/***********************************************************
compile map for fast display
***********************************************************/
void MapModel::Compile(int YLimit)
{
Uncompile();
MapFace * ptr = _faces;
glNewList(_list_name, GL_COMPILE);
glBegin(GL_TRIANGLES);
for(int i=0; i<_nbfaces; ++i, ++ptr)
{
glTexCoord3fv(ptr->p1Text);
glNormal3fv(ptr->p1Norm);
glVertex4fv(ptr->p1Vertex);
glTexCoord3fv(ptr->p2Text);
glNormal3fv(ptr->p2Norm);
glVertex4fv(ptr->p2Vertex);
glTexCoord3fv(ptr->p3Text);
glNormal3fv(ptr->p3Norm);
glVertex4fv(ptr->p3Vertex);
}
glEnd();
glEndList();
}
static void
draw_face(int x, int y, int dim, int face)
{
glViewport(0, 0, piglit_width, piglit_height);
piglit_ortho_projection(piglit_width, piglit_height, GL_FALSE);
glBindFramebufferEXT(GL_FRAMEBUFFER_EXT, piglit_winsys_fbo);
glEnable(GL_TEXTURE_CUBE_MAP);
glTexEnvi(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_REPLACE);
glTexParameteri(GL_TEXTURE_CUBE_MAP, GL_TEXTURE_MIN_FILTER, GL_NEAREST_MIPMAP_NEAREST);
glTexParameteri(GL_TEXTURE_CUBE_MAP, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glBegin(GL_QUADS);
glTexCoord3fv(cube_face_texcoords[face][0]);
glVertex2f(x, y);
glTexCoord3fv(cube_face_texcoords[face][1]);
glVertex2f(x + dim, y);
glTexCoord3fv(cube_face_texcoords[face][2]);
glVertex2f(x + dim, y + dim);
glTexCoord3fv(cube_face_texcoords[face][3]);
glVertex2f(x, y + dim);
glEnd();
glDisable(GL_TEXTURE_CUBE_MAP);
}
static void render_plane(
VRState *state,
Brick *b,
Coord cpt[8],
float cp[4]
)
{
int j, n;
GLfloat p[8][3];
/* Get vertices for plane */
n = get_plane_cube_intersect(cp[0], cp[1], cp[2], cp[3], p, cpt);
if (n > 2)
{
/* Draw plane */
glBegin(GL_POLYGON);
for (j = 0; j < n; j++)
{
glTexCoord3fv(p[j]);
glVertex3fv(p[j]);
}
glEnd();
}
}
static void WINE_GLAPI wine_glMultiTexCoord3fvARB(GLenum target, const GLfloat *v) {
if(target != GL_TEXTURE0) {
ERR("Texture unit > 0 used, but GL_ARB_multitexture is not supported\n");
return;
}
glTexCoord3fv(v);
}
static void draw_skybox( void )
{
if ( use_vertex_arrays ) {
glTexCoordPointer( 3, GL_FLOAT, 0, tex_coords );
glVertexPointer( 3, GL_FLOAT, 0, vtx_coords );
glEnableClientState( GL_TEXTURE_COORD_ARRAY );
glEnableClientState( GL_VERTEX_ARRAY );
glDrawArrays( GL_QUADS, 0, 24 );
glDisableClientState( GL_TEXTURE_COORD_ARRAY );
glDisableClientState( GL_VERTEX_ARRAY );
}
else {
unsigned i;
glBegin(GL_QUADS);
for ( i = 0 ; i < 24 ; i++ ) {
glTexCoord3fv( & tex_coords[ i * 3 ] );
glVertex3fv ( & vtx_coords[ i * 3 ] );
}
glEnd();
}
}
void GeomRenderer::sendTexCoord(GLuint texCoordIndex)
{
assert(texCoordData.size >= 1 && texCoordData.size <= 4);
switch(texCoordData.type)
{
case GL_SHORT:
if (texCoordData.size == 1) glTexCoord1sv((const GLshort*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 2) glTexCoord2sv((const GLshort*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 3) glTexCoord3sv((const GLshort*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 4) glTexCoord4sv((const GLshort*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
break;
case GL_INT:
if (texCoordData.size == 1) glTexCoord1iv((const GLint*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 2) glTexCoord2iv((const GLint*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 3) glTexCoord3iv((const GLint*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 4) glTexCoord4iv((const GLint*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
break;
case GL_FLOAT:
if (texCoordData.size == 1) glTexCoord1fv((const GLfloat*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 2) glTexCoord2fv((const GLfloat*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 3) glTexCoord3fv((const GLfloat*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 4) glTexCoord4fv((const GLfloat*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
break;
case GL_DOUBLE:
if (texCoordData.size == 1) glTexCoord1dv((const GLdouble*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 2) glTexCoord2dv((const GLdouble*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 3) glTexCoord3dv((const GLdouble*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
if (texCoordData.size == 4) glTexCoord4dv((const GLdouble*)((const char*)texCoordData.pointer + texCoordIndex*texCoordData.stride));
break;
}
}
void drawMesh()
{
int i, j;
if (g_mesh){
glBegin(GL_TRIANGLES);
for (i =0; i < g_mesh->numFaces; ++i){
HTriangle face = &g_mesh->triangles[i];
for (j = 0; j < 3; ++j){
if (face->vn[j] >= 0){
glNormal3fv(&g_mesh->normals[face->vn[j]].x);
}
if (face->vt[j] >= 0){
glTexCoord3fv(&g_mesh->texcoords[face->vt[j]].x);
}
glVertex3fv(&g_mesh->vertices[g_mesh->triangles[i].v[j]].x);
}
}
glEnd();
}
}
static void render_slices(
Brick *b,
VRState *state,
Coord cpt[8],
int direction
)
{
int i, j, n;
float d;
float min_z, max_z;
int slice_count;
GLfloat p[8][3];
/* Get slice distance from state */
float delta = state->view->delta;
float dz = delta * (float) direction;
min_z = HUGE;
max_z = -HUGE;
/* Find minimum and maximum z-coordinates */
for (i = 0; i < 8; i++)
{
if (min_z > cpt[i][2])
{
min_z = cpt[i][2];
}
if (max_z < cpt[i][2])
{
max_z = cpt[i][2];
}
}
min_z = floor(min_z / delta) * delta;
max_z = floor(max_z / delta) * delta;
/* For each slice */
slice_count = 0;
for (d = min_z; (direction == 1) ? (d <= max_z) : (d >= max_z); d += dz)
{
/* Get intersection polygon */
n = get_plane_cube_intersect(0.0, 0.0, 1.0, -d, p, cpt);
if (n > 2)
{
slice_count++;
/* Draw slice */
glBegin(GL_POLYGON);
for (j = 0; j < n; j++)
{
glTexCoord3fv(p[j]);
glVertex3fv(p[j]);
}
glEnd();
}
}
}
void yglTexTris(long ntri, float *verts, float *texverts)
{
long i, nd;
if(alpha_pass) return;
/* Draw an array of 3Dtextured triangles. */
glBindTexture(glCurrWin3d->myGL_TEXTURE_3D, texName3d);
glBegin(GL_TRIANGLES);
for(i= 0; i < ntri; i++) {
nd= 9*i; /* 3 coords per vertex, 3 vertices per tri */
glTexCoord3fv(texverts+nd);
glVertex3fv(verts+nd);
glTexCoord3fv(texverts+nd+3);
glVertex3fv(verts+nd+3);
glTexCoord3fv(texverts+nd+6);
glVertex3fv(verts+nd+6);
}
glEnd();
}
inline void vRenderer::renderSlice(int edges,float tc[6][3], float pc[6][3],int order[6])
{
glBegin(GL_POLYGON); {//draw slice and texture map it
for(int j=0; j< edges; ++j)
{
glTexCoord3fv(tc[order[j]]);
glVertex3fv(pc[order[j]]);
}
} glEnd();
}
/**
* Draw the OBJ model.
