#include "fg_internal.h"
/*
- * TODO BEFORE THE STABLE RELEASE:
- *
- * Following functions have been contributed by Andreas Umbach.
- *
- * glutWireCube() -- looks OK
- * glutSolidCube() -- OK
- *
- * Those functions have been implemented by John Fay.
- *
- * glutWireTorus() -- looks OK
- * glutSolidTorus() -- looks OK
- * glutWireDodecahedron() -- looks OK
- * glutSolidDodecahedron() -- looks OK
- * glutWireOctahedron() -- looks OK
- * glutSolidOctahedron() -- looks OK
- * glutWireTetrahedron() -- looks OK
- * glutSolidTetrahedron() -- looks OK
- * glutWireIcosahedron() -- looks OK
- * glutSolidIcosahedron() -- looks OK
- *
- * The Following functions have been updated by Nigel Stewart, based
- * on FreeGLUT 2.0.0 implementations:
- *
- * glutWireSphere() -- looks OK
- * glutSolidSphere() -- looks OK
- * glutWireCone() -- looks OK
- * glutSolidCone() -- looks OK
+ * Need more types of polyhedra? See CPolyhedron in MRPT
*/
-/* -- INTERFACE FUNCTIONS -------------------------------------------------- */
+/* General function for drawing geometry. As for all geometry we have no
+ * redundancy (or hardly any in the case of cones and cylinders) in terms
+ * of the vertex/normal combinations, we just use glDrawArrays.
+ * useWireMode controls the drawing of solids (false) or wire frame
+ * versions (TRUE) of the geometry you pass
+ */
+static void fghDrawGeometry(GLdouble *vertices, GLdouble *normals, GLboolean *edgeFlags, GLsizei numVertices, GLsizei numFaces, GLsizei numEdgePerFace, GLboolean useWireMode)
+{
+# ifdef FREEGLUT_GLES1
+ /* Solid drawing is the same for OpenGL 1.x and OpenGL ES 1.x, just
+ * no edge flags for ES.
+ * WireFrame drawing will have to be done per face though, using
+ * GL_LINE_LOOP and issuing one draw call per face. For triangles,
+ * we use glDrawArrays directly on the vertex data for each face,
+ * while for shapes that are composed of quads or pentagons, we use
+ * glDrawElements with index vector {0,1,2,5} or {0,1,2,8,5},
+ * respectively.
+ * We use the first parameter in glDrawArrays or glDrawElements to
+ * go from face to face.
+ */
+ if (useWireMode)
+ {
+ /* setup reading the right elements from vertex array */
+ GLubyte vertIdx4[4] = {0,1,2,5};
+ GLubyte vertIdx5[5] = {0,1,2,8,5};
+ GLubyte *indices = NULL;
+ int vertStride, i, j;
+
+ switch (numEdgePerFace)
+ {
+ case 3:
+ vertStride = 3; /* there are 3 vertices for each face in the array */
+ break;
+ case 4:
+ indices = vertIdx4;
+ vertStride = 6; /* there are 6 vertices for each face in the array */
+ break;
+ case 5:
+ indices = vertIdx5;
+ vertStride = 9; /* there are 9 vertices for each face in the array */
+ break;
+ }
-/*
- * Draws a wireframed cube. Code contributed by Andreas Umbach <marvin@dataway.ch>
+ glEnableClientState(GL_VERTEX_ARRAY);
+ glEnableClientState(GL_NORMAL_ARRAY);
+
+ glVertexPointer(3, GL_DOUBLE, 0, vertices);
+ glNormalPointer(GL_DOUBLE, 0, normals);
+
+ if (numEdgePerFace==3)
+ for (i=0; i<numFaces; i++)
+ glDrawArrays(GL_LINE_LOOP, i*vertStride, numEdgePerFace);
+ else
+ {
+ GLubyte *vertIndices = malloc(numEdgePerFace*sizeof(GLubyte));
+ for (i=0; i<numFaces; i++)
+ {
+ for (j=0; j< numEdgePerFace; j++)
+ vertIndices[j] = indices[j]+i*vertStride;
+
+ glDrawElements(GL_LINE_LOOP, numEdgePerFace, GL_UNSIGNED_BYTE, vertIndices);
+ }
+ free(vertIndices);
+ }
+
+ glDisableClientState(GL_VERTEX_ARRAY);
+ glDisableClientState(GL_NORMAL_ARRAY);
+ return; /* done */
+ }
+# endif
+
+ if (useWireMode)
+ {
+ glPushAttrib(GL_POLYGON_BIT);
+ glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
+ glDisable(GL_CULL_FACE);
+ }
+
+ glEnableClientState(GL_VERTEX_ARRAY);
+ glEnableClientState(GL_NORMAL_ARRAY);
+# ifndef FREEGLUT_GLES1
+ if (edgeFlags)
+ glEnableClientState(GL_EDGE_FLAG_ARRAY);
+# endif
+
+ glVertexPointer(3, GL_DOUBLE, 0, vertices);
+ glNormalPointer(GL_DOUBLE, 0, normals);
+# ifndef FREEGLUT_GLES1
+ if (edgeFlags)
+ glEdgeFlagPointer(0,edgeFlags);
+# endif
+ glDrawArrays(GL_TRIANGLES, 0, numVertices);
+
+ glDisableClientState(GL_VERTEX_ARRAY);
+ glDisableClientState(GL_NORMAL_ARRAY);
+# ifndef FREEGLUT_GLES1
+ if (edgeFlags)
+ glDisableClientState(GL_EDGE_FLAG_ARRAY);
+# endif
+
+ if (useWireMode)
+ {
+ glPopAttrib();
+ }
+
+ /* Notes on OpenGL 3 and OpenGL ES2, drawing code for programmable pipeline:
+ * As above, we'll have to draw face-by-face for wireframes. On
+ * OpenGL 3 we can probably use glMultiDrawArrays do do this efficiently.
+ * other complications are VBOs and such...
+ */
+}
+
+/* Triangle decomposition and associated edgeFlags generation
+ * Be careful to keep winding of all triangles counter-clockwise,
+ * assuming that input has correct winding...
+ * Could probably do something smarter using glDrawElements and generating
+ * an index vector here for all shapes that are not triangles, but this
+ * suffices for now. We're not talking many vertices in our objects anyway.
*/
-void FGAPIENTRY glutWireCube( GLdouble dSize )
+static GLubyte vertSamp3[3] = {0,1,2};
+static GLubyte vertSamp4[6] = {0,1,2, 0,2,3}; /* quad : 4 input vertices, 6 output (2 triangles) */
+static GLubyte vertSamp5[9] = {0,1,2, 0,2,4, 4,2,3}; /* pentagon: 5 input vertices, 9 output (3 triangles) */
+static GLboolean edgeFlag3[3] = {1,1,1}; /* triangles remain triangles, all edges are external */
+static GLboolean edgeFlag4[6] = {1,1,0, 0,1,1};
+static GLboolean edgeFlag5[9] = {1,1,0, 0,0,1, 0,1,1};
+
+static void fghGenerateGeometryWithEdgeFlag(int numFaces, int numEdgePerFaceIn, GLdouble *vertices, GLubyte *vertIndices, GLdouble *normals, GLdouble *vertOut, GLdouble *normOut, GLboolean *edgeFlagsOut)
{
- double size = dSize * 0.5;
+ int i,j,numEdgePerFaceOut;
+ GLubyte *vertSamps = NULL;
+ GLboolean *edgeFlags = NULL;
+ switch (numEdgePerFaceIn)
+ {
+ case 3:
+ vertSamps = vertSamp3;
+ edgeFlags = edgeFlag3;
+ numEdgePerFaceOut = 3; /* 3 output vertices for each face */
+ break;
+ case 4:
+ vertSamps = vertSamp4;
+ edgeFlags = edgeFlag4;
+ numEdgePerFaceOut = 6; /* 6 output vertices for each face */
+ break;
+ case 5:
+ vertSamps = vertSamp5;
+ edgeFlags = edgeFlag5;
+ numEdgePerFaceOut = 9; /* 9 output vertices for each face */
+ break;
+ }
+ /*
+ * Build array with vertices from vertex coordinates and vertex indices
+ * Do same for normals.
+ * Need to do this because of different normals at shared vertices
+ * (and because normals' coordinates need to be negated).
