// ------------------------------------------------------
// MAIN
// ------------------------------------------------------
int main()
{
try
{
TestRANSACPlanes();
cout << endl << "Now running detection of lines..." << endl << endl;
TestRANSACLines();
win.clear();
return 0;
} catch (std::exception &e)
{
std::cout << "MRPT exception caught: " << e.what() << std::endl;
return -1;
}
catch (...)
{
printf("Untyped exception!!");
return -1;
}
}
// ------------------------------------------------------
// TestRANSACPlanes
// ------------------------------------------------------
void TestRANSACPlanes()
{
randomGenerator.randomize();
// Generate random points:
// ------------------------------------
const size_t N_PLANES = 3;
const size_t N_plane = 300;
const size_t N_noise = 300;
const double PLANE_EQ[N_PLANES][4]={
{ 1,-1,1, -2 },
{ 1,+1.5, 1, -1 },
{ 0,-1,1, +2 } };
CVectorDouble xs,ys,zs;
for (size_t p=0;p<N_PLANES;p++)
{
for (size_t i=0;i<N_plane;i++)
{
const double xx = randomGenerator.drawUniform(-3,3) + 5*cos(0.4*p);
const double yy = randomGenerator.drawUniform(-3,3) + 5*sin(0.4*p);
const double zz = -(PLANE_EQ[p][3]+PLANE_EQ[p][0]*xx+PLANE_EQ[p][1]*yy)/PLANE_EQ[p][2];
xs.push_back(xx);
ys.push_back(yy);
zs.push_back(zz);
}
}
for (size_t i=0;i<N_noise;i++)
{
xs.push_back( randomGenerator.drawUniform(-7,7));
ys.push_back( randomGenerator.drawUniform(-7,7));
zs.push_back( randomGenerator.drawUniform(-7,7));
}
// Run RANSAC
// ------------------------------------
vector<pair<size_t,TPlane> > detectedPlanes;
const double DIST_THRESHOLD = 0.05;
CTicTac tictac;
ransac_detect_3D_planes(xs,ys,zs,detectedPlanes,DIST_THRESHOLD,40 );
// Display output:
cout << "RANSAC method: ransac_detect_3D_planes" << endl;
cout << " Computation time: " << tictac.Tac()*1000.0 << " ms" << endl;
cout << " " << detectedPlanes.size() << " planes detected." << endl;
// Show GUI
// --------------------------
win = mrpt::gui::CDisplayWindow3DPtr( new mrpt::gui::CDisplayWindow3D("RANSAC: 3D planes", 500,500));
opengl::COpenGLScenePtr scene = opengl::COpenGLScene::Create();
scene->insert( opengl::CGridPlaneXY::Create(-20,20,-20,20,0,1) );
scene->insert( opengl::stock_objects::CornerXYZ() );
for (vector<pair<size_t,TPlane> >::iterator p=detectedPlanes.begin();p!=detectedPlanes.end();++p)
{
opengl::CTexturedPlanePtr glPlane = opengl::CTexturedPlane::Create(-10,10,-10,10);
CPose3D glPlanePose;
p->second.getAsPose3D( glPlanePose );
glPlane->setPose(glPlanePose);
glPlane->setColor( randomGenerator.drawUniform(0,1), randomGenerator.drawUniform(0,1),randomGenerator.drawUniform(0,1), 0.6);
scene->insert( glPlane );
}
{
opengl::CPointCloudPtr points = opengl::CPointCloud::Create();
points->setColor(0,0,1);
points->setPointSize(3);
points->enableColorFromZ();
// Convert double -> float:
vector<float> xsf,ysf,zsf;
metaprogramming::copy_container_typecasting(xs,xsf);
metaprogramming::copy_container_typecasting(ys,ysf);
metaprogramming::copy_container_typecasting(zs,zsf);
points->setAllPoints(xsf,ysf,zsf);
scene->insert( points );
}
win->get3DSceneAndLock() = scene;
win->unlockAccess3DScene();
win->forceRepaint();
win->waitForKey();
}
// ------------------------------------------------------
// DoTrackingDemo
// ------------------------------------------------------
int DoTrackingDemo(CCameraSensorPtr cam, bool DO_SAVE_VIDEO)
{
win = mrpt::gui::CDisplayWindow3D::Create("Tracked features",800,600);
mrpt::vision::CVideoFileWriter vidWritter;
bool hasResolution = false;
TCamera cameraParams; // For now, will only hold the image resolution on the arrive of the first frame.
