,Bx; \ + int Ri,Ti; \ + GLfloat Vr=(Edge)*SQRT3/3; \ + GLfloat AmpVr2=(Amp)/sqr(Vr); \ + GLfloat Zf=(Edge)*(Z); \ + \ + Ax=(Edge)*(+0.5/(Divisions)), Ay=(Edge)*(-SQRT3/(2*Divisions)); \ + Bx=(Edge)*(-0.5/(Divisions)); \ + \ + for (Ri=1; Ri<=(Divisions); Ri++) { \ + glBegin(GL_TRIANGLE_STRIP); \ + for (Ti=0; Ti<Ri; Ti++) { \ + Xf=(float)(Ri-Ti)*Ax + (float)Ti*Bx; \ + Yf=Vr+(float)(Ri-Ti)*Ay + (float)Ti*Ay; \ + Xa=Xf+0.001; Yb=Yf+0.001; \ + Factor=1-(((Xf2=sqr(Xf))+(Yf2=sqr(Yf)))*AmpVr2); \ + Factor1=1-((sqr(Xa)+Yf2)*AmpVr2); \ + Factor2=1-((Xf2+sqr(Yb))*AmpVr2); \ + VertX=Factor*Xf; VertY=Factor*Yf; VertZ=Factor*Zf; \ + NeiAX=Factor1*Xa-VertX; NeiAY=Factor1*Yf-VertY; NeiAZ=Factor1*Zf-VertZ; \ + NeiBX=Factor2*Xf-VertX; NeiBY=Factor2*Yb-VertY; NeiBZ=Factor2*Zf-VertZ; \ + glNormal3f(VectMul(NeiAX, NeiAY, NeiAZ, NeiBX, NeiBY, NeiBZ)); \ + glVertex3f(VertX, VertY, VertZ); \ + \ + Xf=(float)(Ri-Ti-1)*Ax + (float)Ti*Bx; \ + Yf=Vr+(float)(Ri-Ti-1)*Ay + (float)Ti*Ay; \ + Xa=Xf+0.001; Yb=Yf+0.001; \ + Factor=1-(((Xf2=sqr(Xf))+(Yf2=sqr(Yf)))*AmpVr2); \ + Factor1=1-((sqr(Xa)+Yf2)*AmpVr2); \ + Factor2=1-((Xf2+sqr(Yb))*AmpVr2); \ + VertX=Factor*Xf; VertY=Factor*Yf; VertZ=Factor*Zf; \ + NeiAX=Factor1*Xa-VertX; NeiAY=Factor1*Yf-VertY; NeiAZ=Factor1*Zf-VertZ; \ + NeiBX=Factor2*Xf-VertX; NeiBY=Factor2*Yb-VertY; NeiBZ=Factor2*Zf-VertZ; \ + glNormal3f(VectMul(NeiAX, NeiAY, NeiAZ, NeiBX, NeiBY, NeiBZ)); \ + glVertex3f(VertX, VertY, VertZ); \ + \ + } \ + Xf=(float)Ri*Bx; \ + Yf=Vr+(float)Ri*Ay; \ + Xa=Xf+0.001; Yb=Yf+0.001; \ + Factor=1-(((Xf2=sqr(Xf))+(Yf2=sqr(Yf)))*AmpVr2); \ + Factor1=1-((sqr(Xa)+Yf2)*AmpVr2); \ + Factor2=1-((Xf2+sqr(Yb))*AmpVr2); \ + VertX=Factor*Xf; VertY=Factor*Yf; VertZ=Factor*Zf; \ + NeiAX=Factor1*Xa-VertX; NeiAY=Factor1*Yf-VertY; NeiAZ=Factor1*Zf-VertZ; \ + NeiBX=Factor2*Xf-VertX; NeiBY=Factor2*Yb-VertY; NeiBZ=Factor2*Zf-VertZ; \ + glNormal3f(VectMul(NeiAX, NeiAY, NeiAZ, NeiBX, NeiBY, NeiBZ)); \ + glVertex3f(VertX, VertY, VertZ); \ + glEnd(); \ + } \ +} + +#define SQUARE(Edge, Amp, Divisions, Z) \ +{ \ + int Xi,Yi; \ + GLfloat Xf,Yf,Y,Xf2,Yf2,Y2,Xa,Yb; \ + GLfloat Factor,Factor1,Factor2; \ + GLfloat VertX,VertY,VertZ,NeiAX,NeiAY,NeiAZ,NeiBX,NeiBY,NeiBZ; \ + GLfloat Zf=(Edge)*(Z); \ + GLfloat AmpVr2=(Amp)/sqr((Edge)*SQRT2/2); \ + \ + for (Yi=0; Yi<(Divisions); Yi++) { \ + Yf=-((Edge)/2.0) + ((float)Yi)/(Divisions)*(Edge); \ + Yf2=sqr(Yf); \ + Y=Yf+1.0/(Divisions)*(Edge); \ + Y2=sqr(Y); \ + glBegin(GL_QUAD_STRIP); \ + for (Xi=0; Xi<=(Divisions); Xi++) { \ + Xf=-((Edge)/2.0) + ((float)Xi)/(Divisions)*(Edge); \ + Xf2=sqr(Xf); \ + \ + Xa=Xf+0.001; Yb=Y+0.001; \ + Factor=1-((Xf2+Y2)*AmpVr2); \ + Factor1=1-((sqr(Xa)+Y2)*AmpVr2); \ + Factor2=1-((Xf2+sqr(Yb))*AmpVr2); \ + VertX=Factor*Xf; VertY=Factor*Y; VertZ=Factor*Zf; \ + NeiAX=Factor1*Xa-VertX; NeiAY=Factor1*Y-VertY; NeiAZ=Factor1*Zf-VertZ; \ + NeiBX=Factor2*Xf-VertX; NeiBY=Factor2*Yb-VertY; NeiBZ=Factor2*Zf-VertZ; \ + glNormal3f(VectMul(NeiAX, NeiAY, NeiAZ, NeiBX, NeiBY, NeiBZ)); \ + glVertex3f(VertX, VertY, VertZ); \ + \ + Xa=Xf+0.001; Yb=Yf+0.001; \ + Factor=1-((Xf2+Yf2)*AmpVr2); \ + Factor1=1-((sqr(Xa)+Yf2)*AmpVr2); \ + Factor2=1-((Xf2+sqr(Yb))*AmpVr2); \ + VertX=Factor*Xf; VertY=Factor*Yf; VertZ=Factor*Zf; \ + NeiAX=Factor1*Xa-VertX; NeiAY=Factor1*Yf-VertY; NeiAZ=Factor1*Zf-VertZ; \ + NeiBX=Factor2*Xf-VertX; NeiBY=Factor2*Yb-VertY; NeiBZ=Factor2*Zf-VertZ; \ + glNormal3f(VectMul(NeiAX, NeiAY, NeiAZ, NeiBX, NeiBY, NeiBZ)); \ + glVertex3f(VertX, VertY, VertZ); \ + } \ + glEnd(); \ + } \ +} + +#define PENTAGON(Edge, Amp, Divisions, Z) \ +{ \ + int Ri,Ti,Fi; \ + GLfloat Xf,Yf,Xa,Yb,Xf2,Yf2; \ + GLfloat x[6],y[6]; \ + GLfloat Factor,Factor1,Factor2; \ + GLfloat VertX,VertY,VertZ,NeiAX,NeiAY,NeiAZ,NeiBX,NeiBY,NeiBZ; \ + GLfloat Zf=(Edge)*(Z); \ + GLfloat AmpVr2=(Amp)/sqr((Edge)*cossec36_2); \ + \ + for(Fi=0;Fi<6;Fi++) { \ + x[Fi]=-cos( Fi*2*Pi/5 + Pi/10 )/(Divisions)*cossec36_2*(Edge); \ + y[Fi]=sin( Fi*2*Pi/5 + Pi/10 )/(Divisions)*cossec36_2*(Edge); \ + } \ + \ + for (Ri=1; Ri<=(Divisions); Ri++) { \ + for (Fi=0; Fi<5; Fi++) { \ + glBegin(GL_TRIANGLE_STRIP); \ + for (Ti=0; Ti<Ri; Ti++) { \ + Xf=(float)(Ri-Ti)*x[Fi] + (float)Ti*x[Fi+1]; \ + Yf=(float)(Ri-Ti)*y[Fi] + (float)Ti*y[Fi+1]; \ + Xa=Xf+0.001; Yb=Yf+0.001; \ + Factor=1-(((Xf2=sqr(Xf))+(Yf2=sqr(Yf)))*AmpVr2); \ + Factor1=1-((sqr(Xa)+Yf2)*AmpVr2); \ + Factor2=1-((Xf2+sqr(Yb))*AmpVr2); \ + VertX=Factor*Xf; VertY=Factor*Yf; VertZ=Factor*Zf; \ + NeiAX=Factor1*Xa-VertX; NeiAY=Factor1*Yf-VertY; NeiAZ=Factor1*Zf-VertZ; \ + NeiBX=Factor2*Xf-VertX; NeiBY=Factor2*Yb-VertY; NeiBZ=Factor2*Zf-VertZ; \ + glNormal3f(VectMul(NeiAX, NeiAY, NeiAZ, NeiBX, NeiBY, NeiBZ)); \ + glVertex3f(VertX, VertY, VertZ); \ + \ + Xf=(float)(Ri-Ti-1)*x[Fi] + (float)Ti*x[Fi+1]; \ + Yf=(float)(Ri-Ti-1)*y[Fi] + (float)Ti*y[Fi+1]; \ + Xa=Xf+0.001; Yb=Yf+0.001; \ + Factor=1-(((Xf2=sqr(Xf))+(Yf2=sqr(Yf)))*AmpVr2); \ + Factor1=1-((sqr(Xa)+Yf2)*AmpVr2); \ + Factor2=1-((Xf2+sqr(Yb))*AmpVr2); \ + VertX=Factor*Xf; VertY=Factor*Yf; VertZ=Factor*Zf; \ + NeiAX=Factor1*Xa-VertX; NeiAY=Factor1*Yf-VertY; NeiAZ=Factor1*Zf-VertZ; \ + NeiBX=Factor2*Xf-VertX; NeiBY=Factor2*Yb-VertY; NeiBZ=Factor2*Zf-VertZ; \ + glNormal3f(VectMul(NeiAX, NeiAY, NeiAZ, NeiBX, NeiBY, NeiBZ)); \ + glVertex3f(VertX, VertY, VertZ); \ + \ + } \ + Xf=(float)Ri*x[Fi+1]; \ + Yf=(float)Ri*y[Fi+1]; \ + Xa=Xf+0.001; Yb=Yf+0.001; \ + Factor=1-(((Xf2=sqr(Xf))+(Yf2=sqr(Yf)))*AmpVr2); \ + Factor1=1-((sqr(Xa)+Yf2)*AmpVr2); \ + Factor2=1-((Xf2+sqr(Yb))*AmpVr2); \ + VertX=Factor*Xf; VertY=Factor*Yf; VertZ=Factor*Zf; \ + NeiAX=Factor1*Xa-VertX; NeiAY=Factor1*Yf-VertY; NeiAZ=Factor1*Zf-VertZ; \ + NeiBX=Factor2*Xf-VertX; NeiBY=Factor2*Yb-VertY; NeiBZ=Factor2*Zf-VertZ; \ + glNormal3f(VectMul(NeiAX, NeiAY, NeiAZ, NeiBX, NeiBY, NeiBZ)); \ + glVertex3f(VertX, VertY, VertZ); \ + glEnd(); \ + } \ + } \ +} + +static void draw_tetra( void ) +{ + GLuint list; + + list = glGenLists( 1 ); + glNewList( list, GL_COMPILE ); + TRIANGLE(2,seno,edgedivisions,0.5/SQRT6); + glEndList(); + + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[0]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,0,1); + glRotatef(-tetraangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[1]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+tetraangle,0.5,SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[2]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+tetraangle,0.5,-SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[3]); + glCallList(list); + + glDeleteLists(list,1); +} + +static void draw_cube( void ) +{ + GLuint list; + + list = glGenLists( 1 ); + glNewList( list, GL_COMPILE ); + SQUARE(2, seno, edgedivisions, 0.5) + glEndList(); + + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[0]); + glCallList(list); + glRotatef(cubeangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[1]); + glCallList(list); + glRotatef(cubeangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[2]); + glCallList(list); + glRotatef(cubeangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[3]); + glCallList(list); + glRotatef(cubeangle,0,1,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[4]); + glCallList(list); + glRotatef(2*cubeangle,0,1,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[5]); + glCallList(list); + + glDeleteLists(list,1); +} + +static void draw_octa( void ) +{ + GLuint list; + + list = glGenLists( 1 ); + glNewList( list, GL_COMPILE ); + TRIANGLE(2,seno,edgedivisions,1/SQRT6); + glEndList(); + + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[0]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,0,1); + glRotatef(-180+octaangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[1]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-octaangle,0.5,SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[2]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-octaangle,0.5,-SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[3]); + glCallList(list); + glPopMatrix(); + glRotatef(180,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[4]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,0,1); + glRotatef(-180+octaangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[5]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-octaangle,0.5,SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[6]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,1,0); + glRotatef(-octaangle,0.5,-SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[7]); + glCallList(list); + + glDeleteLists(list,1); +} + +static void draw_dodeca( void ) +{ + GLuint list; + +#define TAU ((SQRT5+1)/2) + + list = glGenLists( 1 ); + glNewList( list, GL_COMPILE ); + PENTAGON(1,seno,edgedivisions,sqr(TAU) * sqrt((TAU+2)/5) / 