コード例 #1
0
ファイル: PathHybridization.cpp プロジェクト: RickOne16/ompl
void ompl::geometric::PathHybridization::computeHybridPath()
{
    boost::vector_property_map<Vertex> prev(boost::num_vertices(g_));
    boost::dijkstra_shortest_paths(g_, root_, boost::predecessor_map(prev));
    if (prev[goal_] != goal_)
    {
        PathGeometric *h = new PathGeometric(si_);
        for (Vertex pos = prev[goal_]; prev[pos] != pos; pos = prev[pos])
            h->append(stateProperty_[pos]);
        h->reverse();
        hpath_.reset(h);
    }
}
コード例 #2
0
ファイル: FMT.cpp プロジェクト: RickOne16/ompl
void ompl::geometric::FMT::traceSolutionPathThroughTree(Motion *goalMotion)
{
    std::vector<Motion*> mpath;
    Motion *solution = goalMotion;

    // Construct the solution path
    while (solution != nullptr)
    {
        mpath.push_back(solution);
        solution = solution->getParent();
    }

    // Set the solution path
    PathGeometric *path = new PathGeometric(si_);
    int mPathSize = mpath.size();
    for (int i = mPathSize - 1 ; i >= 0 ; --i)
        path->append(mpath[i]->getState());
    pdef_->addSolutionPath(base::PathPtr(path), false, -1.0, getName());
}
コード例 #3
0
ファイル: pSBL.cpp プロジェクト: RickOne16/ompl
void ompl::geometric::pSBL::threadSolve(unsigned int tid, const base::PlannerTerminationCondition &ptc, SolutionInfo *sol)
{
    RNG rng;

    std::vector<Motion*> solution;
    base::State *xstate = si_->allocState();
    bool      startTree = rng.uniformBool();

    while (!sol->found && ptc == false)
    {
        bool retry = true;
        while (retry && !sol->found && ptc == false)
        {
            removeList_.lock.lock();
            if (!removeList_.motions.empty())
            {
                if (loopLock_.try_lock())
                {
                    retry = false;
                    std::map<Motion*, bool> seen;
                    for (unsigned int i = 0 ; i < removeList_.motions.size() ; ++i)
                        if (seen.find(removeList_.motions[i].motion) == seen.end())
                            removeMotion(*removeList_.motions[i].tree, removeList_.motions[i].motion, seen);
                    removeList_.motions.clear();
                    loopLock_.unlock();
                }
            }
            else
                retry = false;
            removeList_.lock.unlock();
        }

        if (sol->found || ptc)
            break;

        loopLockCounter_.lock();
        if (loopCounter_ == 0)
            loopLock_.lock();
        loopCounter_++;
        loopLockCounter_.unlock();


        TreeData &tree      = startTree ? tStart_ : tGoal_;
        startTree = !startTree;
        TreeData &otherTree = startTree ? tStart_ : tGoal_;

        Motion *existing = selectMotion(rng, tree);
        if (!samplerArray_[tid]->sampleNear(xstate, existing->state, maxDistance_))
            continue;

        /* create a motion */
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, xstate);
        motion->parent = existing;
        motion->root = existing->root;

        existing->lock.lock();
        existing->children.push_back(motion);
        existing->lock.unlock();

        addMotion(tree, motion);

        if (checkSolution(rng, !startTree, tree, otherTree, motion, solution))
        {
            sol->lock.lock();
            if (!sol->found)
            {
                sol->found = true;
                PathGeometric *path = new PathGeometric(si_);
                for (unsigned int i = 0 ; i < solution.size() ; ++i)
                    path->append(solution[i]->state);
                pdef_->addSolutionPath(base::PathPtr(path), false, 0.0, getName());
            }
            sol->lock.unlock();
        }


        loopLockCounter_.lock();
        loopCounter_--;
        if (loopCounter_ == 0)
            loopLock_.unlock();
        loopLockCounter_.unlock();
    }

    si_->freeState(xstate);
}
コード例 #4
0
ファイル: BFRRT.cpp プロジェクト: bmagyar/exotica
    base::PlannerStatus BFRRT::solve(
        const base::PlannerTerminationCondition &ptc)
    {
      checkValidity();
      base::GoalSampleableRegion *goal =
          dynamic_cast<base::GoalSampleableRegion*>(pdef_->getGoal().get());

      if (!goal)
      {
        OMPL_ERROR("%s: Unknown type of goal", getName().c_str());
        return base::PlannerStatus::UNRECOGNIZED_GOAL_TYPE;
      }
      TreeGrowingInfo tgi;
      while (const base::State *st = pis_.nextStart())
      {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
        motion->root = motion->state;
        tStart_->add(motion);
        tgi.last_s = motion;
      }

      if (tStart_->size() == 0)
      {
        OMPL_ERROR("%s: Motion planning start tree could not be initialized!",
            getName().c_str());
        return base::PlannerStatus::INVALID_START;
      }

      if (!goal->couldSample())
      {
        OMPL_ERROR("%s: Insufficient states in sampleable goal region",
            getName().c_str());
        return base::PlannerStatus::INVALID_GOAL;
      }

      if (!sampler_) sampler_ = si_->allocStateSampler();

      OMPL_INFORM(
          "%s: Starting planning with %d states already in datastructure",
          getName().c_str(), (int )(tStart_->size() + tGoal_->size()));

      Motion *rmotion = new Motion(si_);
      bool startTree = true;
      bool solved = false;

      while (ptc == false)
      {
        TreeData &tree = startTree ? tStart_ : tGoal_;
        tgi.start = startTree;
        startTree = !startTree;
        TreeData &otherTree = startTree ? tStart_ : tGoal_;

        if (tGoal_->size() == 0
            || pis_.getSampledGoalsCount() < tGoal_->size() / 2)
        {
          const base::State *st =
              tGoal_->size() == 0 ? pis_.nextGoal(ptc) : pis_.nextGoal();
          if (st)
          {
            Motion *motion = new Motion(si_);
            si_->copyState(motion->state, st);
            motion->root = motion->state;
            tGoal_->add(motion);
            tgi.last_g = motion;
          }

          if (tGoal_->size() == 0)
          {
            OMPL_ERROR("%s: Unable to sample any valid states for goal tree",
                getName().c_str());
            break;
          }
        }
        static double nearest_r = 0.05
            * distanceFunction(tgi.last_s, tgi.last_g);
        ///	Get a random state
        bool r_ok = false;
        do
        {
          sampler_->sampleUniform(rmotion->state);
          r_ok = si_->getStateValidityChecker()->isValid(rmotion->state);
        } while (!r_ok && ptc == false);
        Motion *nearest_s = tStart_->nearest(rmotion);
        Motion *nearest_g = tGoal_->nearest(rmotion);
        Motion *last_valid_motion = new Motion(si_);
        std::pair<ompl::base::State*, double> last_valid(
            last_valid_motion->state, 0);

        Motion *new_s = NULL;
        Motion *new_g = NULL;
        ///	Connect random node to start tree
        bool succ_s = si_->checkMotion(nearest_s->state, rmotion->state,
            last_valid);
        if (succ_s)
        {
          Motion *motion = new Motion(si_);
          si_->copyState(motion->state, rmotion->state);
          motion->parent = nearest_s;
          tStart_->add(motion);
          new_s = motion;
        }
        else
        {
          if (last_valid.second == 0) last_valid_motion->state = NULL;
          Eigen::VectorXd eigen_g((int) si_->getStateDimension());
          memcpy(eigen_g.data(),
              rmotion->state->as<ompl::base::RealVectorStateSpace::StateType>()->values,
              sizeof(double) * eigen_g.rows());
          local_map_->jointRef = eigen_g;
          local_solver_->getProblem()->setTau(1e-4);
          Motion *new_motion = new Motion(si_);
          if (localSolve(nearest_s, last_valid_motion->state, new_motion))
          {
            new_s = new_motion;
            tStart_->add(new_motion);
            succ_s = true;
          }
          else if (new_motion->internal_path)
          {
            si_->copyState(rmotion->state, new_motion->state);
            bool addNew = true;
//						std::vector<Motion*> n_motions;
//						tStart_->nearestR(new_motion, nearest_r, n_motions);
//						for (int i = 0; i < n_motions.size(); i++)
//							if (!n_motions[i]->global_valid_)
//							{
//								addNew = false;
//								break;
//							}
            if (addNew)
            {
              new_motion->global_valid_ = false;
              tStart_->add(new_motion);
              si_->copyState(rmotion->state, new_motion->state);
            }
          }
        }

        ///	For goal tree, do the same thing
        last_valid.second = 0;
        bool succ_g = si_->checkMotion(nearest_g->state, rmotion->state,
            last_valid);
        if (succ_g)
        {
          Motion *motion = new Motion(si_);
          si_->copyState(motion->state, rmotion->state);
          motion->parent = nearest_g;
          tGoal_->add(motion);
          new_g = motion;
        }
        else
        {
          if (last_valid.second == 0) last_valid_motion->state = NULL;
          Eigen::VectorXd eigen_g((int) si_->getStateDimension());
          memcpy(eigen_g.data(),
              rmotion->state->as<ompl::base::RealVectorStateSpace::StateType>()->values,
              sizeof(double) * eigen_g.rows());
          local_map_->jointRef = eigen_g;
          local_solver_->getProblem()->setTau(1e-4);
          Motion *new_motion = new Motion(si_);
          if (localSolve(nearest_g, last_valid_motion->state, new_motion))
          {
            new_g = new_motion;
            succ_g = true;
          }
          else if (new_motion->internal_path)
          {
            si_->copyState(rmotion->state, new_motion->state);
            bool addNew = true;
//						std::vector<Motion*> n_motions;
//						tGoal_->nearestR(new_motion, nearest_r, n_motions);
//						for (int i = 0; i < n_motions.size(); i++)
//							if (!n_motions[i]->global_valid_)
//							{
//								addNew = false;
//								break;
//							}
            if (addNew)
            {
              new_motion->global_valid_ = false;
              tGoal_->add(new_motion);
            }
          }
        }

        ///	If succeeded both ways, the a solution is found
        if (succ_s && succ_g)
        {
          connectionPoint_ = std::make_pair(new_s->state, new_g->state);
          Motion *solution = new_s;
          std::vector<Motion*> mpath1;
          while (solution != NULL)
          {
            if (solution->internal_path != nullptr)
            {
              for (int i = solution->internal_path->rows() - 1; i > 0; i--)
              {
                Motion *local_motion = new Motion(si_);
                Eigen::VectorXd tmp = solution->internal_path->row(i);
                memcpy(
                    local_motion->state->as<
                        ompl::base::RealVectorStateSpace::StateType>()->values,
                    tmp.data(),
                    sizeof(double) * (int) si_->getStateDimension());
                mpath1.push_back(local_motion);
              }
              if (solution->inter_state != NULL)
              {
                Motion *local_motion = new Motion(si_);
                si_->copyState(local_motion->state, solution->inter_state);
                mpath1.push_back(local_motion);
              }
            }
            else
              mpath1.push_back(solution);
            solution = solution->parent;
          }

          solution = new_g;
          std::vector<Motion*> mpath2;
          while (solution != NULL)
          {
            if (solution->internal_path != nullptr)
            {
              for (int i = solution->internal_path->rows() - 1; i > 0; i--)
              {
                Motion *local_motion = new Motion(si_);
                Eigen::VectorXd tmp = solution->internal_path->row(i);
                memcpy(
                    local_motion->state->as<
                        ompl::base::RealVectorStateSpace::StateType>()->values,
                    tmp.data(),
                    sizeof(double) * (int) si_->getStateDimension());
                mpath2.push_back(local_motion);
              }
              if (solution->inter_state != NULL)
              {
                Motion *local_motion = new Motion(si_);
                si_->copyState(local_motion->state, solution->inter_state);
                mpath2.push_back(local_motion);
              }
            }
            else
              mpath2.push_back(solution);
            solution = solution->parent;
          }

          PathGeometric *path = new PathGeometric(si_);
          path->getStates().reserve(mpath1.size() + mpath2.size());
          for (int i = mpath1.size() - 1; i >= 0; --i)
            path->append(mpath1[i]->state);
          for (unsigned int i = 0; i < mpath2.size(); ++i)
            path->append(mpath2[i]->state);

          pdef_->addSolutionPath(base::PathPtr(path), false, 0.0, getName());
          solved = true;
          break;
        }
      }

      si_->freeState(rmotion->state);
      delete rmotion;

      OMPL_INFORM("%s: Created %u states (%u start + %u goal)",
          getName().c_str(), tStart_->size() + tGoal_->size(), tStart_->size(),
          tGoal_->size());

      return
          solved ?
              base::PlannerStatus::EXACT_SOLUTION : base::PlannerStatus::TIMEOUT;
    }
コード例 #5
0
ファイル: BKPIECE1.cpp プロジェクト: megan-starr9/UAV_Aiolos
bool ompl::geometric::BKPIECE1::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::GoalSampleableRegion *goal = dynamic_cast<base::GoalSampleableRegion*>(pdef_->getGoal().get());

    if (!goal)
    {
        msg_.error("Unknown type of goal (or goal undefined)");
        return false;
    }

