void ompl::control::EST::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<MotionInfo> motions; tree_.grid.getContent(motions); double stepSize = siC_->getPropagationStepSize(); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (unsigned int i = 0 ; i < motions.size() ; ++i) for (unsigned int j = 0 ; j < motions[i].size() ; ++j) { if (motions[i][j]->parent) { if (data.hasControls()) data.addEdge (base::PlannerDataVertex (motions[i][j]->parent->state), base::PlannerDataVertex (motions[i][j]->state), PlannerDataEdgeControl(motions[i][j]->control, motions[i][j]->steps * stepSize)); else data.addEdge (base::PlannerDataVertex (motions[i][j]->parent->state), base::PlannerDataVertex (motions[i][j]->state)); } else data.addStartVertex (base::PlannerDataVertex (motions[i][j]->state)); } }
void ompl::geometric::TRRTConnect::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; if (tStart_) tStart_->list(motions); for (std::size_t i(0); i < motions.size(); ++i) { if (!motions[i]->parent) { data.addStartVertex(base::PlannerDataVertex(motions[i]->state,1)); } else { data.addEdge(base::PlannerDataVertex(motions[i]->parent->state,1), base::PlannerDataVertex(motions[i]->state,1)); } } motions.clear(); if (tGoal_) tGoal_->list(motions); for (std::size_t i(0); i < motions.size(); ++i) { if (!motions[i]->parent) { data.addGoalVertex(base::PlannerDataVertex(motions[i]->state,2)); } else { //The edges in the goal tree are reversed to be consistent with start tree data.addEdge(base::PlannerDataVertex(motions[i]->state,2), base::PlannerDataVertex(motions[i]->parent->state,2)); } } //Add the edge connecting the two trees data.addEdge(data.vertexIndex(connectionPoint_.first), data.vertexIndex(connectionPoint_.second)); }
void ompl::control::SyclopRRT::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion *> motions; if (nn_) nn_->list(motions); double delta = siC_->getPropagationStepSize(); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (auto &motion : motions) { if (motion->parent) { if (data.hasControls()) data.addEdge(base::PlannerDataVertex(motion->parent->state), base::PlannerDataVertex(motion->state), control::PlannerDataEdgeControl(motion->control, motion->steps * delta)); else data.addEdge(base::PlannerDataVertex(motion->parent->state), base::PlannerDataVertex(motion->state)); } else data.addStartVertex(base::PlannerDataVertex(motion->state)); } }
void ompl::control::SyclopEST::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); double delta = siC_->getPropagationStepSize(); if (lastGoalMotion_) data.addGoalVertex(lastGoalMotion_->state); for (size_t i = 0; i < motions_.size(); ++i) { if (motions_[i]->parent) { if (data.hasControls()) data.addEdge (base::PlannerDataVertex(motions_[i]->parent->state), base::PlannerDataVertex(motions_[i]->state), control::PlannerDataEdgeControl (motions_[i]->control, motions_[i]->steps * delta)); else data.addEdge (base::PlannerDataVertex(motions_[i]->parent->state), base::PlannerDataVertex(motions_[i]->state)); } else data.addStartVertex (base::PlannerDataVertex(motions_[i]->state)); } }
void ompl::geometric::pSBL::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<MotionInfo> motions; tStart_.grid.getContent(motions); for (unsigned int i = 0 ; i < motions.size() ; ++i) for (unsigned int j = 0 ; j < motions[i].size() ; ++j) if (motions[i][j]->parent == nullptr) data.addStartVertex(base::PlannerDataVertex(motions[i][j]->state, 1)); else data.addEdge(base::PlannerDataVertex(motions[i][j]->parent->state, 1), base::PlannerDataVertex(motions[i][j]->state, 1)); motions.clear(); tGoal_.grid.getContent(motions); for (unsigned int i = 0 ; i < motions.size() ; ++i) for (unsigned int j = 0 ; j < motions[i].size() ; ++j) if (motions[i][j]->parent == nullptr) data.addGoalVertex(base::PlannerDataVertex(motions[i][j]->state, 2)); else // The edges in the goal tree are reversed so that they are in the same direction as start tree data.addEdge(base::PlannerDataVertex(motions[i][j]->state, 2), base::PlannerDataVertex(motions[i][j]->parent->state, 2)); data.addEdge(data.vertexIndex(connectionPoint_.first), data.vertexIndex(connectionPoint_.second)); }