TSimpleFeatureList trackedFeats;
unsigned int step_num = 0;
bool SHOW_FEAT_IDS = true;
bool SHOW_RESPONSES = true;
bool SHOW_FEAT_TRACKS = true;
const double SAVE_VIDEO_FPS = 30; // If DO_SAVE_VIDEO=true, the FPS of the video file
const char* SAVE_VIDEO_CODEC = "XVID"; // "XVID", "PIM1", "MJPG"
bool DO_HIST_EQUALIZE_IN_GRAYSCALE = false;
string VIDEO_OUTPUT_FILE = "./tracking_video.avi";
const double MAX_FPS = 5000; // 5.0; // Hz (to slow down visualization).
CGenericFeatureTrackerAutoPtr tracker;
// "CFeatureTracker_KL" is by far the most robust implementation for now:
tracker = CGenericFeatureTrackerAutoPtr( new CFeatureTracker_KL );
tracker->enableTimeLogger(true); // Do time profiling.
// Set of parameters common to any tracker implementation:
// -------------------------------------------------------------
// To see all the existing params and documentation, see mrpt::vision::CGenericFeatureTracker
tracker->extra_params["remove_lost_features"] = 1; // automatically remove out-of-image and badly tracked features
tracker->extra_params["add_new_features"] = 1; // track, AND ALSO, add new features
tracker->extra_params["add_new_feat_min_separation"] = 32;
tracker->extra_params["minimum_KLT_response_to_add"] = 10;
tracker->extra_params["add_new_feat_max_features"] = 350;
tracker->extra_params["add_new_feat_patch_size"] = 11;
tracker->extra_params["update_patches_every"] = 0; // Don't update patches.
tracker->extra_params["check_KLT_response_every"] = 5; // Re-check the KLT-response to assure features are in good points.
tracker->extra_params["minimum_KLT_response"] = 5;
// Specific params for "CFeatureTracker_KL"
// ------------------------------------------------------
tracker->extra_params["window_width"] = 5;
tracker->extra_params["window_height"] = 5;
//tracker->extra_params["LK_levels"] = 3;
//tracker->extra_params["LK_max_iters"] = 10;
//tracker->extra_params["LK_epsilon"] = 0.1;
//tracker->extra_params["LK_max_tracking_error"] = 150;
// --------------------------------
// The main loop
// --------------------------------
CImage previous_image;
TSequenceFeatureObservations feat_track_history;
bool save_tracked_history = true; // Dump feat_track_history to a file at the end
TCameraPoseID curCamPoseId = 0;
cout << endl << "TO END THE PROGRAM: Close the window.\n";
mrpt::opengl::COpenGLViewportPtr gl_view;
{
mrpt::opengl::COpenGLScenePtr scene = win->get3DSceneAndLock();
gl_view = scene->getViewport("main");
win->unlockAccess3DScene();
}
// Aux data for drawing the recent track of features:
static const size_t FEATS_TRACK_LEN = 10;
std::map<TFeatureID,std::list<TPixelCoord> > feat_tracks;
// infinite loop, until we close the win:
while( win->isOpen() )
{
CObservationPtr obs;
try
{
obs= cam->getNextFrame();
}
catch (CExceptionEOF &)
{ // End of a rawlog file.
