X-Git-Url: http://git.mutantstargoat.com/user/nuclear/?a=blobdiff_plain;f=src%2Ffg_geometry.c;h=07e4159160f70c1c56799b6372aa17b2cd588508;hb=4290b0aefec61fb4bd9469cbbdb024d31064a23e;hp=438d44785c28eca51310c85d908ef2984f30817b;hpb=b728f245550aed93c5e33dbccb58ced002f41959;p=freeglut

diff --git a/src/fg_geometry.c b/src/fg_geometry.c
index 438d447..07e4159 100644
--- a/src/fg_geometry.c
+++ b/src/fg_geometry.c
@@ -27,13 +27,24 @@
 
 #include <GL/freeglut.h>
 #include "fg_internal.h"
+#include "fg_gl2.h"
+#include <math.h>
 
 /*
  * Need more types of polyhedra? See CPolyhedron in MRPT
  */
 
+/* VC++6 in C mode doesn't have C99's sinf/cos/sqrtf */
+#ifndef HAVE_SINF
+#define sinf(x) (float)sin((double)(x))
+#endif
+#ifndef HAVE_COSF
+#define cosf(x) (float)cos((double)(x))
+#endif
+#ifndef HAVE_SQRTF
+#define sqrtf(x) (float)sqrt((double)(x))
+#endif
 
-#ifndef GL_ES_VERSION_2_0
 /* General functions for drawing geometry
  * Solids are drawn by glDrawArrays if composed of triangles, or by
  * glDrawElements if consisting of squares or pentagons that were
@@ -43,7 +54,13 @@
  * decomposition needed. We use the "first" parameter in glDrawArrays to go
  * from face to face.
  */
-static void fghDrawGeometryWire(GLfloat *vertices, GLfloat *normals, GLsizei numFaces, GLsizei numEdgePerFace)
+
+/* Version for OpenGL (ES) 1.1 */
+#ifndef GL_ES_VERSION_2_0
+static void fghDrawGeometryWire11(GLfloat *vertices, GLfloat *normals,
+    GLushort *vertIdxs, GLsizei numParts, GLsizei numVertPerPart, GLenum vertexMode,
+    GLushort *vertIdxs2, GLsizei numParts2, GLsizei numVertPerPart2
+    )
 {
     int i;
     
@@ -53,13 +70,156 @@ static void fghDrawGeometryWire(GLfloat *vertices, GLfloat *normals, GLsizei num
     glVertexPointer(3, GL_FLOAT, 0, vertices);
     glNormalPointer(GL_FLOAT, 0, normals);
 
-    /* Draw per face (TODO: could use glMultiDrawArrays if available) */
-    for (i=0; i<numFaces; i++)
-        glDrawArrays(GL_LINE_LOOP, i*numEdgePerFace, numEdgePerFace);
+    
+    if (!vertIdxs)
+        /* Draw per face (TODO: could use glMultiDrawArrays if available) */
+        for (i=0; i<numParts; i++)
+            glDrawArrays(vertexMode, i*numVertPerPart, numVertPerPart);
+    else
+        for (i=0; i<numParts; i++)
+            glDrawElements(vertexMode,numVertPerPart,GL_UNSIGNED_SHORT,vertIdxs+i*numVertPerPart);
+
+    if (vertIdxs2)
+        for (i=0; i<numParts2; i++)
+            glDrawElements(GL_LINE_LOOP,numVertPerPart2,GL_UNSIGNED_SHORT,vertIdxs2+i*numVertPerPart2);
 
     glDisableClientState(GL_VERTEX_ARRAY);
     glDisableClientState(GL_NORMAL_ARRAY);
 }
+#endif
+
+/* Version for OpenGL (ES) >= 2.0 */
+static void fghDrawGeometryWire20(GLfloat *vertices, GLfloat *normals, GLsizei numVertices,
+    GLushort *vertIdxs, GLsizei numParts, GLsizei numVertPerPart, GLenum vertexMode,
+    GLushort *vertIdxs2, GLsizei numParts2, GLsizei numVertPerPart2,
+    GLint attribute_v_coord, GLint attribute_v_normal
+    )
+{
+    GLuint vbo_coords = 0, vbo_normals = 0,
+        ibo_elements = 0, ibo_elements2 = 0;
+    GLsizei numVertIdxs = numParts * numVertPerPart;
+    GLsizei numVertIdxs2 = numParts2 * numVertPerPart2;
+    int i;
+
+    if (numVertices > 0 && attribute_v_coord != -1) {
+        fghGenBuffers(1, &vbo_coords);
+        fghBindBuffer(FGH_ARRAY_BUFFER, vbo_coords);
+        fghBufferData(FGH_ARRAY_BUFFER, numVertices * 3 * sizeof(vertices[0]),
+                      vertices, FGH_STATIC_DRAW);
+    }
+    
+    if (numVertices > 0 && attribute_v_normal != -1) {
+        fghGenBuffers(1, &vbo_normals);
+        fghBindBuffer(FGH_ARRAY_BUFFER, vbo_normals);
+        fghBufferData(FGH_ARRAY_BUFFER, numVertices * 3 * sizeof(normals[0]),
+                      normals, FGH_STATIC_DRAW);
+    }
+    
+    if (vertIdxs != NULL) {
+        fghGenBuffers(1, &ibo_elements);
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, ibo_elements);
+        fghBufferData(FGH_ELEMENT_ARRAY_BUFFER, numVertIdxs * sizeof(vertIdxs[0]),
+                      vertIdxs, FGH_STATIC_DRAW);
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, 0);
+    }
+
+    if (vertIdxs2 != NULL) {
+        fghGenBuffers(1, &ibo_elements2);
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, ibo_elements2);
+        fghBufferData(FGH_ELEMENT_ARRAY_BUFFER, numVertIdxs2 * sizeof(vertIdxs2[0]),
+                      vertIdxs2, FGH_STATIC_DRAW);
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, 0);
+    }
+
+    if (vbo_coords) {
+        fghEnableVertexAttribArray(attribute_v_coord);
+        fghBindBuffer(FGH_ARRAY_BUFFER, vbo_coords);
+        fghVertexAttribPointer(
+            attribute_v_coord,  /* attribute */
+            3,                  /* number of elements per vertex, here (x,y,z) */
+            GL_FLOAT,           /* the type of each element */
+            GL_FALSE,           /* take our values as-is */
+            0,                  /* no extra data between each position */
+            0                   /* offset of first element */
+        );
+        fghBindBuffer(FGH_ARRAY_BUFFER, 0);
+    }
+
+    if (vbo_normals) {
+        fghEnableVertexAttribArray(attribute_v_normal);
+        fghBindBuffer(FGH_ARRAY_BUFFER, vbo_normals);
+        fghVertexAttribPointer(
+            attribute_v_normal, /* attribute */
+            3,                  /* number of elements per vertex, here (x,y,z) */
+            GL_FLOAT,           /* the type of each element */
+            GL_FALSE,           /* take our values as-is */
+            0,                  /* no extra data between each position */
+            0                   /* offset of first element */
+        );
+        fghBindBuffer(FGH_ARRAY_BUFFER, 0);
+    }
+
+    if (!vertIdxs) {
+        /* Draw per face (TODO: could use glMultiDrawArrays if available) */
+        for (i=0; i<numParts; i++)
+            glDrawArrays(vertexMode, i*numVertPerPart, numVertPerPart);
+    } else {
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, ibo_elements);
+        for (i=0; i<numParts; i++)
+            glDrawElements(vertexMode, numVertPerPart,
+                           GL_UNSIGNED_SHORT, (GLvoid*)(sizeof(vertIdxs[0])*i*numVertPerPart));
+        /* Clean existing bindings before clean-up */
+        /* Android showed instability otherwise */
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, 0);
+    }
+
+    if (vertIdxs2) {
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, ibo_elements2);
+        for (i=0; i<numParts2; i++)
+            glDrawElements(GL_LINE_LOOP, numVertPerPart2,
+                           GL_UNSIGNED_SHORT, (GLvoid*)(sizeof(vertIdxs2[0])*i*numVertPerPart2));
+        /* Clean existing bindings before clean-up */
+        /* Android showed instability otherwise */
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, 0);
+    }
+    
+    if (vbo_coords != 0)
+        fghDisableVertexAttribArray(attribute_v_coord);
+    if (vbo_normals != 0)
+        fghDisableVertexAttribArray(attribute_v_normal);
+    
+    if (vbo_coords != 0)
+        fghDeleteBuffers(1, &vbo_coords);
+    if (vbo_normals != 0)
+        fghDeleteBuffers(1, &vbo_normals);
+    if (ibo_elements != 0)
+        fghDeleteBuffers(1, &ibo_elements);
+    if (ibo_elements2 != 0)
+        fghDeleteBuffers(1, &ibo_elements2);
+}
+
+static void fghDrawGeometryWire(GLfloat *vertices, GLfloat *normals, GLsizei numVertices,
+    GLushort *vertIdxs, GLsizei numParts, GLsizei numVertPerPart, GLenum vertexMode,
+    GLushort *vertIdxs2, GLsizei numParts2, GLsizei numVertPerPart2
+    )
+{
+    GLint attribute_v_coord = fgStructure.CurrentWindow->Window.attribute_v_coord;
+    GLint attribute_v_normal = fgStructure.CurrentWindow->Window.attribute_v_normal;
+
+    if (fgState.HasOpenGL20 && (attribute_v_coord != -1 || attribute_v_normal != -1))
+        /* User requested a 2.0 draw */
+        fghDrawGeometryWire20(vertices, normals, numVertices,
+                              vertIdxs, numParts, numVertPerPart, vertexMode,
+                              vertIdxs2, numParts2, numVertPerPart2,
+                              attribute_v_coord, attribute_v_normal);
+#ifndef GL_ES_VERSION_2_0
+    else
+        fghDrawGeometryWire11(vertices, normals,
+                              vertIdxs, numParts, numVertPerPart, vertexMode,
+                              vertIdxs2, numParts2, numVertPerPart2);
+#endif
+}
+
 