*/
void
RenderOBJModel (struct obj_model_t *mdl)
{
int i, j;
//glDisable(GL_LIGHTING);
//printf("%d\n", mdl->num_faces);
for (i = 0; i < mdl->num_faces; ++i)
{
glBegin (mdl->faces[i].type);
for (j = 0; j < mdl->faces[i].num_elems; ++j)
{
if (mdl->has_texCoords) {
//printf("test2 %d\n", i);
//printf("test3 %d\n", mdl->texCoords[mdl->faces[i].uvw_indices[j]].uvw);
glTexCoord3fv (mdl->texCoords[mdl->faces[i].uvw_indices[j]].uvw);
//glTexCoord3fv (mdl->texCoords[mdl->faces[219].uvw_indices[3]].uvw);
}
if (mdl->has_normals){
//glNormal3fv (mdl->normals[mdl->faces[219].norm_indices[3]].ijk);
glNormal3fv (mdl->normals[mdl->faces[i].norm_indices[j]].ijk);
}
glVertex4fv (mdl->vertices [mdl->faces[i].vert_indices[j]].xyzw);
}
glEnd();
}
/*if (hasname) {
glDisable(GL_LIGHTING);
}*/
}
/**
* Draw the OBJ model.
*/
void LoadOBJ::RenderOBJModel ()
{
int i, j;
for (i = 0; i < mdl.num_faces; ++i)
{
glBegin (mdl.faces[i].type);
//glBegin (GL_LINE_STRIP);
for (j = 0; j < mdl.faces[i].num_elems; ++j)
{
if (mdl.has_texCoords)
glTexCoord3fv (mdl.texCoords[mdl.faces[i].uvw_indices[j]].uvw);
if (mdl.has_normals)
glNormal3fv (mdl.normals[mdl.faces[i].norm_indices[j]].ijk);
glVertex4fv (mdl.vertices [mdl.faces[i].vert_indices[j]].xyzw);
}
glEnd();
}
}
/**
* Draw the OBJ model.
*/
void
RenderOBJModel (struct obj_model_t *mdl)
{
int i, j;
for (i = 0; i < mdl->num_faces; ++i)
{
glBegin (mdl->faces[i].type);
for (j = 0; j < mdl->faces[i].num_elems; ++j)
{
if (mdl->has_texCoords)
glTexCoord3fv (mdl->texCoords[mdl->faces[i].uvw_indices[j]].uvw);
if (mdl->has_normals)
glNormal3fv (mdl->normals[mdl->faces[i].norm_indices[j]].ijk);
glVertex4fv (mdl->vertices [mdl->faces[i].vert_indices[j]].xyzw);
}
glEnd();
}
}
void CMesh::draw() const
{
bool isTransparent;
// bind the texture
if (hasTexture()) {
glBindTexture (GL_TEXTURE_2D, m_pTexture->getID());
isTransparent = m_pTexture->isTransparent();
}
else isTransparent = false;
bool isDepthTestEnabled = glIsEnabled(GL_DEPTH_TEST);
if (isTransparent)
glDisable(GL_DEPTH_TEST);
glMaterialfv(GL_FRONT_AND_BACK, GL_AMBIENT, m_material.Ka);
glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, m_material.Kd);
glMaterialfv(GL_FRONT_AND_BACK, GL_SPECULAR, m_material.Ks);
glMaterialf(GL_FRONT_AND_BACK, GL_SHININESS, m_material.Ns);
// draw each face...
for (vector<SPolygonFace>::const_iterator itFace = m_faceVector.begin(); itFace != m_faceVector.end(); ++itFace)
{
glColor3f(1, 1, 0);
glBegin(GL_POLYGON);
// TODO: passer ˆà for_each
for (unsigned i = 0; i < (*itFace).v.size(); ++i) {
glNormal3fv(m_normVector[(*itFace).vn[i]].getVertex3fv());
if (hasTexture() && hasTextureCoords())
glTexCoord3fv(m_texVector[(*itFace).vt[i]].getVertex3fv());
glVertex3fv(m_vertVector[(*itFace).v[i]].getVertex3fv());
}
glEnd(); // GL_POLYGON
}
// restore depth test
if (isDepthTestEnabled)
glEnable(GL_DEPTH_TEST);
else
glDisable(GL_DEPTH_TEST);
}
void __glXDisp_TexCoord3fv(GLbyte *pc)
{
glTexCoord3fv(
(GLfloat *)(pc + 0)
);
}
static GLboolean
draw_at_size(int size, int x_offset, int y_offset, GLboolean mipmapped)
{
GLfloat row_y = PAD + y_offset;
int dim, face;
int color = 0, level = 0;
GLuint texname;
GLboolean pass = GL_TRUE;
/* Create the texture. */
glGenTextures(1, &texname);
glBindTexture(GL_TEXTURE_CUBE_MAP_ARB, texname);
/* For each face drawing, we want to only see that face's contents at
* that mipmap level.