void ompl::geometric::SBL::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<MotionInfo> motionInfo; tStart_.grid.getContent(motionInfo); for (auto &m : motionInfo) for (auto &motion : m.motions_) if (motion->parent == nullptr) data.addStartVertex(base::PlannerDataVertex(motion->state, 1)); else data.addEdge(base::PlannerDataVertex(motion->parent->state, 1), base::PlannerDataVertex(motion->state, 1)); motionInfo.clear(); tGoal_.grid.getContent(motionInfo); for (auto &m : motionInfo) for (auto &motion : m.motions_) if (motion->parent == nullptr) data.addGoalVertex(base::PlannerDataVertex(motion->state, 2)); else // The edges in the goal tree are reversed so that they are in the same direction as start tree data.addEdge(base::PlannerDataVertex(motion->state, 2), base::PlannerDataVertex(motion->parent->state, 2)); data.addEdge(data.vertexIndex(connectionPoint_.first), data.vertexIndex(connectionPoint_.second)); }
void ompl::control::KPIECE1::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); Grid::CellArray cells; tree_.grid.getCells(cells); double delta = siC_->getPropagationStepSize(); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (unsigned int i = 0 ; i < cells.size() ; ++i) { for (unsigned int j = 0 ; j < cells[i]->data->motions.size() ; ++j) { const Motion* m = cells[i]->data->motions[j]; if (m->parent) { if (data.hasControls()) data.addEdge(base::PlannerDataVertex (m->parent->state), base::PlannerDataVertex (m->state, cells[i]->border ? 2 : 1), control::PlannerDataEdgeControl (m->control, m->steps * delta)); else data.addEdge(base::PlannerDataVertex (m->parent->state), base::PlannerDataVertex (m->state, cells[i]->border ? 2 : 1)); } else data.addStartVertex(base::PlannerDataVertex (m->state, cells[i]->border ? 2 : 1)); // A state created as a parent first may have an improper tag variable data.tagState(m->state, cells[i]->border ? 2 : 1); } } }
void ompl::control::EST::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<MotionInfo> motionInfo; tree_.grid.getContent(motionInfo); double stepSize = siC_->getPropagationStepSize(); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (auto &mi : motionInfo) for (auto &motion : mi.motions_) { if (motion->parent) { if (data.hasControls()) data.addEdge(base::PlannerDataVertex(motion->parent->state), base::PlannerDataVertex(motion->state), PlannerDataEdgeControl(motion->control, motion->steps * stepSize)); else data.addEdge(base::PlannerDataVertex(motion->parent->state), base::PlannerDataVertex(motion->state)); } else data.addStartVertex(base::PlannerDataVertex(motion->state)); } }
void ompl::geometric::LazyPRM::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); // Explicitly add start and goal states. Tag all states known to be valid as 1. // Unchecked states are tagged as 0. for (size_t i = 0; i < startM_.size(); ++i) data.addStartVertex(base::PlannerDataVertex(stateProperty_[startM_[i]], 1)); for (size_t i = 0; i < goalM_.size(); ++i) data.addGoalVertex(base::PlannerDataVertex(stateProperty_[goalM_[i]], 1)); // Adding edges and all other vertices simultaneously foreach(const Edge e, boost::edges(g_)) { const Vertex v1 = boost::source(e, g_); const Vertex v2 = boost::target(e, g_); data.addEdge(base::PlannerDataVertex(stateProperty_[v1]), base::PlannerDataVertex(stateProperty_[v2])); // Add the reverse edge, since we're constructing an undirected roadmap data.addEdge(base::PlannerDataVertex(stateProperty_[v2]), base::PlannerDataVertex(stateProperty_[v1])); // Add tags for the newly added vertices data.tagState(stateProperty_[v1], (vertexValidityProperty_[v1] & VALIDITY_TRUE) == 0 ? 0 : 1); data.tagState(stateProperty_[v2], (vertexValidityProperty_[v2] & VALIDITY_TRUE) == 0 ? 0 : 1); } }
void ompl::control::RRT::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; if (nn_) nn_->list(motions); double delta = siC_->getPropagationStepSize(); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (unsigned int i = 0 ; i < motions.size() ; ++i) { const Motion* m = motions[i]; if (m->parent) { if (data.hasControls()) data.addEdge(base::PlannerDataVertex(m->parent->state), base::PlannerDataVertex(m->state), control::PlannerDataEdgeControl(m->control, m->steps * delta)); else data.addEdge(base::PlannerDataVertex(m->parent->state), base::PlannerDataVertex(m->state)); } else data.addStartVertex(base::PlannerDataVertex(m->state)); } }