    Discretization<Motion>::Coord xcoord;

    while (const base::State *st = pis_.nextStart())
    {
        Motion* motion = new Motion(si_);
        si_->copyState(motion->state, st);
        motion->root = motion->state;
        projectionEvaluator_->computeCoordinates(motion->state, xcoord);
        dStart_.addMotion(motion, xcoord);
    }

    if (dStart_.getMotionCount() == 0)
    {
        msg_.error("Motion planning start tree could not be initialized!");
        return false;
    }

    if (!goal->couldSample())
    {
        msg_.error("Insufficient states in sampleable goal region");
        return false;
    }

    if (!sampler_)
        sampler_ = si_->allocValidStateSampler();

    msg_.inform("Starting with %d states", (int)(dStart_.getMotionCount() + dGoal_.getMotionCount()));

    std::vector<Motion*> solution;
    base::State *xstate = si_->allocState();
    bool      startTree = true;
    bool         solved = false;

    while (ptc() == false)
    {
        Discretization<Motion> &disc      = startTree ? dStart_ : dGoal_;
        startTree = !startTree;
        Discretization<Motion> &otherDisc = startTree ? dStart_ : dGoal_;
        disc.countIteration();

        // if we have not sampled too many goals already
        if (dGoal_.getMotionCount() == 0 || pis_.getSampledGoalsCount() < dGoal_.getMotionCount() / 2)
        {
            const base::State *st = dGoal_.getMotionCount() == 0 ? pis_.nextGoal(ptc) : pis_.nextGoal();
            if (st)
            {
                Motion* motion = new Motion(si_);
                si_->copyState(motion->state, st);
                motion->root = motion->state;
                projectionEvaluator_->computeCoordinates(motion->state, xcoord);
                dGoal_.addMotion(motion, xcoord);
            }
            if (dGoal_.getMotionCount() == 0)
            {
                msg_.error("Unable to sample any valid states for goal tree");
                break;
            }
        }

        Discretization<Motion>::Cell *ecell    = NULL;
        Motion                       *existing = NULL;
        disc.selectMotion(existing, ecell);
        assert(existing);
        if (sampler_->sampleNear(xstate, existing->state, maxDistance_))
        {
            std::pair<base::State*, double> fail(xstate, 0.0);
            bool keep = si_->checkMotion(existing->state, xstate, fail);
            if (!keep && fail.second > minValidPathFraction_)
                keep = true;

            if (keep)
            {
                /* create a motion */
                Motion *motion = new Motion(si_);
                si_->copyState(motion->state, xstate);
                motion->root = existing->root;
                motion->parent = existing;

                projectionEvaluator_->computeCoordinates(motion->state, xcoord);
                disc.addMotion(motion, xcoord);

                Discretization<Motion>::Cell* cellC = otherDisc.getGrid().getCell(xcoord);

                if (cellC && !cellC->data->motions.empty())
                {
                    Motion* connectOther = cellC->data->motions[rng_.uniformInt(0, cellC->data->motions.size() - 1)];

                    if (goal->isStartGoalPairValid(startTree ? connectOther->root : motion->root, startTree ? motion->root : connectOther->root) &&
                        si_->checkMotion(motion->state, connectOther->state))
                    {
                        /* extract the motions and put them in solution vector */

                        std::vector<Motion*> mpath1;
                        while (motion != NULL)
                        {
                            mpath1.push_back(motion);
                            motion = motion->parent;
                        }

                        std::vector<Motion*> mpath2;
                        while (connectOther != NULL)
                        {
                            mpath2.push_back(connectOther);
                            connectOther = connectOther->parent;
                        }

                        if (startTree)
                            mpath1.swap(mpath2);

                        PathGeometric *path = new PathGeometric(si_);
                        path->getStates().reserve(mpath1.size() + mpath2.size());
                        for (int i = mpath1.size() - 1 ; i >= 0 ; --i)
                            path->append(mpath1[i]->state);
                        for (unsigned int i = 0 ; i < mpath2.size() ; ++i)
                            path->append(mpath2[i]->state);

                        goal->addSolutionPath(base::PathPtr(path), false, 0.0);
                        solved = true;
                        break;
                    }
                }
            }
            else
              ecell->data->score *= failedExpansionScoreFactor_;
        }
        else
            ecell->data->score *= failedExpansionScoreFactor_;
        disc.updateCell(ecell);
    }

    si_->freeState(xstate);

    msg_.inform("Created %u (%u start + %u goal) states in %u cells (%u start (%u on boundary) + %u goal (%u on boundary))",
                dStart_.getMotionCount() + dGoal_.getMotionCount(), dStart_.getMotionCount(), dGoal_.getMotionCount(),
                dStart_.getCellCount() + dGoal_.getCellCount(), dStart_.getCellCount(), dStart_.getGrid().countExternal(),
                dGoal_.getCellCount(), dGoal_.getGrid().countExternal());

    return solved;
}
コード例 #6
0
ファイル: LBTRRT.cpp プロジェクト: RickOne16/ompl
ompl::base::PlannerStatus ompl::geometric::LBTRRT::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    // update goal and check validity
    base::Goal                 *goal   = pdef_->getGoal().get();
    base::GoalSampleableRegion *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);

    if (!goal)
    {
        OMPL_ERROR("%s: Goal undefined", getName().c_str());
        return base::PlannerStatus::INVALID_GOAL;
    }

    // update start and check validity
    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state_, st);
        motion->id_ = nn_->size();
        idToMotionMap_.push_back(motion);
        nn_->add(motion);
        lowerBoundGraph_.addVertex(motion->id_);
    }

    if (nn_->size() == 0)
    {
        OMPL_ERROR("%s: There are no valid initial states!", getName().c_str());
        return base::PlannerStatus::INVALID_START;
    }

    if (nn_->size() > 1)
    {
        OMPL_ERROR("%s: There are multiple start states - currently not supported!", getName().c_str());
        return base::PlannerStatus::INVALID_START;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    OMPL_INFORM("%s: Starting planning with %u states already in datastructure", getName().c_str(), nn_->size());

    Motion *solution  = lastGoalMotion_;
    Motion *approxSol = nullptr;
    double  approxdif = std::numeric_limits<double>::infinity();
    // e*(1+1/d)  K-nearest constant, as used in RRT*
    double k_rrg      = boost::math::constants::e<double>() +
                        boost::math::constants::e<double>() / (double)si_->getStateDimension();

    Motion *rmotion   = new Motion(si_);
    base::State *rstate = rmotion->state_;
    base::State *xstate = si_->allocState();
    unsigned int statesGenerated = 0;

    bestCost_ = lastGoalMotion_ ? lastGoalMotion_->costApx_ : std::numeric_limits<double>::infinity();
    while (ptc() == false)
    {
        iterations_++;
        /* sample random state (with goal biasing) */
        if (goal_s && rng_.uniform01() < goalBias_ && goal_s->canSample())
            goal_s->sampleGoal(rstate);
        else
            sampler_->sampleUniform(rstate);

        /* find closest state in the tree */
        Motion *nmotion = nn_->nearest(rmotion);
        base::State *dstate = rstate;

        /* find state to add */
        double d = si_->distance(nmotion->state_, rstate);
        if (d == 0) // this takes care of the case that the goal is a single point and we re-sample it multiple times
            continue;
        if (d > maxDistance_)
        {
            si_->getStateSpace()->interpolate(nmotion->state_, rstate, maxDistance_ / d, xstate);
            dstate = xstate;
        }

        if (checkMotion(nmotion->state_, dstate))
        {
            statesGenerated++;
            /* create a motion */
            Motion *motion = new Motion(si_);
            si_->copyState(motion->state_, dstate);

            /* update fields */
            double distN = distanceFunction(nmotion, motion);

            motion->id_ = nn_->size();
            idToMotionMap_.push_back(motion);
            lowerBoundGraph_.addVertex(motion->id_);
            motion->parentApx_ = nmotion;

            std::list<std::size_t> dummy;
            lowerBoundGraph_.addEdge(nmotion->id_, motion->id_, distN, false, dummy);

            motion->costLb_ = nmotion->costLb_ + distN;
            motion->costApx_ = nmotion->costApx_ + distN;
            nmotion->childrenApx_.push_back(motion);

            std::vector<Motion*> nnVec;
            unsigned int k = std::ceil(k_rrg * log((double)(nn_->size() + 1)));
            nn_->nearestK(motion, k, nnVec);
            nn_->add(motion); // if we add the motion before the nearestK call, we will get ourselves...

            IsLessThan isLessThan(this, motion);
            std::sort(nnVec.begin(), nnVec.end(), isLessThan);

            //-------------------------------------------------//
            //  Rewiring Part (i) - find best parent of motion //
            //-------------------------------------------------//
            if (motion->parentApx_ != nnVec.front())
            {
                for (std::size_t i(0); i < nnVec.size(); ++i)
                {
                    Motion *potentialParent = nnVec[i];
                    double dist = distanceFunction(potentialParent, motion);
                    considerEdge(potentialParent, motion, dist);
                }
            }

            //------------------------------------------------------------------//
            //  Rewiring Part (ii)                                              //
            //  check if motion may be a better parent to one of its neighbors  //
            //------------------------------------------------------------------//
            for (std::size_t i(0); i < nnVec.size(); ++i)
            {
                Motion *child = nnVec[i];
                double dist = distanceFunction(motion, child);
                considerEdge(motion, child, dist);
            }

            double dist = 0.0;
            bool sat = goal->isSatisfied(motion->state_, &dist);

            if (sat)
            {
                approxdif = dist;
                solution = motion;
            }
            if (dist < approxdif)
            {
                approxdif = dist;
                approxSol = motion;
            }

            if (solution != nullptr && bestCost_ != solution->costApx_)
            {
                OMPL_INFORM("%s: approximation cost = %g", getName().c_str(),
                    solution->costApx_);
                bestCost_ = solution->costApx_;
            }
        }
    }

    bool solved = false;
    bool approximate = false;

    if (solution == nullptr)
    {
        solution = approxSol;
        approximate = true;
    }

    if (solution != nullptr)
    {
        lastGoalMotion_ = solution;

        /* construct the solution path */
        std::vector<Motion*> mpath;
        while (solution != nullptr)
        {
            mpath.push_back(solution);
            solution = solution->parentApx_;
        }

        /* set the solution path */
        PathGeometric *path = new PathGeometric(si_);
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            path->append(mpath[i]->state_);
        // Add the solution path.
        base::PathPtr bpath(path);
        base::PlannerSolution psol(bpath);
        psol.setPlannerName(getName());
        if (approximate)
            psol.setApproximate(approxdif);
        pdef_->addSolutionPath(psol);
        solved = true;
    }

    si_->freeState(xstate);
    if (rmotion->state_)
        si_->freeState(rmotion->state_);
    delete rmotion;

    OMPL_INFORM("%s: Created %u states", getName().c_str(), statesGenerated);

    return base::PlannerStatus(solved, approximate);
}
コード例 #7
0
bool ompl::geometric::BallTreeRRTstar::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::Goal                 *goal   = pdef_->getGoal().get();
    base::GoalSampleableRegion *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);

    if (!goal)
    {
        msg_.error("Goal undefined");
        return false;
    }

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_, rO_);
        si_->copyState(motion->state, st);
        addMotion(motion);
    }

    if (nn_->size() == 0)
    {
        msg_.error("There are no valid initial states!");
        return false;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    msg_.inform("Starting with %u states", nn_->size());

    Motion *solution       = NULL;
    Motion *approximation  = NULL;
    double approximatedist = std::numeric_limits<double>::infinity();
    bool sufficientlyShort = false;

    Motion *rmotion   = new Motion(si_, rO_);
    Motion *toTrim    = NULL;
    base::State *rstate = rmotion->state;
    base::State *xstate = si_->allocState();
    base::State *tstate = si_->allocState();
    std::vector<Motion*> solCheck;
    std::vector<Motion*> nbh;
    std::vector<double>  dists;
    std::vector<int>     valid;
    long unsigned int    rewireTest = 0;

    std::pair<base::State*,double> lastValid(tstate, 0.0);

    while (ptc() == false)
    {
        bool rejected = false;

        /* sample until a state not within any of the existing volumes is found */
        do
        {
            /* sample random state (with goal biasing) */
            if (goal_s && rng_.uniform01() < goalBias_ && goal_s->canSample())
                goal_s->sampleGoal(rstate);
            else
                sampler_->sampleUniform(rstate);

            /* check to see if it is inside an existing volume */
            if (inVolume(rstate))
            {
                rejected = true;

                /* see if the state is valid */
                if(!si_->isValid(rstate))
                {
                    /* if it's not, reduce the size of the nearest volume to the distance
                       between its center and the rejected state */
                    toTrim = nn_->nearest(rmotion);
                    double newRad = si_->distance(toTrim->state, rstate);
                    if (newRad < toTrim->volRadius)
                        toTrim->volRadius = newRad;
                }

            }
            else

                rejected = false;

        }
        while (rejected);

        /* find closest state in the tree */
        Motion *nmotion = nn_->nearest(rmotion);

        base::State *dstate = rstate;

        /* find state to add */
        double d = si_->distance(nmotion->state, rstate);
        if (d > maxDistance_)
        {
            si_->getStateSpace()->interpolate(nmotion->state, rstate, maxDistance_ / d, xstate);
            dstate = xstate;
        }

        if (si_->checkMotion(nmotion->state, dstate, lastValid))
        {
            /* create a motion */
            double distN = si_->distance(dstate, nmotion->state);
            Motion *motion = new Motion(si_, rO_);
            si_->copyState(motion->state, dstate);
            motion->parent = nmotion;
            motion->cost = nmotion->cost + distN;

            /* find nearby neighbors */
            double r = std::min(ballRadiusConst_ * (sqrt(log((double)(1 + nn_->size())) / ((double)(nn_->size())))),
                                ballRadiusMax_);

            nn_->nearestR(motion, r, nbh);
            rewireTest += nbh.size();

