def Robot_Config_Plot(world,
                      DOF,
                      state_ref,
                      contact_link_dictionary,
                      convex_edges_list,
                      delta_t=0.5):
    # This function is used to plot the robot motion
    # The optimized solution is used to plot the robot motion and the contact forces

    # Initialize the robot motion viewer
    robot_viewer = MyGLPlugin(world)
    # Here it is to unpack the robot optimized solution into a certain sets of the lists

    vis.pushPlugin(robot_viewer)
    vis.add("world", world)
    vis.show()

    sim_robot = world.robot(0)
    sim_robot.setConfig(state_ref[0:DOF])

    contact_link_list = contact_link_dictionary.keys()

    while vis.shown():
        # This is the main plot program
        vis.lock()
        sim_robot.setConfig(state_ref[0:DOF])
        # Convex_Edges_Plot(sim_robot, convex_edges_list, vis)
        # Robot_COM_Plot(sim_robot, vis)
        vis.unlock()
        time.sleep(delta_t)
コード例 #2
0
def launch_test_mvbb_grasps(robotname, box_db, links_to_check = None):
    """Launches a very simple program that spawns a box with dimensions specified in boxes_db.
    """

    world = WorldModel()
    world.loadElement("data/terrains/plane.env")
    robot = make_moving_base_robot(robotname, world)
    xform = resource.get("default_initial_%s.xform" % robotname, description="Initial hand transform",
                         default=se3.identity(), world=world, doedit=False)

    for box_dims, poses in box_db.db.items():
        if world.numRigidObjects() > 0:
            world.remove(world.rigidObject(0))
        obj = make_box(world,
                       box_dims[0],
                       box_dims[1],
                       box_dims[2])
        poses_filtered = []

        R,t = obj.getTransform()
        obj.setTransform(R, [0, 0, box_dims[2]/2.])
        w_T_o = np.array(se3.homogeneous(obj.getTransform()))
        p_T_h = np.array(se3.homogeneous(xform))
        p_T_h[2][3] += 0.02

        for pose in poses:
            w_T_p = w_T_o.dot(pose)
            w_T_h_des_se3 = se3.from_homogeneous(w_T_p.dot(p_T_h))
            if CollisionTestPose(world, robot, obj, w_T_h_des_se3):
                pose_pp = se3.from_homogeneous(pose)
                t_pp = pose_pp[1]
                q_pp = so3.quaternion(pose_pp[0])
                q_pp = [q_pp[1], q_pp[2], q_pp[3], q_pp[0]]
                print "Pose", t_pp + q_pp, "has been filtered since it is in collision for box", box_dims
            elif  w_T_p[2][3] <= 0.:
                print "Pose", t_pp + q_pp, "has been filtered since it penetrates with table"
            else:
                poses_filtered.append(pose)
        print "Filtered", len(poses)-len(poses_filtered), "out of", len(poses), "poses"
        # embed()
        # create a hand emulator from the given robot name
        module = importlib.import_module('plugins.' + robotname)
        # emulator takes the robot index (0), start link index (6), and start driver index (6)
        program = FilteredMVBBTesterVisualizer(box_dims,
                                               poses_filtered,
                                               world,
                                               p_T_h,
                                               module,
                                               box_db,
                                               links_to_check)

        vis.setPlugin(None)
        vis.setPlugin(program)
        program.reshape(800, 600)

        vis.show()
        # this code manually updates the visualization
        while vis.shown():
            time.sleep(0.1)
    return
コード例 #3
0
 def closeEvent(self,event):
     if len(self.modified) > 0:
         reply = QtWidgets.QMessageBox.question(self, "Unsaved changes", "Would you like to save changes to " + ', '.join(self.modified)+ "?",
                                 QtWidgets.QMessageBox.Yes|QtWidgets.QMessageBox.No);
         if reply == QtWidgets.QMessageBox.Yes:
             self.onSaveClicked()
     vis.show(False)
コード例 #4
0
def launch_xform_viewer(robotname):
    """Launches a very simple program that spawns an object from one of the
    databases.
    It launches a visualization of the mvbb decomposition of the object, and corresponding generated poses.
    It then spawns a hand and tries all different poses to check for collision
    """

    world = WorldModel()
    robot = make_moving_base_robot(robotname, world)
    set_moving_base_xform(robot, se3.identity()[0], se3.identity()[1])

    xform = resource.get("default_initial_%s.xform" % robotname,
                         description="Initial hand transform",
                         default=se3.identity(),
                         world=world,
                         doedit=False)
    print "Transform:", xform
    program = XFormVisualizer(world, xform)
    vis.setPlugin(program)
    program.reshape(800, 600)

    vis.show()