+ */
+ for (i=0; i<numFaces; i++)
+ {
+ int normIdx = i*3;
+ int faceIdxVertIdx = i*numEdgePerFaceIn; // index to first element of "row" in vertex indices
+ for (j=0; j<numEdgePerFaceOut; j++)
+ {
+ int outIdx = i*numEdgePerFaceOut*3+j*3;
+ int vertIdx = vertIndices[faceIdxVertIdx+vertSamps[j]]*3;
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireCube" );
+ vertOut[outIdx ] = vertices[vertIdx ];
+ vertOut[outIdx+1] = vertices[vertIdx+1];
+ vertOut[outIdx+2] = vertices[vertIdx+2];
-# define V(a,b,c) glVertex3d( a size, b size, c size );
-# define N(a,b,c) glNormal3d( a, b, c );
+ normOut[outIdx ] = normals [normIdx ];
+ normOut[outIdx+1] = normals [normIdx+1];
+ normOut[outIdx+2] = normals [normIdx+2];
- /* PWO: I dared to convert the code to use macros... */
- glBegin( GL_LINE_LOOP ); N( 1.0, 0.0, 0.0); V(+,-,+); V(+,-,-); V(+,+,-); V(+,+,+); glEnd();
- glBegin( GL_LINE_LOOP ); N( 0.0, 1.0, 0.0); V(+,+,+); V(+,+,-); V(-,+,-); V(-,+,+); glEnd();
- glBegin( GL_LINE_LOOP ); N( 0.0, 0.0, 1.0); V(+,+,+); V(-,+,+); V(-,-,+); V(+,-,+); glEnd();
- glBegin( GL_LINE_LOOP ); N(-1.0, 0.0, 0.0); V(-,-,+); V(-,+,+); V(-,+,-); V(-,-,-); glEnd();
- glBegin( GL_LINE_LOOP ); N( 0.0,-1.0, 0.0); V(-,-,+); V(-,-,-); V(+,-,-); V(+,-,+); glEnd();
- glBegin( GL_LINE_LOOP ); N( 0.0, 0.0,-1.0); V(-,-,-); V(-,+,-); V(+,+,-); V(+,-,-); glEnd();
+ if (edgeFlagsOut)
+ edgeFlagsOut[i*numEdgePerFaceOut+j] = edgeFlags[j];
+ }
+ }
+}
-# undef V
-# undef N
+static void fghGenerateGeometry(int numFaces, int numEdgePerFace, GLdouble *vertices, GLubyte *vertIndices, GLdouble *normals, GLdouble *vertOut, GLdouble *normOut)
+{
+ fghGenerateGeometryWithEdgeFlag(numFaces, numEdgePerFace, vertices, vertIndices, normals, vertOut, normOut, NULL);
}
+
+/* -- INTERNAL SETUP OF GEOMETRY --------------------------------------- */
+/* -- stuff that can be cached -- */
+/* Cache of input to glDrawArrays */
+#define DECLARE_SHAPE_CACHE(name,nameICaps,nameCaps)\
+ static GLboolean name##Cached = FALSE;\
+ static GLdouble name##_verts[nameCaps##_VERT_ELEM_PER_OBJ];\
+ static GLdouble name##_norms[nameCaps##_VERT_ELEM_PER_OBJ];\
+ static void fgh##nameICaps##Generate()\
+ {\
+ fghGenerateGeometry(nameCaps##_NUM_FACES, nameCaps##_NUM_EDGE_PER_FACE,\
+ name##_v, name##_vi, name##_n,\
+ name##_verts, name##_norms);\
+ }
+#define DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(name,nameICaps,nameCaps)\
+ static GLboolean name##Cached = FALSE;\
+ static GLdouble name##_verts[nameCaps##_VERT_ELEM_PER_OBJ];\
+ static GLdouble name##_norms[nameCaps##_VERT_ELEM_PER_OBJ];\
+ static GLboolean name##_edgeFlags[nameCaps##_VERT_PER_OBJ_TRI];\
+ static void fgh##nameICaps##Generate()\
+ {\
+ fghGenerateGeometryWithEdgeFlag(nameCaps##_NUM_FACES, nameCaps##_NUM_EDGE_PER_FACE,\
+ name##_v, name##_vi, name##_n,\
+ name##_verts, name##_norms, name##_edgeFlags);\
+ }
/*
- * Draws a solid cube. Code contributed by Andreas Umbach <marvin@dataway.ch>
+ * In general, we build arrays with all vertices or normals.
+ * We cant compress this and use glDrawElements as all combinations of
+ * vertex and normals are unique.
*/
-void FGAPIENTRY glutSolidCube( GLdouble dSize )
+
+/* -- Cube -- */
+#define CUBE_NUM_VERT 8
+#define CUBE_NUM_FACES 6
+#define CUBE_NUM_EDGE_PER_FACE 4
+#define CUBE_VERT_PER_OBJ (CUBE_NUM_FACES*CUBE_NUM_EDGE_PER_FACE)
+#define CUBE_VERT_PER_OBJ_TRI (CUBE_VERT_PER_OBJ+CUBE_NUM_FACES*2) /* 2 extra edges per face when drawing quads as triangles */
+#define CUBE_VERT_ELEM_PER_OBJ (CUBE_VERT_PER_OBJ_TRI*3)
+/* Vertex Coordinates */
+static GLdouble cube_v[CUBE_NUM_VERT*3] =
+{
+ .5, .5, .5,
+ -.5, .5, .5,
+ -.5,-.5, .5,
+ .5,-.5, .5,
+ .5,-.5,-.5,
+ .5, .5,-.5,
+ -.5, .5,-.5,
+ -.5,-.5,-.5
+};
+/* Normal Vectors */
+static GLdouble cube_n[CUBE_NUM_FACES*3] =
{
- double size = dSize * 0.5;
+ 0.0, 0.0, 1.0,
+ 1.0, 0.0, 0.0,
+ 0.0, 1.0, 0.0,
+ -1.0, 0.0, 0.0,
+ 0.0,-1.0, 0.0,
+ 0.0, 0.0,-1.0
+};
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidCube" );
+/* Vertex indices */
+static GLubyte cube_vi[CUBE_VERT_PER_OBJ] =
+{
+ 0,1,2,3,
+ 0,3,4,5,
+ 0,5,6,1,
+ 1,6,7,2,
+ 7,4,3,2,
+ 4,7,6,5
+};
+DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(cube,Cube,CUBE);
+
+/* -- Dodecahedron -- */
+/* Magic Numbers: It is possible to create a dodecahedron by attaching two
+ * pentagons to each face of of a cube. The coordinates of the points are:
+ * (+-x,0, z); (+-1, 1, 1); (0, z, x )
+ * where x = (-1 + sqrt(5))/2, z = (1 + sqrt(5))/2 or
+ * x = 0.61803398875 and z = 1.61803398875.