 /* Draw the geometric shape with filled triangles
  *
@@ -69,9 +229,14 @@ static void fghDrawGeometryWire(GLfloat *vertices, GLfloat *normals, GLsizei num
  * - If the shape was triangulated (DECOMPOSE_TO_TRIANGLE), some
  *   vertex+normal pairs are reused, so use vertex indices.
  */
-static void fghDrawGeometrySolid(GLfloat *vertices, GLfloat *normals, GLubyte *vertIdxs,
-				 GLsizei numVertices, GLsizei numVertIdxs)
+
+/* Version for OpenGL (ES) 1.1 */
+#ifndef GL_ES_VERSION_2_0
+static void fghDrawGeometrySolid11(GLfloat *vertices, GLfloat *normals, GLushort *vertIdxs,
+                                   GLsizei numVertices, GLsizei numParts, GLsizei numVertIdxsPerPart)
 {
+    int i;
+
     glEnableClientState(GL_VERTEX_ARRAY);
     glEnableClientState(GL_NORMAL_ARRAY);
 
@@ -80,13 +245,124 @@ static void fghDrawGeometrySolid(GLfloat *vertices, GLfloat *normals, GLubyte *v
     if (vertIdxs == NULL)
         glDrawArrays(GL_TRIANGLES, 0, numVertices);
     else
-        glDrawElements(GL_TRIANGLES, numVertIdxs, GL_UNSIGNED_BYTE, vertIdxs);
+        if (numParts>1)
+            for (i=0; i<numParts; i++)
+                glDrawElements(GL_TRIANGLE_STRIP, numVertIdxsPerPart, GL_UNSIGNED_SHORT, vertIdxs+i*numVertIdxsPerPart);
+        else
+            glDrawElements(GL_TRIANGLES, numVertIdxsPerPart, GL_UNSIGNED_SHORT, vertIdxs);
 
     glDisableClientState(GL_VERTEX_ARRAY);
     glDisableClientState(GL_NORMAL_ARRAY);
 }
+#endif
 
+/* Version for OpenGL (ES) >= 2.0 */
+static void fghDrawGeometrySolid20(GLfloat *vertices, GLfloat *normals, GLushort *vertIdxs,
+                                   GLsizei numVertices, GLsizei numParts, GLsizei numVertIdxsPerPart,
+                                   GLint attribute_v_coord, GLint attribute_v_normal)
+{
+    GLuint vbo_coords = 0, vbo_normals = 0, ibo_elements = 0;
+    GLsizei numVertIdxs = numParts * numVertIdxsPerPart;
+    int i;
+  
+    if (numVertices > 0 && attribute_v_coord != -1) {
+        fghGenBuffers(1, &vbo_coords);
+        fghBindBuffer(FGH_ARRAY_BUFFER, vbo_coords);
+        fghBufferData(FGH_ARRAY_BUFFER, numVertices * 3 * sizeof(vertices[0]),
+                      vertices, FGH_STATIC_DRAW);
+        fghBindBuffer(FGH_ARRAY_BUFFER, 0);
+    }
+    
+    if (numVertices > 0 && attribute_v_normal != -1) {
+        fghGenBuffers(1, &vbo_normals);
+        fghBindBuffer(FGH_ARRAY_BUFFER, vbo_normals);
+        fghBufferData(FGH_ARRAY_BUFFER, numVertices * 3 * sizeof(normals[0]),
+                      normals, FGH_STATIC_DRAW);
+        fghBindBuffer(FGH_ARRAY_BUFFER, 0);
+    }
+    
+    if (vertIdxs != NULL) {
+        fghGenBuffers(1, &ibo_elements);
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, ibo_elements);
+        fghBufferData(FGH_ELEMENT_ARRAY_BUFFER, numVertIdxs * sizeof(vertIdxs[0]),
+                      vertIdxs, FGH_STATIC_DRAW);
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, 0);
+    }
+    
+    if (vbo_coords) {
+        fghEnableVertexAttribArray(attribute_v_coord);
+        fghBindBuffer(FGH_ARRAY_BUFFER, vbo_coords);
+        fghVertexAttribPointer(
+            attribute_v_coord,  /* attribute */
+            3,                  /* number of elements per vertex, here (x,y,z) */
+            GL_FLOAT,           /* the type of each element */
+            GL_FALSE,           /* take our values as-is */
+            0,                  /* no extra data between each position */
+            0                   /* offset of first element */
+        );
+        fghBindBuffer(FGH_ARRAY_BUFFER, 0);
+    };
+    
+    if (vbo_normals) {
+        fghEnableVertexAttribArray(attribute_v_normal);
+        fghBindBuffer(FGH_ARRAY_BUFFER, vbo_normals);
+        fghVertexAttribPointer(
+            attribute_v_normal, /* attribute */
+            3,                  /* number of elements per vertex, here (x,y,z) */
+            GL_FLOAT,           /* the type of each element */
+            GL_FALSE,           /* take our values as-is */
+            0,                  /* no extra data between each position */
+            0                   /* offset of first element */
+        );
+        fghBindBuffer(FGH_ARRAY_BUFFER, 0);
+    };
+    
+    if (vertIdxs == NULL) {
+        glDrawArrays(GL_TRIANGLES, 0, numVertices);
+    } else {
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, ibo_elements);
+        if (numParts>1) {
+            for (i=0; i<numParts; i++) {
+                glDrawElements(GL_TRIANGLE_STRIP, numVertIdxsPerPart, GL_UNSIGNED_SHORT, (GLvoid*)(sizeof(vertIdxs[0])*i*numVertIdxsPerPart));
+            }
+        } else {
+            glDrawElements(GL_TRIANGLES, numVertIdxsPerPart, GL_UNSIGNED_SHORT, 0);
+        }
+        /* Clean existing bindings before clean-up */
+        /* Android showed instability otherwise */
+        fghBindBuffer(FGH_ELEMENT_ARRAY_BUFFER, 0);
+    }
+    
+    if (vbo_coords != 0)
+        fghDisableVertexAttribArray(attribute_v_coord);
+    if (vbo_normals != 0)
+        fghDisableVertexAttribArray(attribute_v_normal);
+    
+    if (vbo_coords != 0)
+        fghDeleteBuffers(1, &vbo_coords);
+    if (vbo_normals != 0)
+        fghDeleteBuffers(1, &vbo_normals);
+    if (ibo_elements != 0)
+        fghDeleteBuffers(1, &ibo_elements);
+}
 
+static void fghDrawGeometrySolid(GLfloat *vertices, GLfloat *normals, GLushort *vertIdxs,
+                                 GLsizei numVertices, GLsizei numParts, GLsizei numVertIdxsPerPart)
+{
+    GLint attribute_v_coord = fgStructure.CurrentWindow->Window.attribute_v_coord;
+    GLint attribute_v_normal = fgStructure.CurrentWindow->Window.attribute_v_normal;
+
+    if (fgState.HasOpenGL20 && (attribute_v_coord != -1 || attribute_v_normal != -1))
+        /* User requested a 2.0 draw */
+        fghDrawGeometrySolid20(vertices, normals, vertIdxs,
+                               numVertices, numParts, numVertIdxsPerPart,
+                               attribute_v_coord, attribute_v_normal);
+#ifndef GL_ES_VERSION_2_0
+    else
+        fghDrawGeometrySolid11(vertices, normals, vertIdxs,
+                               numVertices, numParts, numVertIdxsPerPart);
+#endif
+}
 
 /* Shape decomposition to triangles
  * We'll use glDrawElements to draw all shapes that are not naturally
@@ -98,7 +374,7 @@ static void fghDrawGeometrySolid(GLfloat *vertices, GLfloat *normals, GLubyte *v
 static GLubyte   vert4Decomp[6] = {0,1,2, 0,2,3};             /* quad    : 4 input vertices, 6 output (2 triangles) */
 static GLubyte   vert5Decomp[9] = {0,1,2, 0,2,4, 4,2,3};      /* pentagon: 5 input vertices, 9 output (3 triangles) */
 