    # this code manually updates the visualization

    while vis.shown():
        time.sleep(0.01)

    vis.kill()
    return
コード例 #5
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def play_with_trajectory(traj, configs=[3]):
    vis.add("trajectory", traj)
    names = []
    for i, x in enumerate(traj.milestones):
        if i in configs:
            print("Editing", i)
            names.append("milestone " + str(i))
            vis.add(names[-1], x[:])
            vis.edit(names[-1])
    #vis.addPlot("distance")
    vis.show()
    while vis.shown():
        vis.lock()
        t0 = time.time()
        updated = False
        for name in names:
            index = int(name.split()[1])
            qi = vis.getItemConfig(name)
            if qi != traj.milestones[index]:
                traj.milestones[index] = qi
                updated = True
        if updated:
            vis.add("trajectory", traj)
            xnew = trajcache.trajectoryToState(traj)
            ctest2.setx(xnew)
            res = ctest2.minvalue(xtraj)
            print(res)
            ctest2.clearx()
        vis.unlock()
        t1 = time.time()
        #vis.logPlot("timing","opt",t1-t0)
        time.sleep(max(0.001, 0.025 - (t1 - t0)))
コード例 #6
0
def plugin_template(world):
    """Demonstrates the GLPluginInterface functionality"""
    #create a subclass of GLPluginInterface
    plugin = MyGLPlugin(world)
    vis.pushPlugin(plugin)   #put the plugin on top of the standard visualization functionality.
    #vis.setPlugin(plugin)   #use this to completely replace the standard visualization functionality with your own.

    vis.add("world",world)
    vis.setWindowTitle("GLPluginInterface template")
    #run the visualizer 
    if not MULTITHREADED:
        def callback(plugin=plugin):
            if plugin.quit:
                vis.show(False)
        vis.loop(callback=callback,setup=vis.show)
    else:
        #if plugin.quit is True
        vis.show()
        while vis.shown() and not plugin.quit:
            vis.lock()
            #TODO: you may modify the world here
            vis.unlock()
            #changes to the visualization must be done outside the lock
            time.sleep(0.01)
        if plugin.quit:
            #if you want to do other stuff after the window quits, the window needs to be hidden 
            vis.show(False)
    print("Waiting for 2 s...")
    time.sleep(2.0)
    #quit the visualization thread nicely
    vis.kill()
コード例 #7
0
def animate_trajectories(trajs, times, endWaitTime=5.0, speed=0.2):
    global world
    active = 0
    for i in range(len(trajs)):
        vis.add(
            "traj" + str(i), trajs[i].getLinkTrajectory(
                END_EFFECTOR_LINK,
                0.1).getPositionTrajectory(END_EFFECTOR_LOCAL_POSITION))
        vis.hide("traj" + str(i))
        vis.hideLabel("traj" + str(i))
    vis.show()
    t0 = time.time()
    if len(times) == 1:
        tnext = float('inf')
    else:
        tnext = times[active + 1]
    while vis.shown():
        t = time.time()
        if t - t0 > tnext:
            nextactive = (active + 1) % len(times)
            vis.hide("traj" + str(active))
            vis.hide("traj" + str(nextactive), False)
            active = nextactive
            if nextactive + 1 == len(times):
                tnext += endWaitTime
            else:
                tnext += times[active + 1] - times[active]
        vis.lock()
        world.robot(0).setConfig(trajs[active].eval((t - t0) * speed,
                                                    endBehavior='loop'))
        vis.unlock()
        time.sleep(0.01)
    print("Done.")
コード例 #8
0
def edit_template(world):
    """Shows how to pop up a visualization window with a world in which the robot configuration and a transform can be edited"""
    #add the world to the visualizer
    vis.add("world",world)
    xform = se3.identity()
    vis.add("transform",xform)
    robotPath = ("world",world.robot(0).getName())  #compound item reference: refers to robot 0 in the world
    vis.edit(robotPath)   
    vis.edit("transform")