void ompl::geometric::RRTsharp::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; if (nn_) nn_->list(motions); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (std::size_t i = 0 ; i < motions.size() ; ++i) { if (motions[i]->parent == NULL) data.addStartVertex(base::PlannerDataVertex(motions[i]->state)); else data.addEdge(base::PlannerDataVertex(motions[i]->parent->state), base::PlannerDataVertex(motions[i]->state)); // if (visitedMotions.count(motions[i])!=0){ // data.tagState(motions[i]->state,1); // } // if (toVisitMotions.count(motions[i])!=0){ // data.tagState(motions[i]->state,2); // } } }
void ompl::geometric::CForest::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); for (std::size_t i = 0; i < planners_.size(); ++i) { base::PlannerData pd(si_); planners_[i]->getPlannerData(pd); for (unsigned int j = 0; j < pd.numVertices(); ++j) { base::PlannerDataVertex &v = pd.getVertex(j); v.setTag(i); std::vector<unsigned int> edgeList; unsigned int numEdges = pd.getIncomingEdges(j, edgeList); for (unsigned int k = 0; k < numEdges; ++k) { base::Cost edgeWeight; base::PlannerDataVertex &w = pd.getVertex(edgeList[k]); w.setTag(i); pd.getEdgeWeight(j, k, &edgeWeight); data.addEdge(v, w, pd.getEdge(j, k), edgeWeight); } } for (unsigned int j = 0; j < pd.numGoalVertices(); ++j) data.markGoalState(pd.getGoalVertex(j).getState()); for (unsigned int j = 0; j < pd.numStartVertices(); ++j) data.markStartState(pd.getStartVertex(j).getState()); } }
void ompl::control::SST::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; std::vector<Motion*> allMotions; if (nn_) nn_->list(motions); for(unsigned i=0;i<motions.size();i++) { if(motions[i]->numChildren_==0) { allMotions.push_back(motions[i]); } } for(unsigned i=0;i<allMotions.size();i++) { if(allMotions[i]->parent_!=NULL) { allMotions.push_back(allMotions[i]->parent_); } } double delta = siC_->getPropagationStepSize(); if (prevSolution_.size()!=0) data.addGoalVertex(base::PlannerDataVertex(prevSolution_[0])); for (unsigned int i = 0 ; i < allMotions.size() ; ++i) { const Motion *m = allMotions[i]; if (m->parent_) { if (data.hasControls()) data.addEdge(base::PlannerDataVertex(m->parent_->state_), base::PlannerDataVertex(m->state_), control::PlannerDataEdgeControl(m->control_, m->steps_ * delta)); else data.addEdge(base::PlannerDataVertex(m->parent_->state_), base::PlannerDataVertex(m->state_)); } else data.addStartVertex(base::PlannerDataVertex(m->state_)); } }
void ompl::geometric::LBKPIECE1::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); dStart_.getPlannerData(data, 1, true, NULL); dGoal_.getPlannerData(data, 2, false, NULL); // Insert the edge connecting the two trees data.addEdge (data.vertexIndex(connectionPoint_.first), data.vertexIndex(connectionPoint_.second)); }
void ompl::geometric::RRTstar::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; if (nn_) nn_->list(motions); for (unsigned int i = 0 ; i < motions.size() ; ++i) data.addEdge (base::PlannerDataVertex (motions[i]->parent ? motions[i]->parent->state : NULL), base::PlannerDataVertex (motions[i]->state)); }
void ompl::geometric::LightningRetrieveRepair::getPlannerData(base::PlannerData &data) const { OMPL_INFORM("LightningRetrieveRepair: including %d similar paths", nearestPaths_.size()); // Visualize the n candidate paths that we recalled from the database for (std::size_t i = 0 ; i < nearestPaths_.size() ; ++i) { ompl::base::PlannerDataPtr pd = nearestPaths_[i]; for (std::size_t j = 1; j < pd->numVertices(); ++j) { data.addEdge( base::PlannerDataVertex(pd->getVertex(j - 1).getState()), base::PlannerDataVertex(pd->getVertex(j).getState())); } } }
void ompl::control::PID::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); double delta = siC_->getPropagationStepSize(); if (motions.back()) { data.addGoalVertex(base::PlannerDataVertex(motions.back()->state)); } for (int i = motions.size()-1 ; i >= 1 ; --i) { const Motion* m = motions[i]; data.addEdge(base::PlannerDataVertex(motions[i-1]->state), base::PlannerDataVertex(m->state), control::PlannerDataEdgeControl(m->control, delta)); } data.addStartVertex(base::PlannerDataVertex(motions.front()->state)); }