-static void fghGenerateGeometryWithIndexArray(int numFaces, int numEdgePerFace, GLfloat *vertices, GLubyte *vertIndices, GLfloat *normals, GLfloat *vertOut, GLfloat *normOut, GLubyte *vertIdxOut)
+static void fghGenerateGeometryWithIndexArray(int numFaces, int numEdgePerFace, GLfloat *vertices, GLubyte *vertIndices, GLfloat *normals, GLfloat *vertOut, GLfloat *normOut, GLushort *vertIdxOut)
 {
     int i,j,numEdgeIdxPerFace;
     GLubyte   *vertSamps = NULL;
@@ -124,7 +400,7 @@ static void fghGenerateGeometryWithIndexArray(int numFaces, int numEdgePerFace,
     for (i=0; i<numFaces; i++)
     {
         int normIdx         = i*3;
-        int faceIdxVertIdx  = i*numEdgePerFace; // index to first element of "row" in vertex indices
+        int faceIdxVertIdx  = i*numEdgePerFace; /* index to first element of "row" in vertex indices */
         for (j=0; j<numEdgePerFace; j++)
         {
             int outIdx  = i*numEdgePerFace*3+j*3;
@@ -174,7 +450,7 @@ static void fghGenerateGeometry(int numFaces, int numEdgePerFace, GLfloat *verti
     static GLboolean name##Cached = FALSE;\
     static GLfloat  name##_verts[nameCaps##_VERT_ELEM_PER_OBJ];\
     static GLfloat  name##_norms[nameCaps##_VERT_ELEM_PER_OBJ];\
-    static GLubyte   name##_vertIdxs[nameCaps##_VERT_PER_OBJ_TRI];\
+    static GLushort name##_vertIdxs[nameCaps##_VERT_PER_OBJ_TRI];\
     static void fgh##nameICaps##Generate()\
     {\
         fghGenerateGeometryWithIndexArray(nameCaps##_NUM_FACES, nameCaps##_NUM_EDGE_PER_FACE,\
@@ -222,7 +498,7 @@ static GLubyte cube_vi[CUBE_VERT_PER_OBJ] =
     7,4,3,2,
     4,7,6,5
 };
-DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(cube,Cube,CUBE);
+DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(cube,Cube,CUBE)
 
 /* -- Dodecahedron -- */
 /* Magic Numbers:  It is possible to create a dodecahedron by attaching two
@@ -298,7 +574,7 @@ static GLubyte dodecahedron_vi[DODECAHEDRON_VERT_PER_OBJ] =
     18,  1,  0,  5,  9, 
     19, 14, 13, 10, 12
 };
-DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(dodecahedron,Dodecahedron,DODECAHEDRON);
+DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(dodecahedron,Dodecahedron,DODECAHEDRON)
 
 
 /* -- Icosahedron -- */
@@ -377,7 +653,7 @@ static GLubyte icosahedron_vi[ICOSAHEDRON_VERT_PER_OBJ] =
     11,  6,  7 ,
     11, 10,  6 
 };
-DECLARE_SHAPE_CACHE(icosahedron,Icosahedron,ICOSAHEDRON);
+DECLARE_SHAPE_CACHE(icosahedron,Icosahedron,ICOSAHEDRON)
 
 /* -- Octahedron -- */
 #define OCTAHEDRON_NUM_VERT           6
@@ -424,7 +700,7 @@ static GLubyte octahedron_vi[OCTAHEDRON_VERT_PER_OBJ] =
     3, 4, 2,
     3, 5, 4
 };
-DECLARE_SHAPE_CACHE(octahedron,Octahedron,OCTAHEDRON);
+DECLARE_SHAPE_CACHE(octahedron,Octahedron,OCTAHEDRON)
 
 /* -- RhombicDodecahedron -- */
 #define RHOMBICDODECAHEDRON_NUM_VERT            14
@@ -485,7 +761,7 @@ static GLubyte rhombicdodecahedron_vi[RHOMBICDODECAHEDRON_VERT_PER_OBJ] =
     7, 11, 13, 12,
     8, 12, 13,  9
 };
-DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(rhombicdodecahedron,RhombicDodecahedron,RHOMBICDODECAHEDRON);
+DECLARE_SHAPE_CACHE_DECOMPOSE_TO_TRIANGLE(rhombicdodecahedron,RhombicDodecahedron,RHOMBICDODECAHEDRON)
 
 /* -- Tetrahedron -- */
 /* Magic Numbers:  r0 = ( 1, 0, 0 )
@@ -529,7 +805,7 @@ static GLubyte tetrahedron_vi[TETRAHEDRON_VERT_PER_OBJ] =
     0, 3, 1,
     0, 1, 2
 };
-DECLARE_SHAPE_CACHE(tetrahedron,Tetrahedron,TETRAHEDRON);
+DECLARE_SHAPE_CACHE(tetrahedron,Tetrahedron,TETRAHEDRON)
 
 /* -- Sierpinski Sponge -- */
 static unsigned int ipow (int x, unsigned int y)
@@ -652,6 +928,8 @@ static void fghGenerateSphere(GLfloat radius, GLint slices, GLint stacks, GLfloa
         return;
     }
     *nVert = slices*(stacks-1)+2;
+    if ((*nVert) > 65535)       /* TODO: must have a better solution than this low limit, at least for architectures where gluint is available */
+        fgWarning("fghGenerateSphere: too many slices or stacks requested, indices will wrap");
 
     /* precompute values on unit circle */
     fghCircleTable(&sint1,&cost1,-slices,FALSE);
@@ -660,7 +938,7 @@ static void fghGenerateSphere(GLfloat radius, GLint slices, GLint stacks, GLfloa
     /* Allocate vertex and normal buffers, bail out if memory allocation fails */
     *vertices = malloc((*nVert)*3*sizeof(GLfloat));
     *normals  = malloc((*nVert)*3*sizeof(GLfloat));
-    if (!(vertices) || !(normals))
+    if (!(*vertices) || !(*normals))
     {
         free(*vertices);
         free(*normals);
@@ -709,6 +987,258 @@ static void fghGenerateSphere(GLfloat radius, GLint slices, GLint stacks, GLfloa
     free(cost2);
 }
 