    #This prints how to get references to items in the visualizer
    print("Visualization items:")
    vis.listItems(indent=2)

    vis.setWindowTitle("Visualization editing test")
    if not MULTITHREADED:
        vis.loop(setup=vis.show)
    else:
        vis.show()
        while vis.shown():
            vis.lock()
            #TODO: you may modify the world here.
            vis.unlock()
            time.sleep(0.01)
    print("Resulting configuration",vis.getItemConfig(robotPath))
    print("Resulting transform (config)",vis.getItemConfig("transform"))  # this is a vector describing the item parameters
    xform = list(xform)  #convert se3 element from tuple to list
    config.setConfig(xform,vis.getItemConfig("transform"))
    print("Resulting transform (se3)",xform)
    #quit the visualization thread nicely
    vis.kill()
コード例 #9
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def main():
    print("============================================================")
    print(sys.argv[0] + ": Simulates a robot file and Python controller")
    if len(sys.argv) <= 1:
        print("USAGE: simtest.py [world_file] [controller files (.py)]")
    print("============================================================")
    if len(sys.argv) <= 1:
        exit()

    world = WorldModel()
    #load up any world items, control modules, or paths
    control_modules = []
    for fn in sys.argv[1:]:
        path, base = os.path.split(fn)
        mod_name, file_ext = os.path.splitext(base)
        if file_ext == '.py' or file_ext == '.pyc':
            sys.path.append(os.path.abspath(path))
            mod = importlib.import_module(mod_name, base)
            control_modules.append(mod)
        elif file_ext == '.path':
            control_modules.append(fn)
        else:
            res = world.readFile(fn)
            if not res:
                print("Unable to load model " + fn)
                print("Quitting...")
                sys.exit(1)
    viewer = MyGLViewer(world)

    for i, c in enumerate(control_modules):
        if isinstance(c, str):
            sys.path.append(os.path.abspath("../control"))
            import trajectory_controller
            #it's a path file, try to load it
            controller = trajectory_controller.make(world.robot(i), c)
        else:
            try:
                maker = c.make
            except AttributeError:
                print("Module", c.__name__, "must have a make() method")
                print("Quitting...")
                sys.exit(1)
            controller = maker(world.robot(i))
        viewer.sim.setController(world.robot(i), controller)

    vis.setWindowTitle("Klamp't Simulation Tester")
    if SPLIT_SCREEN_TEST:
        viewer2 = MyGLViewer(world)
        vis.setPlugin(viewer)
        vis.addPlugin(viewer2)
        viewer2.window.broadcast = True
        vis.show()
        while vis.shown():
            time.sleep(0.01)
        vis.kill()
    else:
        vis.run(viewer)
コード例 #10
0
 def closeEvent(self,event):
     if self.isVisible():
         reply = QMessageBox.question(self, "Confirm quit", "Do you really want to quit?",
                                 QMessageBox.Yes|QMessageBox.No);
         if reply == QMessageBox.Yes:
             vis.show(False)
             QMainWindow.close(self)
     else:
         QMainWindow.closeEvent(self,event)
コード例 #11
0
        def loop_through_sensors(world=self.world,
                                 sensor=self.sensor,
                                 max_pics=max_pics):
            for counter in tqdm(range(max_pics)):
                if counter > 0:
                    self.chessEngine.randomizePieces(32)

                # Arrange pieces and model world
                self.chessEngine.arrangePieces()

                self._randomlyRotateCamera(20, 40, 0.6)

                sensor.kinematicReset()
                sensor.kinematicSimulate(world, 0.01)

                rgb, depth = sensing.camera_to_images(self.sensor)