break;
}
if (!obs)
{
cerr << "*Warning* getNextFrame() returned NULL!\n";
mrpt::system::sleep(50);
continue;
}
CImage theImg; // The grabbed image:
if (IS_CLASS(obs,CObservationImage))
{
CObservationImagePtr o = CObservationImagePtr(obs);
theImg.copyFastFrom(o->image);
}
else if (IS_CLASS(obs,CObservationStereoImages))
{
CObservationStereoImagesPtr o = CObservationStereoImagesPtr(obs);
theImg.copyFastFrom(o->imageLeft);
}
else if (IS_CLASS(obs,CObservation3DRangeScan))
{
CObservation3DRangeScanPtr o = CObservation3DRangeScanPtr(obs);
if (o->hasIntensityImage)
theImg.copyFastFrom(o->intensityImage);
}
else
{
continue; // Silently ignore non-image observations.
}
// Make sure the image is loaded (for the case it came from a rawlog file)
if (theImg.isExternallyStored())
theImg.loadFromFile( theImg.getExternalStorageFileAbsolutePath());
// Take the resolution upon first valid frame.
if (!hasResolution)
{
hasResolution = true;
// cameraParams.scaleToResolution()...
cameraParams.ncols = theImg.getWidth();
cameraParams.nrows = theImg.getHeight();
}
// Do tracking:
if (step_num>1) // we need "previous_image" to be valid.
{
// This single call makes: detection, tracking, recalculation of KLT_response, etc.
tracker->trackFeatures(previous_image, theImg, trackedFeats);
}
// Save the image for the next step:
previous_image = theImg;
// Save history of feature observations:
tracker->getProfiler().enter("Save history");
for (size_t i=0;i<trackedFeats.size();++i)
{
TSimpleFeature &f = trackedFeats[i];
const TPixelCoordf pxRaw(f.pt.x,f.pt.y);
TPixelCoordf pxUndist;
//mrpt::vision::pinhole::undistort_point(pxRaw,pxUndist, cameraParams);
pxUndist = pxRaw;
feat_track_history.push_back( TFeatureObservation(f.ID,curCamPoseId, pxUndist ) );
}
curCamPoseId++;
tracker->getProfiler().leave("Save history");
// now that we're done with the image, we can directly write onto it
// for the display
// ----------------------------------------------------------------
if (DO_HIST_EQUALIZE_IN_GRAYSCALE && !theImg.isColor())
theImg.equalizeHistInPlace();
// Convert to color so we can draw color marks, etc.
theImg.colorImageInPlace();
double extra_tim_to_wait=0;
{ // FPS:
static CTicTac tictac;
const double T = tictac.Tac();
tictac.Tic();
const double fps = 1.0/(std::max(1e-5,T));
//theImg.filledRectangle(1,1,175,25,TColor(0,0,0));
const int current_adapt_thres = tracker->getDetectorAdaptiveThreshold();
theImg.selectTextFont("6x13B");
theImg.textOut(3,3,format("FPS: %.03f Hz", fps ),TColor(200,200,0) );
theImg.textOut(3,22,format("# feats: %u - Adaptive threshold: %i", (unsigned int)trackedFeats.size(), current_adapt_thres ),TColor(200,200,0) );
theImg.textOut(3,41,
format("# raw feats: %u - Removed: %u",
(unsigned int)tracker->last_execution_extra_info.raw_FAST_feats_detected,