+ */
+#define DODECAHEDRON_NUM_VERT 20
+#define DODECAHEDRON_NUM_FACES 12
+#define DODECAHEDRON_NUM_EDGE_PER_FACE 5
+#define DODECAHEDRON_VERT_PER_OBJ (DODECAHEDRON_NUM_FACES*DODECAHEDRON_NUM_EDGE_PER_FACE)
+#define DODECAHEDRON_VERT_PER_OBJ_TRI (DODECAHEDRON_VERT_PER_OBJ+DODECAHEDRON_NUM_FACES*4) /* 4 extra edges per face when drawing pentagons as triangles */
+#define DODECAHEDRON_VERT_ELEM_PER_OBJ (DODECAHEDRON_VERT_PER_OBJ_TRI*3)
+/* Vertex Coordinates */
+static GLdouble dodecahedron_v[DODECAHEDRON_NUM_VERT*3] =
+{
+ 0.0 , 1.61803398875, 0.61803398875,
+ -1.0 , 1.0 , 1.0 ,
+ -0.61803398875, 0.0 , 1.61803398875,
+ 0.61803398875, 0.0 , 1.61803398875,
+ 1.0 , 1.0 , 1.0 ,
+ 0.0 , 1.61803398875, -0.61803398875,
+ 1.0 , 1.0 , -1.0 ,
+ 0.61803398875, 0.0 , -1.61803398875,
+ -0.61803398875, 0.0 , -1.61803398875,
+ -1.0 , 1.0 , -1.0 ,
+ 0.0 , -1.61803398875, 0.61803398875,
+ 1.0 , -1.0 , 1.0 ,
+ -1.0 , -1.0 , 1.0 ,
+ 0.0 , -1.61803398875, -0.61803398875,
+ -1.0 , -1.0 , -1.0 ,
+ 1.0 , -1.0 , -1.0 ,
+ 1.61803398875, -0.61803398875, 0.0 ,
+ 1.61803398875, 0.61803398875, 0.0 ,
+ -1.61803398875, 0.61803398875, 0.0 ,
+ -1.61803398875, -0.61803398875, 0.0
+};
+/* Normal Vectors */
+static GLdouble dodecahedron_n[DODECAHEDRON_NUM_FACES*3] =
+{
+ 0.0 , 0.525731112119, 0.850650808354,
+ 0.0 , 0.525731112119, -0.850650808354,
+ 0.0 , -0.525731112119, 0.850650808354,
+ 0.0 , -0.525731112119, -0.850650808354,
+
+ 0.850650808354, 0.0 , 0.525731112119,
+ -0.850650808354, 0.0 , 0.525731112119,
+ 0.850650808354, 0.0 , -0.525731112119,
+ -0.850650808354, 0.0 , -0.525731112119,
+
+ 0.525731112119, 0.850650808354, 0.0 ,
+ 0.525731112119, -0.850650808354, 0.0 ,
+ -0.525731112119, 0.850650808354, 0.0 ,
+ -0.525731112119, -0.850650808354, 0.0 ,
+};
-# define V(a,b,c) glVertex3d( a size, b size, c size );
-# define N(a,b,c) glNormal3d( a, b, c );
+/* Vertex indices */
+static GLubyte dodecahedron_vi[DODECAHEDRON_VERT_PER_OBJ] =
+{
+ 0, 1, 2, 3, 4,
+ 5, 6, 7, 8, 9,
+ 10, 11, 3, 2, 12,
+ 13, 14, 8, 7, 15,
+
+ 3, 11, 16, 17, 4,
+ 2, 1, 18, 19, 12,
+ 7, 6, 17, 16, 15,
+ 8, 14, 19, 18, 9,
+
+ 17, 6, 5, 0, 4,
+ 16, 11, 10, 13, 15,
+ 18, 1, 0, 5, 9,
+ 19, 14, 13, 10, 12
+};
+DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(dodecahedron,Dodecahedron,DODECAHEDRON);
+
+
+/* -- Icosahedron -- */
+#define ICOSAHEDRON_NUM_VERT 12
+#define ICOSAHEDRON_NUM_FACES 20
+#define ICOSAHEDRON_NUM_EDGE_PER_FACE 3
+#define ICOSAHEDRON_VERT_PER_OBJ (ICOSAHEDRON_NUM_FACES*ICOSAHEDRON_NUM_EDGE_PER_FACE)
+#define ICOSAHEDRON_VERT_PER_OBJ_TRI ICOSAHEDRON_VERT_PER_OBJ
+#define ICOSAHEDRON_VERT_ELEM_PER_OBJ (ICOSAHEDRON_VERT_PER_OBJ_TRI*3)
+/* Vertex Coordinates */
+static GLdouble icosahedron_v[ICOSAHEDRON_NUM_VERT*3] =
+{
+ 1.0, 0.0, 0.0 ,
+ 0.447213595500, 0.894427191000, 0.0 ,
+ 0.447213595500, 0.276393202252, 0.850650808354,
+ 0.447213595500, -0.723606797748, 0.525731112119,
+ 0.447213595500, -0.723606797748, -0.525731112119,
+ 0.447213595500, 0.276393202252, -0.850650808354,
+ -0.447213595500, -0.894427191000, 0.0 ,
+ -0.447213595500, -0.276393202252, 0.850650808354,
+ -0.447213595500, 0.723606797748, 0.525731112119,
+ -0.447213595500, 0.723606797748, -0.525731112119,
+ -0.447213595500, -0.276393202252, -0.850650808354,
+ -1.0, 0.0, 0.0
+};
+/* Normal Vectors:
+ * icosahedron_n[i][0] = ( icosahedron_v[icosahedron_vi[i][1]][1] - icosahedron_v[icosahedron_vi[i][0]][1] ) * ( icosahedron_v[icosahedron_vi[i][2]][2] - icosahedron_v[icosahedron_vi[i][0]][2] ) - ( icosahedron_v[icosahedron_vi[i][1]][2] - icosahedron_v[icosahedron_vi[i][0]][2] ) * ( icosahedron_v[icosahedron_vi[i][2]][1] - icosahedron_v[icosahedron_vi[i][0]][1] ) ;
+ * icosahedron_n[i][1] = ( icosahedron_v[icosahedron_vi[i][1]][2] - icosahedron_v[icosahedron_vi[i][0]][2] ) * ( icosahedron_v[icosahedron_vi[i][2]][0] - icosahedron_v[icosahedron_vi[i][0]][0] ) - ( icosahedron_v[icosahedron_vi[i][1]][0] - icosahedron_v[icosahedron_vi[i][0]][0] ) * ( icosahedron_v[icosahedron_vi[i][2]][2] - icosahedron_v[icosahedron_vi[i][0]][2] ) ;
+ * icosahedron_n[i][2] = ( icosahedron_v[icosahedron_vi[i][1]][0] - icosahedron_v[icosahedron_vi[i][0]][0] ) * ( icosahedron_v[icosahedron_vi[i][2]][1] - icosahedron_v[icosahedron_vi[i][0]][1] ) - ( icosahedron_v[icosahedron_vi[i][1]][1] - icosahedron_v[icosahedron_vi[i][0]][1] ) * ( icosahedron_v[icosahedron_vi[i][2]][0] - icosahedron_v[icosahedron_vi[i][0]][0] ) ;
+*/
+static GLdouble icosahedron_n[ICOSAHEDRON_NUM_FACES*3] =
+{
+ 0.760845213037948, 0.470228201835026, 0.341640786498800,
+ 0.760845213036861, -0.179611190632978, 0.552786404500000,
+ 0.760845213033849, -0.581234022404097, 0,
+ 0.760845213036861, -0.179611190632978, -0.552786404500000,
+ 0.760845213037948, 0.470228201835026, -0.341640786498800,
+ 0.179611190628666, 0.760845213037948, 0.552786404498399,
+ 0.179611190634277, -0.290617011204044, 0.894427191000000,
+ 0.179611190633958, -0.940456403667806, 0,
+ 0.179611190634278, -0.290617011204044, -0.894427191000000,
+ 0.179611190628666, 0.760845213037948, -0.552786404498399,
+ -0.179611190633958, 0.940456403667806, 0,
+ -0.179611190634277, 0.290617011204044, 0.894427191000000,
+ -0.179611190628666, -0.760845213037948, 0.552786404498399,
+ -0.179611190628666, -0.760845213037948, -0.552786404498399,
+ -0.179611190634277, 0.290617011204044, -0.894427191000000,
+ -0.760845213036861, 0.179611190632978, -0.552786404500000,
+ -0.760845213033849, 0.581234022404097, 0,
+ -0.760845213036861, 0.179611190632978, 0.552786404500000,
+ -0.760845213037948, -0.470228201835026, 0.341640786498800,
+ -0.760845213037948, -0.470228201835026, -0.341640786498800,
+};
- /* PWO: Again, I dared to convert the code to use macros... */
- glBegin( GL_QUADS );
- N( 1.0, 0.0, 0.0); V(+,-,+); V(+,-,-); V(+,+,-); V(+,+,+);
- N( 0.0, 1.0, 0.0); V(+,+,+); V(+,+,-); V(-,+,-); V(-,+,+);
- N( 0.0, 0.0, 1.0); V(+,+,+); V(-,+,+); V(-,-,+); V(+,-,+);
- N(-1.0, 0.0, 0.0); V(-,-,+); V(-,+,+); V(-,+,-); V(-,-,-);
- N( 0.0,-1.0, 0.0); V(-,-,+); V(-,-,-); V(+,-,-); V(+,-,+);
- N( 0.0, 0.0,-1.0); V(-,-,-); V(-,+,-); V(+,+,-); V(+,-,-);
- glEnd();
+/* Vertex indices */
+static GLubyte icosahedron_vi[ICOSAHEDRON_VERT_PER_OBJ] =
+{
+ 0, 1, 2 ,
+ 0, 2, 3 ,
+ 0, 3, 4 ,
+ 0, 4, 5 ,
+ 0, 5, 1 ,
+ 1, 8, 2 ,
+ 2, 7, 3 ,
+ 3, 6, 4 ,
+ 4, 10, 5 ,
+ 5, 9, 1 ,
+ 1, 9, 8 ,
+ 2, 8, 7 ,
+ 3, 7, 6 ,
+ 4, 6, 10 ,
+ 5, 10, 9 ,
+ 11, 9, 10 ,
+ 11, 8, 9 ,
+ 11, 7, 8 ,
+ 11, 6, 7 ,
+ 11, 10, 6
+};
+DECLARE_SHAPE_CACHE(icosahedron,Icosahedron,ICOSAHEDRON);
+
+/* -- Octahedron -- */
+#define OCTAHEDRON_NUM_VERT 6
+#define OCTAHEDRON_NUM_FACES 8
+#define OCTAHEDRON_NUM_EDGE_PER_FACE 3
+#define OCTAHEDRON_VERT_PER_OBJ (OCTAHEDRON_NUM_FACES*OCTAHEDRON_NUM_EDGE_PER_FACE)
+#define OCTAHEDRON_VERT_PER_OBJ_TRI OCTAHEDRON_VERT_PER_OBJ
+#define OCTAHEDRON_VERT_ELEM_PER_OBJ (OCTAHEDRON_VERT_PER_OBJ_TRI*3)
+
+/* Vertex Coordinates */
+static GLdouble octahedron_v[OCTAHEDRON_NUM_VERT*3] =
+{
+ 1., 0., 0.,
+ 0., 1., 0.,
+ 0., 0., 1.,
+ -1., 0., 0.,
+ 0., -1., 0.,
+ 0., 0., -1.,
