Esempio n. 1
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class ShortcutPathTest(object):
    def setUp(self):
        from openravepy import RaveCreateTrajectory

        self.input_path = RaveCreateTrajectory(self.env, '')
        self.input_path.Init(
            self.robot.GetActiveConfigurationSpecification('linear'))
        self.input_path.Insert(0, self.waypoint1)
        self.input_path.Insert(1, self.waypoint2)
        self.input_path.Insert(2, self.waypoint3)

    def test_ShortcutPath_ShortcutExists_ReducesLength(self):
        from numpy.testing import assert_allclose

        # Setup/Test
        smoothed_path = self.planner.ShortcutPath(self.robot, self.input_path)

        # Assert
        self.assertEquals(smoothed_path.GetConfigurationSpecification(),
                          self.input_path.GetConfigurationSpecification())
        self.assertGreaterEqual(smoothed_path.GetNumWaypoints(), 2)

        n = smoothed_path.GetNumWaypoints()
        assert_allclose(smoothed_path.GetWaypoint(0), self.waypoint1)
        assert_allclose(smoothed_path.GetWaypoint(n - 1), self.waypoint3)

        self.assertLess(self.ComputeArcLength(smoothed_path),
                        0.5 * self.ComputeArcLength(self.input_path))
Esempio n. 2
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    def test_get_joint(self):
        """ This test creates a path in openrave format and test the class method get_joint to return a known joint.
        """

        path = blade_coverage.Path(self.rays)
        ind = str()
        for i in range(self.robot.GetDOF()):
            ind += str(i) + ' '

        cs = ConfigurationSpecification()
        _ = cs.AddGroup('joint_values ' + self.robot.GetName() + ' ' + ind,
                        len(self.robot.GetActiveDOFIndices()), 'cubic')
        cs.AddDerivativeGroups(1, False)
        cs.AddDerivativeGroups(2, False)
        _ = cs.AddDeltaTimeGroup()

        traj = RaveCreateTrajectory(self.turbine.env, '')
        traj.Init(cs)
        for i in range(len(self.joints[:1])):
            waypoint = list(self.joints[i])
            waypoint.extend(list(self.joints[i]))
            waypoint.extend(list(self.joints[i]))
            waypoint.extend([0])
            traj.Insert(traj.GetNumWaypoints(), waypoint)
        path.data = [traj]

        joint = path.get_joint(self.robot, 0, 0)
        self.assertTrue(linalg.norm(joint - self.joints[0]) <= 1e-5,
                        msg='get_joint failed')
Esempio n. 3
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    def deserialize(self, turbine, directory):
        """ Method deserializes data in OpenRave format.
        Args:
            turbine: (@ref Turbine) is the turbine object.
            directory: (str) is the relative path to the folder where to load.
        Examples:
            >>> path.deserialize(turbine,'my_folder')
        """

        ind = str()
        for i in range(turbine.robot.GetDOF()):
            ind += str(i) + ' '

        cs = ConfigurationSpecification()
        _ = cs.AddGroup('joint_values ' + turbine.robot.GetName() + ' ' + ind,
                        len(turbine.robot.GetActiveDOFIndices()), 'cubic')
        cs.AddDerivativeGroups(1, False)
        cs.AddDerivativeGroups(2, False)
        _ = cs.AddDeltaTimeGroup()

        directory = realpath(directory)
        TRAJ = []
        onlyfiles = [
            f for f in listdir(directory) if isfile(join(directory, f))
        ]
        onlyfiles.sort(key=int)
        for afile in onlyfiles:
            traj = RaveCreateTrajectory(turbine.env, '')
            traj.Init(cs)
            xml = ET.parse(open(join(directory, afile)))
            traj.deserialize(ET.tostring(xml.getroot()))
            TRAJ.append(traj)
        self.data = TRAJ
        return
Esempio n. 4
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class SmoothTrajectoryTest(object):
    def setUp(self):
        from openravepy import RaveCreateTrajectory

        cspec = self.robot.GetActiveConfigurationSpecification('linear')

        self.feasible_path = RaveCreateTrajectory(self.env, '')
        self.feasible_path.Init(cspec)
        self.feasible_path.Insert(0, self.waypoint1)
        self.feasible_path.Insert(1, self.waypoint2)
        self.feasible_path.Insert(2, self.waypoint3)

    def test_SmoothTrajectory_DoesNotModifyBoundaryPoints(self):
        from numpy.testing import assert_allclose