*/
if (mipmapped) {
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_MIN_FILTER,
GL_NEAREST_MIPMAP_NEAREST);
} else {
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_MIN_FILTER,
GL_NEAREST);
}
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
/* Fill in faces on each level */
for (dim = size; dim > 0; dim /= 2) {
for (face = 0; face < 6; face++) {
set_face_image(level, cube_face_targets[face],
dim, color);
color = (color + 1) % ARRAY_SIZE(colors);
}
if (!mipmapped)
break;
level++;
}
glEnable(GL_TEXTURE_CUBE_MAP_ARB);
color = 0;
level = 0;
for (dim = size; dim > 0; dim /= 2) {
GLfloat row_x = PAD + x_offset;
for (face = 0; face < 6; face++) {
GLfloat base_x = row_x + face * (max_size + PAD);
GLfloat base_y = row_y;
glBegin(GL_QUADS);
glTexCoord3fv(cube_face_texcoords[face][0]);
glVertex2f(base_x, base_y);
glTexCoord3fv(cube_face_texcoords[face][1]);
glVertex2f(base_x + dim, base_y);
glTexCoord3fv(cube_face_texcoords[face][2]);
glVertex2f(base_x + dim, base_y + dim);
glTexCoord3fv(cube_face_texcoords[face][3]);
glVertex2f(base_x, base_y + dim);
glEnd();
if (dim > 2) {
pass = test_results(base_x, base_y,
dim, level, face,
mipmapped,
color) && pass;
}
color = (color + 1) % ARRAY_SIZE(colors);
}
if (!mipmapped)
break;
row_y += dim + PAD;
level++;
}
glDeleteTextures(1, &texname);
return pass;
}
void PolygonForeground::draw(DrawEnv *pEnv)
{
if(getActive() == false)
return;
if(getMFPositions()->size() == 0) // nothing to render
return;
if(pEnv->getPixelWidth() == 0 ||
pEnv->getPixelHeight() == 0 ) // nothing to render to
return;
bool bUseTC = true;
if(getMFPositions()->size() != getMFTexCoords()->size())
{
#if 0
FWARNING(("PolygonForeground::draw: positions and texcoords have "
"different sizes (%d vs. %d)!\n",
getMFPositions()->size(), getMFTexCoords()->size()));
return;
#endif
bUseTC = false;
}
glPushAttrib(GL_ALL_ATTRIB_BITS);
Real32 aspectX = 1.0f, aspectY = 1.0f;
if(getAspectHeight() && getAspectWidth())
{
aspectX =
(Real32(pEnv->getPixelHeight()) / getAspectHeight()) /
(Real32(pEnv->getPixelWidth()) / getAspectWidth());
}
glMatrixMode(GL_MODELVIEW);
glPushMatrix();
glLoadIdentity();
glMatrixMode(GL_PROJECTION);
glPushMatrix();
glLoadIdentity();
Real32 sFac = getScale() > 0 ? getScale() : 1.0f;
UInt32 width = pEnv->getPixelWidth(),
height = pEnv->getPixelHeight();
if(pEnv->getTileFullSize()[0] != 0 && getTile() == false)
{
width = pEnv->getTileFullSize()[0];
height = pEnv->getTileFullSize()[1];
Real32 t = 0;
#if 0
Real32 left = pEnv->getTileRegion()[0]; //cdP->getLeft(),
Real32 right = pEnv->getTileRegion()[1]; //cdP->getRight(),
Real32 top = pEnv->getTileRegion()[3]; //cdP->getTop(),
Real32 bottom = pEnv->getTileRegion()[2]; //cdP->getBottom();
#endif
if (getAspectHeight() && getAspectWidth() &&
height != 0 && width != 0)
{
aspectX =
(Real32(height/getAspectHeight())) /
(Real32(width / getAspectWidth()));
t = Real32(width) * (1 - aspectX) * 0.5f;
t *= Real32(pEnv->getPixelWidth()) / width;
}
Matrix sm = pEnv->calcTileDecorationMatrix();
glLoadMatrixf(sm.getValues());
glOrtho(0, pEnv->getPixelWidth(), 0, pEnv->getPixelHeight(), 0, 1);
glTranslatef(t, 0, 0);
glScalef(aspectX, aspectY, 1);
float t1 = (1 - sFac) * 0.5f * Real32(pEnv->getPixelWidth());
float t2 = (1 - sFac) * 0.5f * Real32(pEnv->getPixelHeight());
glTranslatef(t1, t2, 0);
glScalef(sFac,sFac,1);
}
else
{
glScalef(sFac,sFac,1);
glScalef(aspectX, aspectY, 1);
glOrtho(0, pEnv->getPixelWidth(), 0, pEnv->getPixelHeight(), 0, 1);
}
getMaterial()->getState()->activate(pEnv);
const Vec3f *tc = NULL;
if(bUseTC == true)
{
tc = &((*getMFTexCoords())[0]);
}
const Pnt2f *pos = &((*getMFPositions())[0]);
glBegin(GL_POLYGON);
for(UInt16 i = 0; i < getMFPositions()->size(); i++)
{
if(bUseTC == true)
{
glTexCoord3fv( tc[i].getValues() );
}
glVertex2f( mapCoordinate(pos[i][0], Real32(pEnv->getPixelWidth()),
getNormalizedX()),
mapCoordinate(pos[i][1], Real32(pEnv->getPixelHeight()),
getNormalizedY()) );
}
glEnd();
getMaterial()->getState()->deactivate(pEnv);
glScalef(1, 1, 1);
glPopMatrix();
glMatrixMode(GL_MODELVIEW);
glPopMatrix();
glPopAttrib();
}
void SkyBackground::drawFace( DrawEnv * pEnv,
TextureBaseChunk * tex,
StateChunk *&oldtex,
const Pnt3f &p1,
const Pnt3f &p2,
const Pnt3f &p3,
const Pnt3f &p4,
const Vec3f * texCoord)
{
#if !defined(OSG_OGL_COREONLY) || defined(OSG_CHECK_COREONLY)
if(tex != NULL)
{
if(oldtex != NULL)
{
tex->changeFrom(pEnv, oldtex);
}
else
{
tex->activate(pEnv);
}
if(tex->isTransparent())
{
glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
glEnable(GL_BLEND);
}
// ENRICO: this part holds the informations about
// custom texture coordinates
// Mess with the best, die like the rest
glBegin(GL_QUADS);
{
#if 0 // strange crash with par drawers.
