예제 #1
0
TEST(PressureTest, LinearEquationSetup_Complex)
{
  glm::ivec2 size(50);

  FluidSim sim;
  sim.initialize(1.0f, size.x, size.y);
  sim.set_boundary(boundary_phi);

  AddParticles(size, sim, complex_boundary_phi);

  sim.add_force(0.01f);

  Velocity velocity(*device, size);
  Texture solidPhi(*device, size.x, size.y, vk::Format::eR32Sfloat);
  Texture liquidPhi(*device, size.x, size.y, vk::Format::eR32Sfloat);

  BuildInputs(*device, size, sim, velocity, solidPhi, liquidPhi);

  LinearSolver::Data data(*device, size, VMA_MEMORY_USAGE_CPU_ONLY);
  Buffer<glm::ivec2> valid(*device, size.x * size.y, VMA_MEMORY_USAGE_CPU_ONLY);

  Pressure pressure(*device, 0.01f, size, data, velocity, solidPhi, liquidPhi, valid);

  pressure.BuildLinearEquation();
  device->Handle().waitIdle();

  CheckDiagonal(size, data.Diagonal, sim, 1e-3f);  // FIXME can we reduce error tolerance?
  CheckWeights(size, data.Lower, sim, 1e-3f);      // FIXME can we reduce error tolerance?
  CheckDiv(size, data.B, sim);
}
예제 #2
0
//Main testing code
//-------------
int main(int argc, char **argv)
{
   
   //Setup viewer stuff
   Gluvi::init("GFM Free Surface Liquid Solver with Static Variational Boundaries", &argc, argv);
   Gluvi::camera=&cam;
   Gluvi::userDisplayFunc=display;
   Gluvi::userMouseFunc=mouse;
   Gluvi::userDragFunc=drag;
   glClearColor(1,1,1,1);
   
   glutTimerFunc(1000, timer, 0);
   
   //Set up the simulation
   sim.initialize(grid_width, grid_resolution, grid_resolution);
   
   //set up a circle boundary
   sim.set_boundary(boundary_phi);
   
   //Stick some liquid particles in the domain
   for(int i = 0; i < sqr(grid_resolution); ++i) {
      float x = randhashf(i*2, 0,1);
      float y = randhashf(i*2+1, 0,1);
      Vec2f pt(x,y);
      if(boundary_phi(pt) > 0 && pt[0] > 0.5)
         sim.add_particle(pt);
   }

   Gluvi::run();

   return 0;
}
예제 #3
0
TEST(LinearSolverTests, IncompletePoisson_Simple_PCG)
{
  glm::ivec2 size(50);

  FluidSim sim;
  sim.initialize(1.0f, size.x, size.y);
  sim.set_boundary(boundary_phi);

  AddParticles(size, sim, boundary_phi);

  sim.add_force(0.01f);
  sim.compute_phi();
  sim.extrapolate_phi();
  sim.apply_projection(0.01f);

  LinearSolver::Data data(*device, size, VMA_MEMORY_USAGE_CPU_ONLY);

  BuildLinearEquation(size, data.Diagonal, data.Lower, data.B, sim);

  IncompletePoisson preconditioner(*device, size);

  LinearSolver::Parameters params(LinearSolver::Parameters::SolverType::Iterative, 1000, 1e-5f);
  ConjugateGradient solver(*device, size, preconditioner);

  solver.Bind(data.Diagonal, data.Lower, data.B, data.X);
  solver.Solve(params);

  device->Queue().waitIdle();

  CheckPressure(size, sim.pressure, data.X, 1e-5f);

  std::cout << "Solved with number of iterations: " << params.OutIterations << std::endl;
}
예제 #4
0
TEST(LinearSolverTests, LocalGaussSeidel)
{
  glm::ivec2 size(16);  // maximum size

  FluidSim sim;
  sim.initialize(1.0f, size.x, size.y);
  sim.set_boundary(boundary_phi);

  AddParticles(size, sim, boundary_phi);

  sim.add_force(0.01f);
  sim.compute_phi();
  sim.extrapolate_phi();
  sim.apply_projection(0.01f);

  LinearSolver::Data data(*device, size, VMA_MEMORY_USAGE_CPU_ONLY);

  BuildLinearEquation(size, data.Diagonal, data.Lower, data.B, sim);

  LocalGaussSeidel solver(*device, size);

  solver.Bind(data.Diagonal, data.Lower, data.B, data.X);
  device->Execute([&](vk::CommandBuffer commandBuffer) { solver.Record(commandBuffer); });

  device->Queue().waitIdle();

  CheckPressure(size, sim.pressure, data.X, 1e-3f);
}
예제 #5
0
TEST(LinearSolverTests, Multigrid_Simple_PCG)
{
  glm::ivec2 size(64);

  FluidSim sim;
  sim.initialize(1.0f, size.x, size.y);
  sim.set_boundary(boundary_phi);

  AddParticles(size, sim, boundary_phi);

  sim.add_force(0.01f);
  sim.compute_phi();
  sim.extrapolate_phi();
  sim.apply_projection(0.01f);

  LinearSolver::Data data(*device, size, VMA_MEMORY_USAGE_CPU_ONLY);