        # Setup/Test
        traj = self.planner.RetimeTrajectory(self.robot, self.feasible_path)

        # Assert
        cspec = self.robot.GetActiveConfigurationSpecification('linear')
        self.assertGreaterEqual(traj.GetNumWaypoints(), 2)

        first_waypoint = traj.GetWaypoint(0, cspec)
        last_waypoint = traj.GetWaypoint(traj.GetNumWaypoints() - 1, cspec)
        assert_allclose(first_waypoint, self.waypoint1)
        assert_allclose(last_waypoint, self.waypoint3)
Esempio n. 5
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        def Success_impl(robot):
            import numpy
            from openravepy import RaveCreateTrajectory

            cspec = robot.GetActiveConfigurationSpecification()
            traj = RaveCreateTrajectory(self.env, 'GenericTrajectory')
            traj.Init(cspec)
            traj.Insert(0, numpy.zeros(cspec.GetDOF()))
            traj.Insert(1, numpy.ones(cspec.GetDOF()))
            return traj
Esempio n. 6
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def get_feasible_path(robot, path):
    """
    Check a path for feasibility (collision) and return a truncated path
    containing the path only up to just before the first collision.

    @param robot: the OpenRAVE robot
    @param path: the path to check for feasiblity
    @return tuple with the (possibly) truncated path, and a boolean indicating
      whether or not path was truncated
    """
    env = robot.GetEnv()
    path_cspec = path.GetConfigurationSpecification()
    dof_indices, _ = path_cspec.ExtractUsedIndices(robot)

    # Create a ConfigurationSpecification containing only positions.
    cspec = path.GetConfigurationSpecification()

    with robot.CreateRobotStateSaver(Robot.SaveParameters.LinkTransformation):

        # Check for collision. Compute a unit timing to simplify this.
        if IsTimedTrajectory(path):
            unit_path = path
        else:
            unit_path = ComputeUnitTiming(robot, path)

        t_collision = None
        t_prev = 0.0
        for t, dofvals in GetCollisionCheckPts(robot, unit_path):
            robot.SetDOFValues(dofvals, dof_indices)

            if env.CheckCollision(robot) or robot.CheckSelfCollision():
                t_collision = t_prev
                break
            t_prev = t

    # Build a path (with no timing) that stops before collision.
    output_path = RaveCreateTrajectory(env, '')

    if t_collision is not None:
        end_idx = unit_path.GetFirstWaypointIndexAfterTime(t_collision)
        if end_idx > 0:
            waypoints = unit_path.GetWaypoints(0, end_idx, cspec)
        else:
            waypoints = list()
        waypoints = np.concatenate((waypoints,
                                    unit_path.Sample(t_collision, cspec)))

        output_path.Init(cspec)
        output_path.Insert(0, waypoints)
    else:
        output_path.Clone(path, 0)

    return output_path, t_collision is not None
Esempio n. 7
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class MetaPlannerTests(object):
    def setUp(self):
        from openravepy import Environment, RaveCreateTrajectory

        self.join_timeout = 5.0
        self.env = Environment()
        self.env.Load('data/lab1.env.xml')
        self.robot = self.env.GetRobot('BarrettWAM')

        # Create a valid trajectory used to test planner successes.
        cspec = self.robot.GetActiveConfigurationSpecification()
        self.traj = RaveCreateTrajectory(self.env, 'GenericTrajectory')
        self.traj.Init(cspec)
        self.traj.Insert(0, numpy.zeros(cspec.GetDOF()))
        self.traj.Insert(1, numpy.ones(cspec.GetDOF()))
Esempio n. 8
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    def create_trajectory(turbine, joints, joints_vel, joints_acc, times):
        """ This method creates the trajectory specification in OpenRave format and insert the waypoints:
        joints - vels - accs - times
        DOF - DOF - DOF - DOF - 1
        Args:
            turbine: (@ref Turbine) turbine object
            joints:  (float[n<SUB>i</SUB>][nDOF]) joints to create the trajectory
            joints_vel: (float[n<SUB>i</SUB>][nDOF]) joints_vel to create the trajectory
            joints_acc: (float[n<SUB>i</SUB>][nDOF]) joints_acc to create the trajectory
            times: (float[n<SUB>i</SUB>]) deltatimes
        Returns:
            trajectory: OpenRave object.
        """