+
+};
+/* Normal Vectors */
+static GLdouble octahedron_n[OCTAHEDRON_NUM_FACES*3] =
+{
+ 0.577350269189, 0.577350269189, 0.577350269189, /* sqrt(1/3) */
+ 0.577350269189, 0.577350269189,-0.577350269189,
+ 0.577350269189,-0.577350269189, 0.577350269189,
+ 0.577350269189,-0.577350269189,-0.577350269189,
+ -0.577350269189, 0.577350269189, 0.577350269189,
+ -0.577350269189, 0.577350269189,-0.577350269189,
+ -0.577350269189,-0.577350269189, 0.577350269189,
+ -0.577350269189,-0.577350269189,-0.577350269189
+
+};
+
+/* Vertex indices */
+static GLubyte octahedron_vi[OCTAHEDRON_VERT_PER_OBJ] =
+{
+ 0, 1, 2,
+ 0, 5, 1,
+ 0, 2, 4,
+ 0, 4, 5,
+ 3, 2, 1,
+ 3, 1, 5,
+ 3, 4, 2,
+ 3, 5, 4
+};
+DECLARE_SHAPE_CACHE(octahedron,Octahedron,OCTAHEDRON);
+
+/* -- RhombicDodecahedron -- */
+#define RHOMBICDODECAHEDRON_NUM_VERT 14
+#define RHOMBICDODECAHEDRON_NUM_FACES 12
+#define RHOMBICDODECAHEDRON_NUM_EDGE_PER_FACE 4
+#define RHOMBICDODECAHEDRON_VERT_PER_OBJ (RHOMBICDODECAHEDRON_NUM_FACES*RHOMBICDODECAHEDRON_NUM_EDGE_PER_FACE)
+#define RHOMBICDODECAHEDRON_VERT_PER_OBJ_TRI (RHOMBICDODECAHEDRON_VERT_PER_OBJ+RHOMBICDODECAHEDRON_NUM_FACES*2) /* 2 extra edges per face when drawing quads as triangles */
+#define RHOMBICDODECAHEDRON_VERT_ELEM_PER_OBJ (RHOMBICDODECAHEDRON_VERT_PER_OBJ_TRI*3)
+
+/* Vertex Coordinates */
+static GLdouble rhombicdodecahedron_v[RHOMBICDODECAHEDRON_NUM_VERT*3] =
+{
+ 0.0, 0.0, 1.0,
+ 0.707106781187, 0.0 , 0.5,
+ 0.0 , 0.707106781187, 0.5,
+ -0.707106781187, 0.0 , 0.5,
+ 0.0 , -0.707106781187, 0.5,
+ 0.707106781187, 0.707106781187, 0.0,
+ -0.707106781187, 0.707106781187, 0.0,
+ -0.707106781187, -0.707106781187, 0.0,
+ 0.707106781187, -0.707106781187, 0.0,
+ 0.707106781187, 0.0 , -0.5,
+ 0.0 , 0.707106781187, -0.5,
+ -0.707106781187, 0.0 , -0.5,
+ 0.0 , -0.707106781187, -0.5,
+ 0.0, 0.0, -1.0
+};
+/* Normal Vectors */
+static GLdouble rhombicdodecahedron_n[RHOMBICDODECAHEDRON_NUM_FACES*3] =
+{
+ 0.353553390594, 0.353553390594, 0.5,
+ -0.353553390594, 0.353553390594, 0.5,
+ -0.353553390594, -0.353553390594, 0.5,
+ 0.353553390594, -0.353553390594, 0.5,
+ 0.0 , 1.0 , 0.0,
+ -1.0 , 0.0 , 0.0,
+ 0.0 , -1.0 , 0.0,
+ 1.0 , 0.0 , 0.0,
+ 0.353553390594, 0.353553390594, -0.5,
+ -0.353553390594, 0.353553390594, -0.5,
+ -0.353553390594, -0.353553390594, -0.5,
+ 0.353553390594, -0.353553390594, -0.5
+};
+
+/* Vertex indices */
+static GLubyte rhombicdodecahedron_vi[RHOMBICDODECAHEDRON_VERT_PER_OBJ] =
+{
+ 0, 1, 5, 2,
+ 0, 2, 6, 3,
+ 0, 3, 7, 4,
+ 0, 4, 8, 1,
+ 5, 10, 6, 2,
+ 6, 11, 7, 3,
+ 7, 12, 8, 4,
+ 8, 9, 5, 1,
+ 5, 9, 13, 10,
+ 6, 10, 13, 11,
+ 7, 11, 13, 12,
+ 8, 12, 13, 9
+};
+DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(rhombicdodecahedron,RhombicDodecahedron,RHOMBICDODECAHEDRON);
+
+/* -- Tetrahedron -- */
+/* Magic Numbers: r0 = ( 1, 0, 0 )
+ * r1 = ( -1/3, 2 sqrt(2) / 3, 0 )
+ * r2 = ( -1/3, - sqrt(2) / 3, sqrt(6) / 3 )
+ * r3 = ( -1/3, - sqrt(2) / 3, -sqrt(6) / 3 )
+ * |r0| = |r1| = |r2| = |r3| = 1
+ * Distance between any two points is 2 sqrt(6) / 3
+ *
+ * Normals: The unit normals are simply the negative of the coordinates of the point not on the surface.
+ */
+#define TETRAHEDRON_NUM_VERT 4
+#define TETRAHEDRON_NUM_FACES 4
+#define TETRAHEDRON_NUM_EDGE_PER_FACE 3
+#define TETRAHEDRON_VERT_PER_OBJ (TETRAHEDRON_NUM_FACES*TETRAHEDRON_NUM_EDGE_PER_FACE)
+#define TETRAHEDRON_VERT_PER_OBJ_TRI TETRAHEDRON_VERT_PER_OBJ
+#define TETRAHEDRON_VERT_ELEM_PER_OBJ (TETRAHEDRON_VERT_PER_OBJ_TRI*3)
+
+/* Vertex Coordinates */
+static GLdouble tetrahedron_v[TETRAHEDRON_NUM_VERT*3] =
+{
+ 1.0, 0.0, 0.0,
+ -0.333333333333, 0.942809041582, 0.0,
+ -0.333333333333, -0.471404520791, 0.816496580928,
+ -0.333333333333, -0.471404520791, -0.816496580928
+};
+/* Normal Vectors */
+static GLdouble tetrahedron_n[TETRAHEDRON_NUM_FACES*3] =
+{
+ - 1.0, 0.0, 0.0,
+ 0.333333333333, -0.942809041582, 0.0,
+ 0.333333333333, 0.471404520791, -0.816496580928,
+ 0.333333333333, 0.471404520791, 0.816496580928
+};
+
+/* Vertex indices */
+static GLubyte tetrahedron_vi[TETRAHEDRON_VERT_PER_OBJ] =
+{
+ 1, 3, 2,
+ 0, 2, 3,
+ 0, 3, 1,
+ 0, 1, 2
+};
+DECLARE_SHAPE_CACHE(tetrahedron,Tetrahedron,TETRAHEDRON);
+
+/* -- Sierpinski Sponge -- */
+static unsigned int ipow (int x, unsigned int y)
+{
+ return y==0? 1: y==1? x: (y%2? x: 1) * ipow(x*x, y/2);
+}
-# undef V
-# undef N
+static void fghSierpinskiSpongeGenerate ( int numLevels, GLdouble offset[3], GLdouble scale, GLdouble* vertices, GLdouble* normals )
+{
+ int i, j;
+ if ( numLevels == 0 )
+ {
+ for (i=0; i<TETRAHEDRON_NUM_FACES; i++)
+ {
+ int normIdx = i*3;
+ int faceIdxVertIdx = i*TETRAHEDRON_NUM_EDGE_PER_FACE;
+ for (j=0; j<TETRAHEDRON_NUM_EDGE_PER_FACE; j++)
+ {
+ int outIdx = i*TETRAHEDRON_NUM_EDGE_PER_FACE*3+j*3;
+ int vertIdx = tetrahedron_vi[faceIdxVertIdx+j]*3;
+
+ vertices[outIdx ] = offset[0] + scale * tetrahedron_v[vertIdx ];
+ vertices[outIdx+1] = offset[1] + scale * tetrahedron_v[vertIdx+1];
+ vertices[outIdx+2] = offset[2] + scale * tetrahedron_v[vertIdx+2];
+
+ normals [outIdx ] = tetrahedron_n[normIdx ];
+ normals [outIdx+1] = tetrahedron_n[normIdx+1];
+ normals [outIdx+2] = tetrahedron_n[normIdx+2];
+ }
+ }
+ }
+ else if ( numLevels > 0 )
+ {
+ GLdouble local_offset[3] ; /* Use a local variable to avoid buildup of roundoff errors */
+ unsigned int stride = ipow(4,--numLevels)*TETRAHEDRON_VERT_ELEM_PER_OBJ;
+ scale /= 2.0 ;
+ for ( i = 0 ; i < TETRAHEDRON_NUM_FACES ; i++ )
+ {
+ int idx = i*3;
+ local_offset[0] = offset[0] + scale * tetrahedron_v[idx ];
+ local_offset[1] = offset[1] + scale * tetrahedron_v[idx+1];
+ local_offset[2] = offset[2] + scale * tetrahedron_v[idx+2];
+ fghSierpinskiSpongeGenerate ( numLevels, local_offset, scale, vertices+i*stride, normals+i*stride );
+ }
+ }
}
+/* -- Now the various shapes involving circles -- */
/*
* Compute lookup table of cos and sin values forming a cirle
*
* The last entry is exactly the same as the first
* The sign of n can be flipped to get the reverse loop
*/
-
static void fghCircleTable(double **sint,double **cost,const int n)
{
int i;
(*cost)[size] = (*cost)[0];
}
+
+/* -- INTERNAL DRAWING functions --------------------------------------- */
+#define _DECLARE_INTERNAL_DRAW_DO_DECLARE(name,nameICaps,nameCaps,edgeFlags)\
+ static void fgh##nameICaps( GLboolean useWireMode )\
+ {\
+ if (!name##Cached)\
+ {\
+ fgh##nameICaps##Generate();\
+ name##Cached = GL_TRUE;\
+ }\
+ fghDrawGeometry(name##_verts,name##_norms,edgeFlags,\
+ nameCaps##_VERT_PER_OBJ_TRI,nameCaps##_NUM_FACES,nameCaps##_NUM_EDGE_PER_FACE,\
+ useWireMode);\
+ }
+#define DECLARE_INTERNAL_DRAW(name,nameICaps,nameCaps) _DECLARE_INTERNAL_DRAW_DO_DECLARE(name,nameICaps,nameCaps,NULL)
+#define DECLARE_INTERNAL_DRAW_DECOMPOSED_TO_TRIANGLE(name,nameICaps,nameCaps) _DECLARE_INTERNAL_DRAW_DO_DECLARE(name,nameICaps,nameCaps,name##_edgeFlags)
+
+static void fghCube( GLdouble dSize, GLboolean useWireMode )
+{
+ if (!cubeCached)
+ {
+ fghCubeGenerate();
+ cubeCached = GL_TRUE;
+ }
+
+ if (dSize!=1.)