void ompl::geometric::pRRT::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion *> motions; if (nn_) nn_->list(motions); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (auto &motion : motions) { if (motion->parent == nullptr) data.addStartVertex(base::PlannerDataVertex(motion->state)); else data.addEdge(base::PlannerDataVertex(motion->parent->state), base::PlannerDataVertex(motion->state)); } }
void ompl::geometric::FMT::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; nn_->list(motions); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->getState())); unsigned int size = motions.size(); for (unsigned int i = 0; i < size; ++i) { if (motions[i]->getParent() == nullptr) data.addStartVertex(base::PlannerDataVertex(motions[i]->getState())); else data.addEdge(base::PlannerDataVertex(motions[i]->getParent()->getState()), base::PlannerDataVertex(motions[i]->getState())); } }
void ompl::geometric::ProjEST::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<MotionInfo> motionInfo; tree_.grid.getContent(motionInfo); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (auto &m : motionInfo) for (auto &motion : m.motions_) { if (motion->parent == nullptr) data.addStartVertex(base::PlannerDataVertex(motion->state)); else data.addEdge(base::PlannerDataVertex(motion->parent->state), base::PlannerDataVertex(motion->state)); } }
void ompl::geometric::RRTstarAR::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; if (nn_) nn_->list(motions); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (std::size_t i = 0 ; i < motions.size() ; ++i) { if (motions[i]->parent == NULL) data.addStartVertex(base::PlannerDataVertex(motions[i]->state)); else data.addEdge(base::PlannerDataVertex(motions[i]->parent->state), base::PlannerDataVertex(motions[i]->state)); } }
void ompl::geometric::LBTRRT::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; if (nn_) nn_->list(motions); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state_)); for (unsigned int i = 0 ; i < motions.size() ; ++i) { if (motions[i]->parentApx_ == nullptr) data.addStartVertex(base::PlannerDataVertex(motions[i]->state_)); else data.addEdge(base::PlannerDataVertex(motions[i]->parentApx_->state_), base::PlannerDataVertex(motions[i]->state_)); } }
void ompl::geometric::EST::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<MotionInfo> motions; tree_.grid.getContent(motions); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (unsigned int i = 0 ; i < motions.size() ; ++i) for (unsigned int j = 0 ; j < motions[i].size() ; ++j) { if (motions[i][j]->parent == NULL) data.addStartVertex(base::PlannerDataVertex(motions[i][j]->state)); else data.addEdge(base::PlannerDataVertex(motions[i][j]->parent->state), base::PlannerDataVertex(motions[i][j]->state)); } }
void ompl::geometric::LazyRRT::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; if (nn_) nn_->list(motions); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state, 1)); for (unsigned int i = 0 ; i < motions.size() ; ++i) { if (motions[i]->parent == NULL) data.addStartVertex(base::PlannerDataVertex(motions[i]->state)); else data.addEdge(base::PlannerDataVertex(motions[i]->parent ? motions[i]->parent->state : NULL), base::PlannerDataVertex(motions[i]->state)); data.tagState(motions[i]->state, motions[i]->valid ? 1 : 0); } }
void ompl::geometric::RRTstar::getPlannerData(base::PlannerData &data) const { Planner::getPlannerData(data); std::vector<Motion*> motions; if (nn_) nn_->list(motions); if (lastGoalMotion_) data.addGoalVertex(base::PlannerDataVertex(lastGoalMotion_->state)); for (std::size_t i = 0 ; i < motions.size() ; ++i) { if (motions[i]->parent == NULL) data.addStartVertex(base::PlannerDataVertex(motions[i]->state)); else data.addEdge(base::PlannerDataVertex(motions[i]->parent->state), base::PlannerDataVertex(motions[i]->state)); } data.properties["iterations INTEGER"] = boost::lexical_cast<std::string>(iterations_); data.properties["collision_checks INTEGER"] = boost::lexical_cast<std::string>(collisionChecks_); }