bool FootstepGraph::isGoal(StatePtr state)
  {
    FootstepState::Ptr goal = getGoal(state->getLeg());
    if (publish_progress_) {
      jsk_footstep_msgs::FootstepArray msg;
      msg.header.frame_id = "odom"; // TODO fixed frame_id
      msg.header.stamp = ros::Time::now();
      msg.footsteps.push_back(*state->toROSMsg());
      pub_progress_.publish(msg);
    }
    Eigen::Affine3f pose = state->getPose();
    Eigen::Affine3f goal_pose = goal->getPose();
    Eigen::Affine3f transformation = pose.inverse() * goal_pose;

    if ((parameters_.goal_pos_thr > transformation.translation().norm()) &&
        (parameters_.goal_rot_thr > std::abs(Eigen::AngleAxisf(transformation.rotation()).angle()))) {
      // check collision
      if (state->getLeg() == jsk_footstep_msgs::Footstep::LEFT) {
        if (right_goal_state_->crossCheck(state)) {
          return true;
        }
      } else if (state->getLeg() == jsk_footstep_msgs::Footstep::RIGHT) {
        if (left_goal_state_->crossCheck(state)) {
          return true;
        }
      }
    }
    return false;
  }
int main(int argc, char **argv){
  ros::init (argc, argv, "move_arm_pose_goal");
  ros::NodeHandle nh;
  actionlib::SimpleActionClient<arm_navigation_msgs::MoveArmAction> move_rarm("move_right_arm",true);
  actionlib::SimpleActionClient<arm_navigation_msgs::MoveArmAction> move_larm("move_left_arm",true);
  ROS_INFO("Connecting to server...");
  move_rarm.waitForServer();
  move_larm.waitForServer();
  ROS_INFO("Connected to server");
 
  actualizeGoal(nh, move_rarm, getGoal(0,-0.7,1.2,0,0,0,1, true));
  actualizeGoal(nh, move_rarm, getGoal(0.75,-0.2,0.8,0,0,0,1, true));
  actualizeGoal(nh, move_rarm, getGoal(0.5,-0.35,0.35,0,0,0,1, true));

  ros::shutdown();
}
Example #3
0
void Server::stop(){
    qDebug() << "Server::stop()";

    waitForNewMessage(WAITING_FOR_MESSAGE::DONE);

    emit emitOutput(QString("\nMATCH FINISHED"));
    emit matchFinished(proverSM.getGoals(currentState));

    QThread::currentThread()->msleep(500);


    int nbPlayers = addresses.size();
    QString message = QString("(stop ") % matchId % " ";

    // Likely to be not necessary
    if(stepCounter == 0){
        message += "nil)";
    }
    else{
        message += "( ";
        for(QString move : moves){
            message += QString("(") % move % ") ";
        }
        message += QString(") )");
    }

    for(int i = 0; i<nbPlayers; ++i){
        networkConnections[i]->request(message, startclock);
        emit outputPlayerMessage(i, QString("Score %1").arg(getGoal(i)));
    }

}
Example #4
0
void ompl::control::SimpleSetup::setup()
{
    if (!configured_ || !si_->isSetup() || !planner_->isSetup())
    {
        if (!si_->isSetup())
            si_->setup();
        if (!planner_)
        {
            if (pa_)
                planner_ = pa_(si_);
            if (!planner_)
            {
                OMPL_INFORM("No planner specified. Using default.");
                planner_ = getDefaultPlanner(getGoal());
            }
        }
        planner_->setProblemDefinition(pdef_);
        if (!planner_->isSetup())
            planner_->setup();