+void fghGenerateCone(
+    GLfloat base, GLfloat height, GLint slices, GLint stacks,   /*  input */
+    GLfloat **vertices, GLfloat **normals, int* nVert           /* output */
+    )
+{
+    int i,j;
+    int idx = 0;    /* idx into vertex/normal buffer */
+
+    /* Pre-computed circle */
+    GLfloat *sint,*cost;
+
+    /* Step in z and radius as stacks are drawn. */
+    GLfloat z = 0;
+    GLfloat r = (GLfloat)base;
+
+    const GLfloat zStep = (GLfloat)height / ( ( stacks > 0 ) ? stacks : 1 );
+    const GLfloat rStep = (GLfloat)base / ( ( stacks > 0 ) ? stacks : 1 );
+
+    /* Scaling factors for vertex normals */
+    const GLfloat cosn = ( (GLfloat)height / sqrtf( height * height + base * base ));
+    const GLfloat sinn = ( (GLfloat)base   / sqrtf( height * height + base * base ));
+
+
+
+    /* number of unique vertices */
+    if (slices==0 || stacks<1)
+    {
+        /* nothing to generate */
+        *nVert = 0;
+        return;
+    }
+    *nVert = slices*(stacks+2)+1;   /* need an extra stack for closing off bottom with correct normals */
+
+    if ((*nVert) > 65535)
+        fgWarning("fghGenerateCone: too many slices or stacks requested, indices will wrap");
+
+    /* Pre-computed circle */
+    fghCircleTable(&sint,&cost,-slices,FALSE);
+
+    /* Allocate vertex and normal buffers, bail out if memory allocation fails */
+    *vertices = malloc((*nVert)*3*sizeof(GLfloat));
+    *normals  = malloc((*nVert)*3*sizeof(GLfloat));
+    if (!(*vertices) || !(*normals))
+    {
+        free(*vertices);
+        free(*normals);
+        fgError("Failed to allocate memory in fghGenerateSphere");
+    }
+
+    /* bottom */
+    (*vertices)[0] =  0.f;
+    (*vertices)[1] =  0.f;
+    (*vertices)[2] =  z;
+    (*normals )[0] =  0.f;
+    (*normals )[1] =  0.f;
+    (*normals )[2] = -1.f;
+    idx = 3;
+    /* other on bottom (get normals right) */
+    for (j=0; j<slices; j++, idx+=3)
+    {
+        (*vertices)[idx  ] = cost[j]*r;
+        (*vertices)[idx+1] = sint[j]*r;
+        (*vertices)[idx+2] = z;
+        (*normals )[idx  ] =  0.f;
+        (*normals )[idx+1] =  0.f;
+        (*normals )[idx+2] = -1.f;
+    }
+
+    /* each stack */
+    for (i=0; i<stacks+1; i++ )
+    {
+        for (j=0; j<slices; j++, idx+=3)
+        {
+            (*vertices)[idx  ] = cost[j]*r;
+            (*vertices)[idx+1] = sint[j]*r;
+            (*vertices)[idx+2] = z;
+            (*normals )[idx  ] = cost[j]*sinn;
+            (*normals )[idx+1] = sint[j]*sinn;
+            (*normals )[idx+2] = cosn;
+        }
+
+        z += zStep;
+        r -= rStep;
+    }
+
+    /* Release sin and cos tables */
+    free(sint);
+    free(cost);
+}
+
+void fghGenerateCylinder(
+    GLfloat radius, GLfloat height, GLint slices, GLint stacks, /*  input */
+    GLfloat **vertices, GLfloat **normals, int* nVert           /* output */
+    )
+{
+    int i,j;
+    int idx = 0;    /* idx into vertex/normal buffer */
+
+    /* Step in z as stacks are drawn. */
+    GLfloat radf = (GLfloat)radius;
+    GLfloat z;
+    const GLfloat zStep = (GLfloat)height / ( ( stacks > 0 ) ? stacks : 1 );
+
+    /* Pre-computed circle */
+    GLfloat *sint,*cost;
+
+    /* number of unique vertices */
+    if (slices==0 || stacks<1)
+    {
+        /* nothing to generate */
+        *nVert = 0;
+        return;
+    }
+    *nVert = slices*(stacks+3)+2;   /* need two extra stacks for closing off top and bottom with correct normals */
+
+    if ((*nVert) > 65535)
+        fgWarning("fghGenerateCylinder: too many slices or stacks requested, indices will wrap");
+
+    /* Pre-computed circle */
+    fghCircleTable(&sint,&cost,-slices,FALSE);
+
+    /* Allocate vertex and normal buffers, bail out if memory allocation fails */
+    *vertices = malloc((*nVert)*3*sizeof(GLfloat));
+    *normals  = malloc((*nVert)*3*sizeof(GLfloat));
+    if (!(*vertices) || !(*normals))
+    {
+        free(*vertices);
+        free(*normals);
+        fgError("Failed to allocate memory in fghGenerateCylinder");
+    }
+
+    z=0;
+    /* top on Z-axis */
+    (*vertices)[0] =  0.f;
+    (*vertices)[1] =  0.f;
+    (*vertices)[2] =  0.f;
+    (*normals )[0] =  0.f;
+    (*normals )[1] =  0.f;
+    (*normals )[2] = -1.f;
+    idx = 3;
+    /* other on top (get normals right) */
+    for (j=0; j<slices; j++, idx+=3)
+    {
+        (*vertices)[idx  ] = cost[j]*radf;
+        (*vertices)[idx+1] = sint[j]*radf;
+        (*vertices)[idx+2] = z;
+        (*normals )[idx  ] = 0.f;
+        (*normals )[idx+1] = 0.f;
+        (*normals )[idx+2] = -1.f;
+    }
+
+    /* each stack */
+    for (i=0; i<stacks+1; i++ )
+    {
+        for (j=0; j<slices; j++, idx+=3)
+        {
+            (*vertices)[idx  ] = cost[j]*radf;
+            (*vertices)[idx+1] = sint[j]*radf;
+            (*vertices)[idx+2] = z;
+            (*normals )[idx  ] = cost[j];
+            (*normals )[idx+1] = sint[j];
+            (*normals )[idx+2] = 0.f;
+        }
+
+        z += zStep;
+    }
+
+    /* other on bottom (get normals right) */
+    z -= zStep;
+    for (j=0; j<slices; j++, idx+=3)
+    {
+        (*vertices)[idx  ] = cost[j]*radf;
+        (*vertices)[idx+1] = sint[j]*radf;
+        (*vertices)[idx+2] = z;
+        (*normals )[idx  ] = 0.f;
+        (*normals )[idx+1] = 0.f;
+        (*normals )[idx+2] = 1.f;
+    }
+
+    /* bottom */
+    (*vertices)[idx  ] =  0.f;
+    (*vertices)[idx+1] =  0.f;
+    (*vertices)[idx+2] =  height;
+    (*normals )[idx  ] =  0.f;
+    (*normals )[idx+1] =  0.f;
+    (*normals )[idx+2] =  1.f;
+
+    /* Release sin and cos tables */
+    free(sint);
+    free(cost);
+}
+
+void fghGenerateTorus(
+    double dInnerRadius, double dOuterRadius, GLint nSides, GLint nRings, /*  input */
+    GLfloat **vertices, GLfloat **normals, int* nVert                     /* output */
+    )
+{
+    GLfloat  iradius = (float)dInnerRadius;
+    GLfloat  oradius = (float)dOuterRadius;
+    int    i, j;
+
+    /* Pre-computed circle */
+    GLfloat *spsi, *cpsi;
+    GLfloat *sphi, *cphi;
+
+    /* number of unique vertices */
+    if (nSides<2 || nRings<2)
+    {
+        /* nothing to generate */
+        *nVert = 0;
+        return;
+    }
+    *nVert = nSides * nRings;
+
+    if ((*nVert) > 65535)
+        fgWarning("fghGenerateTorus: too many slices or stacks requested, indices will wrap");
+
+    /* precompute values on unit circle */
+    fghCircleTable(&spsi,&cpsi, nRings,FALSE);
+    fghCircleTable(&sphi,&cphi,-nSides,FALSE);
+
+    /* Allocate vertex and normal buffers, bail out if memory allocation fails */
+    *vertices = malloc((*nVert)*3*sizeof(GLfloat));
+    *normals  = malloc((*nVert)*3*sizeof(GLfloat));
+    if (!(*vertices) || !(*normals))
+    {
+        free(*vertices);
+        free(*normals);
+        fgError("Failed to allocate memory in fghGenerateTorus");
+    }
+
+    for( j=0; j<nRings; j++ )
+    {
+        for( i=0; i<nSides; i++ )
+        {
+            int offset = 3 * ( j * nSides + i ) ;
+
+            (*vertices)[offset  ] = cpsi[j] * ( oradius + cphi[i] * iradius ) ;
+            (*vertices)[offset+1] = spsi[j] * ( oradius + cphi[i] * iradius ) ;
+            (*vertices)[offset+2] =                       sphi[i] * iradius  ;
+            (*normals )[offset  ] = cpsi[j] * cphi[i] ;
+            (*normals )[offset+1] = spsi[j] * cphi[i] ;
+            (*normals )[offset+2] =           sphi[i] ;
+        }
+    }
+
+    /* Release sin and cos tables */
+    free(spsi);
+    free(cpsi);
+    free(sphi);
+    free(cphi);
+}
 
 /* -- INTERNAL DRAWING functions --------------------------------------- */
 #define _DECLARE_INTERNAL_DRAW_DO_DECLARE(name,nameICaps,nameCaps,vertIdxs)\
@@ -722,13 +1252,14 @@ static void fghGenerateSphere(GLfloat radius, GLint slices, GLint stacks, GLfloa
         \
         if (useWireMode)\
         {\
-            fghDrawGeometryWire (name##_verts,name##_norms,\
-                                                             nameCaps##_NUM_FACES,nameCaps##_NUM_EDGE_PER_FACE);\
+            fghDrawGeometryWire (name##_verts,name##_norms,nameCaps##_VERT_PER_OBJ, \
+                                 NULL,nameCaps##_NUM_FACES,nameCaps##_NUM_EDGE_PER_FACE,GL_LINE_LOOP,\
+                                 NULL,0,0);\
         }\
         else\
         {\
             fghDrawGeometrySolid(name##_verts,name##_norms,vertIdxs,\
-                                 nameCaps##_VERT_PER_OBJ, nameCaps##_VERT_PER_OBJ_TRI); \
+                                 nameCaps##_VERT_PER_OBJ, 1, nameCaps##_VERT_PER_OBJ_TRI); \
         }\
     }
 #define DECLARE_INTERNAL_DRAW(name,nameICaps,nameCaps)                        _DECLARE_INTERNAL_DRAW_DO_DECLARE(name,nameICaps,nameCaps,NULL)
@@ -765,22 +1296,23 @@ static void fghCube( GLfloat dSize, GLboolean useWireMode )
         vertices = cube_verts;
 
     if (useWireMode)
-        fghDrawGeometryWire (vertices, cube_norms,
-			     CUBE_NUM_FACES, CUBE_NUM_EDGE_PER_FACE);
+        fghDrawGeometryWire(vertices, cube_norms, CUBE_VERT_PER_OBJ,
+                            NULL,CUBE_NUM_FACES, CUBE_NUM_EDGE_PER_FACE,GL_LINE_LOOP,
+                            NULL,0,0);
     else
         fghDrawGeometrySolid(vertices, cube_norms, cube_vertIdxs,
-			     CUBE_VERT_PER_OBJ, CUBE_VERT_PER_OBJ_TRI);
+                             CUBE_VERT_PER_OBJ, 1, CUBE_VERT_PER_OBJ_TRI);
 
     if (dSize!=1.f)
         /* cleanup allocated memory */
         free(vertices);
 }
 
-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);
+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, double offset[3], GLfloat scale, GLboolean useWireMode )
 {
@@ -808,9 +1340,11 @@ static void fghSierpinskiSponge ( int numLevels, double offset[3], GLfloat scale
 
         /* Draw and cleanup */
         if (useWireMode)
-            fghDrawGeometryWire (vertices,normals,numFace,TETRAHEDRON_NUM_EDGE_PER_FACE);
+            fghDrawGeometryWire (vertices,normals,numVert,
+                                 NULL,numFace,TETRAHEDRON_NUM_EDGE_PER_FACE,GL_LINE_LOOP,
+                                 NULL,0,0);
         else
-            fghDrawGeometrySolid(vertices,normals,NULL,numVert,numVert);
+            fghDrawGeometrySolid(vertices,normals,NULL,numVert,1,0);
 
         free(vertices);
         free(normals );
@@ -832,123 +1366,109 @@ static void fghSphere( double radius, GLint slices, GLint stacks, GLboolean useW
 
     if (useWireMode)
     {
-        GLuint  *sliceIdx, *stackIdx;
+        GLushort  *sliceIdx, *stackIdx;
         /* First, generate vertex index arrays for drawing with glDrawElements
          * We have a bunch of line_loops to draw for each stack, and a
          * bunch for each slice.
          */
 