            // cache for distance computations
            dists.resize(nbh.size());
            // cache for motion validity
            valid.resize(nbh.size());
            std::fill(valid.begin(), valid.end(), 0);

            if (delayCC_)
            {
                // calculate all costs and distances
                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                    if (nbh[i] != nmotion)
                    {
                        double c = nbh[i]->cost + si_->distance(nbh[i]->state, dstate);
                        nbh[i]->cost = c;
                    }

                // sort the nodes
                std::sort(nbh.begin(), nbh.end(), compareMotion);

                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                    if (nbh[i] != nmotion)
                    {
                        dists[i] = si_->distance(nbh[i]->state, dstate);
                        nbh[i]->cost -= dists[i];
                    }
                // collision check until a valid motion is found
                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                    if (nbh[i] != nmotion)
                    {

                        dists[i] = si_->distance(nbh[i]->state, dstate);
                        double c = nbh[i]->cost + dists[i];
                        if (c < motion->cost)
                        {
                            if (si_->checkMotion(nbh[i]->state, dstate, lastValid))
                            {
                                motion->cost = c;
                                motion->parent = nbh[i];
                                valid[i] = 1;
                                break;
                            }
                            else
                            {
                                valid[i] = -1;
                                /* if a collision is found, trim radius to distance from motion to last valid state */
                                double nR = si_->distance(nbh[i]->state, lastValid.first);
                                if (nR < nbh[i]->volRadius)
                                    nbh[i]->volRadius = nR;
                            }
                        }
                    }
                    else
                    {
                        valid[i] = 1;
                        dists[i] = distN;
                        break;
                    }

            }
            else{
                /* find which one we connect the new state to*/
                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                    if (nbh[i] != nmotion)
                    {

                        dists[i] = si_->distance(nbh[i]->state, dstate);
                        double c = nbh[i]->cost + dists[i];
                        if (c < motion->cost)
                        {
                            if (si_->checkMotion(nbh[i]->state, dstate, lastValid))
                            {
                                motion->cost = c;
                                motion->parent = nbh[i];
                                valid[i] = 1;
                            }
                            else
                            {
                                valid[i] = -1;
                                /* if a collision is found, trim radius to distance from motion to last valid state */
                                double newR = si_->distance(nbh[i]->state, lastValid.first);
                                if (newR < nbh[i]->volRadius)
                                    nbh[i]->volRadius = newR;

                            }
                        }
                    }
                    else
                    {
                        valid[i] = 1;
                        dists[i] = distN;
                    }
            }

            /* add motion to tree */
            addMotion(motion);
            motion->parent->children.push_back(motion);

            solCheck.resize(1);
            solCheck[0] = motion;

            /* rewire tree if needed */
            for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                if (nbh[i] != motion->parent)
                {
                    double c = motion->cost + dists[i];
                    if (c < nbh[i]->cost)
                    {
                        bool v = false;
                        if (valid[i] == 0)
                        {
                            if(!si_->checkMotion(nbh[i]->state, dstate, lastValid))
                            {
                                /* if a collision is found, trim radius to distance from motion to last valid state */
                                double R =  si_->distance(nbh[i]->state, lastValid.first);
                                if (R < nbh[i]->volRadius)
                                    nbh[i]->volRadius = R;
                            }
                            else
                            {
                                v = true;
                            }
                        }
                        if (valid[i] == 1)
                            v = true;

                        if (v)
                        {
                            // Remove this node from its parent list
                            removeFromParent (nbh[i]);
                            double delta = c - nbh[i]->cost;

                            nbh[i]->parent = motion;
                            nbh[i]->cost = c;
                            nbh[i]->parent->children.push_back(nbh[i]);
                            solCheck.push_back(nbh[i]);

                            // Update the costs of the node's children
                            updateChildCosts(nbh[i], delta);
                        }
                    }
                }

            // check if we found a solution
            for (unsigned int i = 0 ; i < solCheck.size() ; ++i)
            {
                double dist = 0.0;
                bool solved = goal->isSatisfied(solCheck[i]->state, &dist);
                sufficientlyShort = solved ? goal->isPathLengthSatisfied(solCheck[i]->cost) : false;

                if (solved)
                {
                    if (sufficientlyShort)
                    {
                        solution = solCheck[i];
                        break;
                    }
                    else if (!solution || (solCheck[i]->cost < solution->cost))
                    {
                        solution = solCheck[i];
                    }
                }
                else if (!solution && dist < approximatedist)
                {
                    approximation = solCheck[i];
                    approximatedist = dist;
                }
            }

            // terminate if a sufficient solution is found
            if (solution && sufficientlyShort)
                break;
        }
        else
        {
            /* if a collision is found, trim radius to distance from motion to last valid state */
            toTrim = nn_->nearest(nmotion);
            double newRadius =  si_->distance(toTrim->state, lastValid.first);
            if (newRadius < toTrim->volRadius)
                toTrim->volRadius = newRadius;
        }
    }

    double solutionCost;
    bool approximate = (solution == NULL);
    bool addedSolution = false;
    if (approximate)
    {
        solution = approximation;
        solutionCost = approximatedist;
    }
    else
        solutionCost = solution->cost;

    if (solution != NULL)
    {
        // construct the solution path
        std::vector<Motion*> mpath;
        while (solution != NULL)
        {
            mpath.push_back(solution);
            solution = solution->parent;
        }

        // set the solution path
        PathGeometric *path = new PathGeometric(si_);
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            path->append(mpath[i]->state);
        goal->addSolutionPath(base::PathPtr(path), approximate, solutionCost);
        addedSolution = true;
    }

    si_->freeState(xstate);
    if (rmotion->state)
        si_->freeState(rmotion->state);
    delete rmotion;

    msg_.inform("Created %u states. Checked %lu rewire options.", nn_->size(), rewireTest);

    return addedSolution;
}
コード例 #8
0
ファイル: LazyRRT.cpp プロジェクト: OspreyX/ompl-informed
ompl::base::PlannerStatus ompl::geometric::LazyRRT::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::Goal                 *goal   = pdef_->getGoal().get();
    base::GoalSampleableRegion *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
        motion->valid = true;
        nn_->add(motion);
    }

    if (nn_->size() == 0)
    {
        OMPL_ERROR("%s: There are no valid initial states!", getName().c_str());
        return base::PlannerStatus::INVALID_START;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    OMPL_INFORM("%s: Starting planning with %u states already in datastructure", getName().c_str(), nn_->size());

    Motion *solution = NULL;
    double  distsol  = -1.0;
    Motion *rmotion  = new Motion(si_);
    base::State *rstate = rmotion->state;
    base::State *xstate = si_->allocState();

    bool solutionFound = false;

    while (ptc == false && !solutionFound)
    {
        /* sample random state (with goal biasing) */
        if (goal_s && rng_.uniform01() < goalBias_ && goal_s->canSample())
            goal_s->sampleGoal(rstate);
        else
            sampler_->sampleUniform(rstate);

        /* find closest state in the tree */
        Motion *nmotion = nn_->nearest(rmotion);
        assert(nmotion != rmotion);
        base::State *dstate = rstate;

        /* find state to add */
        double d = si_->distance(nmotion->state, rstate);
        if (d > maxDistance_)
        {
            si_->getStateSpace()->interpolate(nmotion->state, rstate, maxDistance_ / d, xstate);
            dstate = xstate;
        }

        /* create a motion */
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, dstate);
        motion->parent = nmotion;
        nmotion->children.push_back(motion);
        nn_->add(motion);

        double dist = 0.0;
        if (goal->isSatisfied(motion->state, &dist))
        {
            distsol = dist;
            solution = motion;
            solutionFound = true;
            lastGoalMotion_ = solution;

            // Check that the solution is valid:
            // construct the solution path
            std::vector<Motion*> mpath;
            while (solution != NULL)
            {
                mpath.push_back(solution);
                solution = solution->parent;
            }

            // check each segment along the path for validity
            for (int i = mpath.size() - 1 ; i >= 0 && solutionFound; --i)
                if (!mpath[i]->valid)
                {
                    if (si_->checkMotion(mpath[i]->parent->state, mpath[i]->state))
                        mpath[i]->valid = true;
                    else
                    {
                        removeMotion(mpath[i]);
                        solutionFound = false;
                        lastGoalMotion_ = NULL;
                    }
                }

            if (solutionFound)
            {
                // set the solution path
                PathGeometric *path = new PathGeometric(si_);
                for (int i = mpath.size() - 1 ; i >= 0 ; --i)
                    path->append(mpath[i]->state);

                pdef_->addSolutionPath(base::PathPtr(path), false, distsol, getName());
            }
        }
    }

    si_->freeState(xstate);
    si_->freeState(rstate);
    delete rmotion;

    OMPL_INFORM("%s: Created %u states", getName().c_str(), nn_->size());

    return solutionFound ?  base::PlannerStatus::EXACT_SOLUTION : base::PlannerStatus::TIMEOUT;
}
コード例 #9
0
ompl::base::PlannerStatus ompl::geometric::RRTConnect::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::GoalSampleableRegion *goal = dynamic_cast<base::GoalSampleableRegion*>(pdef_->getGoal().get());

    if (!goal)
    {
        logError("Unknown type of goal (or goal undefined)");
        return base::PlannerStatus::UNRECOGNIZED_GOAL_TYPE;
    }

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
        motion->root = motion->state;
        tStart_->add(motion);
    }

    if (tStart_->size() == 0)
    {
        logError("Motion planning start tree could not be initialized!");
        return base::PlannerStatus::INVALID_START;
    }

    if (!goal->couldSample())
    {
        logError("Insufficient states in sampleable goal region");
        return base::PlannerStatus::INVALID_GOAL;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    logInform("Starting with %d states", (int)(tStart_->size() + tGoal_->size()));

    TreeGrowingInfo tgi;
    tgi.xstate = si_->allocState();

    Motion   *rmotion   = new Motion(si_);
    base::State *rstate = rmotion->state;
    bool startTree      = true;
    bool solved         = false;

    while (ptc() == false)
    {
        TreeData &tree      = startTree ? tStart_ : tGoal_;
        tgi.start = startTree;
        startTree = !startTree;
        TreeData &otherTree = startTree ? tStart_ : tGoal_;

        if (tGoal_->size() == 0 || pis_.getSampledGoalsCount() < tGoal_->size() / 2)
        {
            const base::State *st = tGoal_->size() == 0 ? pis_.nextGoal(ptc) : pis_.nextGoal();
            if (st)
            {
                Motion* motion = new Motion(si_);
                si_->copyState(motion->state, st);
                motion->root = motion->state;
                tGoal_->add(motion);
            }

            if (tGoal_->size() == 0)
            {
                logError("Unable to sample any valid states for goal tree");
                break;
            }
        }

        /* sample random state */
        sampler_->sampleUniform(rstate);

        GrowState gs = growTree(tree, tgi, rmotion);

        if (gs != TRAPPED)
        {
            /* remember which motion was just added */
            Motion *addedMotion = tgi.xmotion;

            /* attempt to connect trees */

            /* if reached, it means we used rstate directly, no need top copy again */
            if (gs != REACHED)
                si_->copyState(rstate, tgi.xstate);

            GrowState gsc = ADVANCED;
            tgi.start = startTree;
            while (gsc == ADVANCED)
                gsc = growTree(otherTree, tgi, rmotion);

            Motion *startMotion = startTree ? tgi.xmotion : addedMotion;
            Motion *goalMotion  = startTree ? addedMotion : tgi.xmotion;

            /* if we connected the trees in a valid way (start and goal pair is valid)*/
            if (gsc == REACHED && goal->isStartGoalPairValid(startMotion->root, goalMotion->root))
            {
                // it must be the case that either the start tree or the goal tree has made some progress
                // so one of the parents is not NULL. We go one step 'back' to avoid having a duplicate state
                // on the solution path
                if (startMotion->parent)
                    startMotion = startMotion->parent;
                else
                    goalMotion = goalMotion->parent;

                connectionPoint_ = std::make_pair<base::State*, base::State*>(startMotion->state, goalMotion->state);

                /* construct the solution path */
                Motion *solution = startMotion;
                std::vector<Motion*> mpath1;
                while (solution != NULL)
                {
                    mpath1.push_back(solution);
                    solution = solution->parent;
                }

                solution = goalMotion;
                std::vector<Motion*> mpath2;
                while (solution != NULL)
                {
                    mpath2.push_back(solution);
                    solution = solution->parent;
                }

                PathGeometric *path = new PathGeometric(si_);
                path->getStates().reserve(mpath1.size() + mpath2.size());
                for (int i = mpath1.size() - 1 ; i >= 0 ; --i)
                    path->append(mpath1[i]->state);
                for (unsigned int i = 0 ; i < mpath2.size() ; ++i)
                    path->append(mpath2[i]->state);

                pdef_->addSolutionPath(base::PathPtr(path), false, 0.0);
                solved = true;
                break;
            }
        }
    }

    si_->freeState(tgi.xstate);
    si_->freeState(rstate);
    delete rmotion;

    logInform("Created %u states (%u start + %u goal)", tStart_->size() + tGoal_->size(), tStart_->size(), tGoal_->size());

    return solved ? base::PlannerStatus::EXACT_SOLUTION : base::PlannerStatus::TIMEOUT;
}
コード例 #10
0
ファイル: LBKPIECE1.cpp プロジェクト: giogadi/ompl
ompl::base::PlannerStatus ompl::geometric::LBKPIECE1::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::GoalSampleableRegion *goal = dynamic_cast<base::GoalSampleableRegion*>(pdef_->getGoal().get());

    if (!goal)
    {
        OMPL_ERROR("%s: Unknown type of goal", getName().c_str());
        return base::PlannerStatus::UNRECOGNIZED_GOAL_TYPE;
    }