glTexCoord3fv(static_cast<const GLfloat *>(
texCoord[0].getValues()));
glVertex3fv (static_cast<const GLfloat *>(p1.getValues()));
glTexCoord3fv(static_cast<const GLfloat *>(
texCoord[1].getValues()));
glVertex3fv (static_cast<const GLfloat *>(p2.getValues()));
glTexCoord3fv(static_cast<const GLfloat *>(
texCoord[2].getValues()));
glVertex3fv (static_cast<const GLfloat *>(p3.getValues()));
glTexCoord3fv(static_cast<const GLfloat *>(
texCoord[3].getValues()));
glVertex3fv (static_cast<const GLfloat *>(p4.getValues()));
#else
glTexCoord3fv(static_cast<const GLfloat *>(
texCoord[0].getValues()));
glVertex3f (p1[0], p1[1], p1[2]);
glTexCoord3fv(static_cast<const GLfloat *>(
texCoord[1].getValues()));
glVertex3f (p2[0], p2[1], p2[2]);
glTexCoord3fv(static_cast<const GLfloat *>(
texCoord[2].getValues()));
glVertex3f (p3[0], p3[1], p3[2]);
glTexCoord3fv(texCoord[3].getValues());
glVertex3f (p4[0], p4[1], p4[2]);
#endif
}
glEnd();
if(tex->isTransparent())
{
glDisable(GL_BLEND);
}
oldtex = tex;
}
#endif
}
void
CLineAnimatorInOpenGL::_TraversePoint(int iPointIndex, int iTraceIndex, float fX, float fY, float fZ, float fT)
{
static list<int>::iterator liiParticleIterator;
static VECTOR3 v3PrevPoint;
static VECTOR3 v3PrevTangent;
// ADD-BY-LEETEN 07/07/2010-BEGIN
static VECTOR4 v4PrevColor;
VECTOR4 v4Color = cColorScheme.V4GetColor();
// ADD-BY-LEETEN 07/07/2010-END
VECTOR3 v3Point(fX, fY, fZ);
if( 0 == iPointIndex )
{
for(liiParticleIterator = liParticles.begin();
liiParticleIterator != liParticles.end() && *liiParticleIterator < 0;
liiParticleIterator++)
;
}
VECTOR3 v3Tangent = v3Point - v3PrevPoint;
v3Tangent.Normalize();
if( liiParticleIterator != liParticles.end() && iPointIndex == *liiParticleIterator )
{
#if 0 // MOD-BY-LEETEN 07/05/2010-FROM:
if( iPointIndex > 0 )
{
if( 1 == iPointIndex )
glTexCoord3fv(&v3Tangent[0]);
else
glTexCoord3fv(&v3PrevTangent[0]);
glVertex3fv(&v3PrevPoint[0]);
glTexCoord3fv(&v3Tangent[0]);
glVertex3fv(&v3Point[0]);
}
#else // MOD-BY-LEETEN 07/05/2010-TO:
if( 1 == iPointIndex )
pv4TexCoords.push_back(VECTOR4(v3Tangent[0], v3Tangent[1], v3Tangent[2], 1.0));
else
pv4TexCoords.push_back(VECTOR4(v3PrevTangent[0], v3PrevTangent[1], v3PrevTangent[2], 1.0));
pv4Coords.push_back(VECTOR4(v3PrevPoint[0], v3PrevPoint[1], v3PrevPoint[2], 1.0));
// ADD-BY-LEETEN 07/07/2010-BEGIN
pv4Colors.push_back(v4PrevColor);
// ADD-BY-LEETEN 07/07/2010-END
pv4TexCoords.push_back(VECTOR4(v3Tangent[0], v3Tangent[1], v3Tangent[2], 1.0));
pv4Coords.push_back(VECTOR4(v3Point[0], v3Point[1], v3Point[2], 1.0));
// ADD-BY-LEETEN 07/07/2010-BEGIN
pv4Colors.push_back(v4Color);
// ADD-BY-LEETEN 07/07/2010-END
#endif // MOD-BY-LEETEN 07/05/2010-END
liiParticleIterator++;
iNrOfRenderedParticles++;
}
// ADD-BY-LEETEN 07/07/2010-BEGIN
cColorScheme._MoveToNextPoint();
v4PrevColor = v4Color;
// ADD-BY-LEETEN 07/07/2010-END
v3PrevPoint = v3Point;
v3PrevTangent = v3Tangent;
}
void
RenderOBJModelt (struct obj_model_t *mdl, struct mtl_file *mtlfile)
{
int i, j, k;
GLfloat ambient[4];
GLfloat diffuse[4];
GLfloat specular[4];
GLfloat shininess[1];
//if (hasname) {
glEnable(GL_LIGHTING);
//}
//printf("%d\n", mdl->num_faces);
for (i = 0; i < mdl->num_faces; ++i)
{
if(isalpha(mdl->faces[i].mat[0])) {
///printf("====== material name %s =====\n", mdl->faces[i].mat);
//if(mdl->faces[i].matindex+1 == i) {
for(k=0; k<mtlfile->materials;k++) {
if(!strcmp(mtlfile->mtl[k].name, mdl->faces[i].mat)){
//printf("====== material name %s =====\n", mtlfile->mtl[k].name);
ambient[0] = mtlfile->mtl[k].ka[0];
ambient[1] = mtlfile->mtl[k].ka[1];
ambient[2] = mtlfile->mtl[k].ka[2];
ambient[3] = mtlfile->mtl[k].ni;
diffuse[0] = mtlfile->mtl[k].kd[0];
diffuse[1] = mtlfile->mtl[k].kd[1];
diffuse[2] = mtlfile->mtl[k].kd[2];
diffuse[3] = mtlfile->mtl[k].ni;
specular[0] = mtlfile->mtl[k].ks[0];
specular[1] = mtlfile->mtl[k].ks[1];
specular[2] = mtlfile->mtl[k].ks[2];
specular[3] = mtlfile->mtl[k].ni;
shininess[0] = mtlfile->mtl[k].d;
glMaterialfv(GL_FRONT, GL_AMBIENT, ambient);
glMaterialfv(GL_FRONT, GL_DIFFUSE, diffuse);
glMaterialfv(GL_FRONT, GL_SPECULAR, specular);
glMaterialfv(GL_FRONT, GL_SHININESS, shininess);
}
}
}
//}
glBegin (mdl->faces[i].type);
for (j = 0; j < mdl->faces[i].num_elems; ++j)
{
/*printf("test4 %d\n", mdl->texCoords[mdl->faces[i].uvw_indices[j]].uvw);
if (i==100) {
printf("test4 %d\n", mdl->texCoords[mdl->faces[i].uvw_indices[j]].uvw);
}*/