2); + glEndList(); + + glPushMatrix(); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[0]); + glCallList(list); + glRotatef(180,0,0,1); + glPushMatrix(); + glRotatef(-dodecaangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[1]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(-dodecaangle,cos72,sin72,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[2]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(-dodecaangle,cos72,-sin72,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[3]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(dodecaangle,cos36,-sin36,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[4]); + glCallList(list); + glPopMatrix(); + glRotatef(dodecaangle,cos36,sin36,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[5]); + glCallList(list); + glPopMatrix(); + glRotatef(180,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[6]); + glCallList(list); + glRotatef(180,0,0,1); + glPushMatrix(); + glRotatef(-dodecaangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[7]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(-dodecaangle,cos72,sin72,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[8]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(-dodecaangle,cos72,-sin72,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[9]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(dodecaangle,cos36,-sin36,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[10]); + glCallList(list); + glPopMatrix(); + glRotatef(dodecaangle,cos36,sin36,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[11]); + glCallList(list); + + glDeleteLists(list,1); +} + +static void draw_ico( void ) +{ + GLuint list; + + list = glGenLists( 1 ); + glNewList( list, GL_COMPILE ); + TRIANGLE(1.5,seno,edgedivisions,(3*SQRT3+SQRT15)/12); + glEndList(); + + glPushMatrix(); + + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[0]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,0,1); + glRotatef(-icoangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[1]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[2]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,-SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[3]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[4]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[5]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,0,1); + glRotatef(-icoangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[6]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,-SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[7]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,-SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[8]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,0,1); + glRotatef(-icoangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[9]); + glCallList(list); + glPopMatrix(); + glRotatef(180,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[10]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,0,1); + glRotatef(-icoangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[11]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[12]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,-SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[13]); + glCallList(list); + glPopMatrix(); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[14]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[15]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,0,1); + glRotatef(-icoangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[16]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,-SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[17]); + glCallList(list); + glPushMatrix(); + glRotatef(180,0,1,0); + glRotatef(-180+icoangle,0.5,-SQRT3/2,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[18]); + glCallList(list); + glPopMatrix(); + glRotatef(180,0,0,1); + glRotatef(-icoangle,1,0,0); + glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, MaterialColor[19]); + glCallList(list); + + glDeleteLists(list,1); +} + +static void draw ( void ) { + glClear( GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT ); + + glPushMatrix(); + + glTranslatef( 0.0, 0.0, -10.0 ); + glScalef( Scale*WindH/WindW, Scale, Scale ); + glTranslatef(2.5*WindW/WindH*sin(step*1.11),2.5*cos(step*1.25*1.11),0); + glRotatef(step*100,1,0,0); + glRotatef(step*95,0,1,0); + glRotatef(step*90,0,0,1); + + seno=(sin(step)+1.0/3.0)*(4.0/5.0)*Magnitude; + + draw_object(); + + glPopMatrix(); + + glFlush(); + + glutSwapBuffers(); + + step+=0.05; +} + +static void idle_( void ) +{ + glutPostRedisplay(); +} + +static void reshape( int width, int height ) +{ + glViewport(0, 0, WindW=(GLint)width, WindH=(GLint)height); + glMatrixMode(GL_PROJECTION); + glLoadIdentity(); + glFrustum( -1.0, 1.0, -1.0, 1.0, 5.0, 15.0 ); + glMatrixMode(GL_MODELVIEW); +} + +static void pinit(void); + +static void key( unsigned char k, int x, int y ) +{ + (void) x; + (void) y; + switch (k) { + case '1': object=1; break; + case '2': object=2; break; + case '3': object=3; break; + case '4': object=4; break; + case '5': object=5; break; + case ' ': mono^=1; break; + case 13: smooth^=1; break; + case 27: + exit(0); + } + pinit(); +} + +static void pinit(void) +{ + switch(object) { + case 1: + draw_object=draw_tetra; + MaterialColor[0]=MaterialRed; + MaterialColor[1]=MaterialGreen; + MaterialColor[2]=MaterialBlue; + MaterialColor[3]=MaterialWhite; + edgedivisions=tetradivisions; + Magnitude=2.5; + break; + case 2: + draw_object=draw_cube; + MaterialColor[0]=MaterialRed; + MaterialColor[1]=MaterialGreen; + MaterialColor[2]=MaterialCyan; + MaterialColor[3]=MaterialMagenta; + MaterialColor[4]=MaterialYellow; + MaterialColor[5]=MaterialBlue; + edgedivisions=cubedivisions; + Magnitude=2.0; + break; + case 3: + draw_object=draw_octa; + MaterialColor[0]=MaterialRed; + MaterialColor[1]=MaterialGreen; + MaterialColor[2]=MaterialBlue; + MaterialColor[3]=MaterialWhite; + MaterialColor[4]=MaterialCyan; + MaterialColor[5]=MaterialMagenta; + MaterialColor[6]=MaterialGray; + MaterialColor[7]=MaterialYellow; + edgedivisions=octadivisions; + Magnitude=2.5; + break; + case 4: + draw_object=draw_dodeca; + MaterialColor[ 0]=MaterialRed; + MaterialColor[ 1]=MaterialGreen; + MaterialColor[ 2]=MaterialCyan; + MaterialColor[ 3]=MaterialBlue; + MaterialColor[ 4]=MaterialMagenta; + MaterialColor[ 5]=MaterialYellow; + MaterialColor[ 6]=MaterialGreen; + MaterialColor[ 7]=MaterialCyan; + MaterialColor[ 8]=MaterialRed; + MaterialColor[ 