-        sliceIdx = malloc(slices*(stacks+1)*sizeof(GLuint));
-        stackIdx = malloc(slices*(stacks-1)*sizeof(GLuint));
-
-        /* generate for each stack */
-        for (i=0,idx=0; i<slices; i++)
+        sliceIdx = malloc(slices*(stacks+1)*sizeof(GLushort));
+        stackIdx = malloc(slices*(stacks-1)*sizeof(GLushort));
+        if (!(stackIdx) || !(sliceIdx))
         {
-            GLuint offset = 1+i;                    /* start at 1 (0 is top vertex), and we advance one slice as we go along */
-            sliceIdx[idx++] = 0;                    /* vertex on top */
-            for (j=0; j<stacks-1; j++, idx++)
-            {
-                sliceIdx[idx] = offset+j*slices;
-            }
-            sliceIdx[idx++] = nVert-1;              /* zero based index, last element in array... */
+            free(stackIdx);
+            free(sliceIdx);
+            fgError("Failed to allocate memory in fghSphere");
         }
 
         /* generate for each stack */
         for (i=0,idx=0; i<stacks-1; i++)
         {
-            GLuint offset = 1+i*slices;             /* start at 1 (0 is top vertex), and we advance one stack down as we go along */
+            GLushort offset = 1+i*slices;           /* start at 1 (0 is top vertex), and we advance one stack down as we go along */
             for (j=0; j<slices; j++, idx++)
             {
                 stackIdx[idx] = offset+j;
             }
         }
 
-        /* draw */
-        glEnableClientState(GL_VERTEX_ARRAY);
-        glEnableClientState(GL_NORMAL_ARRAY);
-
-        glVertexPointer(3, GL_FLOAT, 0, vertices);
-        glNormalPointer(GL_FLOAT, 0, normals);
-        /*draw slices*/
-        for (i=0; i<slices; i++)
-            glDrawElements(GL_LINE_STRIP,stacks+1,GL_UNSIGNED_INT,sliceIdx+i*(stacks+1));
-        /*draw stacks*/
-        for (i=0; i<stacks-1; i++)
-            glDrawElements(GL_LINE_LOOP, slices,GL_UNSIGNED_INT,stackIdx+i*slices);
-
-        glDisableClientState(GL_VERTEX_ARRAY);
-        glDisableClientState(GL_NORMAL_ARRAY);
+        /* generate for each slice */
+        for (i=0,idx=0; i<slices; i++)
+        {
+            GLushort offset = 1+i;                  /* start at 1 (0 is top vertex), and we advance one slice as we go along */
+            sliceIdx[idx++] = 0;                    /* vertex on top */
+            for (j=0; j<stacks-1; j++, idx++)
+            {
+                sliceIdx[idx] = offset+j*slices;
+            }
+            sliceIdx[idx++] = nVert-1;              /* zero based index, last element in array... */
+        }
 
+        /* draw */
+        fghDrawGeometryWire(vertices,normals,nVert,
+            sliceIdx,slices,stacks+1,GL_LINE_STRIP,
+            stackIdx,stacks-1,slices);
+        
         /* cleanup allocated memory */
         free(sliceIdx);
         free(stackIdx);
     }
     else
     {
-        GLuint  *topIdx, *bottomIdx, *stripIdx;
         /* First, generate vertex index arrays for drawing with glDrawElements
-         * Top and bottom are covered with a triangle fan
-         * Each other stack with triangle strip. Only need to generate on
-         * of those as we'll have to draw each stack separately, and can
-         * just use different offsets in glDrawElements.
+         * All stacks, including top and bottom are covered with a triangle
+         * strip.
          */
+        GLushort  *stripIdx;
+        /* Create index vector */
+        GLushort offset;
 
         /* Allocate buffers for indices, bail out if memory allocation fails */
-        topIdx = malloc((slices+2)*sizeof(GLuint));
-        bottomIdx = malloc((slices+2)*sizeof(GLuint));
-        stripIdx = malloc((slices+1)*2*(stacks-2)*sizeof(GLuint));
-        if (!(topIdx) || !(bottomIdx) || !(stripIdx))
+        stripIdx = malloc((slices+1)*2*(stacks)*sizeof(GLushort));
+        if (!(stripIdx))
         {
-            free(topIdx);
-            free(bottomIdx);
             free(stripIdx);
-            fgError("Failed to allocate memory in fghGenerateSphere");
+            fgError("Failed to allocate memory in fghSphere");
         }
 
-        topIdx[0]=0;
-        topIdx[1] = 1;                              /* repeat first slice's idx for closing off shape */
-        for (j=slices, idx=2; j>0; j--, idx++)
-            topIdx[idx] = j;
-
-        bottomIdx[0]=nVert-1;                       /* zero based index, last element in array... */
-        for (j=0, idx=1; j<slices; j++, idx++)
-            bottomIdx[idx] = nVert-(slices+1)+j;
-        bottomIdx[idx] = nVert-(slices+1);          /* repeat first slice's idx for closing off shape */
+        /* top stack */
+        for (j=0, idx=0;  j<slices;  j++, idx+=2)
+        {
+            stripIdx[idx  ] = j+1;              /* 0 is top vertex, 1 is first for first stack */
+            stripIdx[idx+1] = 0;
+        }
+        stripIdx[idx  ] = 1;                    /* repeat first slice's idx for closing off shape */
+        stripIdx[idx+1] = 0;
+        idx+=2;
 
+        /* middle stacks: */
         /* Strip indices are relative to first index belonging to strip, NOT relative to first vertex/normal pair in array */
-        for (i=0,idx=0; i<stacks-2; i++, idx+=2)
+        for (i=0; i<stacks-2; i++, idx+=2)
         {
-            GLuint offset = 1+i*slices;             /* triangle_strip indices start at 1 (0 is top vertex), and we advance one stack down as we go along */
+            offset = 1+i*slices;                    /* triangle_strip indices start at 1 (0 is top vertex), and we advance one stack down as we go along */
             for (j=0; j<slices; j++, idx+=2)
             {
                 stripIdx[idx  ] = offset+j+slices;
                 stripIdx[idx+1] = offset+j;
             }
             stripIdx[idx  ] = offset+slices;        /* repeat first slice's idx for closing off shape */
-            stripIdx[idx+1] = offset+0;
+            stripIdx[idx+1] = offset;
+        }
+
+        /* bottom stack */
+        offset = 1+(stacks-2)*slices;               /* triangle_strip indices start at 1 (0 is top vertex), and we advance one stack down as we go along */
+        for (j=0; j<slices; j++, idx+=2)
+        {
+            stripIdx[idx  ] = nVert-1;              /* zero based index, last element in array (bottom vertex)... */
+            stripIdx[idx+1] = offset+j;
         }
+        stripIdx[idx  ] = nVert-1;                  /* repeat first slice's idx for closing off shape */
+        stripIdx[idx+1] = offset;
 
 
         /* draw */
-        glEnableClientState(GL_VERTEX_ARRAY);
-        glEnableClientState(GL_NORMAL_ARRAY);
-
-        glVertexPointer(3, GL_FLOAT, 0, vertices);
-        glNormalPointer(GL_FLOAT, 0, normals);
-        /*draw top*/
-        glDrawElements(GL_TRIANGLE_FAN,slices+2,GL_UNSIGNED_INT,topIdx);
-        /*draw stacks*/
-        for (i=0; i<stacks-2; i++)
-            glDrawElements(GL_TRIANGLE_STRIP,(slices+1)*2,GL_UNSIGNED_INT,stripIdx+i*(slices+1)*2);
-        /*draw bottom*/
-        glDrawElements(GL_TRIANGLE_FAN,slices+2,GL_UNSIGNED_INT,bottomIdx);
-
-        glDisableClientState(GL_VERTEX_ARRAY);
-        glDisableClientState(GL_NORMAL_ARRAY);
+        fghDrawGeometrySolid(vertices,normals,stripIdx,nVert,stacks,(slices+1)*2);
 
         /* cleanup allocated memory */
-        free(topIdx);
-        free(bottomIdx);
         free(stripIdx);
     }
     
@@ -957,251 +1477,386 @@ static void fghSphere( double radius, GLint slices, GLint stacks, GLboolean useW
     free(normals);
 }
 
-#endif /* GL_ES_VERSION_2_0 */
+static void fghCone( double base, double height, GLint slices, GLint stacks, GLboolean useWireMode )
+{
+    int i,j,idx, nVert;
+    GLfloat *vertices, *normals;
 
+    /* Generate vertices and normals */
+    /* Note, (stacks+1)*slices vertices for side of object, slices+1 for top and bottom closures */
+    fghGenerateCone((GLfloat)base,(GLfloat)height,slices,stacks,&vertices,&normals,&nVert);
 
-/* -- INTERFACE FUNCTIONS ---------------------------------------------- */
+    if (nVert==0)
+        /* nothing to draw */
+        return;
 
+    if (useWireMode)
+    {
+        GLushort  *sliceIdx, *stackIdx;
+        /* First, generate vertex index arrays for drawing with glDrawElements
+         * We have a bunch of line_loops to draw for each stack, and a
+         * bunch for each slice.
+         */
 
-#ifndef EGL_VERSION_1_0
-/*
- * Draws a solid sphere
- */
-void FGAPIENTRY glutSolidSphere(double radius, GLint slices, GLint stacks)
-{
-    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidSphere" );
+        stackIdx = malloc(slices*stacks*sizeof(GLushort));
+        sliceIdx = malloc(slices*2     *sizeof(GLushort));
+        if (!(stackIdx) || !(sliceIdx))
+        {
+            free(stackIdx);
+            free(sliceIdx);
+            fgError("Failed to allocate memory in fghCone");
+        }
 