/*printf("i=%d j=%d %d/", i, j, mdl->faces[i].vert_indices[j]);
printf("%d/", mdl->faces[i].uvw_indices[j]);
printf("%d\n", mdl->faces[i].norm_indices[j]);*/
if (mdl->has_texCoords) {
//printf("test2 %d\n", i);
//printf("test3 %d\n", mdl->texCoords[mdl->faces[i].uvw_indices[j]].uvw);
glTexCoord3fv (mdl->texCoords[mdl->faces[i].uvw_indices[j]].uvw);
//glTexCoord3fv (mdl->texCoords[mdl->faces[219].uvw_indices[3]].uvw);
}
if (mdl->has_normals){
//glNormal3fv (mdl->normals[mdl->faces[219].norm_indices[3]].ijk);
glNormal3fv (mdl->normals[mdl->faces[i].norm_indices[j]].ijk);
}
glVertex4fv (mdl->vertices [mdl->faces[i].vert_indices[j]].xyzw);
}
glEnd();
}
//glDisable(GL_COLOR_MATERIAL);
//if (hasname) {
glDisable(GL_LIGHTING);
//}
/*printf ("mtl results 222222222222: read\n");
printf (" * %s name\n", mtlfile->mtl[0].name);
printf (" * %f ns\n", mtlfile->mtl[0].ns);
printf (" * %f %f %f ka\n", mtlfile->mtl[0].ka[0], mtlfile->mtl[0].ka[1], mtlfile->mtl[0].ka[2]);
printf (" * %f %f %f kd\n", mtlfile->mtl[0].kd[0], mtlfile->mtl[0].kd[1], mtlfile->mtl[0].kd[2]);
printf (" * %f %f %f ks\n", mtlfile->mtl[0].ks[0], mtlfile->mtl[0].ks[1], mtlfile->mtl[0].ks[2]);
printf (" * %f ni\n", mtlfile->mtl[0].ni);*/
}
M(void, glTexCoord3fv, jobject v) {
glTexCoord3fv(BUFF(GLfloat, v));
}
void drawParticles(std::list<Particle> &drawList, GLuint texture)
{
static float overTime = 0.0;
int particlesToEmit = particles_per_Second * t + overTime;
overTime += particles_per_Second * t - particlesToEmit;
glBindTexture(GL_TEXTURE_2D, texture);
glTexEnvi(GL_POINT_SPRITE, GL_COORD_REPLACE, GL_TRUE);
for(std::list<Particle>::iterator it = drawList.begin(); it != drawList.end(); ++it)
{
//update and draw particles if alive
if(it->isAlive)
{
it->t += t;
if(it->t > it->lifeTime)
it->isAlive = false;
glPointSize(10.0 * (it->lifeTime - it->t) / it->lifeTime + 0.1);
glColor4f(1 - (it->lifeTime - it->t) / it->lifeTime,
1-(it->lifeTime - it->t) / it->lifeTime
,1.0f, 1.0);
glBegin(GL_POINTS);
glVertex3f( it->position[0] + it->t * it->velocity[0],
it->position[1] + it->t * it->velocity[1] - 0.5 * 9.81 * it->t * it->t,
it->position[2] + it->t * it->velocity[2]);
glEnd();
}
//revive particle if necessary
else if(particlesToEmit > 0)
{
--particlesToEmit;
it->isAlive = true;
it->t = 0;
it->lifeTime = myRand(1.5,2.5);
it->position[0] = myRand(-0.5,0.5);
it->position[1] = 0;
it->position[2] = myRand(-0.5,0.5);
it->velocity[0] = myRand(-2, 2);
it->velocity[1] = myRand(5.0,10.0);
it->velocity[2] = myRand(-2, 2);
cgGLEnableTextureParameter(cg_parameter_vertex_velocity);
glVertex2f(0.0f, 0.0f);
glTexCoord3fv(it->velocity);
cgGLDisableTextureParameter(cg_parameter_vertex_velocity);
}
}
//create new particles if necessary
for(int i = 0; i < particlesToEmit; ++i)
{
Particle neu;
neu.isAlive = true;
neu.t = 0;
neu.lifeTime = myRand(1.5,2.5);
neu.position[0] = myRand(-0.5,0.5);
neu.position[1] = 0;
neu.position[2] = myRand(-0.5, 0.5);
neu.velocity[0] = myRand(-2, 2);
neu.velocity[1] = myRand(5.0,10.0);
neu.velocity[2] = myRand(-2, 2);
cgGLEnableTextureParameter(cg_parameter_vertex_velocity);
glVertex2f(0.0f, 0.0f);
glTexCoord3fv(neu->velocity);
cgGLDisableTextureParameter(cg_parameter_vertex_velocity);
water_list.push_back(neu);
}
}
inline void glTexCoord3v( const GLfloat * v ) { glTexCoord3fv( v ); }
static void
RandomPrimitive(void)
{
int i;
int len = MinVertexCount + RandomInt(MaxVertexCount - MinVertexCount);
Vprim = RandomInt(10);
glBegin(Vprim);
Vbuffer[Vcount].type = BEGIN;
Vbuffer[Vcount].v[0] = Vprim;
Vcount++;
for (i = 0; i < len; i++) {
Vbuffer[Vcount].v[0] = RandomFloat(-3, 3);
Vbuffer[Vcount].v[1] = RandomFloat(-3, 3);
Vbuffer[Vcount].v[2] = RandomFloat(-3, 3);
Vbuffer[Vcount].v[3] = RandomFloat(-3, 3);
int k = RandomInt(9);
switch (k) {
case 0:
glVertex2fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = VERTEX2;
break;
case 1:
glVertex3fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = VERTEX3;
break;
case 2:
glVertex4fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = VERTEX4;
break;
case 3:
glColor3fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = COLOR3;
break;
case 4:
glColor4fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = COLOR4;
break;
case 5:
glTexCoord2fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = TEX2;
break;
case 6:
glTexCoord3fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = TEX3;
break;
case 7:
glTexCoord4fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = TEX4;