        params_.clear();
        params_.include(si_->params());
        params_.include(planner_->params());
        configured_ = true;
    }
}
Example #5
0
void KoulesSetup::initialize(unsigned int numKoules, const std::string& plannerName,
    const std::vector<double>& stateVec)
{
    const ob::StateSpacePtr& space = getStateSpace();
    space->setup();
    // setup start state
    ob::ScopedState<> start(space);
    if (stateVec.size() == space->getDimension())
        space->copyFromReals(start.get(), stateVec);
    else
    {
        // Pick koule positions evenly radially distributed, but at a linearly
        // increasing distance from the center. The ship's initial position is
        // at the center. Initial velocities are 0.
        std::vector<double> startVec(space->getDimension(), 0.);
        double r, theta = boost::math::constants::pi<double>(), delta = 2.*theta / numKoules;
        startVec[0] = .5 * sideLength;
        startVec[1] = .5 * sideLength;
        startVec[4] = .5 * delta;
        for (unsigned int i = 0; i < numKoules; ++i, theta += delta)
        {
            r = .1 + i * .1 / numKoules;
            startVec[4 * i + 5] = .5 * sideLength + r * cos(theta);
            startVec[4 * i + 6] = .5 * sideLength + r * sin(theta);
        }
        space->copyFromReals(start.get(), startVec);
    }
    setStartState(start);
    // set goal
    setGoal(std::make_shared<KoulesGoal>(si_));
    // set propagation step size
    si_->setPropagationStepSize(propagationStepSize);
    // set min/max propagation steps
    si_->setMinMaxControlDuration(propagationMinSteps, propagationMaxSteps);
    // set directed control sampler; when using the PDST planner, propagate as long as possible
    bool isPDST = plannerName == "pdst";
    const ompl::base::GoalPtr& goal = getGoal();
    si_->setDirectedControlSamplerAllocator(
        [&goal, isPDST](const ompl::control::SpaceInformation *si)
        {
            return KoulesDirectedControlSamplerAllocator(si,  goal, isPDST);
        });
    // set planner
    setPlanner(getConfiguredPlannerInstance(plannerName));
    // set validity checker
    setStateValidityChecker(std::make_shared<KoulesStateValidityChecker>(si_));
    // set state propagator
    setStatePropagator(std::make_shared<KoulesStatePropagator>(si_));
}
Example #6
0
 bool FootstepGraph::isGoal(StatePtr state)
 {
   FootstepState::Ptr goal = getGoal(state->getLeg());
   if (publish_progress_) {
     jsk_footstep_msgs::FootstepArray msg;
     msg.header.frame_id = "odom";
     msg.header.stamp = ros::Time::now();
     msg.footsteps.push_back(*state->toROSMsg());
     pub_progress_.publish(msg);
   }
   Eigen::Affine3f pose = state->getPose();
   Eigen::Affine3f goal_pose = goal->getPose();
   Eigen::Affine3f transformation = pose.inverse() * goal_pose;
   return (pos_goal_thr_ > transformation.translation().norm()) &&
     (rot_goal_thr_ > std::abs(Eigen::AngleAxisf(transformation.rotation()).angle()));
 }
Example #7
0
inline std::ostream& FileConfig::print(std::ostream& os) const
{
    return os <<
        "bruijn="                  << getBruijn()                  << "\n" <<
        "emch="                    << getEmch()                    << "\n" <<
        "outputFormat="            << getOutputFormat()            << "\n" <<
        "fitFilter="               << getFitFilter()               << "\n" <<
        "goal="                    << getGoal()                    << "\n" <<
        "info="                    << getInfo()                    << "\n" <<
        "mch="                     << getMch()                     << "\n" <<
        "orderingHeuristicConfig=" << getOrderingHeuristicConfig() << "\n" <<
        "parityBacktrack="         << getParityBacktrack()         << "\n" <<
        "parityFilter="            << getParityFilter()            << "\n" <<
        "quiet="                   << getQuiet()                   << "\n" <<
        "redundancyFilter="        << getRedundancyFilter()        << "\n" <<
        "redundancyFilterFirst="   << getRedundancyFilterFirst()   << "\n" <<
        "sample="                  << getMonteCarlo()              << "\n" <<
        "trace="                   << getTrace()                   << "\n" <<
        "unique="                  << getUnique()                  << "\n" <<
        "volumeBacktrack="         << getVolumeBacktrack()         << "\n" <<
        "volumeFilter="            << getVolumeFilter()            << std::endl;
}
Example #8
0
void ompl::geometric::SimpleSetup::setup()
{
    if (!configured_ || !si_->isSetup() || !planner_->isSetup())
    {
        if (!si_->isSetup())
            si_->setup();
        if (!planner_)
        {
            if (pa_)
                planner_ = pa_(si_);
            if (!planner_)
            {
                OMPL_INFORM("No planner specified. Using default.");
                planner_ = tools::SelfConfig::getDefaultPlanner(getGoal());
            }
        }
        planner_->setProblemDefinition(pdef_);
        if (!planner_->isSetup())
            planner_->setup();
        configured_ = true;
    }
}
Example #9
0
//check whether the game is over
int checkGameState(Agent agents[],Graph g,int cycle,int maxCycles){
  if(cycle >= maxCycles) {
    printf("GAME OVER: YOU LOSE - TIME IS UP\n");
    return OVER;
  } else {
    Vertex currThiefLoc = getCurrentLocation (agents[THIEF]);
    int i = 1;
    while (i <= NUM_DETECTIVES) {
      if (currThiefLoc == getCurrentLocation (agents[i])) {
	printf("D%d caught the thief in %s (%d)\n", i, getCityName(g, currThiefLoc), currThiefLoc);
	printf("YOU WIN - THIEF CAUGHT!\n");
	return WIN;
      }
      i++;
    }
    if ( currThiefLoc == getGoal (agents[THIEF]) ) {
      printf("T got away to  %s (%d)\n", getCityName(g, currThiefLoc), currThiefLoc);      
      printf("GAME OVER: YOU LOSE - THIEF GOT TO GETAWAY\n");
      return LOSE;
    }
    return CONTINUE;
  }
}
int main(int argc, char *argv[]) {
	Maze maze;