                # Project RGB and depth images to rectify them
                local_corner_coords = np.float32([
                    sensing.camera_project(self.sensor, self.robot, pt)[:2]
                    for pt in self._boardWorldCorners
                ])

                H = cv2.getPerspectiveTransform(local_corner_coords,
                                                self._rectifiedPictureCorners)

                color_rectified = cv2.warpPerspective(
                    rgb, H, (DataUtils.IMAGE_SIZE, DataUtils.IMAGE_SIZE))
                depth_rectified = cv2.warpPerspective(
                    depth, H, (DataUtils.IMAGE_SIZE, DataUtils.IMAGE_SIZE))

                depth_rectified = np.uint8(
                    (depth_rectified - depth_rectified.min()) /
                    (depth_rectified.max() - depth_rectified.min()))

                pieces_arrangement = self.chessEngine.getPieceArrangement()

                images, classes = DataUtils.split_image_by_classes(
                    color_rectified, depth_rectified, data_distribution,
                    pieces_arrangement)

                rectified_fname = self._rectifiedFNFormat % (counter)
                Image.fromarray(color_rectified).save(rectified_fname)

                for idx in range(sum(data_distribution)):
                    color_fname = self._colorFNFormat % (counter, idx)
                    depth_fname = self._depthFNFormat % (counter, idx)

                    Image.fromarray(images[idx, :, :, :3]).save(color_fname)
                    Image.fromarray(images[idx, :, :, 3]).save(depth_fname)

                    metadata_f.write(
                        f'{color_fname},{depth_fname},{classes[idx]}\n')

            vis.show(False)
def PIP_Config_Plot(world, DOF, state_ref, pips_list, CPFlag, delta_t=0.5):
    # This function is used to plot the robot motion
    # The optimized solution is used to plot the robot motion and the contact forces

    # Initialize the robot motion viewer
    robot_viewer = MyGLPlugin(world)
    # Here it is to unpack the robot optimized solution into a certain sets of the lists

    vis.pushPlugin(robot_viewer)
    vis.add("world", world)
    vis.show()

    sim_robot = world.robot(0)
    sim_robot.setConfig(state_ref[0:DOF])

    InfeasiFlag = 0

    while vis.shown():
        # This is the main plot program
        vis.lock()
        sim_robot.setConfig(state_ref[0:DOF])
        PIPs_Number = len(pips_list[0])
        COM_Pos = sim_robot.getCom()
        EdgeAList = pips_list[0]
        EdgeBList = pips_list[1]
        EdgeCOMList = pips_list[2]
        EdgexList = pips_list[3]
        EdgeyList = pips_list[4]
        EdgezList = pips_list[5]

        for i in range(0, PIPs_Number):
            EdgeA = EdgeAList[i]
            EdgeB = EdgeBList[i]
            EdgeCOM = EdgeCOMList[i]
            Edgey = EdgexList[i]
            Edgez = EdgeyList[i]
            Edgex = EdgezList[i]
            PIP_Subplot(i, EdgeA, EdgeB, EdgeCOM, Edgex, Edgey, Edgez, COM_Pos,
                        vis)

        Robot_COM_Plot(sim_robot, vis)

        if CPFlag is 1:
            try:
                h = ConvexHull(EdgeAList)
            except:
                InfeasiFlag = 1
        if InfeasiFlag is 0 and CPFlag is 1:
            h = ConvexHull(EdgeAList)
            hrender = draw_hull.PrettyHullRenderer(h)
            vis.add("blah", h)
            vis.setDrawFunc("blah", my_draw_hull)

        vis.unlock()
        time.sleep(delta_t)
コード例 #13
0
def multiwindow_template(world):
    """Tests multiple windows and views."""
    vis.add("world", world)
    vp = vis.getViewport()
    vp.w, vp.h = 400, 600
    vis.setViewport(vp)
    vis.addText("label1", "This is Window 1", (20, 20))
    vis.setWindowTitle("Window 1")
    vis.show()
    id1 = vis.getWindow()
    print("First window ID:", id1)

    id2 = vis.createWindow("Window 2")
    vis.add("Lone point", [0, 0, 0])
    vis.setViewport(vp)
    vis.addText("label1", "This is Window 2", (20, 20))
    print("Second window ID:", vis.getWindow())
    vis.setWindow(id2)
    vis.spin(float('inf'))