    Discretization<Motion>::Coord xcoord;

    while (const base::State *st = pis_.nextStart())
    {
        Motion* motion = new Motion(si_);
        si_->copyState(motion->state, st);
        motion->root = st;
        motion->valid = true;
        projectionEvaluator_->computeCoordinates(motion->state, xcoord);
        dStart_.addMotion(motion, xcoord);
    }

    if (dStart_.getMotionCount() == 0)
    {
        OMPL_ERROR("%s: Motion planning start tree could not be initialized!", getName().c_str());
        return base::PlannerStatus::INVALID_START;
    }

    if (!goal->couldSample())
    {
        OMPL_ERROR("%s: Insufficient states in sampleable goal region", getName().c_str());
        return base::PlannerStatus::INVALID_GOAL;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    OMPL_INFORM("%s: Starting with %d states", getName().c_str(), (int)(dStart_.getMotionCount() + dGoal_.getMotionCount()));

    base::State *xstate = si_->allocState();
    bool      startTree = true;
    bool         solved = false;

    while (ptc == false)
    {
        Discretization<Motion> &disc      = startTree ? dStart_ : dGoal_;
        startTree = !startTree;
        Discretization<Motion> &otherDisc = startTree ? dStart_ : dGoal_;
        disc.countIteration();

        // if we have not sampled too many goals already
        if (dGoal_.getMotionCount() == 0 || pis_.getSampledGoalsCount() < dGoal_.getMotionCount() / 2)
        {
            const base::State *st = dGoal_.getMotionCount() == 0 ? pis_.nextGoal(ptc) : pis_.nextGoal();
            if (st)
            {
                Motion* motion = new Motion(si_);
                si_->copyState(motion->state, st);
                motion->root = motion->state;
                motion->valid = true;
                projectionEvaluator_->computeCoordinates(motion->state, xcoord);
                dGoal_.addMotion(motion, xcoord);
            }
            if (dGoal_.getMotionCount() == 0)
            {
                OMPL_ERROR("%s: Unable to sample any valid states for goal tree", getName().c_str());
                break;
            }
        }

        Discretization<Motion>::Cell *ecell    = NULL;
        Motion                       *existing = NULL;
        disc.selectMotion(existing, ecell);
        assert(existing);
        sampler_->sampleUniformNear(xstate, existing->state, maxDistance_);

        /* create a motion */
        Motion* motion = new Motion(si_);
        si_->copyState(motion->state, xstate);
        motion->parent = existing;
        motion->root = existing->root;
        existing->children.push_back(motion);
        projectionEvaluator_->computeCoordinates(motion->state, xcoord);
        disc.addMotion(motion, xcoord);

        /* attempt to connect trees */
        Discretization<Motion>::Cell *ocell = otherDisc.getGrid().getCell(xcoord);
        if (ocell && !ocell->data->motions.empty())
        {
            Motion* connectOther = ocell->data->motions[rng_.uniformInt(0, ocell->data->motions.size() - 1)];

            if (goal->isStartGoalPairValid(startTree ? connectOther->root : motion->root, startTree ? motion->root : connectOther->root))
            {
                Motion* connect = new Motion(si_);
                si_->copyState(connect->state, connectOther->state);
                connect->parent = motion;
                connect->root = motion->root;
                motion->children.push_back(connect);
                projectionEvaluator_->computeCoordinates(connect->state, xcoord);
                disc.addMotion(connect, xcoord);

                if (isPathValid(disc, connect, xstate) && isPathValid(otherDisc, connectOther, xstate))
                {
                    if (startTree)
                        connectionPoint_ = std::make_pair(connectOther->state, motion->state);
                    else
                        connectionPoint_ = std::make_pair(motion->state, connectOther->state);

                    /* extract the motions and put them in solution vector */

                    std::vector<Motion*> mpath1;
                    while (motion != NULL)
                    {
                        mpath1.push_back(motion);
                        motion = motion->parent;
                    }

                    std::vector<Motion*> mpath2;
                    while (connectOther != NULL)
                    {
                        mpath2.push_back(connectOther);
                        connectOther = connectOther->parent;
                    }

                    if (startTree)
                        mpath1.swap(mpath2);

                    PathGeometric *path = new PathGeometric(si_);
                    path->getStates().reserve(mpath1.size() + mpath2.size());
                    for (int i = mpath1.size() - 1 ; i >= 0 ; --i)
                        path->append(mpath1[i]->state);
                    for (unsigned int i = 0 ; i < mpath2.size() ; ++i)
                        path->append(mpath2[i]->state);

                    pdef_->addSolutionPath(base::PathPtr(path), false, 0.0);
                    solved = true;
                    break;
                }
            }
        }
    }

    si_->freeState(xstate);

    OMPL_INFORM("%s: Created %u (%u start + %u goal) states in %u cells (%u start (%u on boundary) + %u goal (%u on boundary))",
                getName().c_str(),
                dStart_.getMotionCount() + dGoal_.getMotionCount(), dStart_.getMotionCount(), dGoal_.getMotionCount(),
                dStart_.getCellCount() + dGoal_.getCellCount(), dStart_.getCellCount(), dStart_.getGrid().countExternal(),
                dGoal_.getCellCount(), dGoal_.getGrid().countExternal());

    return solved ? base::PlannerStatus::EXACT_SOLUTION : base::PlannerStatus::TIMEOUT;
}
コード例 #11
0
ファイル: RRTstar.cpp プロジェクト: mpomarlan/ompl_slprm
ompl::base::PlannerStatus ompl::geometric::RRTstar::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::Goal                  *goal   = pdef_->getGoal().get();
    base::GoalSampleableRegion  *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);
    base::OptimizationObjective *opt    = pdef_->getOptimizationObjective().get();
    
    // when no optimization objective is specified, we create a temporary one (we should not modify the ProblemDefinition)
    boost::scoped_ptr<base::OptimizationObjective> temporaryOptimizationObjective;

    if (opt && !dynamic_cast<base::PathLengthOptimizationObjective*>(opt))
    {
        opt = NULL;
        OMPL_WARN("Optimization objective '%s' specified, but such an objective is not appropriate for %s. Only path length can be optimized.", getName().c_str(), opt->getDescription().c_str());
    }
    
    if (!opt)
    { 
        // by default, optimize path length and run until completion
        opt = new base::PathLengthOptimizationObjective(si_, std::numeric_limits<double>::epsilon());
        temporaryOptimizationObjective.reset(opt);
        OMPL_INFORM("No optimization objective specified. Defaulting to optimization of path length for the allowed planning time.");
    }

    if (!goal)
    {
        OMPL_ERROR("Goal undefined");
        return base::PlannerStatus::INVALID_GOAL;
    }

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
        nn_->add(motion);
    }

    if (nn_->size() == 0)
    {
        OMPL_ERROR("There are no valid initial states!");
        return base::PlannerStatus::INVALID_START;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    OMPL_INFORM("Starting with %u states", nn_->size());

    Motion *solution       = NULL;
    Motion *approximation  = NULL;
    double approximatedist = std::numeric_limits<double>::infinity();
    bool sufficientlyShort = false;

    Motion *rmotion     = new Motion(si_);
    base::State *rstate = rmotion->state;
    base::State *xstate = si_->allocState();
    std::vector<Motion*> solCheck;
    std::vector<Motion*> nbh;
    std::vector<double>  dists;
    std::vector<int>     valid;
    unsigned int         rewireTest = 0;
    double               stateSpaceDimensionConstant = 1.0 / (double)si_->getStateSpace()->getDimension();

    while (ptc == false)
    {
        // sample random state (with goal biasing)
        if (goal_s && rng_.uniform01() < goalBias_ && goal_s->canSample())
            goal_s->sampleGoal(rstate);
        else
            sampler_->sampleUniform(rstate);

        // find closest state in the tree
        Motion *nmotion = nn_->nearest(rmotion);

        base::State *dstate = rstate;

        // find state to add
        double d = si_->distance(nmotion->state, rstate);
        if (d > maxDistance_)
        {
            si_->getStateSpace()->interpolate(nmotion->state, rstate, maxDistance_ / d, xstate);
            dstate = xstate;
        }

        if (si_->checkMotion(nmotion->state, dstate))
        {
            // create a motion
            double distN = si_->distance(dstate, nmotion->state);
            Motion *motion = new Motion(si_);
            si_->copyState(motion->state, dstate);
            motion->parent = nmotion;
            motion->cost = nmotion->cost + distN;

            // find nearby neighbors
            double r = std::min(ballRadiusConst_ * pow(log((double)(1 + nn_->size())) / (double)(nn_->size()), stateSpaceDimensionConstant),
                                ballRadiusMax_);

            nn_->nearestR(motion, r, nbh);
            rewireTest += nbh.size();

            // cache for distance computations
            dists.resize(nbh.size());
            // cache for motion validity
            valid.resize(nbh.size());
            std::fill(valid.begin(), valid.end(), 0);

            if (delayCC_)
            {
                // calculate all costs and distances
                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                    nbh[i]->cost += si_->distance(nbh[i]->state, dstate);

                // sort the nodes
                std::sort(nbh.begin(), nbh.end(), compareMotion);

                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                {
                    dists[i] = si_->distance(nbh[i]->state, dstate);
                    nbh[i]->cost -= dists[i];
                }

                // collision check until a valid motion is found
                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                {
                    if (nbh[i] != nmotion)
                    {
                        double c = nbh[i]->cost + dists[i];
                        if (c < motion->cost)
                        {
                            if (si_->checkMotion(nbh[i]->state, dstate))
                            {
                                motion->cost = c;
                                motion->parent = nbh[i];
                                valid[i] = 1;
                                break;
                            }
                            else
                                valid[i] = -1;
                        }
                    }
                    else
                    {
                        valid[i] = 1;
                        dists[i] = distN;
                        break;
                    }
                }
            }
            else
            {
                // find which one we connect the new state to
                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                {
                    if (nbh[i] != nmotion)
                    {
                        dists[i] = si_->distance(nbh[i]->state, dstate);
                        double c = nbh[i]->cost + dists[i];
                        if (c < motion->cost)
                        {
                            if (si_->checkMotion(nbh[i]->state, dstate))
                            {
                                motion->cost = c;
                                motion->parent = nbh[i];
                                valid[i] = 1;
                            }
                            else
                                valid[i] = -1;
                        }
                    }
                    else
                    {
                        valid[i] = 1;
                        dists[i] = distN;
                    }
                }
            }

            // add motion to the tree
            nn_->add(motion);
            motion->parent->children.push_back(motion);

            solCheck.resize(1);
            solCheck[0] = motion;

            // rewire tree if needed
            for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                if (nbh[i] != motion->parent)
                {
                    double c = motion->cost + dists[i];
                    if (c < nbh[i]->cost)
                    {
                        bool v = valid[i] == 0 ? si_->checkMotion(nbh[i]->state, dstate) : valid[i] == 1;
                        if (v)
                        {
                            // Remove this node from its parent list
                            removeFromParent (nbh[i]);
                            double delta = c - nbh[i]->cost;

                            // Add this node to the new parent
                            nbh[i]->parent = motion;
                            nbh[i]->cost = c;
                            nbh[i]->parent->children.push_back(nbh[i]);
                            solCheck.push_back(nbh[i]);

                            // Update the costs of the node's children
                            updateChildCosts(nbh[i], delta);
                        }
                    }
                }

            // Make sure to check the existing solution for improvement
            if (solution)
                solCheck.push_back(solution);

            // check if we found a solution
            for (unsigned int i = 0 ; i < solCheck.size() ; ++i)
            {
                double dist = 0.0;
                bool solved = goal->isSatisfied(solCheck[i]->state, &dist);
                sufficientlyShort = solved ? opt->isSatisfied(solCheck[i]->cost) : false;

                if (solved)
                {
                    if (sufficientlyShort)
                    {
                        solution = solCheck[i];
                        break;
                    }
                    else if (!solution || (solCheck[i]->cost < solution->cost))
                    {
                        solution = solCheck[i];
                    }
                }
                else if (!solution && dist < approximatedist)
                {
                    approximation = solCheck[i];
                    approximatedist = dist;
                }
            }
        }

        // terminate if a sufficient solution is found
        if (solution && sufficientlyShort)
            break;
    }
    
    double solutionCost;
    bool approximate = (solution == NULL);
    bool addedSolution = false;
    if (approximate)
    {
        solution = approximation;
        solutionCost = approximatedist;
    }
    else
        solutionCost = solution->cost;

    if (solution != NULL)
    {
        // construct the solution path
        std::vector<Motion*> mpath;
        while (solution != NULL)
        {
            mpath.push_back(solution);
            solution = solution->parent;
        }

        // set the solution path
        PathGeometric *path = new PathGeometric(si_);
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            path->append(mpath[i]->state);
        pdef_->addSolutionPath(base::PathPtr(path), approximate, solutionCost);
        addedSolution = true;
    }

    si_->freeState(xstate);
    if (rmotion->state)
        si_->freeState(rmotion->state);
    delete rmotion;

    OMPL_INFORM("Created %u states. Checked %lu rewire options.", nn_->size(), rewireTest);

    return base::PlannerStatus(addedSolution, approximate);
}
コード例 #12
0
ファイル: KPIECE1.cpp プロジェクト: giogadi/ompl
ompl::base::PlannerStatus ompl::geometric::KPIECE1::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::Goal                   *goal = pdef_->getGoal().get();
    base::GoalSampleableRegion *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);

    Discretization<Motion>::Coord xcoord;