+ {
+ int i;
+
+ /* Need to build new vertex list containing vertices for cube of different size */
+ GLdouble *vertices = malloc(CUBE_VERT_ELEM_PER_OBJ * sizeof(GLdouble));
+ /* Bail out if memory allocation fails, fgError never returns */
+ if (!vertices)
+ {
+ free(vertices);
+ fgError("Failed to allocate memory in fghCube");
+ }
+ for (i=0; i<CUBE_VERT_ELEM_PER_OBJ; i++)
+ vertices[i] = dSize*cube_verts[i];
+
+ fghDrawGeometry(vertices ,cube_norms,cube_edgeFlags,CUBE_VERT_PER_OBJ_TRI,CUBE_NUM_FACES,CUBE_NUM_EDGE_PER_FACE,useWireMode);
+
+ /* cleanup allocated memory */
+ free(vertices);
+ }
+ else
+ fghDrawGeometry(cube_verts,cube_norms,cube_edgeFlags,CUBE_VERT_PER_OBJ_TRI,CUBE_NUM_FACES,CUBE_NUM_EDGE_PER_FACE,useWireMode);
+}
+
+DECLARE_INTERNAL_DRAW_DECOMPOSED_TO_TRIANGLE(dodecahedron,Dodecahedron,DODECAHEDRON);
+DECLARE_INTERNAL_DRAW(icosahedron,Icosahedron,ICOSAHEDRON);
+DECLARE_INTERNAL_DRAW(octahedron,Octahedron,OCTAHEDRON);
+DECLARE_INTERNAL_DRAW_DECOMPOSED_TO_TRIANGLE(rhombicdodecahedron,RhombicDodecahedron,RHOMBICDODECAHEDRON);
+DECLARE_INTERNAL_DRAW(tetrahedron,Tetrahedron,TETRAHEDRON);
+
+static void fghSierpinskiSponge ( int numLevels, GLdouble offset[3], GLdouble scale, GLboolean useWireMode )
+{
+ GLdouble *vertices;
+ GLdouble * normals;
+ GLsizei numTetr = numLevels<0? 0 : ipow(4,numLevels); /* No sponge for numLevels below 0 */
+ GLsizei numVert = numTetr*TETRAHEDRON_VERT_PER_OBJ;
+ GLsizei numFace = numTetr*TETRAHEDRON_NUM_FACES;
+
+ if (numTetr)
+ {
+ /* Allocate memory */
+ vertices = malloc(numVert*3 * sizeof(GLdouble));
+ normals = malloc(numVert*3 * sizeof(GLdouble));
+ /* Bail out if memory allocation fails, fgError never returns */
+ if (!vertices || !normals)
+ {
+ free(vertices);
+ free(normals);
+ fgError("Failed to allocate memory in fghSierpinskiSponge");
+ }
+
+ /* Generate elements */
+ fghSierpinskiSpongeGenerate ( numLevels, offset, scale, vertices, normals );
+
+ /* Draw and cleanup */
+ fghDrawGeometry(vertices,normals,NULL,numVert,numFace,TETRAHEDRON_NUM_EDGE_PER_FACE,useWireMode);
+ free(vertices);
+ free(normals );
+ }
+}
+
+
+/* -- INTERFACE FUNCTIONS ---------------------------------------------- */
+
+
/*
* Draws a solid sphere
*/
glPopMatrix();
}
-/*
- *
- */
-void FGAPIENTRY glutWireDodecahedron( void )
-{
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireDodecahedron" );
-
- /* Magic Numbers: It is possible to create a dodecahedron by attaching two pentagons to each face of
- * of a cube. The coordinates of the points are:
- * (+-x,0, z); (+-1, 1, 1); (0, z, x )
- * where x = (-1 + sqrt(5))/2, z = (1 + sqrt(5))/2 or
- * x = 0.61803398875 and z = 1.61803398875.
- */
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( 0.0, 0.525731112119, 0.850650808354 ) ; glVertex3d ( 0.0, 1.61803398875, 0.61803398875 ) ; glVertex3d ( -1.0, 1.0, 1.0 ) ; glVertex3d ( -0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( 0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( 1.0, 1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( 0.0, 0.525731112119, -0.850650808354 ) ; glVertex3d ( 0.0, 1.61803398875, -0.61803398875 ) ; glVertex3d ( 1.0, 1.0, -1.0 ) ; glVertex3d ( 0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( -0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( -1.0, 1.0, -1.0 ) ;
- glEnd () ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( 0.0, -0.525731112119, 0.850650808354 ) ; glVertex3d ( 0.0, -1.61803398875, 0.61803398875 ) ; glVertex3d ( 1.0, -1.0, 1.0 ) ; glVertex3d ( 0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( -0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( -1.0, -1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( 0.0, -0.525731112119, -0.850650808354 ) ; glVertex3d ( 0.0, -1.61803398875, -0.61803398875 ) ; glVertex3d ( -1.0, -1.0, -1.0 ) ; glVertex3d ( -0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( 0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( 1.0, -1.0, -1.0 ) ;
- glEnd () ;
-
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( 0.850650808354, 0.0, 0.525731112119 ) ; glVertex3d ( 0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( 1.0, -1.0, 1.0 ) ; glVertex3d ( 1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( 1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( 1.0, 1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( -0.850650808354, 0.0, 0.525731112119 ) ; glVertex3d ( -0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( -1.0, 1.0, 1.0 ) ; glVertex3d ( -1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( -1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( -1.0, -1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( 0.850650808354, 0.0, -0.525731112119 ) ; glVertex3d ( 0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( 1.0, 1.0, -1.0 ) ; glVertex3d ( 1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( 1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( 1.0, -1.0, -1.0 ) ;
- glEnd () ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( -0.850650808354, 0.0, -0.525731112119 ) ; glVertex3d ( -0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( -1.0, -1.0, -1.0 ) ; glVertex3d ( -1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( -1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( -1.0, 1.0, -1.0 ) ;
- glEnd () ;
-
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( 0.525731112119, 0.850650808354, 0.0 ) ; glVertex3d ( 1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( 1.0, 1.0, -1.0 ) ; glVertex3d ( 0.0, 1.61803398875, -0.61803398875 ) ; glVertex3d ( 0.0, 1.61803398875, 0.61803398875 ) ; glVertex3d ( 1.0, 1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( 0.525731112119, -0.850650808354, 0.0 ) ; glVertex3d ( 1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( 1.0, -1.0, 1.0 ) ; glVertex3d ( 0.0, -1.61803398875, 0.61803398875 ) ; glVertex3d ( 0.0, -1.61803398875, -0.61803398875 ) ; glVertex3d ( 1.0, -1.0, -1.0 ) ;
- glEnd () ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( -0.525731112119, 0.850650808354, 0.0 ) ; glVertex3d ( -1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( -1.0, 1.0, 1.0 ) ; glVertex3d ( 0.0, 1.61803398875, 0.61803398875 ) ; glVertex3d ( 0.0, 1.61803398875, -0.61803398875 ) ; glVertex3d ( -1.0, 1.0, -1.0 ) ;
- glEnd () ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( -0.525731112119, -0.850650808354, 0.0 ) ; glVertex3d ( -1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( -1.0, -1.0, -1.0 ) ; glVertex3d ( 0.0, -1.61803398875, -0.61803398875 ) ; glVertex3d ( 0.0, -1.61803398875, 0.61803398875 ) ; glVertex3d ( -1.0, -1.0, 1.0 ) ;
- glEnd () ;
-}
-
-/*
- *
- */
-void FGAPIENTRY glutSolidDodecahedron( void )
-{
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidDodecahedron" );
-
- /* Magic Numbers: It is possible to create a dodecahedron by attaching two pentagons to each face of
- * of a cube. The coordinates of the points are:
- * (+-x,0, z); (+-1, 1, 1); (0, z, x )
- * where x = (-1 + sqrt(5))/2, z = (1 + sqrt(5))/2 or
- * x = 0.61803398875 and z = 1.61803398875.