    #restore back to 1 window, clear the text
    vis.setWindow(id1)
    vis.clearText()

    vp = vis.getViewport()
    vp.w, vp.h = 800, 800
    vis.setViewport(vp)

    vis.setWindowTitle("vis.spin test: will close in 5 seconds...")
    vis.spin(5.0)

    #Now testing ability to re-launch windows
    vis.setWindowTitle("Shown again.  Close me to proceed.")
    vis.spin(float('inf'))

    vis.setWindowTitle("Dialog test. Close me to proceed.")
    vp = vis.getViewport()
    vp.w, vp.h = 400, 600
    vis.setViewport(vp)
    vis.dialog()

    vp.w, vp.h = 640, 480
    vis.setViewport(vp)
    for i in range(3):
        widgets = GLWidgetPlugin()
        widgets.addWidget(RobotPoser(world.robot(0)))
        vis.addPlugin(widgets)
    vis.setWindowTitle("Split screen test")
    vis.spin(float('inf'))

    vis.setPlugin(None)
    vis.setWindowTitle("Back to normal. Close me to quit.")
    vis.dialog()
    vis.kill()
コード例 #14
0
def testCartesianDrive():
    w = WorldModel()
    #w.readFile("../../data/tx90scenario0.xml")
    w.readFile("../../data/robots/jaco.rob")
    r = w.robot(0)
    solver = CartesianDriveSolver(r)
    #set a non-singular configuration
    q = r.getConfig()
    q[3] = 0.5
    r.setConfig(q)
    solver.start(q, 6)
    vis.add("world", w)
    vis.addPlot("timing")
    vis.addPlot("info")
    vis.show()
    time.sleep(0.1)
    dt = 0.01
    t = 0
    while t < 20 and vis.shown():
        vis.lock()
        if t < 2:
            v = [0, 0, 0.25]
        elif t < 3:
            v = [0, 0, -0.1]
        elif t < 3.2:
            v = [0, 0, -1]
        elif t < 8:
            v = [0, 0, 0]
        elif t < 10:
            v = [-1, 0, 0]
        else:
            v = [1, 0, 0]
        if t < 4:
            w = [0, 0, 0]
        elif t < 10:
            w = [0, -0.25, 0]
        else:
            w = None
        t0 = time.time()
        progress, qnext = solver.drive(q, w, v, dt)
        t1 = time.time()
        vis.addText("debug", "Vel %s" % (str(v), ))
        vis.logPlot("timing", "t", t1 - t0)
        vis.logPlot("info", "progress", progress)
        vis.logPlot("info", "adj", solver.driveSpeedAdjustment)
        r.setConfig(qnext)
        q = qnext
        vis.unlock()
        vis.add("tgt", solver.driveTransforms[0])
        t += dt
        time.sleep(max(0.005 - (t1 - t0), 0))
    vis.show(False)
    vis.clear()
コード例 #15
0
ファイル: ex.py プロジェクト: ezhang887/Klampt-examples
def run_ex3():
    world = WorldModel()
    res = world.readFile("ex3_file.xml")
    if not res: raise RuntimeError("Unable to load world file")
    vis.add("world", world)
    vis.setWindowTitle("Pick and place test, use a/b/c/d to select target")
    vis.pushPlugin(GLPickAndPlacePlugin(world))
    vis.show()
    while vis.shown():
        time.sleep(0.1)
    vis.setPlugin(None)
    vis.kill()
コード例 #16
0
def Robot_Config_Plot(world, DOF, config_init):
    robot_viewer = MyGLPlugin(world)
    vis.pushPlugin(robot_viewer)
    vis.add("world", world)
    vis.show()

    # Here we would like to read point cloud for visualization of planning.
    # 1. All Reachable Points
    # IdealReachableContacts_data = ContactDataLoader("IdealReachableContact")
    # # 2. Active Reachable Points
    # ReachableContacts_data = ContactDataLoader("ReachableContacts")
    # # 3. Contact Free Points
    # CollisionFreeContacts_data = ContactDataLoader("CollisionFreeContacts")
    # # 4. Supportive Points
    # SupportiveContacts_data = ContactDataLoader("SupportiveContacts")

