Exemplo n.º 1
0
void App::octreeHandler(const lcm::ReceiveBuffer* rbuf, const std::string& channel, const  drc::map_octree_t* msg){
  std::cout << "MAP_OCTREE received\n";

  // TODO: Currently not handling transform, assuming identity transform

  std::stringstream datastream;
  datastream.write((const char*) msg->data.data(), msg->num_bytes);
  tree_ = new octomap::OcTree(1); //resolution will be set by data from message
  tree_->readBinary(datastream);

  std::stringstream s;
  s <<  "/tmp/map_octomap.bt" ;
  printf("Saving MAP_OCTREE to: %s\n", s.str().c_str());
  tree_->writeBinary(s.str().c_str());

  exit(-1);
}
Exemplo n.º 2
0
int main(int argc, char** argv) {

  if (argc != 2){
    std::cerr << "Error: you need to specify a testfile (.bt) as argument to read" << std::endl;
    return 1; // exit 1 means failure
  }

  std::cout << "Testing empty OcTree...\n";
  //empty tree
  {
    OcTree emptyTree(0.999);
    EXPECT_EQ(emptyTree.size(), 0);
    EXPECT_TRUE(emptyTree.writeBinary("empty.bt"));
    EXPECT_TRUE(emptyTree.write("empty.ot"));

    OcTree emptyReadTree(0.2);
    EXPECT_TRUE(emptyReadTree.readBinary("empty.bt"));
    EXPECT_EQ(emptyReadTree.size(), 0);
    EXPECT_TRUE(emptyTree == emptyReadTree);

    
    AbstractOcTree* readTreeAbstract = AbstractOcTree::read("empty.ot");
    EXPECT_TRUE(readTreeAbstract);
    OcTree* readTreeOt = dynamic_cast<OcTree*>(readTreeAbstract);
    EXPECT_TRUE(readTreeOt);  
    EXPECT_EQ(readTreeOt->size(), 0);
    EXPECT_TRUE(emptyTree == *readTreeOt);
    delete readTreeOt;
  }

  std::cout << "Testing reference OcTree from file ...\n";
  string filename = string(argv[1]);

  {
    string filenameOt = "test_io_file.ot";
    string filenameBtOut = "test_io_file.bt";
    string filenameBtCopyOut = "test_io_file_copy.bt";

    // read reference tree from input file
    OcTree tree (0.1);
    EXPECT_TRUE (tree.readBinary(filename));

    std::cout << "    Copy Constructor / assignment / ==\n";
    // test copy constructor / assignment:
    OcTree* treeCopy = new OcTree(tree);
    EXPECT_TRUE(tree == *treeCopy);
    EXPECT_TRUE(treeCopy->writeBinary(filenameBtCopyOut));

    // change a tree property, trees must be different afterwards
    treeCopy->setResolution(tree.getResolution()*2.0);
    EXPECT_FALSE(tree == *treeCopy);
    treeCopy->setResolution(tree.getResolution());
    EXPECT_TRUE(tree == *treeCopy);

    // flip one value, trees must be different afterwards:
    point3d pt(0.5, 0.5, 0.5);
    OcTreeNode* node = treeCopy->search(pt);
    if (node && treeCopy->isNodeOccupied(node))
      treeCopy->updateNode(pt, false);
    else
      treeCopy->updateNode(pt, true);

    EXPECT_FALSE(tree == *treeCopy);


    delete treeCopy;

    std::cout << "    Swap\n";
    // test swap:
    OcTree emptyT(tree.getResolution());
    OcTree emptySw(emptyT);
    OcTree otherSw(tree);
    emptySw.swapContent(otherSw);
    EXPECT_FALSE(emptyT == emptySw);
    EXPECT_TRUE(emptySw == tree);
    EXPECT_TRUE(otherSw == emptyT);


    // write again to bt, read & compare
    EXPECT_TRUE(tree.writeBinary(filenameBtOut));
    OcTree readTreeBt(0.1);
    EXPECT_TRUE(readTreeBt.readBinary(filenameBtOut));
    EXPECT_TRUE(tree == readTreeBt);

    std::cout <<"    Write to .ot / read through AbstractOcTree\n";
    // now write to .ot, read & compare
    EXPECT_TRUE(tree.write(filenameOt));
    
    AbstractOcTree* readTreeAbstract = AbstractOcTree::read(filenameOt);
    EXPECT_TRUE(readTreeAbstract);

    OcTree* readTreeOt = dynamic_cast<OcTree*>(readTreeAbstract);
    EXPECT_TRUE(readTreeOt);
    EXPECT_TRUE(tree == *readTreeOt);

    // sanity test for "==": flip one node, compare again
    point3d coord(0.1f, 0.1f, 0.1f);
    node = readTreeOt->search(coord);
    if (node && readTreeOt->isNodeOccupied(node))
      readTreeOt->updateNode(coord, false);
    else
      readTreeOt->updateNode(coord, true);

    EXPECT_FALSE(tree == *readTreeOt);
    
    delete readTreeOt;
  }

  // Test for tree headers and IO factory registry (color)
  {
    std::cout << "Testing ColorOcTree...\n";

    double res = 0.02;
    std::string filenameColor = "test_io_color_file.ot";
    ColorOcTree colorTree(res);
    EXPECT_EQ(colorTree.getTreeType(), "ColorOcTree");
    ColorOcTreeNode* colorNode = colorTree.updateNode(point3d(0.0, 0.0, 0.0), true);
    ColorOcTreeNode::Color color_red(255, 0, 0);
    colorNode->setColor(color_red);
    colorTree.setNodeColor(0.0, 0.0, 0.0, 255, 0, 0);
    colorTree.updateNode(point3d(0.1f, 0.1f, 0.1f), true);
    colorTree.setNodeColor(0.1f, 0.1f, 0.1f, 0, 0, 255);