        robot = turbine.robot

        ind = str()
        for i in range(robot.GetDOF()):
            ind += str(i) + ' '

        cs = ConfigurationSpecification()
        _ = cs.AddGroup('joint_values ' + robot.GetName() + ' ' + ind,
                        len(robot.GetActiveDOFIndices()), 'cubic')
        cs.AddDerivativeGroups(1, False)
        cs.AddDerivativeGroups(2, False)
        _ = cs.AddDeltaTimeGroup()

        traj = RaveCreateTrajectory(turbine.env, '')
        traj.Init(cs)

        for i in range(len(joints)):
            waypoint = list(joints[i])
            waypoint.extend(list(joints_vel[i]))
            waypoint.extend(list(joints_acc[i]))
            waypoint.extend([times[i]])
            traj.Insert(traj.GetNumWaypoints(), waypoint)
        return traj
Esempio n. 9
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    def test_serialize(self):
        """ This test verifies if the class can serialize a path in openrave format.
        """

        ind = str()
        for i in range(self.robot.GetDOF()):
            ind += str(i) + ' '

        cs = ConfigurationSpecification()
        _ = cs.AddGroup('joint_values ' + self.robot.GetName() + ' ' + ind,
                        len(self.robot.GetActiveDOFIndices()), 'cubic')

        traj = RaveCreateTrajectory(self.turbine.env, '')
        traj.Init(cs)
        for i in range(len(self.joints)):
            waypoint = list(self.joints[i])
            traj.Insert(traj.GetNumWaypoints(), waypoint)
        path = blade_coverage.Path(self.rays)
        path.data = [traj]
        try:
            path.serialize('test_serialize')
            shutil.rmtree('test_serialize')
        except:
            self.assertTrue(False, msg='Data can not be serialized')
Esempio n. 10
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    def _get_trajectory(self, robot, q_goal, dof_indices):
        """
        Generates a hand trajectory that attempts to move the specified
        dof_indices to the configuration indicated in q_goal. The trajectory
        will move the hand until q_goal is reached or an invalid configuration
        (usually collision) is detected.

        @param robot: OpenRAVE robot
        @param q_goal: goal configuration (dof values)
        @param dof_indices: indices of the dofs specified in q_goal
        @return hand trajectory
        """
        def collision_callback(report, is_physics):
            """
            Callback for collision detection. Add the links that are in
            collision to the colliding_links set in the enclosing frame.

            @param report: collision report
            @param is_physics: whether collision is from physics
            @return ignore collision action
            """
            colliding_links.update([report.plink1, report.plink2])
            return CollisionAction.Ignore

        env = robot.GetEnv()
        collision_checker = env.GetCollisionChecker()
        dof_indices = np.array(dof_indices, dtype='int')

        report = CollisionReport()

        handle = env.RegisterCollisionCallback(collision_callback)

        with \
            robot.CreateRobotStateSaver(
                Robot.SaveParameters.ActiveDOF
                | Robot.SaveParameters.LinkTransformation), \
            CollisionOptionsStateSaver(
                collision_checker,
                CollisionOptions.ActiveDOFs):

            robot.SetActiveDOFs(dof_indices)
            q_prev = robot.GetActiveDOFValues()

            # Create the output trajectory.
            cspec = robot.GetActiveConfigurationSpecification('linear')
            cspec.AddDeltaTimeGroup()

            traj = RaveCreateTrajectory(env, '')
            traj.Init(cspec)

            # Velocity that each joint will be moving at while active.
            qd = np.sign(q_goal - q_prev) * robot.GetActiveDOFMaxVel()

            # Duration required for each joint to reach the goal.
            durations = (q_goal - q_prev) / qd
            durations[qd == 0.] = 0.

            t_prev = 0.
            events = np.concatenate((
                [0.],
                durations,
                np.arange(0., durations.max(), 0.01),
            ))
            mask = np.array([True] * len(q_goal), dtype='bool')

            for t_curr in np.unique(events):
                robot.SetActiveDOFs(dof_indices[mask])

                # Disable joints that have reached the goal.
                mask = np.logical_and(mask, durations >= t_curr)

                # Advance the active DOFs.
                q_curr = q_prev.copy()
                q_curr[mask] += (t_curr - t_prev) * qd[mask]
                robot.SetDOFValues(q_curr, dof_indices)