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
        projectionEvaluator_->computeCoordinates(motion->state, xcoord);
        disc_.addMotion(motion, xcoord, 1.0);
    }

    if (disc_.getMotionCount() == 0)
    {
        OMPL_ERROR("%s: There are no valid initial states!", getName().c_str());
        return base::PlannerStatus::INVALID_START;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    OMPL_INFORM("%s: Starting with %u states", getName().c_str(), disc_.getMotionCount());

    Motion *solution    = NULL;
    Motion *approxsol   = NULL;
    double  approxdif   = std::numeric_limits<double>::infinity();
    base::State *xstate = si_->allocState();

    while (ptc == false)
    {
        disc_.countIteration();

        /* Decide on a state to expand from */
        Motion                       *existing = NULL;
        Discretization<Motion>::Cell *ecell    = NULL;
        disc_.selectMotion(existing, ecell);
        assert(existing);

        /* sample random state (with goal biasing) */
        if (goal_s && rng_.uniform01() < goalBias_ && goal_s->canSample())
            goal_s->sampleGoal(xstate);
        else
            sampler_->sampleUniformNear(xstate, existing->state, maxDistance_);

        std::pair<base::State*, double> fail(xstate, 0.0);
        bool keep = si_->checkMotion(existing->state, xstate, fail);
        if (!keep && fail.second > minValidPathFraction_)
            keep = true;

        if (keep)
        {
            /* create a motion */
            Motion *motion = new Motion(si_);
            si_->copyState(motion->state, xstate);
            motion->parent = existing;

            double dist = 0.0;
            bool solv = goal->isSatisfied(motion->state, &dist);
            projectionEvaluator_->computeCoordinates(motion->state, xcoord);
            disc_.addMotion(motion, xcoord, dist); // this will also update the discretization heaps as needed, so no call to updateCell() is needed

            if (solv)
            {
                approxdif = dist;
                solution = motion;
                break;
            }
            if (dist < approxdif)
            {
                approxdif = dist;
                approxsol = motion;
            }
        }
        else
            ecell->data->score *= failedExpansionScoreFactor_;
        disc_.updateCell(ecell);
    }

    bool solved = false;
    bool approximate = false;
    if (solution == NULL)
    {
        solution = approxsol;
        approximate = true;
    }

    if (solution != NULL)
    {
        lastGoalMotion_ = solution;

        /* construct the solution path */
        std::vector<Motion*> mpath;
        while (solution != NULL)
        {
            mpath.push_back(solution);
            solution = solution->parent;
        }

        /* set the solution path */
        PathGeometric *path = new PathGeometric(si_);
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            path->append(mpath[i]->state);
        pdef_->addSolutionPath(base::PathPtr(path), approximate, approxdif);
        solved = true;
    }

    si_->freeState(xstate);

    OMPL_INFORM("%s: Created %u states in %u cells (%u internal + %u external)",
                getName().c_str(),
                disc_.getMotionCount(), disc_.getCellCount(),
                disc_.getGrid().countInternal(), disc_.getGrid().countExternal());

    return base::PlannerStatus(solved, approximate);
}
コード例 #13
0
ompl::base::PlannerStatus ompl::geometric::BiTRRT::solve(const base::PlannerTerminationCondition &ptc)
{
    // Basic error checking
    checkValidity();

    // Goal information
    base::Goal                 *goal = pdef_->getGoal().get();
    base::GoalSampleableRegion *gsr  = dynamic_cast<base::GoalSampleableRegion*>(goal);

    if (!gsr)
    {
        OMPL_ERROR("%s: Goal object does not derive from GoalSampleableRegion", getName().c_str());
        return base::PlannerStatus::INVALID_GOAL;
    }

    // Loop through the (valid) input states and add them to the start tree
    while (const base::State *state = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, state);
        motion->cost = opt_->stateCost(motion->state);
        motion->root = motion->state; // this state is the root of a tree

        if (tStart_->size() == 0)  // do not overwrite best/worst from a prior call to solve
            worstCost_ = bestCost_ = motion->cost;

        // Add start motion to the tree
        tStart_->add(motion);
    }

    if (tStart_->size() == 0)
    {
        OMPL_ERROR("%s: Start tree has no valid states!", getName().c_str());
        return base::PlannerStatus::INVALID_START;
    }

    // Do the same for the goal tree, if it is empty, but only once
    if (tGoal_->size() == 0)
    {
        const base::State *state = pis_.nextGoal(ptc);
        if (state)
        {
            Motion* motion = addMotion(state, tGoal_);
            motion->root = motion->state; // this state is the root of a tree
        }
    }

    if (tGoal_->size() == 0)
    {
        OMPL_ERROR("%s: Goal tree has no valid states!", getName().c_str());
        return base::PlannerStatus::INVALID_GOAL;
    }

    OMPL_INFORM("%s: Planning started with %d states already in datastructure", getName().c_str(), (int)(tStart_->size() + tGoal_->size()));

    base::StateSamplerPtr sampler = si_->allocStateSampler();

    Motion   *rmotion   = new Motion(si_);
    base::State *rstate = rmotion->state;

    Motion   *xmotion   = new Motion(si_);
    base::State *xstate = xmotion->state;

    TreeData tree = tStart_;
    TreeData otherTree = tGoal_;

    bool solved = false;
    // Planning loop
    while (ptc == false)
    {
        // Check if there are more goal states
        if (pis_.getSampledGoalsCount() < tGoal_->size() / 2)
        {
            if (const base::State *state = pis_.nextGoal())
            {
                Motion* motion = addMotion(state, tGoal_);
                motion->root = motion->state; // this state is the root of a tree
            }
        }

        // Sample a state uniformly at random
        sampler->sampleUniform(rstate);

        Motion* result; // the motion that gets added in extendTree
        if (extendTree(rmotion, tree, result) != FAILED) // we added something new to the tree
        {
            // Try to connect the other tree to the node we just added
            if (connectTrees(result, otherTree, xmotion))
            {
                // The trees have been connected.  Construct the solution path
                Motion *solution = connectionPoint_.first;
                std::vector<Motion*> mpath1;
                while (solution != NULL)
                {
                    mpath1.push_back(solution);
                    solution = solution->parent;
                }

                solution = connectionPoint_.second;
                std::vector<Motion*> mpath2;
                while (solution != NULL)
                {
                    mpath2.push_back(solution);
                    solution = solution->parent;
                }

                PathGeometric *path = new PathGeometric(si_);
                path->getStates().reserve(mpath1.size() + mpath2.size());
                for (int i = mpath1.size() - 1 ; i >= 0 ; --i)
                    path->append(mpath1[i]->state);
                for (unsigned int i = 0 ; i < mpath2.size() ; ++i)
                    path->append(mpath2[i]->state);

                pdef_->addSolutionPath(base::PathPtr(path), false, 0.0, getName());
                solved = true;
                break;
            }
        }

        std::swap(tree, otherTree);
    }

    si_->freeState(rstate);
    si_->freeState(xstate);
    delete rmotion;
    delete xmotion;

    OMPL_INFORM("%s: Created %u states (%u start + %u goal)", getName().c_str(), tStart_->size() + tGoal_->size(), tStart_->size(), tGoal_->size());
    return solved ? base::PlannerStatus::EXACT_SOLUTION : base::PlannerStatus::TIMEOUT;
}
コード例 #14
0
ファイル: PathSimplifier.cpp プロジェクト: RickOne16/ompl
bool ompl::geometric::PathSimplifier::findBetterGoal(PathGeometric &path, const base::PlannerTerminationCondition &ptc,
                                                     unsigned int samplingAttempts, double rangeRatio, double snapToVertex)
{
    if (path.getStateCount() < 2)
        return false;

    if (!gsr_)
    {
        OMPL_WARN("%s: No goal sampleable object to sample a better goal from.", "PathSimplifier::findBetterGoal");
        return false;
    }

    unsigned int maxGoals = std::min((unsigned)10, gsr_->maxSampleCount()); // the number of goals we will sample
    unsigned int failedTries = 0;
    bool betterGoal = false;

    const base::StateSpacePtr& ss = si_->getStateSpace();
    std::vector<base::State*> &states = path.getStates();

    // dists[i] contains the cumulative length of the path up to and including state i
    std::vector<double> dists(states.size(), 0.0);
    for (unsigned int i = 1 ; i < dists.size() ; ++i)
        dists[i] = dists[i-1] + si_->distance(states[i-1], states[i]);

    // Sampled states closer than 'threshold' distance to any existing state in the path
    // are snapped to the close state
    double threshold = dists.back() * snapToVertex;
    // The range (distance) of a single connection that will be attempted
    double rd = rangeRatio * dists.back();

    base::State* temp = si_->allocState();
    base::State* tempGoal = si_->allocState();

    while(!ptc && failedTries++ < maxGoals && !betterGoal)
    {
        gsr_->sampleGoal(tempGoal);

        // Goal state is not compatible with the start state
        if (!gsr_->isStartGoalPairValid(path.getState(0), tempGoal))
            continue;

        unsigned int numSamples = 0;
        while (!ptc && numSamples++ < samplingAttempts && !betterGoal)
        {
            // sample a state within rangeRatio
            double t = rng_.uniformReal(std::max(dists.back() - rd, 0.0), dists.back());    // Sample a random point within rd of the end of the path

            std::vector<double>::iterator end = std::lower_bound(dists.begin(), dists.end(), t);
            std::vector<double>::iterator start = end;
            while(start != dists.begin() && *start >= t)
                start -= 1;

            unsigned int startIndex = start - dists.begin();
            unsigned int endIndex = end - dists.begin();

            // Snap the random point to the nearest vertex, if within the threshold
            if (t - (*start) < threshold) // snap to the starting waypoint
                endIndex = startIndex;
            if ((*end) - t < threshold)  // snap to the ending waypoint
                startIndex = endIndex;

            // Compute the state value and the accumulated cost up to that state
            double costToCome = dists[startIndex];
            base::State* state;
            if (startIndex == endIndex)
            {
                state = states[startIndex];
            }
            else
            {
                double tSeg = (t - (*start)) / (*end - *start);
                ss->interpolate(states[startIndex], states[endIndex], tSeg, temp);
                state = temp;

                costToCome += si_->distance(states[startIndex], state);
            }

            double costToGo = si_->distance(state, tempGoal);
            double candidateCost = costToCome + costToGo;

            // Make sure we improve before attempting validation
            if (dists.back() - candidateCost > std::numeric_limits<float>::epsilon() && si_->checkMotion(state, tempGoal))
            {
                // insert the new states
                if (startIndex == endIndex)
                {
                    // new intermediate state
                    si_->copyState(states[startIndex], state);
                    // new goal state
                    si_->copyState(states[startIndex+1], tempGoal);

                    if (freeStates_)
                    {
                        for(size_t i = startIndex + 2; i < states.size(); ++i)
                            si_->freeState(states[i]);
                    }
                    states.erase(states.begin() + startIndex + 2, states.end());
                }
                else
                {
                    // overwriting the end of the segment with the new state
                    si_->copyState(states[endIndex], state);
                    if (endIndex == states.size()-1)
                    {
                        path.append(tempGoal);
                    }
                    else
                    {
                        // adding goal new goal state
                        si_->copyState(states[endIndex + 1], tempGoal);
                        if (freeStates_)
                        {
                            for(size_t i = endIndex + 2; i < states.size(); ++i)
                                si_->freeState(states[i]);
                        }
                        states.erase(states.begin() + endIndex + 2, states.end());
                    }
                }

                // fix the helper variables
                dists.resize(states.size(), 0.0);
                for (unsigned int j = std::max(1u, startIndex); j < dists.size() ; ++j)
                    dists[j] = dists[j-1] + si_->distance(states[j-1], states[j]);

                betterGoal = true;
            }
        }
    }

    si_->freeState(temp);
    si_->freeState(tempGoal);

    return betterGoal;
}
コード例 #15
0
ファイル: RRTsharp.cpp プロジェクト: EmmanuelBoidot/RRTsharp
ompl::base::PlannerStatus ompl::geometric::RRTsharp::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::Goal                  *goal   = pdef_->getGoal().get();
    base::GoalSampleableRegion  *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);

    bool symCost = opt_->isSymmetric();

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
        motion->cost = opt_->identityCost();
        nn_->add(motion);
        startMotion_ = motion;
    }

    if (nn_->size() == 0)
    {
        OMPL_ERROR("%s: There are no valid initial states!", getName().c_str());
        return base::PlannerStatus::INVALID_START;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    OMPL_INFORM("%s: Starting planning with %u states already in datastructure", getName().c_str(), nn_->size());

    if (prune_ && !si_->getStateSpace()->isMetricSpace())
        OMPL_WARN("%s: tree pruning was activated but since the state space %s is not a metric space, "
                  "the optimization objective might not satisfy the triangle inequality. You may need to disable pruning."
                  , getName().c_str(), si_->getStateSpace()->getName().c_str());

    const base::ReportIntermediateSolutionFn intermediateSolutionCallback = pdef_->getIntermediateSolutionCallback();

    Motion *solution       = lastGoalMotion_;

    // \todo Make this variable unnecessary, or at least have it
    // persist across solve runs
    base::Cost bestCost    = opt_->infiniteCost();

    bestCost_ = opt_->infiniteCost();

    Motion *approximation  = NULL;
    double approximatedist = std::numeric_limits<double>::infinity();
    bool sufficientlyShort = false;

    Motion *rmotion        = new Motion(si_);
    base::State *rstate    = rmotion->state;
    base::State *xstate    = si_->allocState();