    EXPECT_TRUE(colorTree.write(filenameColor));
    AbstractOcTree* readTreeAbstract = AbstractOcTree::read(filenameColor);
    EXPECT_TRUE(readTreeAbstract);
    EXPECT_EQ(colorTree.getTreeType(),  readTreeAbstract->getTreeType());
    ColorOcTree* readColorTree = dynamic_cast<ColorOcTree*>(readTreeAbstract);
    EXPECT_TRUE(readColorTree);
    EXPECT_TRUE(colorTree == *readColorTree);
    colorNode = colorTree.search(0.0, 0.0, 0.0);
    EXPECT_TRUE(colorNode);
    EXPECT_EQ(colorNode->getColor(), color_red);
    delete readColorTree;
  }

  // Test for tree headers and IO factory registry (stamped)
  {
    std::cout << "Testing OcTreeStamped...\n";
    double res = 0.05;
    std::string filenameStamped = "test_io_stamped_file.ot";
    OcTreeStamped stampedTree(res);
    EXPECT_EQ(stampedTree.getTreeType(), "OcTreeStamped");
    // TODO: add / modify some stamped nodes
    //ColorOcTreeNode* colorNode = colorTree.updateNode(point3d(0.0, 0.0, 0.0), true);
    //ColorOcTreeNode::Color color_red(255, 0, 0);
    //colorNode->setColor(color_red);
    //colorTree.setNodeColor(0.0, 0.0, 0.0, 255, 0, 0);
    //colorTree.updateNode(point3d(0.1f, 0.1f, 0.1f), true);
    //colorTree.setNodeColor(0.1f, 0.1f, 0.1f, 0, 0, 255);

    EXPECT_TRUE(stampedTree.write(filenameStamped));
    AbstractOcTree* readTreeAbstract = AbstractOcTree::read(filenameStamped);
    EXPECT_TRUE(readTreeAbstract);
    EXPECT_EQ(stampedTree.getTreeType(), readTreeAbstract->getTreeType());
    OcTreeStamped* readStampedTree = dynamic_cast<OcTreeStamped*>(readTreeAbstract);
    EXPECT_TRUE(readStampedTree);
    EXPECT_TRUE(stampedTree == *readStampedTree);
    //colorNode = colorTree.search(0.0, 0.0, 0.0);
    //EXPECT_TRUE(colorNode);
    //EXPECT_EQ(colorNode->getColor(), color_red);    
    
    delete readStampedTree;    
  }


  std::cerr << "Test successful.\n";
  return 0;
}
Exemplo n.º 3
0
int main(int argc, char** argv) {
  string inputFilename = "";
  string outputFilename = "";

  if (argc < 2 || argc > 3 || (argc > 1 && strcmp(argv[1], "-h") == 0)){
    printUsage(argv[0]);
  }

  inputFilename = std::string(argv[1]);
  if (argc == 3)
    outputFilename = std::string(argv[2]);
  else{
    outputFilename = inputFilename + ".ot";
  }


  cout << "\nReading OcTree file\n===========================\n";
  std::ifstream file(inputFilename.c_str(), std::ios_base::in |std::ios_base::binary);

  if (!file.is_open()){
    OCTOMAP_ERROR_STR("Filestream to "<< inputFilename << " not open, nothing read.");
    exit(-1);
  }

  std::istream::pos_type streampos = file.tellg();
  AbstractOcTree* tree;

  // reading binary:
  if (inputFilename.length() > 3 && (inputFilename.compare(inputFilename.length()-3, 3, ".bt") == 0)){
    OcTree* binaryTree = new OcTree(0.1);

    if (binaryTree->readBinary(file) && binaryTree->size() > 1)
      tree = binaryTree;
    else {
      OCTOMAP_ERROR_STR("Could not detect binary OcTree format in file.");
      exit(-1);

    }
  } else {
    tree = AbstractOcTree::read(file);
    if (!tree){
      OCTOMAP_WARNING_STR("Could not detect OcTree in file, trying legacy formats.");
      // TODO: check if .cot extension, try old format only then
      // reset and try old ColorOcTree format:
      file.clear(); // clear eofbit of istream
      file.seekg(streampos);
      ColorOcTree* colorTree = new ColorOcTree(0.1);
      colorTree->readData(file);
      if (colorTree->size() > 1 && file.good()){
        OCTOMAP_WARNING_STR("Detected Binary ColorOcTree to convert. \nPlease check and update the new file header (resolution will likely be wrong).");
        tree = colorTree;
      } else{
        delete colorTree;
        std::cerr << "Error reading from file " << inputFilename << std::endl;
        exit(-1);
      }
    }


  }

  // close filestream
  file.close();


  if (outputFilename.length() > 3 && (outputFilename.compare(outputFilename.length()-3, 3, ".bt") == 0)){
    std::cerr << "Writing binary (BonsaiTree) file" << std::endl;
    AbstractOccupancyOcTree* octree = dynamic_cast<AbstractOccupancyOcTree*>(tree);
    if (octree){
      if (!octree->writeBinary(outputFilename)){
        std::cerr << "Error writing to " << outputFilename << std::endl;
        exit(-2);
      }
    } else {
      std::cerr << "Error: Writing to .bt is not supported for this tree type: " << tree->getTreeType() << std::endl;
      exit(-2);
    }
  } else{
    std::cerr << "Writing general OcTree file" << std::endl;
    if (!tree->write(outputFilename)){
      std::cerr << "Error writing to " << outputFilename << std::endl;
      exit(-2);
    }
  }





  std::cout << "Finished writing to " << outputFilename << std::endl;
  exit(0);

}