                # Check for collision. This only operates on the active DOFs
                # because the ActiveDOFs flag is set. We use a collision
                # callback to build a set of all links in collision.
                colliding_links = set()
                env.CheckCollision(robot, report=report)
                robot.CheckSelfCollision(report=report)

                # Check which DOF(s) are involved in the collision.
                mask = np.logical_and(mask, [
                    not any(
                        robot.DoesAffect(dof_index, link.GetIndex())
                        for link in colliding_links)
                    for dof_index in dof_indices
                ])

                # Revert the DOFs that are in collision.
                # TODO: This doesn't seem to take the links out of collision.
                q_curr = q_prev.copy()
                q_curr[mask] += (t_curr - t_prev) * qd[mask]

                # Add a waypoint to the output trajectory.
                waypoint = np.empty(cspec.GetDOF())
                cspec.InsertDeltaTime(waypoint, t_curr - t_prev)
                cspec.InsertJointValues(waypoint, q_curr, robot, dof_indices,
                                        0)
                traj.Insert(traj.GetNumWaypoints(), waypoint)

                t_prev = t_curr
                q_prev = q_curr

                # Terminate if all joints are inactive.
                if not mask.any():
                    break

        del handle
        return traj
Esempio n. 11
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    def MoveUntilTouch(manipulator, direction, distance, max_distance=None,
                       max_force=5.0, max_torque=None, ignore_collisions=None,
                       velocity_limit_scale=0.25, **kw_args):
        """Execute a straight move-until-touch action.
        This action stops when a sufficient force is is felt or the manipulator
        moves the maximum distance. The motion is considered successful if the
        end-effector moves at least distance. In simulation, a move-until-touch
        action proceeds until the end-effector collids with the environment.

        @param direction unit vector for the direction of motion in the world frame
        @param distance minimum distance in meters
        @param max_distance maximum distance in meters
        @param max_force maximum force in Newtons
        @param max_torque maximum torque in Newton-Meters
        @param ignore_collisions collisions with these objects are ignored when 
        planning the path, e.g. the object you think you will touch
        @param velocity_limit_scale A multiplier to use to scale velocity limits 
        when executing MoveUntilTouch ( < 1 in most cases).           
        @param **kw_args planner parameters
        @return felt_force flag indicating whether we felt a force.
        """
        from contextlib import nested
        from openravepy import CollisionReport, KinBody, Robot, RaveCreateTrajectory
        from prpy.planning.exceptions import CollisionPlanningError

        delta_t = 0.01

        robot = manipulator.GetRobot()
        env = robot.GetEnv()
        dof_indices = manipulator.GetArmIndices()

        direction = numpy.array(direction, dtype='float')

        # Default argument values.
        if max_distance is None:
            max_distance = 1.
            warnings.warn(
                'MoveUntilTouch now requires the "max_distance" argument.'
                ' This will be an error in the future.',
                DeprecationWarning)

        if max_torque is None:
            max_torque = numpy.array([100.0, 100.0, 100.0])

        if ignore_collisions is None:
            ignore_collisions = []

        with env:
            # Compute the expected force direction in the hand frame.
            hand_pose = manipulator.GetEndEffectorTransform()
            force_direction = numpy.dot(hand_pose[0:3, 0:3].T, -direction)

            # Disable the KinBodies listed in ignore_collisions. We backup the
            # "enabled" state of all KinBodies so we can restore them later.
            body_savers = [
                body.CreateKinBodyStateSaver() for body in ignore_collisions]
            robot_saver = robot.CreateRobotStateSaver(
                  Robot.SaveParameters.ActiveDOF
                | Robot.SaveParameters.ActiveManipulator
                | Robot.SaveParameters.LinkTransformation)

            with robot_saver, nested(*body_savers) as f:
                manipulator.SetActive()
                robot_cspec = robot.GetActiveConfigurationSpecification()

                for body in ignore_collisions:
                    body.Enable(False)

                path = robot.PlanToEndEffectorOffset(direction=direction,
                    distance=distance, max_distance=max_distance, **kw_args)