  Velocity velocity(*device, size);
  Texture liquidPhi(*device, size.x, size.y, vk::Format::eR32Sfloat);
  Texture solidPhi(*device, size.x, size.y, vk::Format::eR32Sfloat);
  Buffer<glm::ivec2> valid(*device, size.x * size.y, VMA_MEMORY_USAGE_CPU_ONLY);

  SetSolidPhi(*device, size, solidPhi, sim, (float)size.x);
  SetLiquidPhi(*device, size, liquidPhi, sim, (float)size.x);

  BuildLinearEquation(size, data.Diagonal, data.Lower, data.B, sim);

  Pressure pressure(*device, 0.01f, size, data, velocity, solidPhi, liquidPhi, valid);

  Multigrid preconditioner(*device, size, 0.01f);
  preconditioner.BuildHierarchiesBind(pressure, solidPhi, liquidPhi);

  LinearSolver::Parameters params(LinearSolver::Parameters::SolverType::Iterative, 1000, 1e-5f);
  ConjugateGradient solver(*device, size, preconditioner);

  solver.Bind(data.Diagonal, data.Lower, data.B, data.X);

  preconditioner.BuildHierarchies();
  solver.Solve(params);

  device->Queue().waitIdle();

  CheckPressure(size, sim.pressure, data.X, 1e-5f);

  std::cout << "Solved with number of iterations: " << params.OutIterations << std::endl;
}
예제 #6
0
TEST(PressureTest, Project_Complex)
{
  glm::ivec2 size(50);

  FluidSim sim;
  sim.initialize(1.0f, size.x, size.y);
  sim.set_boundary(boundary_phi);

  AddParticles(size, sim, boundary_phi);

  sim.add_force(0.01f);

  Velocity velocity(*device, size);
  Texture solidPhi(*device, size.x, size.y, vk::Format::eR32Sfloat);
  Texture liquidPhi(*device, size.x, size.y, vk::Format::eR32Sfloat);

  BuildInputs(*device, size, sim, velocity, solidPhi, liquidPhi);

  LinearSolver::Data data(*device, size, VMA_MEMORY_USAGE_CPU_ONLY);

  std::vector<float> computedPressureData(size.x * size.y, 0.0f);
  for (std::size_t i = 0; i < computedPressureData.size(); i++)
  {
    computedPressureData[i] = (float)sim.pressure[i];
  }
  CopyFrom(data.X, computedPressureData);

  Buffer<glm::ivec2> valid(*device, size.x * size.y, VMA_MEMORY_USAGE_CPU_ONLY);

  Pressure pressure(*device, 0.01f, size, data, velocity, solidPhi, liquidPhi, valid);

  pressure.ApplyPressure();
  device->Handle().waitIdle();

  CheckVelocity(*device, size, velocity, sim);
  CheckValid(size, sim, valid);
}
예제 #7
0
int main(int argc, char** argv)
{
    bool run = GL_TRUE;

    if(!glfwInit())
    {
        exit(EXIT_FAILURE);
    }

    if(!glfwOpenWindow(windows_width, windows_height, 8, 8, 8, 8, 24, 0, GLFW_WINDOW))
    {
        glfwTerminate();
        exit(EXIT_FAILURE);
    }

    glewInit();
    if (!glewIsSupported( "GL_VERSION_2_0 "
                          "GL_ARB_pixel_buffer_object"
                        )) {
        fprintf( stderr, "ERROR: Support for necessary OpenGL extensions missing.");
        fflush( stderr);
        return false;
    }

    //glfwSetKeyCallback(Viewer::keyCallback);
    //glfwSetMouseButtonCallback(Viewer::mouseButtonCallback);
    //glfwSetMousePosCallback(Viewer::mousePosCallback);
    //glfwSetMouseWheelCallback(Viewer::mouseWheelCallback);

    glClearColor(0.0f, 0.0f, 0.0f, 1.0f);
    glEnable(GL_DEPTH_TEST);
    glDepthFunc(GL_LEQUAL);

    FluidSim sph;
    sph.initialize();
    sph.resetFrameNum();
    sph.outputObj(true);

    vec3 center(0.0f, -0.15f, 0.0f);
    Viewer::camera()->setFocal(center.x, center.y, center.z);
    Viewer::camera()->resetLookAt();

    old_now = glfwGetTime();
    while(run)
    {
        unsigned int frame_num = sph.getFrameNum();
        if(frame_num > 450)
            exit(0);
        Viewer::camera()->aim();

        printf("frame number: %d\n", frame_num);
        sph.compute(0.004);
        sph.draw();

        utils::drawAxis();
        utils::grabScreen(windows_width, windows_height, sph.getFrameNum());
        now = glfwGetTime();
        char fpsInfo[256];
        sprintf(fpsInfo, "Frame: %u. Time cost per frame: %f", frame_num, now - old_now);
        old_now = now;
        glfwSetWindowTitle(fpsInfo);

        glfwSwapBuffers();

        run = !glfwGetKey(GLFW_KEY_ESC) && glfwGetWindowParam(GLFW_OPENED);
    }

    glfwTerminate();
    exit(EXIT_SUCCESS);
}