-    fghSphere( radius, slices, stacks, FALSE );
-}
-
-/*
- * Draws a wire sphere
- */
-void FGAPIENTRY glutWireSphere(double radius, GLint slices, GLint stacks)
-{
-    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireSphere" );
-
-    fghSphere( radius, slices, stacks, TRUE );
-    
-}
-
-/*
- * Draws a solid cone
- */
-void FGAPIENTRY glutSolidCone( double base, double height, GLint slices, GLint stacks )
-{
-    int i,j;
-
-    /* Step in z and radius as stacks are drawn. */
-
-    GLfloat z0,z1;
-    GLfloat r0,r1;
-
-    const GLfloat zStep = (GLfloat)height / ( ( stacks > 0 ) ? stacks : 1 );
-    const GLfloat rStep = (GLfloat)base / ( ( stacks > 0 ) ? stacks : 1 );
-
-    /* Scaling factors for vertex normals */
-
-    const GLfloat cosn = ( (GLfloat)height / sqrtf( height * height + base * base ));
-    const GLfloat sinn = ( (GLfloat)base   / sqrtf( height * height + base * base ));
+        /* generate for each stack */
+        for (i=0,idx=0; i<stacks; i++)
+        {
+            GLushort offset = 1+(i+1)*slices;       /* start at 1 (0 is top vertex), and we advance one stack down as we go along */
+            for (j=0; j<slices; j++, idx++)
+            {
+                stackIdx[idx] = offset+j;
+            }
+        }
 
-    /* Pre-computed circle */
+        /* generate for each slice */
+        for (i=0,idx=0; i<slices; i++)
+        {
+            GLushort offset = 1+i;                  /* start at 1 (0 is top vertex), and we advance one slice as we go along */
+            sliceIdx[idx++] = offset+slices;
+            sliceIdx[idx++] = offset+(stacks+1)*slices;
+        }
 
-    GLfloat *sint,*cost;
+        /* draw */
+        fghDrawGeometryWire(vertices,normals,nVert,
+            sliceIdx,1,slices*2,GL_LINES,
+            stackIdx,stacks,slices);
 
-    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidCone" );
+        /* cleanup allocated memory */
+        free(sliceIdx);
+        free(stackIdx);
+    }
+    else
+    {
+        /* First, generate vertex index arrays for drawing with glDrawElements
+         * All stacks, including top and bottom are covered with a triangle
+         * strip.
+         */
+        GLushort  *stripIdx;
+        /* Create index vector */
+        GLushort offset;
 
-    fghCircleTable(&sint,&cost,-slices,FALSE);
+        /* Allocate buffers for indices, bail out if memory allocation fails */
+        stripIdx = malloc((slices+1)*2*(stacks+1)*sizeof(GLushort));    /*stacks +1 because of closing off bottom */
+        if (!(stripIdx))
+        {
+            free(stripIdx);
+            fgError("Failed to allocate memory in fghCone");
+        }
 
-    /* Cover the circular base with a triangle fan... */
+        /* top stack */
+        for (j=0, idx=0;  j<slices;  j++, idx+=2)
+        {
+            stripIdx[idx  ] = 0;
+            stripIdx[idx+1] = j+1;              /* 0 is top vertex, 1 is first for first stack */
+        }
+        stripIdx[idx  ] = 0;                    /* repeat first slice's idx for closing off shape */
+        stripIdx[idx+1] = 1;
+        idx+=2;
 
-    z0 = 0;
-    z1 = zStep;
+        /* middle stacks: */
+        /* Strip indices are relative to first index belonging to strip, NOT relative to first vertex/normal pair in array */
+        for (i=0; i<stacks; i++, idx+=2)
+        {
+            offset = 1+(i+1)*slices;                /* triangle_strip indices start at 1 (0 is top vertex), and we advance one stack down as we go along */
+            for (j=0; j<slices; j++, idx+=2)
+            {
+                stripIdx[idx  ] = offset+j;
+                stripIdx[idx+1] = offset+j+slices;
+            }
+            stripIdx[idx  ] = offset;               /* repeat first slice's idx for closing off shape */
+            stripIdx[idx+1] = offset+slices;
+        }
 
-    r0 = (GLfloat)base;
-    r1 = r0 - rStep;
+        /* draw */
+        fghDrawGeometrySolid(vertices,normals,stripIdx,nVert,stacks+1,(slices+1)*2);
 
-    glBegin(GL_TRIANGLE_FAN);
+        /* cleanup allocated memory */
+        free(stripIdx);
+    }
 
-        glNormal3f(0,0,-1);
-        glVertex3f(0,0, z0 );
+    /* cleanup allocated memory */
+    free(vertices);
+    free(normals);
+}
 
-        for (j=0; j<=slices; j++)
-            glVertex3f(cost[j]*r0, sint[j]*r0, z0);
+static void fghCylinder( double radius, double height, GLint slices, GLint stacks, GLboolean useWireMode )
+{
+    int i,j,idx, nVert;
+    GLfloat *vertices, *normals;
 
-    glEnd();
+    /* Generate vertices and normals */
+    /* Note, (stacks+1)*slices vertices for side of object, 2*slices+2 for top and bottom closures */
+    fghGenerateCylinder((GLfloat)radius,(GLfloat)height,slices,stacks,&vertices,&normals,&nVert);
 
-    /* Cover each stack with a quad strip, except the top stack */
+    if (nVert==0)
+        /* nothing to draw */
+        return;
 
-    for( i=0; i<stacks-1; i++ )
+    if (useWireMode)
     {
-        glBegin(GL_QUAD_STRIP);
+        GLushort  *sliceIdx, *stackIdx;
+        /* First, generate vertex index arrays for drawing with glDrawElements
+         * We have a bunch of line_loops to draw for each stack, and a
+         * bunch for each slice.
+         */
 
-            for(j=0; j<=slices; j++)
+        stackIdx = malloc(slices*(stacks+1)*sizeof(GLushort));
+        sliceIdx = malloc(slices*2         *sizeof(GLushort));
+        if (!(stackIdx) || !(sliceIdx))
+        {
+            free(stackIdx);
+            free(sliceIdx);
+            fgError("Failed to allocate memory in fghCylinder");
+        }
+
+        /* generate for each stack */
+        for (i=0,idx=0; i<stacks+1; i++)
+        {
+            GLushort offset = 1+(i+1)*slices;       /* start at 1 (0 is top vertex), and we advance one stack down as we go along */
+            for (j=0; j<slices; j++, idx++)
             {
-                glNormal3f(cost[j]*cosn, sint[j]*cosn, sinn);
-                glVertex3f(cost[j]*r0,   sint[j]*r0,   z0  );
-                glVertex3f(cost[j]*r1,   sint[j]*r1,   z1  );
+                stackIdx[idx] = offset+j;
             }
+        }
+
+        /* generate for each slice */
+        for (i=0,idx=0; i<slices; i++)
+        {
+            GLushort offset = 1+i;                  /* start at 1 (0 is top vertex), and we advance one slice as we go along */
+            sliceIdx[idx++] = offset+slices;
+            sliceIdx[idx++] = offset+(stacks+1)*slices;
+        }
 
-            z0 = z1; z1 += zStep;
-            r0 = r1; r1 -= rStep;
+        /* draw */
+        fghDrawGeometryWire(vertices,normals,nVert,
+            sliceIdx,1,slices*2,GL_LINES,
+            stackIdx,stacks+1,slices);
 
-        glEnd();
+        /* cleanup allocated memory */
+        free(sliceIdx);
+        free(stackIdx);
     }
+    else
+    {
+        /* First, generate vertex index arrays for drawing with glDrawElements
+         * All stacks, including top and bottom are covered with a triangle
+         * strip.
+         */
+        GLushort  *stripIdx;
+        /* Create index vector */
+        GLushort offset;
 
-    /* The top stack is covered with individual triangles */
+        /* Allocate buffers for indices, bail out if memory allocation fails */
+        stripIdx = malloc((slices+1)*2*(stacks+2)*sizeof(GLushort));    /*stacks +2 because of closing off bottom and top */
+        if (!(stripIdx))
+        {
+            free(stripIdx);
+            fgError("Failed to allocate memory in fghCylinder");
+        }
 
-    glBegin(GL_TRIANGLES);
+        /* top stack */
+        for (j=0, idx=0;  j<slices;  j++, idx+=2)
+        {
+            stripIdx[idx  ] = 0;
+            stripIdx[idx+1] = j+1;              /* 0 is top vertex, 1 is first for first stack */
+        }
+        stripIdx[idx  ] = 0;                    /* repeat first slice's idx for closing off shape */
+        stripIdx[idx+1] = 1;
+        idx+=2;
 
-        glNormal3f(cost[0]*sinn, sint[0]*sinn, cosn);
+        /* middle stacks: */
+        /* Strip indices are relative to first index belonging to strip, NOT relative to first vertex/normal pair in array */
+        for (i=0; i<stacks; i++, idx+=2)
+        {
+            offset = 1+(i+1)*slices;                /* triangle_strip indices start at 1 (0 is top vertex), and we advance one stack down as we go along */
+            for (j=0; j<slices; j++, idx+=2)
+            {
+                stripIdx[idx  ] = offset+j;
+                stripIdx[idx+1] = offset+j+slices;
+            }
+            stripIdx[idx  ] = offset;               /* repeat first slice's idx for closing off shape */
+            stripIdx[idx+1] = offset+slices;
+        }
 