        # Execute on the real robot by tagging the trajectory with options that
        # tell the controller to stop on force/torque input.
        if not manipulator.simulated:
            raise NotImplementedError('MoveUntilTouch not yet implemented under ros_control.')
        # Forward-simulate the motion until it hits an object.
        else:
            traj = robot.PostProcessPath(path)
            is_collision = False

            traj_cspec = traj.GetConfigurationSpecification()
            new_traj = RaveCreateTrajectory(env, '')
            new_traj.Init(traj_cspec)

            robot_saver = robot.CreateRobotStateSaver(
                Robot.SaveParameters.LinkTransformation)
            
            with env, robot_saver:
                for t in numpy.arange(0, traj.GetDuration(), delta_t):
                    waypoint = traj.Sample(t)

                    dof_values = robot_cspec.ExtractJointValues(
                        waypoint, robot, dof_indices, 0)
                    manipulator.SetDOFValues(dof_values)

                    # Terminate if we detect collision with the environment.
                    report = CollisionReport()
                    if env.CheckCollision(robot, report=report):
                        logger.info('Terminated from collision: %s',
                            str(CollisionPlanningError.FromReport(report)))
                        is_collision = True
                        break
                    elif robot.CheckSelfCollision(report=report):
                        logger.info('Terminated from self-collision: %s',
                            str(CollisionPlanningError.FromReport(report)))
                        is_collision = True
                        break

                    # Build the output trajectory that stops in contact.
                    if new_traj.GetNumWaypoints() == 0:
                        traj_cspec.InsertDeltaTime(waypoint, 0.)
                    else:
                        traj_cspec.InsertDeltaTime(waypoint, delta_t)
                    
                    new_traj.Insert(new_traj.GetNumWaypoints(), waypoint)

            if new_traj.GetNumWaypoints() > 0:
                robot.ExecuteTrajectory(new_traj)

            return is_collision
Esempio n. 12
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    def FollowVectorField(self, robot, fn_vectorfield, fn_terminate,
                          integration_time_interval=10.0, timelimit=5.0,
                          sampling_func=util.SampleTimeGenerator,
                          norm_order=2, **kw_args):
        """
        Follow a joint space vectorfield to termination.

        @param robot
        @param fn_vectorfield a vectorfield of joint velocities
        @param fn_terminate custom termination condition
        @param integration_time_interval The time interval to integrate
                                         over.
        @param timelimit time limit before giving up
        @param sampling_func sample generator to compute validity checks
           Note: Function will terminate as soon as invalid configuration is 
                 encountered. No more samples will be requested from the 
                 sampling_func after this occurs.
        @param norm_order order of norm to use for collision checking
        @param kw_args keyword arguments to be passed to fn_vectorfield
        @return traj
        """
        from .exceptions import (
            CollisionPlanningError,
            SelfCollisionPlanningError,
        )
        from openravepy import CollisionReport, RaveCreateTrajectory
        from ..util import GetLinearCollisionCheckPts
        import time
        import scipy.integrate

        CheckLimitsAction = openravepy.KinBody.CheckLimitsAction

        # This is a workaround to emulate 'nonlocal' in Python 2.
        nonlocals = {
            'exception': None,
            't_cache': None,
            # Must be negative so we check the start of the trajectory.
            't_check': -1.,
        }

        env = robot.GetEnv()
        active_indices = robot.GetActiveDOFIndices()

        # Create a new trajectory matching the current
        # robot's joint configuration specification
        cspec = robot.GetActiveConfigurationSpecification('linear')
        cspec.AddDeltaTimeGroup()
        cspec.ResetGroupOffsets()
        path = RaveCreateTrajectory(env, '')
        path.Init(cspec)

        time_start = time.time()

        def fn_wrapper(t, q):
            """
            The integrator will try to solve this equation
            at each time step.
            Note: t is the integration time and is non-monotonic.
            """
            # Set the joint values, without checking the joint limits
            robot.SetActiveDOFValues(q, CheckLimitsAction.Nothing)

            return fn_vectorfield()

        def fn_status_callback(t, q):
            """
            Check joint-limits and collisions for a specific joint
            configuration. This is called multiple times at DOF
            resolution in order to check along the entire length of the
            trajectory.
            Note: This is called by fn_callback, which is currently
            called after each integration time step, which means we are
            doing more checks than required.
            """
            if time.time() - time_start >= timelimit:
                raise TimeLimitError()

            # Check joint position limits.
            # We do this before setting the joint angles.
            util.CheckJointLimits(robot, q)

            robot.SetActiveDOFValues(q)