9]=MaterialMagenta; + MaterialColor[10]=MaterialBlue; + MaterialColor[11]=MaterialYellow; + edgedivisions=dodecadivisions; + Magnitude=2.0; + break; + case 5: + draw_object=draw_ico; + MaterialColor[ 0]=MaterialRed; + MaterialColor[ 1]=MaterialGreen; + MaterialColor[ 2]=MaterialBlue; + MaterialColor[ 3]=MaterialCyan; + MaterialColor[ 4]=MaterialYellow; + MaterialColor[ 5]=MaterialMagenta; + MaterialColor[ 6]=MaterialRed; + MaterialColor[ 7]=MaterialGreen; + MaterialColor[ 8]=MaterialBlue; + MaterialColor[ 9]=MaterialWhite; + MaterialColor[10]=MaterialCyan; + MaterialColor[11]=MaterialYellow; + MaterialColor[12]=MaterialMagenta; + MaterialColor[13]=MaterialRed; + MaterialColor[14]=MaterialGreen; + MaterialColor[15]=MaterialBlue; + MaterialColor[16]=MaterialCyan; + MaterialColor[17]=MaterialYellow; + MaterialColor[18]=MaterialMagenta; + MaterialColor[19]=MaterialGray; + edgedivisions=icodivisions; + Magnitude=2.5; + break; + } + if (mono) { + int loop; + for (loop=0; loop<20; loop++) MaterialColor[loop]=MaterialGray; + } + if (smooth) { + glShadeModel( GL_SMOOTH ); + } else { + glShadeModel( GL_FLAT ); + } + +} + +static void INIT(void) +{ + printf("Morph 3D - Shows morphing platonic polyhedra\n"); + printf("Author: Marcelo Fernandes Vianna (vianna@cat.cbpf.br)\n\n"); + printf(" [1] - Tetrahedron\n"); + printf(" [2] - Hexahedron (Cube)\n"); + printf(" [3] - Octahedron\n"); + printf(" [4] - Dodecahedron\n"); + printf(" [5] - Icosahedron\n"); + printf("[SPACE] - Toggle colored faces\n"); + printf("[RETURN] - Toggle smooth/flat shading\n"); + printf(" [ESC] - Quit\n"); + + object=1; + + glutInitWindowPosition(0,0); + glutInitWindowSize(640,480); + + glutInitDisplayMode( GLUT_DEPTH | GLUT_DOUBLE | GLUT_RGB ); + + if (glutCreateWindow("Morph 3D - Shows morphing platonic polyhedra") <= 0) { + exit(0); + } + + glClearDepth(1.0); + glClearColor( 0.0, 0.0, 0.0, 1.0 ); + glColor3f( 1.0, 1.0, 1.0 ); + + glClear( GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT ); + glFlush(); + glutSwapBuffers(); + + glLightfv(GL_LIGHT0, GL_AMBIENT, ambient); + glLightfv(GL_LIGHT0, GL_DIFFUSE, diffuse); + glLightfv(GL_LIGHT0, GL_POSITION, position0); + glLightfv(GL_LIGHT1, GL_AMBIENT, ambient); + glLightfv(GL_LIGHT1, GL_DIFFUSE, diffuse); + glLightfv(GL_LIGHT1, GL_POSITION, position1); + glLightModelfv(GL_LIGHT_MODEL_AMBIENT, lmodel_ambient); + glLightModelfv(GL_LIGHT_MODEL_TWO_SIDE, lmodel_twoside); + glEnable(GL_LIGHTING); + glEnable(GL_LIGHT0); + glEnable(GL_LIGHT1); + glEnable(GL_DEPTH_TEST); + glEnable(GL_NORMALIZE); + + glMaterialfv(GL_FRONT_AND_BACK, GL_SHININESS, front_shininess); + glMaterialfv(GL_FRONT_AND_BACK, GL_SPECULAR, front_specular); + + glHint(GL_FOG_HINT, GL_FASTEST); + glHint(GL_PERSPECTIVE_CORRECTION_HINT, GL_FASTEST); + glHint(GL_POLYGON_SMOOTH_HINT, GL_FASTEST); + + pinit(); + + glutReshapeFunc( reshape ); + glutKeyboardFunc( key ); + glutIdleFunc( idle_ ); + glutDisplayFunc( draw ); + glutMainLoop(); + +} + +int main(int argc, char **argv) +{ + INIT(); + return(0); +} |