    // e+e/d.  K-nearest RRT*
    double k_rrg           = boost::math::constants::e<double>() +
                             (boost::math::constants::e<double>() / (double)si_->getStateSpace()->getDimension());

    std::vector<Motion*>       nbh;

    std::vector<base::Cost>    costs;
    std::vector<base::Cost>    incCosts;
    std::vector<std::size_t>   sortedCostIndices;

    std::vector<int>           valid;
    rewireTest = 0;
    statesGenerated = 0;

    if (solution)
        OMPL_INFORM("%s: Starting planning with existing solution of cost %.5f", getName().c_str(), solution->cost.value());
    OMPL_INFORM("%s: Initial k-nearest value of %u", getName().c_str(), (unsigned int)std::ceil(k_rrg * log((double)(nn_->size() + 1))));

    // our functor for sorting nearest neighbors
    CostIndexCompare compareFn(costs, *opt_);

    while (ptc == false)
    {
        iterations_++;

        // sample random state (with goal biasing)
        // Goal samples are only sampled until maxSampleCount() goals are in the tree, to prohibit duplicate goal states.
        if (goal_s && goalMotions_.size() < goal_s->maxSampleCount() && rng_.uniform01() < goalBias_ && goal_s->canSample())
            goal_s->sampleGoal(rstate);
        else
        {
            sampler_->sampleUniform(rstate);

            if (prune_ && opt_->isCostBetterThan(bestCost_, costToGo(rmotion)))
                continue;
        }

        // find closest state in the tree
        Motion *nmotion = nn_->nearest(rmotion);

        if (intermediateSolutionCallback && si_->equalStates(nmotion->state, rstate))
            continue;

        base::State *dstate = rstate;

        // find state to add to the tree
        double d = si_->distance(nmotion->state, rstate);
        if (d > maxDistance_)
        {
            si_->getStateSpace()->interpolate(nmotion->state, rstate, maxDistance_ / d, xstate);
            dstate = xstate;
        }

        // Check if the motion between the nearest state and the state to add is valid
        if (si_->checkMotion(nmotion->state, dstate))
        {
            // create a motion
            Motion *motion = new Motion(si_);
            si_->copyState(motion->state, dstate);
            motion->parent = nmotion;
            motion->incCost = opt_->motionCost(nmotion->state, motion->state);
            motion->cost = opt_->combineCosts(nmotion->cost, motion->incCost);

            // Find nearby neighbors of the new motion - k-nearest RRT*
            unsigned int k = std::ceil(k_rrg * log((double)(nn_->size() + 1)));
            nn_->nearestK(motion, k, nbh);
            rewireTest += nbh.size();
            statesGenerated++;

            // cache for distance computations
            //
            // Our cost caches only increase in size, so they're only
            // resized if they can't fit the current neighborhood
            if (costs.size() < nbh.size())
            {
                costs.resize(nbh.size());
                incCosts.resize(nbh.size());
                sortedCostIndices.resize(nbh.size());
            }

            // cache for motion validity (only useful in a symmetric space)
            //
            // Our validity caches only increase in size, so they're
            // only resized if they can't fit the current neighborhood
            if (valid.size() < nbh.size())
                valid.resize(nbh.size());
            std::fill(valid.begin(), valid.begin() + nbh.size(), 0);

            // Finding the nearest neighbor to connect to
            // By default, neighborhood states are sorted by cost, and collision checking
            // is performed in increasing order of cost
            if (delayCC_)
            {
                // calculate all costs and distances
                for (std::size_t i = 0 ; i < nbh.size(); ++i)
                {
                    incCosts[i] = opt_->motionCost(nbh[i]->state, motion->state);
                    costs[i] = opt_->combineCosts(nbh[i]->cost, incCosts[i]);
                }

                // sort the nodes
                //
                // we're using index-value pairs so that we can get at
                // original, unsorted indices
                for (std::size_t i = 0; i < nbh.size(); ++i)
                    sortedCostIndices[i] = i;
                std::sort(sortedCostIndices.begin(), sortedCostIndices.begin() + nbh.size(),
                          compareFn);

                // collision check until a valid motion is found
                //
                // ASYMMETRIC CASE: it's possible that none of these
                // neighbors are valid. This is fine, because motion
                // already has a connection to the tree through
                // nmotion (with populated cost fields!).
                for (std::vector<std::size_t>::const_iterator i = sortedCostIndices.begin();
                     i != sortedCostIndices.begin() + nbh.size();
                     ++i)
                {
                    if (nbh[*i] == nmotion || si_->checkMotion(nbh[*i]->state, motion->state))
                    {
                        motion->incCost = incCosts[*i];
                        motion->cost = costs[*i];
                        motion->parent = nbh[*i];
                        valid[*i] = 1;
                        break;
                    }
                    else valid[*i] = -1;
                }
            }
            else // if not delayCC
            {
                motion->incCost = opt_->motionCost(nmotion->state, motion->state);
                motion->cost = opt_->combineCosts(nmotion->cost, motion->incCost);
                // find which one we connect the new state to
                for (std::size_t i = 0 ; i < nbh.size(); ++i)
                {
                    if (nbh[i] != nmotion)
                    {
                        incCosts[i] = opt_->motionCost(nbh[i]->state, motion->state);
                        costs[i] = opt_->combineCosts(nbh[i]->cost, incCosts[i]);
                        if (opt_->isCostBetterThan(costs[i], motion->cost))
                        {
                            if (si_->checkMotion(nbh[i]->state, motion->state))
                            {
                                motion->incCost = incCosts[i];
                                motion->cost = costs[i];
                                motion->parent = nbh[i];
                                valid[i] = 1;
                            }
                            else valid[i] = -1;
                        }
                    }
                    else
                    {
                        incCosts[i] = motion->incCost;
                        costs[i] = motion->cost;
                        valid[i] = 1;
                    }
                }
            }

            if (prune_)
            {
                if (opt_->isCostBetterThan(costToGo(motion, false), bestCost_))
                {
                    nn_->add(motion);
                    motion->parent->children.push_back(motion);
                }
                else // If the new motion does not improve the best cost it is ignored.
                {
                    --statesGenerated;
                    si_->freeState(motion->state);
                    delete motion;
                    continue;
                }
            }
            else
            {
                // add motion to the tree
                nn_->add(motion);
                motion->parent->children.push_back(motion);
            }

            this->nodesToAnalyzeForRewiring = std::priority_queue< Motion* ,std::vector<Motion*>, std::greater<Motion*>>();
            assert(nodesToAnalyzeForRewiring.empty());
            this->visitedMotions.clear();
            this->toVisitMotions.clear();
            bool checkForSolution = false;

            toVisitMotions.insert(motion);
            nodesToAnalyzeForRewiring.push(motion);

            while (!nodesToAnalyzeForRewiring.empty())
            {
//                if (((int)nn_->size())>7000)
//                    usleep(200000);
                Motion* mc = nodesToAnalyzeForRewiring.top();
                nodesToAnalyzeForRewiring.pop();
                visitedMotions.insert(mc);
                toVisitMotions.erase(mc);

                nn_->nearestK(mc, k, nbh);
//                Cost minNbhCost = mc->cost;

                bool updatedWiring = false;
                if (mc!=motion){
                    for (std::size_t i = 0; i < nbh.size(); ++i){
                        rewireTest++;
                        // TODO: add if(symCost) option
                        base::Cost temp_incCost = opt_->motionCost(nbh[i]->state, mc->state);
                        base::Cost temp_Cost = opt_->combineCosts(nbh[i]->cost, temp_incCost);

                        if (opt_->isCostBetterThan(temp_Cost,mc->cost)){
                            if (si_->checkMotion(nbh[i]->state, mc->state))
                            {
                                removeFromParent (mc);

                                mc->parent = nbh[i];
                                mc->cost = temp_Cost;
                                mc->incCost = temp_incCost;
                                mc->parent->children.push_back(mc);
                                updatedWiring = true;

                                checkForSolution = true;
                            }
                        }
                    }
                } else {
                    updatedWiring = true;
                }

                if (updatedWiring){
                    // add children to update list
                    for (std::size_t j = 0; j < mc->children.size(); ++j){
                        if (toVisitMotions.count(mc->children[j])==0 && visitedMotions.count(mc->children[j])==0){
                            nodesToAnalyzeForRewiring.push(mc->children[j]);
                            toVisitMotions.insert(mc->children[j]);
                        }
                    }

                    for (std::size_t i = 0; i < nbh.size(); ++i){
                        // TODO: avoid repeated calculation of same value
                        if (opt_->isCostBetterThan(opt_->combineCosts(mc->cost, opt_->motionCost(mc->state, nbh[i]->state)),nbh[i]->cost) && toVisitMotions.count(nbh[i])==0 && visitedMotions.count(nbh[i])==0){
                            nodesToAnalyzeForRewiring.push(nbh[i]);
                            toVisitMotions.insert(nbh[i]);
                        }
                    }
                }
            }

            // Add the new motion to the goalMotion_ list, if it satisfies the goal
            double distanceFromGoal;
            if (goal->isSatisfied(motion->state, &distanceFromGoal))
            {
                goalMotions_.push_back(motion);
                checkForSolution = true;
            }

            // Checking for solution or iterative improvement
            if (checkForSolution)
            {
                bool updatedSolution = false;
                for (size_t i = 0; i < goalMotions_.size(); ++i)
                {
                    if (opt_->isCostBetterThan(goalMotions_[i]->cost, bestCost))
                    {
                        bestCost = goalMotions_[i]->cost;
                        bestCost_ = bestCost;
                        updatedSolution = true;
                    }

                    sufficientlyShort = opt_->isSatisfied(goalMotions_[i]->cost);
                    if (sufficientlyShort)
                     {
                         solution = goalMotions_[i];
                         break;
                     }
                     else if (!solution ||
                         opt_->isCostBetterThan(goalMotions_[i]->cost,solution->cost))
                    {
                        solution = goalMotions_[i];
                        updatedSolution = true;
                    }
                }

                if (updatedSolution)
                {
                    if (prune_)
                    {
                        int n = pruneTree(bestCost_);
                        statesGenerated -= n;
                    }

                    if (intermediateSolutionCallback)
                    {
                        std::vector<const base::State *> spath;
                        Motion *intermediate_solution = solution->parent; // Do not include goal state to simplify code.

                        do
                        {
                            spath.push_back(intermediate_solution->state);
                            intermediate_solution = intermediate_solution->parent;
                        } while (intermediate_solution->parent != 0); // Do not include the start state.

                        intermediateSolutionCallback(this, spath, bestCost_);
                    }
                }
            }

            // Checking for approximate solution (closest state found to the goal)
            if (goalMotions_.size() == 0 && distanceFromGoal < approximatedist)
            {
                approximation = motion;
                approximatedist = distanceFromGoal;
            }

        }

        // terminate if a sufficient solution is found
        if (solution && sufficientlyShort)
            break;
    }

    bool approximate = (solution == NULL);
    bool addedSolution = false;
    if (approximate)
        solution = approximation;
    else
        lastGoalMotion_ = solution;

    if (solution != NULL)
    {
        ptc.terminate();
        // construct the solution path
        std::vector<Motion*> mpath;
        while (solution != NULL)
        {
            mpath.push_back(solution);
            solution = solution->parent;
        }

        // set the solution path
        PathGeometric *geoPath = new PathGeometric(si_);
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            geoPath->append(mpath[i]->state);

        base::PathPtr path(geoPath);
        // Add the solution path.
        base::PlannerSolution psol(path);
        psol.setPlannerName(getName());
        if (approximate)
            psol.setApproximate(approximatedist);
        // Does the solution satisfy the optimization objective?
        psol.setOptimized(opt_, bestCost, sufficientlyShort);
        pdef_->addSolutionPath(psol);

        addedSolution = true;
    }

    si_->freeState(xstate);
    if (rmotion->state)
        si_->freeState(rmotion->state);
    delete rmotion;

    OMPL_INFORM("%s: Created %u new states. Checked %u rewire options. %u goal states in tree.", getName().c_str(), statesGenerated, rewireTest, goalMotions_.size());

    return base::PlannerStatus(addedSolution, approximate);
}
コード例 #16
0
ompl::base::PathPtr ompl::geometric::LazyPRM::constructSolution(const Vertex &start, const Vertex &goal)
{
    // Need to update the index map here, becuse nodes may have been removed and
    // the numbering will not be 0 .. N-1 otherwise.
    unsigned long int index = 0;
    boost::graph_traits<Graph>::vertex_iterator vi, vend;
    for(boost::tie(vi, vend) = boost::vertices(g_); vi != vend; ++vi, ++index)
        indexProperty_[*vi] = index;

    boost::property_map<Graph, boost::vertex_predecessor_t>::type prev;
    try
    {
        // Consider using a persistent distance_map if it's slow
        boost::astar_search(g_, start,
                            boost::bind(&LazyPRM::costHeuristic, this, _1, goal),
                            boost::predecessor_map(prev).
                            distance_compare(boost::bind(&base::OptimizationObjective::
                                                         isCostBetterThan, opt_.get(), _1, _2)).
                            distance_combine(boost::bind(&base::OptimizationObjective::
                                                         combineCosts, opt_.get(), _1, _2)).
                            distance_inf(opt_->infiniteCost()).
                            distance_zero(opt_->identityCost()).
                            visitor(AStarGoalVisitor<Vertex>(goal)));
    }
    catch (AStarFoundGoal&)
    {
    }
    if (prev[goal] == goal)
        throw Exception(name_, "Could not find solution path");