break;
case 8:
glSecondaryColor3fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = SECCOLOR3;
break;
case 9:
glNormal3fv(Vbuffer[Vcount].v);
Vbuffer[Vcount].type = NORMAL3;
break;
default:
abort();
}
Vcount++;
if (Vcount >= BufferSize - 2) {
/* reset */
Vcount = 0;
}
}
Vbuffer[Vcount++].type = END;
glEnd();
}
static void do_EvalCoord2f( GLcontext* ctx, GLfloat u, GLfloat v )
{
/** Color Index **/
if (ctx->Eval.Map2Index) {
GLfloat findex;
struct gl_2d_map *map = &ctx->EvalMap.Map2Index;
GLfloat uu = (u - map->u1) * map->du;
GLfloat vv = (v - map->v1) * map->dv;
_math_horner_bezier_surf(map->Points, &findex, uu, vv, 1,
map->Uorder, map->Vorder);
glIndexi( (GLuint) (GLint) findex );
}
/** Color **/
if (ctx->Eval.Map2Color4) {
GLfloat fcolor[4];
struct gl_2d_map *map = &ctx->EvalMap.Map2Color4;
GLfloat uu = (u - map->u1) * map->du;
GLfloat vv = (v - map->v1) * map->dv;
_math_horner_bezier_surf(map->Points, fcolor, uu, vv, 4,
map->Uorder, map->Vorder);
glColor4fv( fcolor );
}
/** Normal **/
if (ctx->Eval.Map2Normal &&
(!ctx->Eval.AutoNormal || (!ctx->Eval.Map2Vertex3 &&
!ctx->Eval.Map2Vertex4))) {
GLfloat normal[3];
struct gl_2d_map *map = &ctx->EvalMap.Map2Normal;
GLfloat uu = (u - map->u1) * map->du;
GLfloat vv = (v - map->v1) * map->dv;
_math_horner_bezier_surf(map->Points, normal, uu, vv, 3,
map->Uorder, map->Vorder);
glNormal3fv( normal );
}
/** Texture Coordinates **/
if (ctx->Eval.Map2TextureCoord4) {
GLfloat texcoord[4];
struct gl_2d_map *map = &ctx->EvalMap.Map2Texture4;
GLfloat uu = (u - map->u1) * map->du;
GLfloat vv = (v - map->v1) * map->dv;
_math_horner_bezier_surf(map->Points, texcoord, uu, vv, 4,
map->Uorder, map->Vorder);
glTexCoord4fv( texcoord );
}
else if (ctx->Eval.Map2TextureCoord3) {
GLfloat texcoord[4];
struct gl_2d_map *map = &ctx->EvalMap.Map2Texture3;
GLfloat uu = (u - map->u1) * map->du;
GLfloat vv = (v - map->v1) * map->dv;
_math_horner_bezier_surf(map->Points, texcoord, uu, vv, 3,
map->Uorder, map->Vorder);
glTexCoord3fv( texcoord );
}
else if (ctx->Eval.Map2TextureCoord2) {
GLfloat texcoord[4];
struct gl_2d_map *map = &ctx->EvalMap.Map2Texture2;
GLfloat uu = (u - map->u1) * map->du;
GLfloat vv = (v - map->v1) * map->dv;
_math_horner_bezier_surf(map->Points, texcoord, uu, vv, 2,
map->Uorder, map->Vorder);
glTexCoord2fv( texcoord );
}
else if (ctx->Eval.Map2TextureCoord1) {
GLfloat texcoord[4];
struct gl_2d_map *map = &ctx->EvalMap.Map2Texture1;
GLfloat uu = (u - map->u1) * map->du;
GLfloat vv = (v - map->v1) * map->dv;
_math_horner_bezier_surf(map->Points, texcoord, uu, vv, 1,
map->Uorder, map->Vorder);
glTexCoord1fv( texcoord );
}
/** Vertex **/
if(ctx->Eval.Map2Vertex4) {
GLfloat vertex[4];
GLfloat normal[3];
struct gl_2d_map *map = &ctx->EvalMap.Map2Vertex4;
GLfloat uu = (u - map->u1) * map->du;
GLfloat vv = (v - map->v1) * map->dv;
if (ctx->Eval.AutoNormal) {
GLfloat du[4], dv[4];
_math_de_casteljau_surf(map->Points, vertex, du, dv, uu, vv, 4,
map->Uorder, map->Vorder);
CROSS_PROD(normal, du, dv);
NORMALIZE_3FV(normal);
glNormal3fv( normal );
glVertex4fv( vertex );
}
else {
_math_horner_bezier_surf(map->Points, vertex, uu, vv, 4,
map->Uorder, map->Vorder);
glVertex4fv( vertex );
}
}
else if (ctx->Eval.Map2Vertex3) {
GLfloat vertex[4];
struct gl_2d_map *map = &ctx->EvalMap.Map2Vertex3;
GLfloat uu = (u - map->u1) * map->du;
GLfloat vv = (v - map->v1) * map->dv;
if (ctx->Eval.AutoNormal) {
GLfloat du[3], dv[3];
GLfloat normal[3];
_math_de_casteljau_surf(map->Points, vertex, du, dv, uu, vv, 3,
map->Uorder, map->Vorder);
CROSS_PROD(normal, du, dv);
NORMALIZE_3FV(normal);
glNormal3fv( normal );
glVertex3fv( vertex );
}
else {
_math_horner_bezier_surf(map->Points, vertex, uu, vv, 3,
map->Uorder, map->Vorder);
glVertex3fv( vertex );
}
}
}
void MultiplanarSliceRenderer::renderSlice(SliceAlignment sliceAlign, int sliceNo, tgt::TextureUnit& texUnit) {
tgtAssert(inport_.hasData(), "No volume");
const VolumeBase* volume = inport_.getData();
tgt::ivec3 volDim = volume->getDimensions();
tgt::vec3 textureSize = volume->getCubeSize();
tgt::vec3 dim = static_cast<tgt::vec3>(volDim - tgt::ivec3(1));
tgt::vec3 llb = volume->getLLF();
tgt::ivec3 permutation(0, 1, 2);
switch (sliceAlign) {
default:
case SLICE_XY:
break;
case SLICE_XZ:
permutation = tgt::ivec3(0, 2, 1);
break;
case SLICE_YZ:
permutation = tgt::ivec3(2, 1, 0);
break;
}
float s = tgt::clamp(sliceNo / (dim[permutation.z]-1), 0.f, 1.f);