            # Check collision (throws an exception on collision)
            robot_checker.VerifyCollisionFree()

            # Check the termination condition.
            status = fn_terminate()

            if Status.DoesCache(status):
                nonlocals['t_cache'] = t

            if Status.DoesTerminate(status):
                raise TerminationError()

        def fn_callback(t, q):
            """
            This is called at every successful integration step.
            """
            try:
                # Add the waypoint to the trajectory.
                waypoint = numpy.zeros(cspec.GetDOF())
                cspec.InsertDeltaTime(waypoint, t - path.GetDuration())
                cspec.InsertJointValues(waypoint, q, robot, active_indices, 0)
                path.Insert(path.GetNumWaypoints(), waypoint)

                # Run constraint checks at DOF resolution.
                if path.GetNumWaypoints() == 1:
                    checks = [(t, q)]
                else:
                    # This returns collision checks for the entire trajectory,
                    # including the part that has already been checked. These
                    # duplicate checks will be filtered out below.
                    checks = GetLinearCollisionCheckPts(robot, path,
                                                        norm_order=norm_order,
                                                        sampling_func=sampling_func)

                for t_check, q_check in checks:
                    # TODO: It would be more efficient to only generate checks
                    # for the new part of the trajectory.
                    if t_check <= nonlocals['t_check']:
                        continue

                    # Record the time of this check so we continue checking
                    # from where we left off. We do this first, just in case
                    # fn_status_callback raises an exception.
                    nonlocals['t_check'] = t_check

                    fn_status_callback(t_check, q_check)

                return 0  # Keep going.
            except PlanningError as e:
                nonlocals['exception'] = e
                return -1  # Stop.

        with self.robot_checker_factory(robot) as robot_checker, \
            robot.CreateRobotStateSaver(Robot.SaveParameters.LinkTransformation):
            # Integrate the vector field to get a configuration space path.
            #
            # TODO: Tune the integrator parameters.
            #
            # Integrator: 'dopri5'
            # DOPRI (Dormand & Prince 1980) is an explicit method for solving ODEs.
            # It is a member of the Runge-Kutta family of solvers.
            integrator = scipy.integrate.ode(f=fn_wrapper)
            integrator.set_integrator(name='dopri5',
                                      first_step=0.1,
                                      atol=1e-3,
                                      rtol=1e-3)
            # Set function to be called at every successful integration step.
            integrator.set_solout(fn_callback)
            integrator.set_initial_value(y=robot.GetActiveDOFValues(), t=0.)

            integrator.integrate(t=integration_time_interval)

        t_cache = nonlocals['t_cache']
        exception = nonlocals['exception']

        if t_cache is None:
            raise exception or PlanningError(
                'An unknown error has occurred.', deterministic=True)
        elif exception:
            logger.warning('Terminated early: %s', str(exception))

        # Remove any parts of the trajectory that are not cached. This also
        # strips the (potentially infeasible) timing information.
        output_cspec = robot.GetActiveConfigurationSpecification('linear')
        output_path = RaveCreateTrajectory(env, '')
        output_path.Init(output_cspec)

        # Add all waypoints before the last integration step. GetWaypoints does
        # not include the upper bound, so this is safe.
        cached_index = path.GetFirstWaypointIndexAfterTime(t_cache)
        output_path.Insert(0, path.GetWaypoints(0, cached_index), cspec)

        # Add a segment for the feasible part of the last integration step.
        output_path.Insert(output_path.GetNumWaypoints(),
                           path.Sample(t_cache),
                           cspec)

        util.SetTrajectoryTags(output_path, {
            Tags.SMOOTH: True,
            Tags.CONSTRAINED: True,
            Tags.DETERMINISTIC_TRAJECTORY: True,
            Tags.DETERMINISTIC_ENDPOINT: True,
        }, append=True)

        return output_path
Esempio n. 13
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class RetimeTrajectoryTest(object):
    def setUp(self):
        from openravepy import planningutils, Planner, RaveCreateTrajectory

        cspec = self.robot.GetActiveConfigurationSpecification('linear')

        self.feasible_path = RaveCreateTrajectory(self.env, '')
        self.feasible_path.Init(cspec)
        self.feasible_path.Insert(0, self.waypoint1)
        self.feasible_path.Insert(1, self.waypoint2)
        self.feasible_path.Insert(2, self.waypoint3)

        self.dt = 0.01
        self.tolerance = 0.1  # 10% error

    def test_RetimeTrajectory(self):
        import numpy
        from numpy.testing import assert_allclose
        from openravepy import planningutils, Planner