    // First, get the solution states without copying them, and check them for validity.
    // We do all the node validity checks for the vertices, as this may remove a larger
    // part of the graph (compared to removing an edge).
    std::vector<const base::State*> states(1, stateProperty_[goal]);
    std::set<Vertex> milestonesToRemove;
    for (Vertex pos = prev[goal]; prev[pos] != pos; pos = prev[pos])
    {
        const base::State *st = stateProperty_[pos];
        unsigned int &vd = vertexValidityProperty_[pos];
        if ((vd & VALIDITY_TRUE) == 0)
            if (si_->isValid(st))
                vd |= VALIDITY_TRUE;
        if ((vd & VALIDITY_TRUE) == 0)
            milestonesToRemove.insert(pos);
        if (milestonesToRemove.empty())
            states.push_back(st);
    }

    // We remove *all* invalid vertices. This is not entirely as described in the original LazyPRM
    // paper, as the paper suggest removing the first vertex only, and then recomputing the
    // shortest path. Howeve, the paper says the focus is on efficient vertex & edge removal,
    // rather than collision checking, so this modification is in the spirit of the paper.
    if (!milestonesToRemove.empty())
    {
        unsigned long int comp = vertexComponentProperty_[start];
        // Remember the current neighbors.
        std::set<Vertex> neighbors;
        for (std::set<Vertex>::iterator it = milestonesToRemove.begin() ; it != milestonesToRemove.end() ; ++it)
        {
            boost::graph_traits<Graph>::adjacency_iterator nbh, last;
            for (boost::tie(nbh, last) = boost::adjacent_vertices(*it, g_) ; nbh != last ; ++nbh)
                if (milestonesToRemove.find(*nbh) == milestonesToRemove.end())
                    neighbors.insert(*nbh);
            // Remove vertex from nearest neighbors data structure.
            nn_->remove(*it);
            // Free vertex state.
            si_->freeState(stateProperty_[*it]);
            // Remove all edges.
            boost::clear_vertex(*it, g_);
            // Remove the vertex.
            boost::remove_vertex(*it, g_);
        }
        // Update the connected component ID for neighbors.
        for (std::set<Vertex>::iterator it = neighbors.begin() ; it != neighbors.end() ; ++it)
        {
            if (comp == vertexComponentProperty_[*it])
            {
                unsigned long int newComponent = componentCount_++;
                componentSize_[newComponent] = 0;
                markComponent(*it, newComponent);
            }
        }
        return base::PathPtr();
    }

    // start is checked for validity already
    states.push_back(stateProperty_[start]);

    // Check the edges too, if the vertices were valid. Remove the first invalid edge only.
    std::vector<const base::State*>::const_iterator prevState = states.begin(), state = prevState + 1;
    Vertex prevVertex = goal, pos = prev[goal];
    do
    {
        Edge e = boost::lookup_edge(pos, prevVertex, g_).first;
        unsigned int &evd = edgeValidityProperty_[e];
        if ((evd & VALIDITY_TRUE) == 0)
        {
            if (si_->checkMotion(*state, *prevState))
                evd |= VALIDITY_TRUE;
        }
        if ((evd & VALIDITY_TRUE) == 0)
        {
            boost::remove_edge(e, g_);
            unsigned long int newComponent = componentCount_++;
            componentSize_[newComponent] = 0;
            markComponent(pos, newComponent);
            return base::PathPtr();
        }
        prevState = state;
        ++state;
        prevVertex = pos;
        pos = prev[pos];
    }
    while (prevVertex != pos);

    PathGeometric *p = new PathGeometric(si_);
    for (std::vector<const base::State*>::const_reverse_iterator st = states.rbegin(); st != states.rend(); ++st)
        p->append(*st);
    return base::PathPtr(p);
}
コード例 #17
0
ファイル: EST.cpp プロジェクト: giogadi/ompl
ompl::base::PlannerStatus ompl::geometric::EST::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::Goal                   *goal = pdef_->getGoal().get();
    base::GoalSampleableRegion *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
        addMotion(motion);
    }

    if (tree_.grid.size() == 0)
    {
        OMPL_ERROR("%s: There are no valid initial states!", getName().c_str());
        return base::PlannerStatus::INVALID_START;
    }

    if (!sampler_)
        sampler_ = si_->allocValidStateSampler();

    OMPL_INFORM("%s: Starting with %u states", getName().c_str(), tree_.size);

    Motion *solution  = NULL;
    Motion *approxsol = NULL;
    double  approxdif = std::numeric_limits<double>::infinity();
    base::State *xstate = si_->allocState();

    while (ptc == false)
    {
        /* Decide on a state to expand from */
        Motion *existing = selectMotion();
        assert(existing);

        /* sample random state (with goal biasing) */
        if (goal_s && rng_.uniform01() < goalBias_ && goal_s->canSample())
            goal_s->sampleGoal(xstate);
        else
            if (!sampler_->sampleNear(xstate, existing->state, maxDistance_))
                continue;

        if (si_->checkMotion(existing->state, xstate))
        {
            /* create a motion */
            Motion *motion = new Motion(si_);
            si_->copyState(motion->state, xstate);
            motion->parent = existing;

            addMotion(motion);
            double dist = 0.0;
            bool solved = goal->isSatisfied(motion->state, &dist);
            if (solved)
            {
                approxdif = dist;
                solution = motion;
                break;
            }
            if (dist < approxdif)
            {
                approxdif = dist;
                approxsol = motion;
            }
        }
    }

    bool solved = false;
    bool approximate = false;
    if (solution == NULL)
    {
        solution = approxsol;
        approximate = true;
    }

    if (solution != NULL)
    {
        lastGoalMotion_ = solution;

        /* construct the solution path */
        std::vector<Motion*> mpath;
        while (solution != NULL)
        {
            mpath.push_back(solution);
            solution = solution->parent;
        }

        /* set the solution path */
        PathGeometric *path = new PathGeometric(si_);
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            path->append(mpath[i]->state);
        pdef_->addSolutionPath(base::PathPtr(path), approximate, approxdif);
        solved = true;
    }

    si_->freeState(xstate);

    OMPL_INFORM("%s: Created %u states in %u cells", getName().c_str(), tree_.size, tree_.grid.size());

    return base::PlannerStatus(solved, approximate);
}
コード例 #18
0
ファイル: LazyRRT.cpp プロジェクト: megan-starr9/UAV_Aiolos
bool ompl::geometric::LazyRRT::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::Goal                 *goal   = pdef_->getGoal().get();
    base::GoalSampleableRegion *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
        motion->valid = true;
        nn_->add(motion);
    }

    if (nn_->size() == 0)
    {
        msg_.error("There are no valid initial states!");
        return false;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    msg_.inform("Starting with %u states", nn_->size());

    Motion *solution = NULL;
    double  distsol  = -1.0;
    Motion *rmotion  = new Motion(si_);
    base::State *rstate = rmotion->state;
    base::State *xstate = si_->allocState();

 RETRY:

    while (ptc() == false)
    {
        /* sample random state (with goal biasing) */
        if (goal_s && rng_.uniform01() < goalBias_ && goal_s->canSample())
            goal_s->sampleGoal(rstate);
        else
            sampler_->sampleUniform(rstate);

        /* find closest state in the tree */
        Motion *nmotion = nn_->nearest(rmotion);
        assert(nmotion != rmotion);
        base::State *dstate = rstate;

        /* find state to add */
        double d = si_->distance(nmotion->state, rstate);
        if (d > maxDistance_)
        {
            si_->getStateSpace()->interpolate(nmotion->state, rstate, maxDistance_ / d, xstate);
            dstate = xstate;
        }

        /* create a motion */
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, dstate);
        motion->parent = nmotion;
        nmotion->children.push_back(motion);
        nn_->add(motion);

        double dist = 0.0;
        if (goal->isSatisfied(motion->state, &dist))
        {
            distsol = dist;
            solution = motion;
            break;
        }
    }

    bool solved = false;
    if (solution != NULL)
    {
        /* construct the solution path */
        std::vector<Motion*> mpath;
        while (solution != NULL)
        {
            mpath.push_back(solution);
            solution = solution->parent;
        }

        /* check the path */
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            if (!mpath[i]->valid)
            {
                if (si_->checkMotion(mpath[i]->parent->state, mpath[i]->state))
                    mpath[i]->valid = true;
                else
                {
                    removeMotion(mpath[i]);
                    goto RETRY;
                }
            }

        /* set the solution path */
        PathGeometric *path = new PathGeometric(si_);
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            path->append(mpath[i]->state);

        goal->addSolutionPath(base::PathPtr(path), false, distsol);
        solved = true;
    }

    si_->freeState(xstate);
    si_->freeState(rstate);
    delete rmotion;

    msg_.inform("Created %u states", nn_->size());

    return solved;
}
コード例 #19
0
ファイル: RRTstar.cpp プロジェクト: arjungm/ompl
ompl::base::PlannerStatus ompl::geometric::RRTstar::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::Goal                  *goal   = pdef_->getGoal().get();
    base::GoalSampleableRegion  *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);

    bool symCost = opt_->isSymmetric();

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
        motion->cost = opt_->identityCost();
        nn_->add(motion);
    }

    if (nn_->size() == 0)
    {
        OMPL_ERROR("%s: There are no valid initial states!", getName().c_str());
        return base::PlannerStatus::INVALID_START;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    OMPL_INFORM("%s: Starting planning with %u states already in datastructure", getName().c_str(), nn_->size());

    Motion *solution       = lastGoalMotion_;

    // \TODO Make this variable unnecessary, or at least have it
    // persist across solve runs
    base::Cost bestCost    = opt_->infiniteCost();

    Motion *approximation  = NULL;
    double approximatedist = std::numeric_limits<double>::infinity();
    bool sufficientlyShort = false;

    Motion *rmotion        = new Motion(si_);
    base::State *rstate    = rmotion->state;
    base::State *xstate    = si_->allocState();

    // e+e/d.  K-nearest RRT*
    double k_rrg           = boost::math::constants::e<double>() +
                             (boost::math::constants::e<double>() / (double)si_->getStateSpace()->getDimension());

    std::vector<Motion*>       nbh;

    std::vector<base::Cost>    costs;
    std::vector<base::Cost>    incCosts;
    std::vector<std::size_t>   sortedCostIndices;

    std::vector<int>           valid;
    unsigned int               rewireTest = 0;
    unsigned int               statesGenerated = 0;

    if (solution)
        OMPL_INFORM("%s: Starting planning with existing solution of cost %.5f", getName().c_str(), solution->cost.v);
    OMPL_INFORM("%s: Initial k-nearest value of %u", getName().c_str(), (unsigned int)std::ceil(k_rrg * log((double)(nn_->size()+1))));


    // our functor for sorting nearest neighbors
    CostIndexCompare compareFn(costs, *opt_);

    while (ptc == false)
    {
        iterations_++;
        // sample random state (with goal biasing)
        // Goal samples are only sampled until maxSampleCount() goals are in the tree, to prohibit duplicate goal states.
        if (goal_s && goalMotions_.size() < goal_s->maxSampleCount() && rng_.uniform01() < goalBias_ && goal_s->canSample())
            goal_s->sampleGoal(rstate);
        else
            sampler_->sampleUniform(rstate);

        // find closest state in the tree
        Motion *nmotion = nn_->nearest(rmotion);

        base::State *dstate = rstate;

        // find state to add to the tree
        double d = si_->distance(nmotion->state, rstate);
        if (d > maxDistance_)
        {
            si_->getStateSpace()->interpolate(nmotion->state, rstate, maxDistance_ / d, xstate);
            dstate = xstate;
        }

        // Check if the motion between the nearest state and the state to add is valid
        ++collisionChecks_;
        if (si_->checkMotion(nmotion->state, dstate))
        {
            // create a motion
            Motion *motion = new Motion(si_);
            si_->copyState(motion->state, dstate);
            motion->parent = nmotion;
            motion->incCost = opt_->motionCost(nmotion->state, motion->state);
            motion->cost = opt_->combineCosts(nmotion->cost, motion->incCost);

            // Find nearby neighbors of the new motion - k-nearest RRT*
            unsigned int k = std::ceil(k_rrg * log((double)(nn_->size() + 1)));
            nn_->nearestK(motion, k, nbh);

            rewireTest += nbh.size();
            statesGenerated++;

            // cache for distance computations
            //
            // Our cost caches only increase in size, so they're only
            // resized if they can't fit the current neighborhood
            if (costs.size() < nbh.size())
            {
                costs.resize(nbh.size());
                incCosts.resize(nbh.size());
                sortedCostIndices.resize(nbh.size());
            }

            // cache for motion validity (only useful in a symmetric space)
            //
            // Our validity caches only increase in size, so they're
            // only resized if they can't fit the current neighborhood
            if (valid.size() < nbh.size())
                valid.resize(nbh.size());
            std::fill(valid.begin(), valid.begin() + nbh.size(), 0);

            // Finding the nearest neighbor to connect to
            // By default, neighborhood states are sorted by cost, and collision checking
            // is performed in increasing order of cost
            if (delayCC_)
            {
                // calculate all costs and distances
                for (std::size_t i = 0 ; i < nbh.size(); ++i)
                {
                    incCosts[i] = opt_->motionCost(nbh[i]->state, motion->state);
                    costs[i] = opt_->combineCosts(nbh[i]->cost, incCosts[i]);
                }

                // sort the nodes
                //
                // we're using index-value pairs so that we can get at
                // original, unsorted indices
                for (std::size_t i = 0; i < nbh.size(); ++i)
                    sortedCostIndices[i] = i;
                std::sort(sortedCostIndices.begin(), sortedCostIndices.begin() + nbh.size(),
                          compareFn);