tgt::vec3 ll = permuteComponents(tgt::vec3(0.f, 0.f, s), permutation);
tgt::vec3 lr = permuteComponents(tgt::vec3(1.f, 0.f, s), permutation);
tgt::vec3 ur = permuteComponents(tgt::vec3(1.f, 1.f, s), permutation);
tgt::vec3 ul = permuteComponents(tgt::vec3(0.f, 1.f, s), permutation);
if (texMode_.isSelected("2d-texture")) {
tgt::vec3 texLowerLeft = ll;//(textureMatrix_*ll).xyz();
tgt::vec3 texUpperRight = ur;//(textureMatrix_*ur).xyz();
tgt::Texture* sliceTexture = generateAlignedSliceTexture(inport_.getData(), texLowerLeft, texUpperRight);
if (sliceTexture) {
bindSliceTexture(sliceShader_, inport_.getData(), sliceTexture, &texUnit);
LGL_ERROR;
sliceShader_->setUniform("textureMatrix_", tgt::mat4::identity);
glBegin(GL_QUADS);
glTexCoord2f(0.f, 0.f);
glVertex3fv( ((ll * textureSize) + llb).elem );
if (sliceAlign == SLICE_YZ)
glTexCoord2f(0.f, 1.f);
else
glTexCoord2f(1.f, 0.f);
glVertex3fv( ((lr * textureSize) + llb).elem );
glTexCoord2f(1.f, 1.f);
glVertex3fv( ((ur * textureSize) + llb).elem );
if (sliceAlign == SLICE_YZ)
glTexCoord2f(1.f, 0.f);
else
glTexCoord2f(0.f, 1.f);
glVertex3fv( ((ul * textureSize) + llb).elem );
glEnd();
delete sliceTexture;
LGL_ERROR;
}
}
else if (texMode_.isSelected("3d-texture")) {
glBegin(GL_QUADS);
glTexCoord3fv(ll.elem);
glVertex3fv( ((ll * textureSize) + llb).elem );
glTexCoord3fv(lr.elem);
glVertex3fv( ((lr * textureSize) + llb).elem );
glTexCoord3fv(ur.elem);
glVertex3fv( ((ur * textureSize) + llb).elem );
glTexCoord3fv(ul.elem);
glVertex3fv( ((ul * textureSize) + llb).elem );
glEnd();
}
}
static void do_EvalCoord1f(GLcontext* ctx, GLfloat u)
{
/** Color Index **/
if (ctx->Eval.Map1Index)
{
GLfloat findex;
struct gl_1d_map *map = &ctx->EvalMap.Map1Index;
GLfloat uu = (u - map->u1) * map->du;
_math_horner_bezier_curve(map->Points, &findex, uu, 1, map->Order);
glIndexi( (GLint) findex );
}
/** Color **/
if (ctx->Eval.Map1Color4) {
GLfloat fcolor[4];
struct gl_1d_map *map = &ctx->EvalMap.Map1Color4;
GLfloat uu = (u - map->u1) * map->du;
_math_horner_bezier_curve(map->Points, fcolor, uu, 4, map->Order);
glColor4fv( fcolor );
}
/** Normal Vector **/
if (ctx->Eval.Map1Normal) {
GLfloat normal[3];
struct gl_1d_map *map = &ctx->EvalMap.Map1Normal;
GLfloat uu = (u - map->u1) * map->du;
_math_horner_bezier_curve(map->Points, normal, uu, 3, map->Order);
glNormal3fv( normal );
}
/** Texture Coordinates **/
if (ctx->Eval.Map1TextureCoord4) {
GLfloat texcoord[4];
struct gl_1d_map *map = &ctx->EvalMap.Map1Texture4;
GLfloat uu = (u - map->u1) * map->du;
_math_horner_bezier_curve(map->Points, texcoord, uu, 4, map->Order);
glTexCoord4fv( texcoord );
}
else if (ctx->Eval.Map1TextureCoord3) {
GLfloat texcoord[4];
struct gl_1d_map *map = &ctx->EvalMap.Map1Texture3;
GLfloat uu = (u - map->u1) * map->du;
_math_horner_bezier_curve(map->Points, texcoord, uu, 3, map->Order);
glTexCoord3fv( texcoord );
}
else if (ctx->Eval.Map1TextureCoord2) {
GLfloat texcoord[4];
struct gl_1d_map *map = &ctx->EvalMap.Map1Texture2;
GLfloat uu = (u - map->u1) * map->du;
_math_horner_bezier_curve(map->Points, texcoord, uu, 2, map->Order);
glTexCoord2fv( texcoord );
}
else if (ctx->Eval.Map1TextureCoord1) {
GLfloat texcoord[4];
struct gl_1d_map *map = &ctx->EvalMap.Map1Texture1;
GLfloat uu = (u - map->u1) * map->du;
_math_horner_bezier_curve(map->Points, texcoord, uu, 1, map->Order);
glTexCoord1fv( texcoord );
}
/** Vertex **/
if (ctx->Eval.Map1Vertex4)
{
GLfloat vertex[4];
struct gl_1d_map *map = &ctx->EvalMap.Map1Vertex4;
GLfloat uu = (u - map->u1) * map->du;
_math_horner_bezier_curve(map->Points, vertex, uu, 4, map->Order);
glVertex4fv( vertex );
}
else if (ctx->Eval.Map1Vertex3)
{
GLfloat vertex[4];
struct gl_1d_map *map = &ctx->EvalMap.Map1Vertex3;
GLfloat uu = (u - map->u1) * map->du;
_math_horner_bezier_curve(map->Points, vertex, uu, 3, map->Order);
glVertex3fv( vertex );
}
}
static GLboolean
draw_at_size(int size, int x_offset, int y_offset, GLboolean mipmapped)
{
GLfloat row_y = PAD + y_offset;
int dim, face;
int color = 0, level = 0, maxlevel, baselevel = 3;
GLuint texname;
GLboolean pass = GL_TRUE;
GLint loc;
glUseProgram(program_cube);
loc = glGetUniformLocation(program_cube, "tex");
glUniform1i(loc, 0); /* texture unit p */
/* Create the texture. */
glGenTextures(1, &texname);
glBindTexture(GL_TEXTURE_CUBE_MAP_ARB, texname);
/* For each face drawing, we want to only see that face's contents at
* that mipmap level.