- */
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( 0.0, 0.525731112119, 0.850650808354 ) ; glVertex3d ( 0.0, 1.61803398875, 0.61803398875 ) ; glVertex3d ( -1.0, 1.0, 1.0 ) ; glVertex3d ( -0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( 0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( 1.0, 1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( 0.0, 0.525731112119, -0.850650808354 ) ; glVertex3d ( 0.0, 1.61803398875, -0.61803398875 ) ; glVertex3d ( 1.0, 1.0, -1.0 ) ; glVertex3d ( 0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( -0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( -1.0, 1.0, -1.0 ) ;
- glEnd () ;
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( 0.0, -0.525731112119, 0.850650808354 ) ; glVertex3d ( 0.0, -1.61803398875, 0.61803398875 ) ; glVertex3d ( 1.0, -1.0, 1.0 ) ; glVertex3d ( 0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( -0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( -1.0, -1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( 0.0, -0.525731112119, -0.850650808354 ) ; glVertex3d ( 0.0, -1.61803398875, -0.61803398875 ) ; glVertex3d ( -1.0, -1.0, -1.0 ) ; glVertex3d ( -0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( 0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( 1.0, -1.0, -1.0 ) ;
- glEnd () ;
-
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( 0.850650808354, 0.0, 0.525731112119 ) ; glVertex3d ( 0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( 1.0, -1.0, 1.0 ) ; glVertex3d ( 1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( 1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( 1.0, 1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( -0.850650808354, 0.0, 0.525731112119 ) ; glVertex3d ( -0.61803398875, 0.0, 1.61803398875 ) ; glVertex3d ( -1.0, 1.0, 1.0 ) ; glVertex3d ( -1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( -1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( -1.0, -1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( 0.850650808354, 0.0, -0.525731112119 ) ; glVertex3d ( 0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( 1.0, 1.0, -1.0 ) ; glVertex3d ( 1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( 1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( 1.0, -1.0, -1.0 ) ;
- glEnd () ;
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( -0.850650808354, 0.0, -0.525731112119 ) ; glVertex3d ( -0.61803398875, 0.0, -1.61803398875 ) ; glVertex3d ( -1.0, -1.0, -1.0 ) ; glVertex3d ( -1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( -1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( -1.0, 1.0, -1.0 ) ;
- glEnd () ;
-
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( 0.525731112119, 0.850650808354, 0.0 ) ; glVertex3d ( 1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( 1.0, 1.0, -1.0 ) ; glVertex3d ( 0.0, 1.61803398875, -0.61803398875 ) ; glVertex3d ( 0.0, 1.61803398875, 0.61803398875 ) ; glVertex3d ( 1.0, 1.0, 1.0 ) ;
- glEnd () ;
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( 0.525731112119, -0.850650808354, 0.0 ) ; glVertex3d ( 1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( 1.0, -1.0, 1.0 ) ; glVertex3d ( 0.0, -1.61803398875, 0.61803398875 ) ; glVertex3d ( 0.0, -1.61803398875, -0.61803398875 ) ; glVertex3d ( 1.0, -1.0, -1.0 ) ;
- glEnd () ;
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( -0.525731112119, 0.850650808354, 0.0 ) ; glVertex3d ( -1.61803398875, 0.61803398875, 0.0 ) ; glVertex3d ( -1.0, 1.0, 1.0 ) ; glVertex3d ( 0.0, 1.61803398875, 0.61803398875 ) ; glVertex3d ( 0.0, 1.61803398875, -0.61803398875 ) ; glVertex3d ( -1.0, 1.0, -1.0 ) ;
- glEnd () ;
- glBegin ( GL_POLYGON ) ;
- glNormal3d ( -0.525731112119, -0.850650808354, 0.0 ) ; glVertex3d ( -1.61803398875, -0.61803398875, 0.0 ) ; glVertex3d ( -1.0, -1.0, -1.0 ) ; glVertex3d ( 0.0, -1.61803398875, -0.61803398875 ) ; glVertex3d ( 0.0, -1.61803398875, 0.61803398875 ) ; glVertex3d ( -1.0, -1.0, 1.0 ) ;
- glEnd () ;
-}
-/*
- *
- */
-void FGAPIENTRY glutWireOctahedron( void )
-{
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireOctahedron" );
-
-#define RADIUS 1.0f
- glBegin( GL_LINE_LOOP );
- glNormal3d( 0.577350269189, 0.577350269189, 0.577350269189); glVertex3d( RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, RADIUS, 0.0 ); glVertex3d( 0.0, 0.0, RADIUS );
- glNormal3d( 0.577350269189, 0.577350269189,-0.577350269189); glVertex3d( RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, 0.0,-RADIUS ); glVertex3d( 0.0, RADIUS, 0.0 );
- glNormal3d( 0.577350269189,-0.577350269189, 0.577350269189); glVertex3d( RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, 0.0, RADIUS ); glVertex3d( 0.0,-RADIUS, 0.0 );
- glNormal3d( 0.577350269189,-0.577350269189,-0.577350269189); glVertex3d( RADIUS, 0.0, 0.0 ); glVertex3d( 0.0,-RADIUS, 0.0 ); glVertex3d( 0.0, 0.0,-RADIUS );
- glNormal3d(-0.577350269189, 0.577350269189, 0.577350269189); glVertex3d(-RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, 0.0, RADIUS ); glVertex3d( 0.0, RADIUS, 0.0 );
- glNormal3d(-0.577350269189, 0.577350269189,-0.577350269189); glVertex3d(-RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, RADIUS, 0.0 ); glVertex3d( 0.0, 0.0,-RADIUS );
- glNormal3d(-0.577350269189,-0.577350269189, 0.577350269189); glVertex3d(-RADIUS, 0.0, 0.0 ); glVertex3d( 0.0,-RADIUS, 0.0 ); glVertex3d( 0.0, 0.0, RADIUS );
- glNormal3d(-0.577350269189,-0.577350269189,-0.577350269189); glVertex3d(-RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, 0.0,-RADIUS ); glVertex3d( 0.0,-RADIUS, 0.0 );
- glEnd();
-#undef RADIUS
-}
-
-/*
- *
- */
-void FGAPIENTRY glutSolidOctahedron( void )
-{
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidOctahedron" );
-
-#define RADIUS 1.0f
- glBegin( GL_TRIANGLES );
- glNormal3d( 0.577350269189, 0.577350269189, 0.577350269189); glVertex3d( RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, RADIUS, 0.0 ); glVertex3d( 0.0, 0.0, RADIUS );
- glNormal3d( 0.577350269189, 0.577350269189,-0.577350269189); glVertex3d( RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, 0.0,-RADIUS ); glVertex3d( 0.0, RADIUS, 0.0 );
- glNormal3d( 0.577350269189,-0.577350269189, 0.577350269189); glVertex3d( RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, 0.0, RADIUS ); glVertex3d( 0.0,-RADIUS, 0.0 );
- glNormal3d( 0.577350269189,-0.577350269189,-0.577350269189); glVertex3d( RADIUS, 0.0, 0.0 ); glVertex3d( 0.0,-RADIUS, 0.0 ); glVertex3d( 0.0, 0.0,-RADIUS );
- glNormal3d(-0.577350269189, 0.577350269189, 0.577350269189); glVertex3d(-RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, 0.0, RADIUS ); glVertex3d( 0.0, RADIUS, 0.0 );
- glNormal3d(-0.577350269189, 0.577350269189,-0.577350269189); glVertex3d(-RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, RADIUS, 0.0 ); glVertex3d( 0.0, 0.0,-RADIUS );
- glNormal3d(-0.577350269189,-0.577350269189, 0.577350269189); glVertex3d(-RADIUS, 0.0, 0.0 ); glVertex3d( 0.0,-RADIUS, 0.0 ); glVertex3d( 0.0, 0.0, RADIUS );
- glNormal3d(-0.577350269189,-0.577350269189,-0.577350269189); glVertex3d(-RADIUS, 0.0, 0.0 ); glVertex3d( 0.0, 0.0,-RADIUS ); glVertex3d( 0.0,-RADIUS, 0.0 );
- glEnd();
-#undef RADIUS
-}
-
-/* Magic Numbers: r0 = ( 1, 0, 0 )
- * r1 = ( -1/3, 2 sqrt(2) / 3, 0 )
- * r2 = ( -1/3, -sqrt(2) / 3, sqrt(6) / 3 )
- * r3 = ( -1/3, -sqrt(2) / 3, -sqrt(6) / 3 )
- * |r0| = |r1| = |r2| = |r3| = 1
- * Distance between any two points is 2 sqrt(6) / 3
- *
- * Normals: The unit normals are simply the negative of the coordinates of the point not on the surface.