                // collision check until a valid motion is found
                //
                // ASYMMETRIC CASE: it's possible that none of these
                // neighbors are valid. This is fine, because motion
                // already has a connection to the tree through
                // nmotion (with populated cost fields!).
                for (std::vector<std::size_t>::const_iterator i = sortedCostIndices.begin();
                     i != sortedCostIndices.begin() + nbh.size();
                     ++i)
                {
                    if (nbh[*i] != nmotion)
                        ++collisionChecks_;
                    if (nbh[*i] == nmotion || si_->checkMotion(nbh[*i]->state, motion->state))
                    {
                        motion->incCost = incCosts[*i];
                        motion->cost = costs[*i];
                        motion->parent = nbh[*i];
                        valid[*i] = 1;
                        break;
                    }
                    else valid[*i] = -1;
                }
            }
            else // if not delayCC
            {
                motion->incCost = opt_->motionCost(nmotion->state, motion->state);
                motion->cost = opt_->combineCosts(nmotion->cost, motion->incCost);
                // find which one we connect the new state to
                for (std::size_t i = 0 ; i < nbh.size(); ++i)
                {
                    if (nbh[i] != nmotion)
                    {
                        incCosts[i] = opt_->motionCost(nbh[i]->state, motion->state);
                        costs[i] = opt_->combineCosts(nbh[i]->cost, incCosts[i]);
                        if (opt_->isCostBetterThan(costs[i], motion->cost))
                        {
                            ++collisionChecks_;
                            if (si_->checkMotion(nbh[i]->state, motion->state))
                            {
                                motion->incCost = incCosts[i];
                                motion->cost = costs[i];
                                motion->parent = nbh[i];
                                valid[i] = 1;
                            }
                            else valid[i] = -1;
                        }
                    }
                    else
                    {
                        incCosts[i] = motion->incCost;
                        costs[i] = motion->cost;
                        valid[i] = 1;
                    }
                }
            }

            // add motion to the tree
            nn_->add(motion);
            motion->parent->children.push_back(motion);

            bool checkForSolution = false;
            for (std::size_t i = 0; i < nbh.size(); ++i)
            {
                if (nbh[i] != motion->parent)
                {
                    base::Cost nbhIncCost;
                    if (symCost)
                        nbhIncCost = incCosts[i];
                    else
                        nbhIncCost = opt_->motionCost(motion->state, nbh[i]->state);
                    base::Cost nbhNewCost = opt_->combineCosts(motion->cost, nbhIncCost);
                    if (opt_->isCostBetterThan(nbhNewCost, nbh[i]->cost))
                    {
                        bool motionValid;
                        if (valid[i] == 0)
                        {
                            ++collisionChecks_;
                            motionValid = si_->checkMotion(motion->state, nbh[i]->state);
                        }
                        else
                            motionValid = (valid[i] == 1);

                        if (motionValid)
                        {
                            // Remove this node from its parent list
                            removeFromParent (nbh[i]);

                            // Add this node to the new parent
                            nbh[i]->parent = motion;
                            nbh[i]->incCost = nbhIncCost;
                            nbh[i]->cost = nbhNewCost;
                            nbh[i]->parent->children.push_back(nbh[i]);

                            // Update the costs of the node's children
                            updateChildCosts(nbh[i]);

                            checkForSolution = true;
                        }
                    }
                }
            }

            // Add the new motion to the goalMotion_ list, if it satisfies the goal
            double distanceFromGoal;
            if (goal->isSatisfied(motion->state, &distanceFromGoal))
            {
                goalMotions_.push_back(motion);
                checkForSolution = true;
            }

            // Checking for solution or iterative improvement
            if (checkForSolution)
            {
                for (size_t i = 0; i < goalMotions_.size(); ++i)
                {
                    if (opt_->isCostBetterThan(goalMotions_[i]->cost, bestCost))
                    {
                        bestCost = goalMotions_[i]->cost;
                        bestCost_ = bestCost;
                    }

                    sufficientlyShort = opt_->isSatisfied(goalMotions_[i]->cost);
                    if (sufficientlyShort)
                    {
                        solution = goalMotions_[i];
                        break;
                    }
                    else if (!solution ||
                             opt_->isCostBetterThan(goalMotions_[i]->cost,solution->cost))
                        solution = goalMotions_[i];
                }
            }

            // Checking for approximate solution (closest state found to the goal)
            if (goalMotions_.size() == 0 && distanceFromGoal < approximatedist)
            {
                approximation = motion;
                approximatedist = distanceFromGoal;
            }
        }

        // terminate if a sufficient solution is found
        if (solution && sufficientlyShort)
            break;
    }

    bool approximate = (solution == 0);
    bool addedSolution = false;
    if (approximate)
        solution = approximation;
    else
        lastGoalMotion_ = solution;

    if (solution != 0)
    {
        // construct the solution path
        std::vector<Motion*> mpath;
        while (solution != 0)
        {
            mpath.push_back(solution);
            solution = solution->parent;
        }

        // set the solution path
        PathGeometric *geoPath = new PathGeometric(si_);
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            geoPath->append(mpath[i]->state);

        base::PathPtr path(geoPath);
        // Add the solution path, whether it is approximate (not reaching the goal), and the
        // distance from the end of the path to the goal (-1 if satisfying the goal).
        base::PlannerSolution psol(path, approximate, approximate ? approximatedist : -1.0, getName());
        // Does the solution satisfy the optimization objective?
        psol.optimized_ = sufficientlyShort;

        pdef_->addSolutionPath (psol);

        addedSolution = true;
    }

    si_->freeState(xstate);
    if (rmotion->state)
        si_->freeState(rmotion->state);
    delete rmotion;

    OMPL_INFORM("%s: Created %u new states. Checked %u rewire options. %u goal states in tree.", getName().c_str(), statesGenerated, rewireTest, goalMotions_.size());

    return base::PlannerStatus(addedSolution, approximate);
}
コード例 #20
0
ファイル: RRTstar.cpp プロジェクト: megan-starr9/UAV_Aiolos
bool ompl::geometric::RRTstar::solve(const base::PlannerTerminationCondition &ptc)
{
    checkValidity();
    base::Goal                 *goal   = pdef_->getGoal().get();
    base::GoalSampleableRegion *goal_s = dynamic_cast<base::GoalSampleableRegion*>(goal);
	parent_ = NULL;

    if (!goal)
    {
        msg_.error("Goal undefined");
        return false;
    }

    while (const base::State *st = pis_.nextStart())
    {
        Motion *motion = new Motion(si_);
        si_->copyState(motion->state, st);
	// TODO set this based on initial bearing
	motion->set_bearing(initialBearing_);
        nn_->add(motion);
    }

    if (nn_->size() == 0)
    {
        msg_.error("There are no valid initial states!");
        return false;
    }

    if (!sampler_)
        sampler_ = si_->allocStateSampler();

    msg_.inform("Starting with %u states", nn_->size());

    Motion *solution       = NULL;
    Motion *approximation  = NULL;
    double approximatedist = std::numeric_limits<double>::infinity();
    bool sufficientlyShort = false;

    Motion *rmotion     = new Motion(si_);
    base::State *rstate = rmotion->state;
    base::State *xstate = si_->allocState();
    std::vector<Motion*> solCheck;
    std::vector<Motion*> nbh;
    std::vector<double>  dists;
    std::vector<int>     valid;
    unsigned int         rewireTest = 0;

    while (ptc() == false)
    {
	bool validneighbor = false;
	Motion *nmotion;
	base::State *dstate;
		//ADDED
	parent_ = NULL;
	//while (!validneighbor)
	//{
		if (ptc())
		{
			msg_.error("Loop failed to find proper states!");
			return false;
		}
	        // sample random state (with goal biasing)
	        if (goal_s && rng_.uniform01() < goalBias_ && goal_s->canSample())
	            goal_s->sampleGoal(rstate);
	        else
	            sampler_->sampleUniform(rstate);

	        // find closest state in the tree
	        nmotion = nn_->nearest(rmotion);

	        dstate = rstate;

        	// find state to add
        	double d = si_->distance(nmotion->state, rstate);
        	if (d > maxDistance_)
        	{
            		si_->getStateSpace()->interpolate(nmotion->state, rstate, maxDistance_ / d, xstate);
            		dstate = xstate;
       		}
		
		validneighbor = check_bearing(nmotion, dstate);
	//} 
 	
	parent_ = nmotion;
        if (si_->checkMotion(nmotion->state, dstate))
        {
            // create a motion
		//ADDED
            double distN = si_->distance(dstate, nmotion->state);
            Motion *motion = new Motion(si_);
            si_->copyState(motion->state, dstate);
            motion->parent = nmotion;
		motion->set_bearing();
            motion->cost = nmotion->cost + distN;

            // find nearby neighbors
            double r = std::min(ballRadiusConst_ * (sqrt(log((double)(1 + nn_->size())) / ((double)(nn_->size())))),
                                ballRadiusMax_);

            nn_->nearestR(motion, r, nbh);
            rewireTest += nbh.size();

            // cache for distance computations
            dists.resize(nbh.size());
            // cache for motion validity
            valid.resize(nbh.size());
            std::fill(valid.begin(), valid.end(), 0);

            if(delayCC_)
            {
                // calculate all costs and distances
                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                    nbh[i]->cost += si_->distance(nbh[i]->state, dstate);

                // sort the nodes
                std::sort(nbh.begin(), nbh.end(), compareMotion);

                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                {
                    dists[i] = si_->distance(nbh[i]->state, dstate);
                    nbh[i]->cost -= dists[i];
                }

                // collision check until a valid motion is found
                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                {
                    if (nbh[i] != nmotion)
                    {
                        double c = nbh[i]->cost + dists[i];
                        if (c < motion->cost)
                        {
				//ADDED
				parent_ = nbh[i];
                            if (si_->checkMotion(nbh[i]->state, dstate) /*&& check_bearing(nbh[i], motion->state)*/)
                            {
                                motion->cost = c;
                                motion->parent = nbh[i];
				motion->set_bearing();
                                valid[i] = 1;
                                break;
                            }
                            else
                                valid[i] = -1;
                        }
                    }
                    else
                    {
                        valid[i] = 1;
                        dists[i] = distN;
                        break;
                    }
                }
            }
            else
            {
                // find which one we connect the new state to
                for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                {
                    if (nbh[i] != nmotion)
                    {
                        dists[i] = si_->distance(nbh[i]->state, dstate);
                        double c = nbh[i]->cost + dists[i];
                        if (c < motion->cost)
                        {
				// ADDED
				parent_ = nbh[i];
                            if (si_->checkMotion(nbh[i]->state, dstate) /*&& check_bearing(nbh[i], dstate)*/)
                            {
                                motion->cost = c;
                                motion->parent = nbh[i];
				motion->set_bearing();
                                valid[i] = 1;
                            }
                            else
                                valid[i] = -1;
                        }
                    }
                    else
                    {
                        valid[i] = 1;
                        dists[i] = distN;
                    }
                }
            }

            // add motion to the tree
            nn_->add(motion);
            motion->parent->children.push_back(motion);

            solCheck.resize(1);
            solCheck[0] = motion;

            // rewire tree if needed
            for (unsigned int i = 0 ; i < nbh.size() ; ++i)
                if (nbh[i] != motion->parent)
                {
                    double c = motion->cost + dists[i];
                    if ((c < nbh[i]->cost))
                    {
			parent_ = motion;
                        bool v = valid[i] == 0 ? si_->checkMotion(nbh[i]->state, dstate) : valid[i] == 1;
                        if (v /*&& check_bearing(motion, nbh[i]->state)*/)
                        {
                            // Remove this node from its parent list
                            removeFromParent (nbh[i]);
                            double delta = c - nbh[i]->cost;

                            // Add this node to the new parent
                            nbh[i]->parent = motion;
                            nbh[i]->cost = c;
				nbh[i]->set_bearing();
                            nbh[i]->parent->children.push_back(nbh[i]);
                            solCheck.push_back(nbh[i]);

                            // Update the costs of the node's children
                            updateChildCosts(nbh[i], delta);
                        }
                    }
                }

            // check if we found a solution
            for (unsigned int i = 0 ; i < solCheck.size() ; ++i)
            {
                double dist = 0.0;
                bool solved = goal->isSatisfied(solCheck[i]->state, &dist);
                sufficientlyShort = solved ? goal->isPathLengthSatisfied(solCheck[i]->cost) : false;

                if (solved)
                {
                    if (sufficientlyShort)
                    {
                        solution = solCheck[i];
                        break;
                    }
                    else if (!solution || (solCheck[i]->cost < solution->cost))
                    {
                        solution = solCheck[i];
                    }
                }
                else if (!solution && dist < approximatedist)
                {
                    approximation = solCheck[i];
                    approximatedist = dist;
                }
            }
        }

        // terminate if a sufficient solution is found
        if (solution && sufficientlyShort)
            break;
    }

    double solutionCost;
    bool approximate = (solution == NULL);
    bool addedSolution = false;
    if (approximate)
    {
        solution = approximation;
        solutionCost = approximatedist;
    }
    else
        solutionCost = solution->cost;

    if (solution != NULL)
    {
        // construct the solution path
        std::vector<Motion*> mpath;
        while (solution != NULL)
        {
            mpath.push_back(solution);
            solution = solution->parent;
        }

        // set the solution path
        PathGeometric *path = new PathGeometric(si_);
        for (int i = mpath.size() - 1 ; i >= 0 ; --i)
            path->append(mpath[i]->state);
        goal->addSolutionPath(base::PathPtr(path), approximate, solutionCost);
        addedSolution = true;
    }

    si_->freeState(xstate);
    if (rmotion->state)
        si_->freeState(rmotion->state);
    delete rmotion;

    msg_.inform("Created %u states. Checked %lu rewire options.", nn_->size(), rewireTest);

    return addedSolution;
}