*/
if (mipmapped) {
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_MIN_FILTER,
GL_NEAREST_MIPMAP_NEAREST);
} else {
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_MIN_FILTER,
GL_NEAREST);
}
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB,
GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
/* Fill in faces on each level */
for (dim = size; dim > 0; dim /= 2) {
if (test_state != STATE_PLAIN_SHADER)
color = (level) % ARRAY_SIZE(colors);
for (face = 0; face < 6; face++) {
set_face_image(level, cube_face_targets[face],
dim, color);
if (test_state == STATE_PLAIN_SHADER)
color = (color + 1) % ARRAY_SIZE(colors);
}
if (!mipmapped)
break;
level++;
}
maxlevel = level;
if (maxlevel >= ARRAY_SIZE(colors))
maxlevel = ARRAY_SIZE(colors) - 1;
glEnable(GL_TEXTURE_CUBE_MAP_ARB);
color = 0;
level = 0;
if (test_state == STATE_LOD_BIAS_SHADER)
level = baselevel;
for (dim = size; dim > 0; dim /= 2) {
GLfloat row_x = PAD + x_offset;
if (test_state == STATE_LOD_SHADER)
level = baselevel;
for (face = 0; face < 6; face++) {
GLfloat base_x = row_x + face * (max_size + PAD);
GLfloat base_y = row_y;
if (test_state != STATE_PLAIN_SHADER) {
color = level;
if (color >= ARRAY_SIZE(colors))
color = ARRAY_SIZE(colors) - 1;
}
glBegin(GL_QUADS);
glTexCoord3fv(cube_face_texcoords[face][0]);
glVertex2f(base_x, base_y);
glTexCoord3fv(cube_face_texcoords[face][1]);
glVertex2f(base_x + dim, base_y);
glTexCoord3fv(cube_face_texcoords[face][2]);
glVertex2f(base_x + dim, base_y + dim);
glTexCoord3fv(cube_face_texcoords[face][3]);
glVertex2f(base_x, base_y + dim);
glEnd();
if (dim > 2) {
pass = test_results(base_x, base_y,
dim, level, face,
mipmapped,
color, maxlevel) && pass;
}
if (test_state == STATE_PLAIN_SHADER)
color = (color + 1) % ARRAY_SIZE(colors);
}
if (!mipmapped)
break;
row_y += dim + PAD;
level++;
if (test_state != STATE_PLAIN_SHADER)
if (level > maxlevel)
level = maxlevel;
}
glUseProgram(0);
glDeleteTextures(1, &texname);
return pass;
}
void PolygonBackground::clear(DrawEnv *pEnv)
{
#if !defined(OSG_OGL_COREONLY) || defined(OSG_CHECK_COREONLY)
if(pEnv->getPixelWidth() == 0 ||
pEnv->getPixelHeight() == 0 )
{
FWARNING(("Port has zero size: nothing to render to!\n"));
return;
}
if(getMFPositions()->size() == 0 ||
getMFPositions()->size() != getMFTexCoords()->size())
{
FWARNING(("PolygonBackground::clear: positions and texcoords have "
"different/ invalid sizes (%d vs. %d)!\n",
getMFPositions()->size(), getMFTexCoords()->size()));
return;
}
Int32 bit = getClearStencilBit(); // 0x0
if(bit >= 0)
{
glClearStencil(bit);
glClear(GL_COLOR_BUFFER_BIT |
GL_DEPTH_BUFFER_BIT |
GL_STENCIL_BUFFER_BIT);
}
else
{
glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
}
glPushAttrib(GL_ALL_ATTRIB_BITS);
glDisable(GL_DEPTH_TEST);
glDepthFunc(GL_ALWAYS);
if(getCleanup())
glDepthMask(GL_FALSE);
Real32 aspectX = 1.0f, aspectY = 1.0f;
if(getAspectHeight() != 0 && getAspectWidth() != 0)
{
aspectX = (Real32(pEnv->getPixelHeight()) / getAspectHeight()) /
(Real32(pEnv->getPixelWidth ()) / getAspectWidth ());
}
Real32 sFac = getScale() > 0 ? getScale() : 1.0f;
UInt32 fullWidth;
UInt32 fullHeight;
if(!getTile())
{
beginOrthoRender(pEnv, getNormalizedX(), getNormalizedY(),
fullWidth, fullHeight );
Real32 t = 0;
if(getAspectHeight() != 0 && getAspectWidth() != 0 &&
fullHeight != 0 && fullHeight != 0 )
{
aspectX = (Real32(fullHeight) / getAspectHeight()) /
(Real32(fullWidth ) / getAspectWidth ());
t = Real32(fullWidth) * (1.0f - aspectX) * 0.5f;
t *= Real32(pEnv->getPixelWidth()) / fullWidth;
}
glTranslatef(t, 0.0f, 0.0f);
glScalef (aspectX, aspectY, 1.0f);
Real32 tW = (1.0f - sFac) * 0.5f * Real32(pEnv->getPixelWidth ());
Real32 tH = (1.0f - sFac) * 0.5f * Real32(pEnv->getPixelHeight());
glTranslatef(tW, tH, 0.0f);
glScalef (sFac, sFac, 1.0f);
}
else
{
glScalef(sFac, sFac, 1.0f);
glScalef(aspectX, aspectY, 1.0f);
beginOrthoRender(pEnv, getNormalizedX(), getNormalizedY(),
fullWidth, fullHeight );
}
getMaterial()->getState()->activate(pEnv);
const Vec3f *tc = &getMFTexCoords()->front();
const Pnt2f *pos = &getMFPositions()->front();
glBegin(GL_POLYGON);
for (UInt16 i=0; i < getMFPositions()->size(); i++)
{
glTexCoord3fv( tc[i].getValues());
glVertex2fv (pos[i].getValues());
}
glEnd();
getMaterial()->getState()->deactivate(pEnv);
glScalef(1, 1, 1);
if(getCleanup())
{
if(bit >= 0)
{
glClear(GL_DEPTH_BUFFER_BIT | GL_STENCIL_BUFFER_BIT);
}
else
{
glClear(GL_DEPTH_BUFFER_BIT);
}
}
endOrthoRender(pEnv);
glPopAttrib();
#endif
}