(unsigned int)tracker->last_execution_extra_info.num_deleted_feats ),
TColor(200,200,0) );
extra_tim_to_wait = 1.0/MAX_FPS - 1.0/fps;
}
// Draw feature tracks
if (SHOW_FEAT_TRACKS)
{
// Update new feature coords:
tracker->getProfiler().enter("drawFeatureTracks");
std::set<TFeatureID> observed_IDs;
for (size_t i=0;i<trackedFeats.size();++i)
{
const TSimpleFeature &ft = trackedFeats[i];
std::list<TPixelCoord> & seq = feat_tracks[ft.ID];
observed_IDs.insert(ft.ID);
if (seq.size()>=FEATS_TRACK_LEN) seq.erase(seq.begin());
seq.push_back(ft.pt);
// Draw:
if (seq.size()>1)
{
const std::list<TPixelCoord>::const_iterator it_end = seq.end();
std::list<TPixelCoord>::const_iterator it = seq.begin();
std::list<TPixelCoord>::const_iterator it_prev = it++;
for (;it!=it_end;++it)
{
theImg.line(it_prev->x,it_prev->y,it->x,it->y, TColor(190,190,190) );
it_prev = it;
}
}
}
tracker->getProfiler().leave("drawFeatureTracks");
// Purge old data:
for (std::map<TFeatureID,std::list<TPixelCoord> >::iterator it=feat_tracks.begin();it!=feat_tracks.end(); )
{
if (observed_IDs.find(it->first)==observed_IDs.end())
{
std::map<TFeatureID,std::list<TPixelCoord> >::iterator next_it = it;
next_it++;
feat_tracks.erase(it);
it = next_it;
}
else ++it;
}
}
// Draw Tracked feats:
{
theImg.selectTextFont("5x7");
tracker->getProfiler().enter("drawFeatures");
theImg.drawFeatures(trackedFeats, TColor(0,0,255), SHOW_FEAT_IDS, SHOW_RESPONSES);
tracker->getProfiler().leave("drawFeatures");
}
// Update window:
win->get3DSceneAndLock();
gl_view->setImageView(theImg);
win->unlockAccess3DScene();
win->repaint();
// Save debug output video:
// ----------------------------------
if (DO_SAVE_VIDEO)
{
static bool first = true;
if (first)
{
first=false;
if (vidWritter.open(
VIDEO_OUTPUT_FILE,
SAVE_VIDEO_FPS /* fps */, theImg.getSize(),
SAVE_VIDEO_CODEC,
true /* force color video */ ) )
{
cout << "[track-video] Saving tracking video to: " << VIDEO_OUTPUT_FILE << endl;
}
else
cerr << "ERROR: Trying to create output video: " << VIDEO_OUTPUT_FILE << endl;
}
vidWritter << theImg;
}
if (extra_tim_to_wait>0)
mrpt::system::sleep(1000*extra_tim_to_wait);
step_num++;
} // end infinite loop
// Save tracked feats:
if (save_tracked_history)
{
cout << "Saving tracked features to: tracked_feats.txt..."; cout.flush();
feat_track_history.saveToTextFile("./tracked_feats.txt");
cout << "Done!\n"; cout.flush();
#if 0
// SBA:
cout << "Saving cams.txt & pts.txt files in SBA library format..."; cout.flush();
feat_track_history.removeFewObservedFeatures(3);
feat_track_history.decimateCameraFrames(20);
feat_track_history.compressIDs();
TLandmarkLocationsVec locs;
TFramePosesVec cams;
feat_track_history.saveAsSBAFiles(locs,"pts.txt", cams, "cams.txt");
cout << "Done!\n"; cout.flush();
#endif
}
return 0; // End ok.