        # Setup/Test
        traj = self.planner.RetimeTrajectory(self.robot, self.feasible_path)

        # Assert
        position_cspec = self.feasible_path.GetConfigurationSpecification()
        velocity_cspec = position_cspec.ConvertToDerivativeSpecification(1)
        zero_dof_values = numpy.zeros(position_cspec.GetDOF())

        # Verify that the trajectory passes through the original waypoints.
        waypoints = [self.waypoint1, self.waypoint2, self.waypoint3]
        waypoint_indices = [None] * len(waypoints)

        for iwaypoint in xrange(traj.GetNumWaypoints()):
            joint_values = traj.GetWaypoint(iwaypoint, position_cspec)

            # Compare the waypoint against every input waypoint.
            for icandidate, candidate_waypoint in enumerate(waypoints):
                if numpy.allclose(joint_values, candidate_waypoint):
                    self.assertIsNone(
                        waypoint_indices[icandidate],
                        'Input waypoint {} appears twice in the output'
                        ' trajectory (indices: {} and {})'.format(
                            icandidate, waypoint_indices[icandidate],
                            iwaypoint))

                    waypoint_indices[icandidate] = iwaypoint

        self.assertEquals(waypoint_indices[0], 0)
        self.assertEquals(waypoint_indices[-1], traj.GetNumWaypoints() - 1)

        for iwaypoint in waypoint_indices:
            self.assertIsNotNone(iwaypoint)

            # Verify that the velocity at the waypoint is zero.
            joint_velocities = traj.GetWaypoint(iwaypoint, velocity_cspec)
            assert_allclose(joint_velocities, zero_dof_values)

        # Verify the trajectory between waypoints.
        for t in numpy.arange(self.dt, traj.GetDuration(), self.dt):
            iafter = traj.GetFirstWaypointIndexAfterTime(t)
            ibefore = iafter - 1

            joint_values = traj.Sample(t, position_cspec)
            joint_values_before = traj.GetWaypoint(ibefore, position_cspec)
            joint_values_after = traj.GetWaypoint(iafter, position_cspec)

            distance_full = numpy.linalg.norm(joint_values_after -
                                              joint_values_before)
            distance_before = numpy.linalg.norm(joint_values -
                                                joint_values_before)
            distance_after = numpy.linalg.norm(joint_values -
                                               joint_values_after)
            deviation = distance_before + distance_after - distance_full
            self.assertLess(deviation, self.tolerance * distance_full)

        # Check joint limits and dynamic feasibility.
        params = Planner.PlannerParameters()
        params.SetRobotActiveJoints(self.robot)

        planningutils.VerifyTrajectory(params, traj, self.dt)
Esempio n. 14
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    def FollowVectorField(self,
                          robot,
                          fn_vectorfield,
                          fn_terminate,
                          integration_time_interval=10.0,
                          timelimit=5.0,
                          **kw_args):
        """
        Follow a joint space vectorfield to termination.

        @param robot
        @param fn_vectorfield a vectorfield of joint velocities
        @param fn_terminate custom termination condition
        @param integration_time_interval The time interval to integrate
                                         over.
        @param timelimit time limit before giving up
        @param kw_args keyword arguments to be passed to fn_vectorfield
        @return traj
        """
        from .exceptions import (
            CollisionPlanningError,
            SelfCollisionPlanningError,
        )
        from openravepy import CollisionReport, RaveCreateTrajectory
        from ..util import GetCollisionCheckPts
        import time
        import scipy.integrate

        CheckLimitsAction = openravepy.KinBody.CheckLimitsAction

        # This is a workaround to emulate 'nonlocal' in Python 2.
        nonlocals = {
            'exception': None,
            't_cache': None,
            't_check': 0.,
        }

        env = robot.GetEnv()
        active_indices = robot.GetActiveDOFIndices()

