Node *AbsoluteTransformator::toAbsolute(Node *relativeRoot, glm::mat4 transform) {
if (relativeRoot == nullptr) new Group();
glm::mat4 newTransform = relativeRoot->transform() * transform;
Node *absoluteRoot;
if (relativeRoot->children().size() > 0) {
Group *absoluteGroup = new Group();
for (auto child : relativeRoot->children()) {
Node *absoluteChild = toAbsolute(static_cast<Node *>(child), newTransform);
if (absoluteChild != nullptr) {
absoluteGroup->append(absoluteChild);
}
}
absoluteRoot = absoluteGroup;
} else {
PolygonalDrawable *poly = dynamic_cast<PolygonalDrawable *>(relativeRoot);
if (poly == nullptr) {
absoluteRoot = new Group();
} else {
auto relativeGeometry = poly->geometry();
auto vertices = relativeGeometry->copyVertices();
auto absoluteGeometry = new TriangleObject();
p_TriangleList triangles = absoluteGeometry->triangles();
for (auto index : relativeGeometry->indices()) {
glm::vec4 homogenous = newTransform * glm::vec4(vertices.at(index), 1.0f);
triangles->push_back(homogenous.xyz * (1 / homogenous.w));
}
absoluteRoot = absoluteGeometry;
}
}
absoluteRoot->setName(relativeRoot->name());
absoluteRoot->setReferenceFrame(Node::RF_Absolute);
return absoluteRoot;
}
PolygonalDrawable * AssimpLoader::parseMesh(const aiMesh & mesh) const
{
auto geometry = std::make_shared<PolygonalGeometry>(m_registry);
const bool usesNormalIndices(mesh.mNormals != NULL);
for (unsigned int i = 0; i < mesh.mNumVertices; i++) {
glm::vec3 vector(
mesh.mVertices[i].x, mesh.mVertices[i].y, mesh.mVertices[i].z
);
geometry->setVertex(i, vector);
}
if (usesNormalIndices) {
for (unsigned int i = 0; i < mesh.mNumVertices; i++) {
glm::vec3 vector(
mesh.mNormals[i].x, mesh.mNormals[i].y, mesh.mNormals[i].z
);
geometry->setNormal(i, vector);
}
}
unsigned int currentIndex = 0;
for (unsigned int i = 0; i < mesh.mNumFaces; i++) {
if (mesh.mFaces[i].mNumIndices != 3)
qCritical("Ignore polygon with num vertices != 3 (only triangles are supported).");
else
for (unsigned int j = 0; j < mesh.mFaces[i].mNumIndices; j++)
geometry->setIndex(currentIndex++, mesh.mFaces[i].mIndices[j]);
}
if (!usesNormalIndices)
geometry->retrieveNormals();
PolygonalDrawable * drawable = new PolygonalDrawable(mesh.mName.C_Str());
drawable->setGeometry(geometry);
drawable->setMode(GL_TRIANGLES);
return drawable;
}
PolygonalDrawable * ObjIO::createPolygonalDrawable(
const ObjObject & object
, const ObjGroup & group)
{
if(group.vis.empty())
return NULL;
// TODO: this should test if all consecutive offsets are equal 3.
// The current expression could return false positives.
if(group.vis.size() / 3 != group.foffs.size())
{
qCritical("Ignore polygon with num vertices != 3 (only triangles are supported).");
return NULL;
}
const bool usesTexCoordIndices(!group.vtis.empty());
const bool usesNormalIndices(!group.vnis.empty());
PolygonalDrawable * drawable = new PolygonalDrawable();
const GLuint size(static_cast<GLuint>(group.vis.size()));
for(GLuint i = 0; i < size; ++i)
{
// add vertex and its new index based on obj index
// TODO: make use of vertex reuse!
drawable->indices().push_back(i);
drawable->vertices().push_back(object.vs[group.vis[i]]);
if(usesTexCoordIndices)
drawable->texcs().push_back(object.vts[group.vtis[i]]);
if(usesNormalIndices)
drawable->normals().push_back(object.vns[group.vnis[i]]);
}
// TODO: support other modes here!
drawable->setMode(GL_TRIANGLES);
if(!usesNormalIndices)
drawable->retrieveNormals();
return drawable;
}
void HalfEdgeStructure::setup(PolygonalDrawable & drawable)
{
if(drawable.indices().isEmpty())
return;
const int nTriangles(drawable.indices().size() / 3);
m_faces.resize(nTriangles);
// TODO: there is strict triangle support only...
assert(drawable.indices().size() % 3 == 0);
// Map of edges (given by two indices) -> opposite half-edge
typedef std::map<std::pair<QVector3D const *, QVector3D const *>, HalfEdge*> t_opp_map;
t_opp_map opp;
const int he_count = nTriangles * 3;
m_halfEdges.resize(he_count);
for(int k = 0; k < nTriangles; k++)
{
m_faces[k].he = &m_halfEdges[k * 3];
for (int i = 0; i < 3; ++i)
{
const int j(k * 3 + i);
m_halfEdges[j].prev = &m_halfEdges[(i == 0) ? j + 2 : j - 1];
m_halfEdges[j].next = &m_halfEdges[(i == 2) ? j - 2 : j + 1];
m_halfEdges[j].opp = NULL;
m_halfEdges[j].face = &m_faces[k];
const int l(drawable.indices()[j]);
m_halfEdges[j].vertex = &(drawable.vertices()[l]);
m_halfEdges[j].normal = drawable.normals()[l];
}
// set opposite-pointers
for (int i = 0; i < 3; ++i)
{
const int j(k * 3 + i);
QVector3D const * v0 = m_halfEdges[j].vertex;
QVector3D const * v1 = m_halfEdges[j].next->vertex;
// Check if opposite half-edge is already stored
t_opp_map::iterator p = opp.find(t_opp_map::key_type(v0, v1));
if(p == opp.end())
{ // no: Add half-edge in opposite direction
opp[t_opp_map::key_type(v1, v0)] = &m_halfEdges[j];
}
else
{
// yes: Set opposite-pointers of both half-edges
p->second->opp = &m_halfEdges[j];
m_halfEdges[j].opp = p->second;
opp.erase(p);
}
}
}
calculatePerFaceNormals();
calculatePerVertexNormals(0.f);
}