-        for (j=0; j<slices; j++)
+        /* top stack */
+        offset = 1+(stacks+2)*slices;
+        for (j=0; j<slices; j++, idx+=2)
         {
-            glVertex3f(cost[j+0]*r0,   sint[j+0]*r0,            z0    );
-            glVertex3f(0,              0,              (GLfloat)height);
-            glNormal3f(cost[j+1]*sinn, sint[j+1]*sinn,          cosn  );
-            glVertex3f(cost[j+1]*r0,   sint[j+1]*r0,            z0    );
+            stripIdx[idx  ] = offset+j;
+            stripIdx[idx+1] = nVert-1;              /* zero based index, last element in array (bottom vertex)... */
         }
+        stripIdx[idx  ] = offset;
+        stripIdx[idx+1] = nVert-1;                  /* repeat first slice's idx for closing off shape */
 
-    glEnd();
+        /* draw */
+        fghDrawGeometrySolid(vertices,normals,stripIdx,nVert,stacks+2,(slices+1)*2);
 
-    /* Release sin and cos tables */
+        /* cleanup allocated memory */
+        free(stripIdx);
+    }
 
-    free(sint);
-    free(cost);
+    /* cleanup allocated memory */
+    free(vertices);
+    free(normals);
 }
 
-/*
- * Draws a wire cone
- */
-void FGAPIENTRY glutWireCone( double base, double height, GLint slices, GLint stacks)
+static void fghTorus( double dInnerRadius, double dOuterRadius, GLint nSides, GLint nRings, GLboolean useWireMode )
 {
-    int i,j;
-
-    /* Step in z and radius as stacks are drawn. */
-
-    GLfloat z = 0;
-    GLfloat r = (GLfloat)base;
+    int i,j,idx, nVert;
+    GLfloat *vertices, *normals;
 
-    const GLfloat zStep = (GLfloat)height / ( ( stacks > 0 ) ? stacks : 1 );
-    const GLfloat rStep = (GLfloat)base / ( ( stacks > 0 ) ? stacks : 1 );
+    /* Generate vertices and normals */
+    fghGenerateTorus((GLfloat)dInnerRadius,(GLfloat)dOuterRadius,nSides,nRings, &vertices,&normals,&nVert);
 
-    /* Scaling factors for vertex normals */
+    if (nVert==0)
+        /* nothing to draw */
+        return;
 
-    const GLfloat cosn = ( (GLfloat)height / sqrtf( height * height + base * base ));
-    const GLfloat sinn = ( (GLfloat)base   / sqrtf( height * height + base * base ));
+    if (useWireMode)
+    {
+        GLushort  *sideIdx, *ringIdx;
+        /* First, generate vertex index arrays for drawing with glDrawElements
+         * We have a bunch of line_loops to draw each side, and a
+         * bunch for each ring.
+         */
 
-    /* Pre-computed circle */
+        ringIdx = malloc(nRings*nSides*sizeof(GLushort));
+        sideIdx = malloc(nSides*nRings*sizeof(GLushort));
+        if (!(ringIdx) || !(sideIdx))
+        {
+            free(ringIdx);
+            free(sideIdx);
+            fgError("Failed to allocate memory in fghTorus");
+        }
 
-    GLfloat *sint,*cost;
+        /* generate for each ring */
+        for( j=0,idx=0; j<nRings; j++ )
+            for( i=0; i<nSides; i++, idx++ )
+                ringIdx[idx] = j * nSides + i;
 
-    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireCone" );
+        /* generate for each side */
+        for( i=0,idx=0; i<nSides; i++ )
+            for( j=0; j<nRings; j++, idx++ )
+                sideIdx[idx] = j * nSides + i;
 
-    fghCircleTable(&sint,&cost,-slices,FALSE);
+        /* draw */
+        fghDrawGeometryWire(vertices,normals,nVert,
+            ringIdx,nRings,nSides,GL_LINE_LOOP,
+            sideIdx,nSides,nRings);
+        
+        /* cleanup allocated memory */
+        free(sideIdx);
+        free(ringIdx);
+    }
+    else
+    {
+        /* First, generate vertex index arrays for drawing with glDrawElements
+         * All stacks, including top and bottom are covered with a triangle
+         * strip.
+         */
+        GLushort  *stripIdx;
 
-    /* Draw the stacks... */
+        /* Allocate buffers for indices, bail out if memory allocation fails */
+        stripIdx = malloc((nRings+1)*2*nSides*sizeof(GLushort));
+        if (!(stripIdx))
+        {
+            free(stripIdx);
+            fgError("Failed to allocate memory in fghTorus");
+        }
 
-    for (i=0; i<stacks; i++)
-    {
-        glBegin(GL_LINE_LOOP);
+        for( i=0, idx=0; i<nSides; i++ )
+        {
+            int ioff = 1;
+            if (i==nSides-1)
+                ioff = -i;
 
-            for( j=0; j<slices; j++ )
+            for( j=0; j<nRings; j++, idx+=2 )
             {
-                glNormal3f(cost[j]*sinn, sint[j]*sinn, cosn);
-                glVertex3f(cost[j]*r,    sint[j]*r,    z   );
+                int offset = j * nSides + i;
+                stripIdx[idx  ] = offset;
+                stripIdx[idx+1] = offset + ioff;
             }
+            /* repeat first to close off shape */
+            stripIdx[idx  ] = i;
+            stripIdx[idx+1] = i + ioff;
+            idx +=2;
+        }
 
-        glEnd();
+        /* draw */
+        fghDrawGeometrySolid(vertices,normals,stripIdx,nVert,nSides,(nRings+1)*2);
 
-        z += zStep;
-        r -= rStep;
+        /* cleanup allocated memory */
+        free(stripIdx);
     }
 
-    /* Draw the slices */
-
-    r = (GLfloat)base;
+    /* cleanup allocated memory */
+    free(vertices);
+    free(normals);
+}
 
-    glBegin(GL_LINES);
 
-        for (j=0; j<slices; j++)
-        {
-            glNormal3f(cost[j]*sinn, sint[j]*sinn,          cosn  );
-            glVertex3f(cost[j]*r,    sint[j]*r,             0     );
-            glVertex3f(0,            0,            (GLfloat)height);
-        }
+/* -- INTERFACE FUNCTIONS ---------------------------------------------- */
 
-    glEnd();
 
-    /* Release sin and cos tables */
+/*
+ * Draws a solid sphere
+ */
+void FGAPIENTRY glutSolidSphere(double radius, GLint slices, GLint stacks)
+{
+    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidSphere" );
 
-    free(sint);
-    free(cost);
+    fghSphere( radius, slices, stacks, FALSE );
 }
 
-
 /*
- * Draws a solid cylinder
+ * Draws a wire sphere
  */
-void FGAPIENTRY glutSolidCylinder(double radius, double height, GLint slices, GLint stacks)
+void FGAPIENTRY glutWireSphere(double radius, GLint slices, GLint stacks)
 {
-    int i,j;
-
-    /* Step in z and radius as stacks are drawn. */
-    GLfloat radf = (GLfloat)radius;
-    GLfloat z0,z1;
-    const GLfloat zStep = (GLfloat)height / ( ( stacks > 0 ) ? stacks : 1 );
-
-    /* Pre-computed circle */
-
-    GLfloat *sint,*cost;
-
-    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidCylinder" );
-
-    fghCircleTable(&sint,&cost,-slices,FALSE);
-
-    /* Cover the base and top */
-
-    glBegin(GL_TRIANGLE_FAN);
-        glNormal3f(0, 0, -1 );
-        glVertex3f(0, 0,  0 );
-        for (j=0; j<=slices; j++)
-          glVertex3f(cost[j]*radf, sint[j]*radf, 0);
-    glEnd();
+    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireSphere" );
 
-    glBegin(GL_TRIANGLE_FAN);
-        glNormal3f(0, 0,          1     );
-        glVertex3f(0, 0, (GLfloat)height);
-        for (j=slices; j>=0; j--)
-          glVertex3f(cost[j]*radf, sint[j]*radf, (GLfloat)height);
-    glEnd();
+    fghSphere( radius, slices, stacks, TRUE );
+    
+}
 
-    /* Do the stacks */
+/*
+ * Draws a solid cone
+ */
+void FGAPIENTRY glutSolidCone( double base, double height, GLint slices, GLint stacks )
+{
+    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidCone" );
 
-    z0 = 0;
-    z1 = zStep;
+    fghCone( base, height, slices, stacks, FALSE );
+}
 
-    for (i=1; i<=stacks; i++)
-    {
-        if (i==stacks)
-            z1 = (GLfloat)height;
+/*
+ * Draws a wire cone
+ */
+void FGAPIENTRY glutWireCone( double base, double height, GLint slices, GLint stacks)
+{
+    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireCone" );
 
-        glBegin(GL_QUAD_STRIP);
-            for (j=0; j<=slices; j++ )
-            {
-                glNormal3f(cost[j],      sint[j],      0  );
-                glVertex3f(cost[j]*radf, sint[j]*radf, z0 );
-                glVertex3f(cost[j]*radf, sint[j]*radf, z1 );
-            }
-        glEnd();
+    fghCone( base, height, slices, stacks, TRUE );
+}
 
-        z0 = z1; z1 += zStep;
-    }
 
-    /* Release sin and cos tables */
+/*
+ * Draws a solid cylinder
+ */
+void FGAPIENTRY glutSolidCylinder(double radius, double height, GLint slices, GLint stacks)
+{
+    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidCylinder" );
 
-    free(sint);
-    free(cost);
+    fghCylinder( radius, height, slices, stacks, FALSE );
 }
 