    OptimalContact_data = ContactDataLoader("OptimalContact")

    OptimalContactWeights_data = ContactDataLoader("OptimalContactWeights")

    OptimalContact_data, OptimalContactWeights_data = ContactDataRefine(
        OptimalContact_data, OptimalContactWeights_data)
    # # 6.
    # TransitionPoints_data = ContactDataLoader("TransitionPoints")
    # import ipdb; ipdb.set_trace()
    # 7.
    InitialTransitionPoints_data = ContactDataLoader("InitialPathWayPoints")
    # 8.
    ShiftedTransitionPoints_data = ContactDataLoader("ShiftedPathWayPoints")
    # 9.
    # FineShiftedPathWayPoints_data = ContactDataLoader("FineShiftedPathWayPoints")
    #
    # ReducedOptimalContact_data = ContactDataLoader("ReducedOptimalContact")

    ContactChoice = ShiftedTransitionPoints_data
    # ContactChoice = SupportiveContacts_data
    SimRobot = world.robot(0)
    SimRobot.setConfig(config_init)
    while vis.shown():
        # This is the main plot program
        vis.lock()
        SimRobot.setConfig(config_init)
        WeightedContactDataPlot(vis, OptimalContact_data,
                                OptimalContactWeights_data)
        ContactDataPlot(vis, ContactChoice)

        vis.unlock()
        time.sleep(0.1)
        import ipdb
        ipdb.set_trace()
        WeightedContactDataUnPlot(vis, OptimalContact_data)
        ContactDataUnplot(vis, ContactChoice)
コード例 #17
0
ファイル: ex.py プロジェクト: ezhang887/Klampt-examples
def run_ex1():
    world = WorldModel()
    res = world.readFile("ex1_file.xml")
    if not res: raise RuntimeError("Unable to load world file")
    vis.add("world", world)
    vis.setWindowTitle(
        "Transit plan test, press l/r to plan with left/right arm")
    vis.pushPlugin(GLTransitPlanPlugin(world))
    vis.show()
    while vis.shown():
        time.sleep(0.1)
    vis.setPlugin(None)
    vis.kill()
コード例 #18
0
ファイル: ex.py プロジェクト: ezhang887/Klampt-examples
def run_ex2():
    world = WorldModel()
    res = world.readFile("ex2_file.xml")
    if not res: raise RuntimeError("Unable to load world file")
    vis.add("world", world)
    vis.pushPlugin(GLTransferPlanPlugin(world))
    vis.setWindowTitle(
        "Transfer plan test, press r/f to plan with right/forward target")
    vis.show()
    while vis.shown():
        time.sleep(0.1)
    vis.setPlugin(None)
    vis.kill()
コード例 #19
0
ファイル: vis_template.py プロジェクト: Hu-i/Klampt-examples
def animation_template(world):
    """Shows how to animate a robot."""
    #first, build a trajectory with 10 random configurations
    robot = world.robot(0)
    times = range(10)
    milestones = []
    for t in times:
        robot.randomizeConfig()
        milestones.append(robot.getConfig())
    traj = trajectory.RobotTrajectory(robot, times, milestones)
    vis.add("world", world)
    robotPath = ("world", world.robot(0).getName()
                 )  #compound item reference: refers to robot 0 in the world

    #we're also going to visualize the end effector trajectory
    #eetraj = traj.getLinkTrajectory(robot.numLinks()-1,0.05)
    #vis.add("end effector trajectory",eetraj)