}
/** Callback: On recalc local map & publish it */
void onDoPublish(const ros::TimerEvent& )
{
mrpt::utils::CTimeLoggerEntry tle(m_profiler,"onDoPublish");
// Purge old observations & latch a local copy:
TListObservations obs;
{
mrpt::utils::CTimeLoggerEntry tle(m_profiler,"onDoPublish.removingOld");
m_hist_obs_mtx.lock();
// Purge old obs:
if (!m_hist_obs.empty())
{
const double last_time = m_hist_obs.rbegin()->first;
TListObservations::iterator it_first_valid = m_hist_obs.lower_bound( last_time-m_time_window );
const size_t nToRemove = std::distance( m_hist_obs.begin(), it_first_valid );
ROS_DEBUG("[onDoPublish] Removing %u old entries, last_time=%lf",static_cast<unsigned int>(nToRemove), last_time);
m_hist_obs.erase(m_hist_obs.begin(), it_first_valid);
}
// Local copy in this thread:
obs = m_hist_obs;
m_hist_obs_mtx.unlock();
}
ROS_DEBUG("Building local map with %u observations.",static_cast<unsigned int>(obs.size()));
if (obs.empty())
return;
// Build local map(s):
// -----------------------------------------------
m_localmap_pts.clear();
mrpt::poses::CPose3D curRobotPose;
{
mrpt::utils::CTimeLoggerEntry tle2(m_profiler,"onDoPublish.buildLocalMap");
// Get the latest robot pose in the reference frame (typ: /odom -> /base_link)
// so we can build the local map RELATIVE to it:
try {
tf::StampedTransform tx;
m_tf_listener.lookupTransform(m_frameid_reference,m_frameid_robot, ros::Time(0), tx);
mrpt_bridge::convert(tx,curRobotPose);
ROS_DEBUG("[onDoPublish] Building local map relative to latest robot pose: %s", curRobotPose.asString().c_str() );
}
catch (tf::TransformException &ex) {
ROS_ERROR("%s",ex.what());
return;
}
// For each observation: compute relative robot pose & insert obs into map:
for (TListObservations::const_iterator it=obs.begin();it!=obs.end();++it)
{
const TInfoPerTimeStep & ipt = it->second;
// Relative pose in the past:
mrpt::poses::CPose3D relPose(mrpt::poses::UNINITIALIZED_POSE);
relPose.inverseComposeFrom( ipt.robot_pose, curRobotPose );
// Insert obs:
m_localmap_pts.insertObservationPtr(ipt.observation,&relPose);
} // end for
}
// Publish them:
if (m_pub_local_map_pointcloud.getNumSubscribers()>0)
{
sensor_msgs::PointCloudPtr msg_pts = sensor_msgs::PointCloudPtr( new sensor_msgs::PointCloud);
msg_pts->header.frame_id = m_frameid_robot;
msg_pts->header.stamp = ros::Time( obs.rbegin()->first );
mrpt_bridge::point_cloud::mrpt2ros(m_localmap_pts,msg_pts->header, *msg_pts);
m_pub_local_map_pointcloud.publish(msg_pts);
}
// Show gui:
if (m_show_gui)
{
if (!m_gui_win)
{
m_gui_win = mrpt::gui::CDisplayWindow3D::Create("LocalObstaclesNode",800,600);
mrpt::opengl::COpenGLScenePtr &scene = m_gui_win->get3DSceneAndLock();
scene->insert( mrpt::opengl::CGridPlaneXY::Create() );
scene->insert( mrpt::opengl::stock_objects::CornerXYZSimple(1.0,4.0) );
mrpt::opengl::CSetOfObjectsPtr gl_obs = mrpt::opengl::CSetOfObjects::Create();
gl_obs->setName("obstacles");
scene->insert( gl_obs );
mrpt::opengl::CPointCloudPtr gl_pts = mrpt::opengl::CPointCloud::Create();
gl_pts->setName("points");
gl_pts->setPointSize(2.0);
gl_pts->setColor_u8( mrpt::utils::TColor(0x0000ff) );
scene->insert( gl_pts );
m_gui_win->unlockAccess3DScene();
}
mrpt::opengl::COpenGLScenePtr &scene = m_gui_win->get3DSceneAndLock();
mrpt::opengl::CSetOfObjectsPtr gl_obs = mrpt::opengl::CSetOfObjectsPtr( scene->getByName("obstacles") );