- */
-
-#define NUM_TETR_FACES 4
-
-static GLdouble tet_r[4][3] = { { 1.0, 0.0, 0.0 },
- { -0.333333333333, 0.942809041582, 0.0 },
- { -0.333333333333, -0.471404520791, 0.816496580928 },
- { -0.333333333333, -0.471404520791, -0.816496580928 } } ;
-
-static GLint tet_i[4][3] = /* Vertex indices */
-{
- { 1, 3, 2 }, { 0, 2, 3 }, { 0, 3, 1 }, { 0, 1, 2 }
-} ;
-
-/*
- *
- */
-void FGAPIENTRY glutWireTetrahedron( void )
-{
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireTetrahedron" );
-
- glBegin( GL_LINE_LOOP ) ;
- glNormal3d ( -tet_r[0][0], -tet_r[0][1], -tet_r[0][2] ) ; glVertex3dv ( tet_r[1] ) ; glVertex3dv ( tet_r[3] ) ; glVertex3dv ( tet_r[2] ) ;
- glNormal3d ( -tet_r[1][0], -tet_r[1][1], -tet_r[1][2] ) ; glVertex3dv ( tet_r[0] ) ; glVertex3dv ( tet_r[2] ) ; glVertex3dv ( tet_r[3] ) ;
- glNormal3d ( -tet_r[2][0], -tet_r[2][1], -tet_r[2][2] ) ; glVertex3dv ( tet_r[0] ) ; glVertex3dv ( tet_r[3] ) ; glVertex3dv ( tet_r[1] ) ;
- glNormal3d ( -tet_r[3][0], -tet_r[3][1], -tet_r[3][2] ) ; glVertex3dv ( tet_r[0] ) ; glVertex3dv ( tet_r[1] ) ; glVertex3dv ( tet_r[2] ) ;
- glEnd() ;
-}
-
-/*
- *
- */
-void FGAPIENTRY glutSolidTetrahedron( void )
-{
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidTetrahedron" );
-
- glBegin( GL_TRIANGLES ) ;
- glNormal3d ( -tet_r[0][0], -tet_r[0][1], -tet_r[0][2] ) ; glVertex3dv ( tet_r[1] ) ; glVertex3dv ( tet_r[3] ) ; glVertex3dv ( tet_r[2] ) ;
- glNormal3d ( -tet_r[1][0], -tet_r[1][1], -tet_r[1][2] ) ; glVertex3dv ( tet_r[0] ) ; glVertex3dv ( tet_r[2] ) ; glVertex3dv ( tet_r[3] ) ;
- glNormal3d ( -tet_r[2][0], -tet_r[2][1], -tet_r[2][2] ) ; glVertex3dv ( tet_r[0] ) ; glVertex3dv ( tet_r[3] ) ; glVertex3dv ( tet_r[1] ) ;
- glNormal3d ( -tet_r[3][0], -tet_r[3][1], -tet_r[3][2] ) ; glVertex3dv ( tet_r[0] ) ; glVertex3dv ( tet_r[1] ) ; glVertex3dv ( tet_r[2] ) ;
- glEnd() ;
-}
-
-/*
- *
- */
-static double icos_r[12][3] = {
- { 1.0, 0.0, 0.0 },
- { 0.447213595500, 0.894427191000, 0.0 },
- { 0.447213595500, 0.276393202252, 0.850650808354 },
- { 0.447213595500, -0.723606797748, 0.525731112119 },
- { 0.447213595500, -0.723606797748, -0.525731112119 },
- { 0.447213595500, 0.276393202252, -0.850650808354 },
- { -0.447213595500, -0.894427191000, 0.0 },
- { -0.447213595500, -0.276393202252, 0.850650808354 },
- { -0.447213595500, 0.723606797748, 0.525731112119 },
- { -0.447213595500, 0.723606797748, -0.525731112119 },
- { -0.447213595500, -0.276393202252, -0.850650808354 },
- { -1.0, 0.0, 0.0 }
-};
-
-static int icos_v [20][3] = {
- { 0, 1, 2 },
- { 0, 2, 3 },
- { 0, 3, 4 },
- { 0, 4, 5 },
- { 0, 5, 1 },
- { 1, 8, 2 },
- { 2, 7, 3 },
- { 3, 6, 4 },
- { 4, 10, 5 },
- { 5, 9, 1 },
- { 1, 9, 8 },
- { 2, 8, 7 },
- { 3, 7, 6 },
- { 4, 6, 10 },
- { 5, 10, 9 },
- { 11, 9, 10 },
- { 11, 8, 9 },
- { 11, 7, 8 },
- { 11, 6, 7 },
- { 11, 10, 6 }
-};
-void FGAPIENTRY glutWireIcosahedron( void )
-{
- int i ;
-
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireIcosahedron" );
-
- for ( i = 0; i < 20; i++ )
- {
- double normal[3] ;
- normal[0] = ( icos_r[icos_v[i][1]][1] - icos_r[icos_v[i][0]][1] ) * ( icos_r[icos_v[i][2]][2] - icos_r[icos_v[i][0]][2] ) - ( icos_r[icos_v[i][1]][2] - icos_r[icos_v[i][0]][2] ) * ( icos_r[icos_v[i][2]][1] - icos_r[icos_v[i][0]][1] ) ;
- normal[1] = ( icos_r[icos_v[i][1]][2] - icos_r[icos_v[i][0]][2] ) * ( icos_r[icos_v[i][2]][0] - icos_r[icos_v[i][0]][0] ) - ( icos_r[icos_v[i][1]][0] - icos_r[icos_v[i][0]][0] ) * ( icos_r[icos_v[i][2]][2] - icos_r[icos_v[i][0]][2] ) ;
- normal[2] = ( icos_r[icos_v[i][1]][0] - icos_r[icos_v[i][0]][0] ) * ( icos_r[icos_v[i][2]][1] - icos_r[icos_v[i][0]][1] ) - ( icos_r[icos_v[i][1]][1] - icos_r[icos_v[i][0]][1] ) * ( icos_r[icos_v[i][2]][0] - icos_r[icos_v[i][0]][0] ) ;
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3dv ( normal ) ;
- glVertex3dv ( icos_r[icos_v[i][0]] ) ;
- glVertex3dv ( icos_r[icos_v[i][1]] ) ;
- glVertex3dv ( icos_r[icos_v[i][2]] ) ;
- glEnd () ;
- }
-}
+/* -- INTERFACE FUNCTIONS -------------------------------------------------- */
+/* Macro to generate interface functions */
+#define DECLARE_SHAPE_INTERFACE(nameICaps)\
+ void FGAPIENTRY glutWire##nameICaps( void )\
+ {\
+ FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWire"#nameICaps );\
+ fgh##nameICaps( TRUE );\
+ }\
+ void FGAPIENTRY glutSolid##nameICaps( void )\
+ {\
+ FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolid"#nameICaps );\
+ fgh##nameICaps( FALSE );\
+ }
-/*
- *
- */
-void FGAPIENTRY glutSolidIcosahedron( void )
+void FGAPIENTRY glutWireCube( GLdouble dSize )
{
- int i ;
-
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidIcosahedron" );
-
- glBegin ( GL_TRIANGLES ) ;
- for ( i = 0; i < 20; i++ )
- {
- double normal[3] ;
- normal[0] = ( icos_r[icos_v[i][1]][1] - icos_r[icos_v[i][0]][1] ) * ( icos_r[icos_v[i][2]][2] - icos_r[icos_v[i][0]][2] ) - ( icos_r[icos_v[i][1]][2] - icos_r[icos_v[i][0]][2] ) * ( icos_r[icos_v[i][2]][1] - icos_r[icos_v[i][0]][1] ) ;
- normal[1] = ( icos_r[icos_v[i][1]][2] - icos_r[icos_v[i][0]][2] ) * ( icos_r[icos_v[i][2]][0] - icos_r[icos_v[i][0]][0] ) - ( icos_r[icos_v[i][1]][0] - icos_r[icos_v[i][0]][0] ) * ( icos_r[icos_v[i][2]][2] - icos_r[icos_v[i][0]][2] ) ;
- normal[2] = ( icos_r[icos_v[i][1]][0] - icos_r[icos_v[i][0]][0] ) * ( icos_r[icos_v[i][2]][1] - icos_r[icos_v[i][0]][1] ) - ( icos_r[icos_v[i][1]][1] - icos_r[icos_v[i][0]][1] ) * ( icos_r[icos_v[i][2]][0] - icos_r[icos_v[i][0]][0] ) ;