	readMazeFromFile(&maze, "maze3D.txt");

	unsigned int solution_count = 13;
	Direction solution[] = {EAST, NORTH, EAST, SOUTH, EAST, NORTH, UP, WEST, WEST, NORTH, NORTH, DOWN, SOUTH};

	Position position, goal;
	getPosition(maze, &position);
	getGoal(maze, &goal);

	printf("Current position: "); printPositionWithNewline(position);
	printf("Goal: "); printPositionWithNewline(goal); printf("\n");

	printMaze(maze);

	printPossibleMoves(maze);
	printf("\n");

	for (int i=0; i < solution_count; i++) {
		if (makeMove(&maze, solution[i]) == 1) {
			if (isSolved(maze)) {
				printf("Maze solved!\n");
				printPathWithNewline(maze.path);
				break;
			}
			else {
				printf("Movement successful, maze not solved.\n");
			}
		}
		else {
			printf("Error moving from: "); printPosition(maze.pos); printf (" to %s\n", convertDirectionToString(solution[i]));
		}
	}
	return EXIT_SUCCESS;
}
bool parallelPlanning(bool output, enum SPACE_TYPE space, std::vector<enum PLANNER_TYPE> &planners, unsigned int links,
                      unsigned int chains, struct ConstrainedOptions &c_opt, struct AtlasOptions &a_opt, bool bench)
{
    // Create a shared pointer to our constraint.
    auto constraint = std::make_shared<ParallelConstraint>(links, chains);

    ConstrainedProblem cp(space, constraint->createSpace(), constraint);
    cp.setConstrainedOptions(c_opt);
    cp.setAtlasOptions(a_opt);

    cp.css->registerProjection("parallel", constraint->getProjection(cp.css));

    Eigen::VectorXd start, goal;
    constraint->getStart(start);
    constraint->getGoal(goal);

    cp.setStartAndGoalStates(start, goal);
    cp.ss->setStateValidityChecker(std::bind(&ParallelConstraint::isValid, constraint, std::placeholders::_1));

    if (!bench)
        return parallelPlanningOnce(cp, planners[0], output);
    else
        return parallelPlanningBench(cp, planners);
}
Example #12
0
void Arcade::updateBoard(float dt){
  if(_stop) return;
  if(!_in_combo && _time > 0){
    switch(getGoal()){
    case SCORE_WIN:
      if(_score > getScoreLowWin()){
	unlockNextLevel();
	showWinner();
	return;
      }
      break;
    case COMBO_WIN:
      if(_combo_count > getComboWin()){
	showWinner();
	unlockNextLevel();
      }
      break;
    }
  }
  _time_roll_board.update(dt);
  _time_combo.update(dt);
  updateClock(dt);
  updateTutorial(dt);
}