 /*
@@ -1209,58 +1864,9 @@ void FGAPIENTRY glutSolidCylinder(double radius, double height, GLint slices, GL
  */
 void FGAPIENTRY glutWireCylinder(double radius, double height, GLint slices, GLint stacks)
 {
-    int i,j;
-
-    /* Step in z and radius as stacks are drawn. */
-    GLfloat radf = (GLfloat)radius;
-          GLfloat z = 0;
-    const GLfloat zStep = (GLfloat)height / ( ( stacks > 0 ) ? stacks : 1 );
-
-    /* Pre-computed circle */
-
-    GLfloat *sint,*cost;
-
     FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireCylinder" );
 
-    fghCircleTable(&sint,&cost,-slices,FALSE);
-
-    /* Draw the stacks... */
-
-    for (i=0; i<=stacks; i++)
-    {
-        if (i==stacks)
-            z = (GLfloat)height;
-
-        glBegin(GL_LINE_LOOP);
-
-            for( j=0; j<slices; j++ )
-            {
-                glNormal3f(cost[j],      sint[j],      0);
-                glVertex3f(cost[j]*radf, sint[j]*radf, z);
-            }
-
-        glEnd();
-
-        z += zStep;
-    }
-
-    /* Draw the slices */
-
-    glBegin(GL_LINES);
-
-        for (j=0; j<slices; j++)
-        {
-            glNormal3f(cost[j],      sint[j],               0     );
-            glVertex3f(cost[j]*radf, sint[j]*radf,          0     );
-            glVertex3f(cost[j]*radf, sint[j]*radf, (GLfloat)height);
-        }
-
-    glEnd();
-
-    /* Release sin and cos tables */
-
-    free(sint);
-    free(cost);
+    fghCylinder( radius, height, slices, stacks, TRUE );
 }
 
 /*
@@ -1268,81 +1874,9 @@ void FGAPIENTRY glutWireCylinder(double radius, double height, GLint slices, GLi
  */
 void FGAPIENTRY glutWireTorus( double dInnerRadius, double dOuterRadius, GLint nSides, GLint nRings )
 {
-  GLfloat  iradius = (float)dInnerRadius, oradius = (float)dOuterRadius;
-  GLfloat phi, psi, dpsi, dphi;
-  GLfloat *vertex, *normal;
-  int    i, j;
-  GLfloat spsi, cpsi, sphi, cphi ;
-
-  FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireTorus" );
-
-  if ( nSides < 1 ) nSides = 1;
-  if ( nRings < 1 ) nRings = 1;
-
-  /* Allocate the vertices array */
-  vertex = (GLfloat *)calloc( sizeof(GLfloat), 3 * nSides * nRings );
-  normal = (GLfloat *)calloc( sizeof(GLfloat), 3 * nSides * nRings );
-
-  glPushMatrix();
-
-  dpsi =  2.0f * (GLfloat)M_PI / (GLfloat)(nRings) ;
-  dphi = -2.0f * (GLfloat)M_PI / (GLfloat)(nSides) ;
-  psi  = 0.0f;
-
-  for( j=0; j<nRings; j++ )
-  {
-    cpsi = cosf( psi ) ;
-    spsi = sinf( psi ) ;
-    phi = 0.0f;
-
-    for( i=0; i<nSides; i++ )
-    {
-      int offset = 3 * ( j * nSides + i ) ;
-      cphi = cosf( phi ) ;
-      sphi = sinf( phi ) ;
-      *(vertex + offset + 0) = cpsi * ( oradius + cphi * iradius ) ;
-      *(vertex + offset + 1) = spsi * ( oradius + cphi * iradius ) ;
-      *(vertex + offset + 2) =                    sphi * iradius  ;
-      *(normal + offset + 0) = cpsi * cphi ;
-      *(normal + offset + 1) = spsi * cphi ;
-      *(normal + offset + 2) =        sphi ;
-      phi += dphi;
-    }
-
-    psi += dpsi;
-  }
-
-  for( i=0; i<nSides; i++ )
-  {
-    glBegin( GL_LINE_LOOP );
-
-    for( j=0; j<nRings; j++ )
-    {
-      int offset = 3 * ( j * nSides + i ) ;
-      glNormal3fv( normal + offset );
-      glVertex3fv( vertex + offset );
-    }
-
-    glEnd();
-  }
-
-  for( j=0; j<nRings; j++ )
-  {
-    glBegin(GL_LINE_LOOP);
+    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutWireTorus" );
 
-    for( i=0; i<nSides; i++ )
-    {
-      int offset = 3 * ( j * nSides + i ) ;
-      glNormal3fv( normal + offset );
-      glVertex3fv( vertex + offset );
-    }
-
-    glEnd();
-  }
-
-  free ( vertex ) ;
-  free ( normal ) ;
-  glPopMatrix();
+    fghTorus(dInnerRadius, dOuterRadius, nSides, nRings, TRUE);
 }
 
 /*
@@ -1350,78 +1884,10 @@ void FGAPIENTRY glutWireTorus( double dInnerRadius, double dOuterRadius, GLint n
  */
 void FGAPIENTRY glutSolidTorus( double dInnerRadius, double dOuterRadius, GLint nSides, GLint nRings )
 {
-  GLfloat  iradius = (float)dInnerRadius, oradius = (float)dOuterRadius;
-  GLfloat phi, psi, dpsi, dphi;
-  GLfloat *vertex, *normal;
-  int    i, j;
-  GLfloat spsi, cpsi, sphi, cphi ;
-
-  FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidTorus" );
-
-  if ( nSides < 1 ) nSides = 1;
-  if ( nRings < 1 ) nRings = 1;
-
-  /* Increment the number of sides and rings to allow for one more point than surface */
-  nSides ++ ;
-  nRings ++ ;
-
-  /* Allocate the vertices array */
-  vertex = (GLfloat *)calloc( sizeof(GLfloat), 3 * nSides * nRings );
-  normal = (GLfloat *)calloc( sizeof(GLfloat), 3 * nSides * nRings );
-
-  glPushMatrix();
-
-  dpsi =  2.0f * (GLfloat)M_PI / (GLfloat)(nRings - 1) ;
-  dphi = -2.0f * (GLfloat)M_PI / (GLfloat)(nSides - 1) ;
-  psi  = 0.0f;
-
-  for( j=0; j<nRings; j++ )
-  {
-    cpsi = cosf( psi ) ;
-    spsi = sinf( psi ) ;
-    phi = 0.0f;
-
-    for( i=0; i<nSides; i++ )
-    {
-      int offset = 3 * ( j * nSides + i ) ;
-      cphi = cosf( phi ) ;
-      sphi = sinf( phi ) ;
-      *(vertex + offset + 0) = cpsi * ( oradius + cphi * iradius ) ;
-      *(vertex + offset + 1) = spsi * ( oradius + cphi * iradius ) ;
-      *(vertex + offset + 2) =                    sphi * iradius  ;
-      *(normal + offset + 0) = cpsi * cphi ;
-      *(normal + offset + 1) = spsi * cphi ;
-      *(normal + offset + 2) =        sphi ;
-      phi += dphi;
-    }
-
-    psi += dpsi;
-  }
-
-    glBegin( GL_QUADS );
-  for( i=0; i<nSides-1; i++ )
-  {
-    for( j=0; j<nRings-1; j++ )
-    {
-      int offset = 3 * ( j * nSides + i ) ;
-      glNormal3fv( normal + offset );
-      glVertex3fv( vertex + offset );
-      glNormal3fv( normal + offset + 3 );
-      glVertex3fv( vertex + offset + 3 );
-      glNormal3fv( normal + offset + 3 * nSides + 3 );
-      glVertex3fv( vertex + offset + 3 * nSides + 3 );
-      glNormal3fv( normal + offset + 3 * nSides );
-      glVertex3fv( vertex + offset + 3 * nSides );
-    }
-  }
-
-  glEnd();
+    FREEGLUT_EXIT_IF_NOT_INITIALISED ( "glutSolidTorus" );
 
-  free ( vertex ) ;
-  free ( normal ) ;
-  glPopMatrix();
+    fghTorus(dInnerRadius, dOuterRadius, nSides, nRings, FALSE);
 }
-#endif /* EGL_VERSION_1_0 */
 
 
 
@@ -1450,10 +1916,10 @@ void FGAPIENTRY glutSolidCube( double dSize )
     fghCube( (GLfloat)dSize, FALSE );
 }
 
-DECLARE_SHAPE_INTERFACE(Dodecahedron);
-DECLARE_SHAPE_INTERFACE(Icosahedron);
-DECLARE_SHAPE_INTERFACE(Octahedron);
-DECLARE_SHAPE_INTERFACE(RhombicDodecahedron);
+DECLARE_SHAPE_INTERFACE(Dodecahedron)
+DECLARE_SHAPE_INTERFACE(Icosahedron)
+DECLARE_SHAPE_INTERFACE(Octahedron)
+DECLARE_SHAPE_INTERFACE(RhombicDodecahedron)
 
 void FGAPIENTRY glutWireSierpinskiSponge ( int num_levels, double offset[3], double scale )
 {
@@ -1466,7 +1932,7 @@ void FGAPIENTRY glutSolidSierpinskiSponge ( int num_levels, double offset[3], do
     fghSierpinskiSponge ( num_levels, offset, (GLfloat)scale, FALSE );
 }
 
-DECLARE_SHAPE_INTERFACE(Tetrahedron);
+DECLARE_SHAPE_INTERFACE(Tetrahedron)
 
 
 /*** END OF FILE ***/