ROS_ASSERT(gl_obs.present());
gl_obs->clear();
mrpt::opengl::CPointCloudPtr gl_pts = mrpt::opengl::CPointCloudPtr( scene->getByName("points") );
for (TListObservations::const_iterator it=obs.begin();it!=obs.end();++it)
{
const TInfoPerTimeStep & ipt = it->second;
// Relative pose in the past:
mrpt::poses::CPose3D relPose(mrpt::poses::UNINITIALIZED_POSE);
relPose.inverseComposeFrom( ipt.robot_pose, curRobotPose );
mrpt::opengl::CSetOfObjectsPtr gl_axis = mrpt::opengl::stock_objects::CornerXYZSimple(0.9,2.0);
gl_axis->setPose(relPose);
gl_obs->insert(gl_axis);
} // end for
gl_pts->loadFromPointsMap(&m_localmap_pts);
m_gui_win->unlockAccess3DScene();
m_gui_win->repaint();
}
} // onDoPublish
// ------------------------------------------------------
// MAIN
// ------------------------------------------------------
int main(int argc, char **argv)
{
try
{
printf(" track-video-features - Part of MRPT\n");
printf(" MRPT C++ Library: %s - BUILD DATE %s\n", mrpt::system::MRPT_getVersion().c_str(), mrpt::system::MRPT_getCompilationDate().c_str());
printf("-------------------------------------------------------------------\n");
// The video source:
CCameraSensorPtr cam;
// process cmd line arguments?
if (argc<1 || argc>3)
{
cerr << "Incorrect number of arguments.\n";
showUsage(argv[0]);
return -1;
}
const bool last_arg_is_save_video = !strcmp("--save-video",argv[argc-1]);
if (last_arg_is_save_video)
argc--; // Discard last argument
if (argc==2)
{
if (!strcmp(argv[1],"--help"))
{
showUsage(argv[0]);
return 0;
}
if (!mrpt::system::fileExists(argv[1]))
{
cerr << "File does not exist: " << argv[1] << endl;
return -1;
}
const string fil = string(argv[1]);
const string ext = mrpt::system::lowerCase(mrpt::system::extractFileExtension(fil,true));
if (ext=="rawlog")
{
// It's a rawlog:
cout << "Interpreting '" << fil << "' as a rawlog file...\n";
cam = CCameraSensorPtr(new CCameraSensor);
CConfigFileMemory cfg;
cfg.write("CONFIG","grabber_type","rawlog");
cfg.write("CONFIG","rawlog_file", fil );
// For delayed-load images:
CImage::IMAGES_PATH_BASE = CRawlog::detectImagesDirectory(fil);
cam->loadConfig(cfg,"CONFIG");
cam->initialize(); // This will raise an exception if neccesary
}
else
{
// Assume it's a video:
cout << "Interpreting '" << fil << "' as a video file...\n";
cam = CCameraSensorPtr(new CCameraSensor);
CConfigFileMemory cfg;
cfg.write("CONFIG","grabber_type","ffmpeg");
cfg.write("CONFIG","ffmpeg_url", fil );
cam->loadConfig(cfg,"CONFIG");
cam->initialize(); // This will raise an exception if neccesary
}
}
if (!cam)
{
cout << "You didn't specify any video source in the command line.\n"
"(You can run with --help to see usage).\n"
"Showing a GUI window to select the video source...\n";
// If no camera opened so far, ask the user for one:
cam = mrpt::hwdrivers::prepareVideoSourceFromUserSelection();
if (!cam)
{
cerr << "No images source was correctly initialized! Exiting.\n";
return -1;
}
}
// do it:
const int ret = DoTrackingDemo(cam, last_arg_is_save_video);
win.clear();
mrpt::system::sleep(150); // give time to close GUI threads
return ret;
}
catch (std::exception &e)
{
std::cerr << e.what() << std::endl << "Program finished for an exception!!" << std::endl;
mrpt::system::pause();
return -1;
}
catch (...)
{
std::cerr << "Untyped exception!!" << std::endl;
mrpt::system::pause();
return -1;
}
}