- glNormal3dv ( normal ) ;
- glVertex3dv ( icos_r[icos_v[i][0]] ) ;
- glVertex3dv ( icos_r[icos_v[i][1]] ) ;
- glVertex3dv ( icos_r[icos_v[i][2]] ) ;
- }
-
- glEnd () ;
+ FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireCube" );
+ fghCube( dSize, TRUE );
}
-
-/*
- *
- */
-static double rdod_r[14][3] = {
- { 0.0, 0.0, 1.0 },
- { 0.707106781187, 0.000000000000, 0.5 },
- { 0.000000000000, 0.707106781187, 0.5 },
- { -0.707106781187, 0.000000000000, 0.5 },
- { 0.000000000000, -0.707106781187, 0.5 },
- { 0.707106781187, 0.707106781187, 0.0 },
- { -0.707106781187, 0.707106781187, 0.0 },
- { -0.707106781187, -0.707106781187, 0.0 },
- { 0.707106781187, -0.707106781187, 0.0 },
- { 0.707106781187, 0.000000000000, -0.5 },
- { 0.000000000000, 0.707106781187, -0.5 },
- { -0.707106781187, 0.000000000000, -0.5 },
- { 0.000000000000, -0.707106781187, -0.5 },
- { 0.0, 0.0, -1.0 }
-} ;
-
-static int rdod_v [12][4] = {
- { 0, 1, 5, 2 },
- { 0, 2, 6, 3 },
- { 0, 3, 7, 4 },
- { 0, 4, 8, 1 },
- { 5, 10, 6, 2 },
- { 6, 11, 7, 3 },
- { 7, 12, 8, 4 },
- { 8, 9, 5, 1 },
- { 5, 9, 13, 10 },
- { 6, 10, 13, 11 },
- { 7, 11, 13, 12 },
- { 8, 12, 13, 9 }
-};
-
-static double rdod_n[12][3] = {
- { 0.353553390594, 0.353553390594, 0.5 },
- { -0.353553390594, 0.353553390594, 0.5 },
- { -0.353553390594, -0.353553390594, 0.5 },
- { 0.353553390594, -0.353553390594, 0.5 },
- { 0.000000000000, 1.000000000000, 0.0 },
- { -1.000000000000, 0.000000000000, 0.0 },
- { 0.000000000000, -1.000000000000, 0.0 },
- { 1.000000000000, 0.000000000000, 0.0 },
- { 0.353553390594, 0.353553390594, -0.5 },
- { -0.353553390594, 0.353553390594, -0.5 },
- { -0.353553390594, -0.353553390594, -0.5 },
- { 0.353553390594, -0.353553390594, -0.5 }
-};
-
-void FGAPIENTRY glutWireRhombicDodecahedron( void )
+void FGAPIENTRY glutSolidCube( GLdouble dSize )
{
- int i ;
-
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireRhombicDodecahedron" );
-
- for ( i = 0; i < 12; i++ )
- {
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3dv ( rdod_n[i] ) ;
- glVertex3dv ( rdod_r[rdod_v[i][0]] ) ;
- glVertex3dv ( rdod_r[rdod_v[i][1]] ) ;
- glVertex3dv ( rdod_r[rdod_v[i][2]] ) ;
- glVertex3dv ( rdod_r[rdod_v[i][3]] ) ;
- glEnd () ;
- }
+ FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidCube" );
+ fghCube( dSize, FALSE );
}
-/*
- *
- */
-void FGAPIENTRY glutSolidRhombicDodecahedron( void )
-{
- int i ;
-
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidRhombicDodecahedron" );
-
- glBegin ( GL_QUADS ) ;
- for ( i = 0; i < 12; i++ )
- {
- glNormal3dv ( rdod_n[i] ) ;
- glVertex3dv ( rdod_r[rdod_v[i][0]] ) ;
- glVertex3dv ( rdod_r[rdod_v[i][1]] ) ;
- glVertex3dv ( rdod_r[rdod_v[i][2]] ) ;
- glVertex3dv ( rdod_r[rdod_v[i][3]] ) ;
- }
-
- glEnd () ;
-}
+DECLARE_SHAPE_INTERFACE(Dodecahedron);
+DECLARE_SHAPE_INTERFACE(Icosahedron);
+DECLARE_SHAPE_INTERFACE(Octahedron);
+DECLARE_SHAPE_INTERFACE(RhombicDodecahedron);
void FGAPIENTRY glutWireSierpinskiSponge ( int num_levels, GLdouble offset[3], GLdouble scale )
{
- int i, j ;
-
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireSierpinskiSponge" );
-
- if ( num_levels == 0 )
- {
-
- for ( i = 0 ; i < NUM_TETR_FACES ; i++ )
- {
- glBegin ( GL_LINE_LOOP ) ;
- glNormal3d ( -tet_r[i][0], -tet_r[i][1], -tet_r[i][2] ) ;
- for ( j = 0; j < 3; j++ )
- {
- double x = offset[0] + scale * tet_r[tet_i[i][j]][0] ;
- double y = offset[1] + scale * tet_r[tet_i[i][j]][1] ;
- double z = offset[2] + scale * tet_r[tet_i[i][j]][2] ;
- glVertex3d ( x, y, z ) ;
- }
-
- glEnd () ;
- }
- }
- else if ( num_levels > 0 )
- {
- GLdouble local_offset[3] ; /* Use a local variable to avoid buildup of roundoff errors */
- num_levels -- ;
- scale /= 2.0 ;
- for ( i = 0 ; i < NUM_TETR_FACES ; i++ )
- {
- local_offset[0] = offset[0] + scale * tet_r[i][0] ;
- local_offset[1] = offset[1] + scale * tet_r[i][1] ;
- local_offset[2] = offset[2] + scale * tet_r[i][2] ;
- glutWireSierpinskiSponge ( num_levels, local_offset, scale ) ;
- }
- }
+ FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireSierpinskiSponge" );
+ fghSierpinskiSponge ( num_levels, offset, scale, TRUE );
}
-
void FGAPIENTRY glutSolidSierpinskiSponge ( int num_levels, GLdouble offset[3], GLdouble scale )
{
- int i, j ;
-
- FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidSierpinskiSponge" );
-
- if ( num_levels == 0 )
- {
- glBegin ( GL_TRIANGLES ) ;
+ FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidSierpinskiSponge" );
+ fghSierpinskiSponge ( num_levels, offset, scale, FALSE );
+}
- for ( i = 0 ; i < NUM_TETR_FACES ; i++ )
- {
- glNormal3d ( -tet_r[i][0], -tet_r[i][1], -tet_r[i][2] ) ;
- for ( j = 0; j < 3; j++ )
- {
- double x = offset[0] + scale * tet_r[tet_i[i][j]][0] ;
- double y = offset[1] + scale * tet_r[tet_i[i][j]][1] ;
- double z = offset[2] + scale * tet_r[tet_i[i][j]][2] ;
- glVertex3d ( x, y, z ) ;
- }
- }
+DECLARE_SHAPE_INTERFACE(Tetrahedron);
- glEnd () ;
- }
- else if ( num_levels > 0 )
- {
- GLdouble local_offset[3] ; /* Use a local variable to avoid buildup of roundoff errors */
- num_levels -- ;
- scale /= 2.0 ;
- for ( i = 0 ; i < NUM_TETR_FACES ; i++ )
- {
- local_offset[0] = offset[0] + scale * tet_r[i][0] ;
- local_offset[1] = offset[1] + scale * tet_r[i][1] ;
- local_offset[2] = offset[2] + scale * tet_r[i][2] ;
- glutSolidSierpinskiSponge ( num_levels, local_offset, scale ) ;
- }
- }
-}
/*** END OF FILE ***/