void VTKMeshFileExporter::execute() { if(mFilename == "") throw Exception("No filename given to the VTKMeshFileExporter"); Mesh::pointer surface = getStaticInputData<Mesh>(); // Get transformation AffineTransformation::pointer transform = SceneGraph::getAffineTransformationFromData(surface); std::ofstream file(mFilename.c_str()); if(!file.is_open()) throw Exception("Unable to open the file " + mFilename); // Write header file << "# vtk DataFile Version 3.0\n" "vtk output\n" "ASCII\n" "DATASET POLYDATA\n"; // Write vertices MeshAccess::pointer access = surface->getMeshAccess(ACCESS_READ); std::vector<MeshVertex> vertices = access->getVertices(); file << "POINTS " << vertices.size() << " float\n"; for(int i = 0; i < vertices.size(); i++) { MeshVertex vertex = vertices[i]; vertex.position = (transform->matrix()*vertex.position.homogeneous()).head(3); file << vertex.position.x() << " " << vertex.position.y() << " " << vertex.position.z() << "\n"; } // Write triangles std::vector<Vector3ui> triangles = access->getTriangles(); file << "POLYGONS " << surface->getNrOfTriangles() << " " << surface->getNrOfTriangles()*4 << "\n"; for(int i = 0; i < triangles.size(); i++) { Vector3ui triangle = triangles[i]; file << "3 " << triangle.x() << " " << triangle.y() << " " << triangle.z() << "\n"; } // Write normals file << "POINT_DATA " << vertices.size() << "\n"; file << "NORMALS Normals float\n"; for(int i = 0; i < vertices.size(); i++) { MeshVertex vertex = vertices[i]; // Transform it vertex.normal = transform->linear()*vertex.normal; // Normalize it float length = vertex.normal.norm(); if(length == 0) { // prevent NaN situations file << "0 1 0\n"; } else { file << (vertex.normal.x()/length) << " " << (vertex.normal.y()/length) << " " << (vertex.normal.z()/length) << "\n"; } } file.close(); }
void MeshRenderer::draw2D( cl::BufferGL PBO, uint width, uint height, Eigen::Transform<float, 3, Eigen::Affine> pixelToViewportTransform, float PBOspacing, Vector2f translation ) { boost::lock_guard<boost::mutex> lock(mMutex); OpenCLDevice::pointer device = getMainDevice(); cl::CommandQueue queue = device->getCommandQueue(); std::vector<cl::Memory> v; v.push_back(PBO); queue.enqueueAcquireGLObjects(&v); // Map would probably be better here, but doesn't work on NVIDIA, segfault surprise! //float* pixels = (float*)queue.enqueueMapBuffer(PBO, CL_TRUE, CL_MAP_WRITE, 0, width*height*sizeof(float)*4); boost::shared_array<float> pixels(new float[width*height*sizeof(float)*4]); queue.enqueueReadBuffer(PBO, CL_TRUE, 0, width*height*4*sizeof(float), pixels.get()); boost::unordered_map<uint, Mesh::pointer>::iterator it; for(it = mMeshToRender.begin(); it != mMeshToRender.end(); it++) { Mesh::pointer mesh = it->second; if(mesh->getDimensions() != 2) // Mesh must be 2D continue; Color color = mDefaultColor; ProcessObjectPort port = getInputPort(it->first); if(mInputColors.count(port) > 0) { color = mInputColors[port]; } MeshAccess::pointer access = mesh->getMeshAccess(ACCESS_READ); std::vector<VectorXui> lines = access->getLines(); std::vector<MeshVertex> vertices = access->getVertices(); // Draw each line for(int i = 0; i < lines.size(); ++i) { Vector2ui line = lines[i]; Vector2f a = vertices[line.x()].getPosition(); Vector2f b = vertices[line.y()].getPosition(); Vector2f direction = b - a; float lengthInPixels = ceil(direction.norm() / PBOspacing); // Draw the line for(int j = 0; j <= lengthInPixels; ++j) { Vector2f positionInMM = a + direction*((float)j/lengthInPixels); Vector2f positionInPixels = positionInMM / PBOspacing; int x = round(positionInPixels.x()); int y = round(positionInPixels.y()); y = height - 1 - y; if(x < 0 || y < 0 || x >= width || y >= height) continue; pixels[4*(x + y*width)] = color.getRedValue(); pixels[4*(x + y*width) + 1] = color.getGreenValue(); pixels[4*(x + y*width) + 2] = color.getBlueValue(); } } } //queue.enqueueUnmapMemObject(PBO, pixels); queue.enqueueWriteBuffer(PBO, CL_TRUE, 0, width*height*4*sizeof(float), pixels.get()); queue.enqueueReleaseGLObjects(&v); }