        # Create a new trajectory matching the current
        # robot's joint configuration specification
        cspec = robot.GetActiveConfigurationSpecification('linear')
        cspec.AddDeltaTimeGroup()
        cspec.ResetGroupOffsets()
        path = RaveCreateTrajectory(env, '')
        path.Init(cspec)

        time_start = time.time()

        def fn_wrapper(t, q):
            """
            The integrator will try to solve this equation
            at each time step.
            Note: t is the integration time and is non-monotonic.
            """
            # Set the joint values, without checking the joint limits
            robot.SetActiveDOFValues(q, CheckLimitsAction.Nothing)

            return fn_vectorfield()

        def fn_status_callback(t, q):
            """
            Check joint-limits and collisions for a specific joint
            configuration. This is called multiple times at DOF
            resolution in order to check along the entire length of the
            trajectory.
            Note: This is called by fn_callback, which is currently
            called after each integration time step, which means we are
            doing more checks than required.
            """
            if time.time() - time_start >= timelimit:
                raise TimeLimitError()

            # Check joint position limits.
            # We do this before setting the joint angles.
            util.CheckJointLimits(robot, q)

            robot.SetActiveDOFValues(q)

            # Check collision.
            report = CollisionReport()
            if env.CheckCollision(robot, report=report):
                raise CollisionPlanningError.FromReport(report)
            elif robot.CheckSelfCollision(report=report):
                raise SelfCollisionPlanningError.FromReport(report)

            # Check the termination condition.
            status = fn_terminate()

            if Status.DoesCache(status):
                nonlocals['t_cache'] = t

            if Status.DoesTerminate(status):
                raise TerminationError()

        def fn_callback(t, q):
            """
            This is called at every successful integration step.
            """
            try:
                # Add the waypoint to the trajectory.
                waypoint = numpy.zeros(cspec.GetDOF())
                cspec.InsertDeltaTime(waypoint, t - path.GetDuration())
                cspec.InsertJointValues(waypoint, q, robot, active_indices, 0)
                path.Insert(path.GetNumWaypoints(), waypoint)

                # Run constraint checks at DOF resolution.
                if path.GetNumWaypoints() == 1:
                    checks = [(t, q)]
                else:
                    # TODO: This should start at t_check. Unfortunately, a bug
                    # in GetCollisionCheckPts causes this to enter an infinite
                    # loop.
                    checks = GetCollisionCheckPts(robot,
                                                  path,
                                                  include_start=False)
                    # start_time=nonlocals['t_check'])

                for t_check, q_check in checks:
                    fn_status_callback(t_check, q_check)

                    # Record the time of this check so we continue checking at
                    # DOF resolution the next time the integrator takes a step.
                    nonlocals['t_check'] = t_check

                return 0  # Keep going.
            except PlanningError as e:
                nonlocals['exception'] = e
                return -1  # Stop.

        # Integrate the vector field to get a configuration space path.
        #
        # TODO: Tune the integrator parameters.
        #
        # Integrator: 'dopri5'
        # DOPRI (Dormand & Prince 1980) is an explicit method for solving ODEs.
        # It is a member of the Runge-Kutta family of solvers.
        integrator = scipy.integrate.ode(f=fn_wrapper)
        integrator.set_integrator(name='dopri5',
                                  first_step=0.1,
                                  atol=1e-3,
                                  rtol=1e-3)
        # Set function to be called at every successful integration step.
        integrator.set_solout(fn_callback)
        # Initial conditions
        integrator.set_initial_value(y=robot.GetActiveDOFValues(), t=0.)
        integrator.integrate(t=integration_time_interval)

        t_cache = nonlocals['t_cache']
        exception = nonlocals['exception']

        if t_cache is None:
            raise exception or PlanningError('An unknown error has occurred.')
        elif exception:
            logger.warning('Terminated early: %s', str(exception))

        # Remove any parts of the trajectory that are not cached. This also
        # strips the (potentially infeasible) timing information.
        output_cspec = robot.GetActiveConfigurationSpecification('linear')
        output_path = RaveCreateTrajectory(env, '')
        output_path.Init(output_cspec)

        # Add all waypoints before the last integration step. GetWaypoints does
        # not include the upper bound, so this is safe.
        cached_index = path.GetFirstWaypointIndexAfterTime(t_cache)
        output_path.Insert(0, path.GetWaypoints(0, cached_index), cspec)

        # Add a segment for the feasible part of the last integration step.
        output_path.Insert(output_path.GetNumWaypoints(), path.Sample(t_cache),
                           cspec)

        # Flag this trajectory as constrained.
        util.SetTrajectoryTags(output_path, {
            Tags.CONSTRAINED: 'true',
            Tags.SMOOTH: 'true'
        },
                               append=True)
        return output_path