    #uncomment this to automatically visualize the end effector trajectory
    vis.add("robot trajectory", traj)
    vis.setAttribute("robot trajectory", "endeffectors", [13, 20])

    vis.setWindowTitle("Animation test")
    MANUAL_ANIMATION = False
    if not MANUAL_ANIMATION:
        #automatic animation, just call vis.animate
        vis.animate(robotPath, traj)
    if not MULTITHREADED:
        #need to set up references to function-local variables manually, and the easiest way is to use a default argument
        def callback(robot=robot):
            if MANUAL_ANIMATION:
                #with manual animation, you just set the robot's configuration based on the current time.
                t = vis.animationTime()
                q = traj.eval(t, endBehavior='loop')
                robot.setConfig(q)
            pass

        vis.loop(callback=callback, setup=vis.show)
    else:
        vis.show()
        while vis.shown():
            vis.lock()
            if MANUAL_ANIMATION:
                #with manual animation, you just set the robot's configuration based on the current time.
                t = vis.animationTime()
                q = traj.eval(t, endBehavior='loop')
                robot.setConfig(q)
            vis.unlock()
            time.sleep(0.01)
    #quit the visualization thread nicely
    vis.kill()
コード例 #20
0
def main():
    #creates a world and loads all the items on the command line
    world = WorldModel()
    res = world.readFile("./HRP2_Robot.xml")
    if not res:
        raise RuntimeError("Unable to load model")
    robot = world.robot(0)
    # coordinates.setWorldModel(world)
    plugin = MyGLPlugin(world)
    vis.pushPlugin(plugin)
    #add the world to the visualizer
    vis.add("world", world)
    vis.add("robot", world.robot(0))
    vis.show()
    # ipdb.set_trace()

    Robotstate_Traj, Contact_Force_Traj = Traj_Loader()
    h = 0.0068  # 0.0043: vert
    # 0.0033: flat
    playspeed = 2.5
    norm = 500
    while vis.shown():
        # This is the main plot program
        for i in range(0, Robotstate_Traj.shape[1]):
            vis.lock()
            Robotstate_Traj_i = Robotstate_Traj[:, i]
            Robotstate_Traj_Full_i = Dimension_Recovery(Robotstate_Traj_i)
            # Now it is the plot of the contact force at the contact extremities
            robot.setConfig(Robotstate_Traj_Full_i)
            Contact_Force_Traj_i = Contact_Force_Traj[:, i]
            left_ft, rght_ft, left_hd, rght_hd, left_ft_end, rght_ft_end, left_hd_end, rght_hd_end = Contact_Force_vec(
                robot, Contact_Force_Traj_i, norm)
            vis.add("left foot force",
                    Trajectory([0, 1], [left_ft, left_ft_end]))
            vis.add("right foot force",
                    Trajectory([0, 1], [rght_ft, rght_ft_end]))
            vis.add("left hand force",
                    Trajectory([0, 1], [left_hd, left_hd_end]))
            vis.add("right hand force",
                    Trajectory([0, 1], [rght_hd, rght_hd_end]))
            COMPos_start = robot.getCom()
            COMPos_end = COMPos_start
            COMPos_end[2] = COMPos_end[2] + 100
            vis.add("Center of Mass",
                    Trajectory([0, 1], [COMPos_start, COMPos_end]))

            # ipdb.set_trace()

            vis.unlock()
            time.sleep(h * playspeed)
コード例 #21
0
    def visualiser_init(self, no_display=False):
        """Delayed *initialisation* method for environment visualiser.

        :param no_display: Controls whether turn on the
            visualisation or not, defaults to False. This option is deprecated,
            and instead, the environment should derived directly from the base
            visualisation to turn off visualisation.

        """
        if not no_display:
            from klampt import vis

            vis.add("world", self.args.cc.world)
            vis.show()
コード例 #22
0
def basic_template(world):
    """Shows how to pop up a visualization window with a world"""
    #add the world to the visualizer
    vis.add("world", world)

    #adding a point
    vis.add("point", [1, 1, 1])
    vis.setColor("point", 0, 1, 0)
    vis.setAttribute("point", "size", 5.0)

    #adding lines is currently not super convenient because a list of lists is treated as
    #a Configs object... this is a workaround to force the vis module to treat it as a polyline.
    vis.add("line", trajectory.Trajectory([0, 1], [[0, 0, 0], [1, 1, 1]]))
    vis.setAttribute("line", "width", 1.0)

    sphere = klampt.GeometricPrimitive()
    sphere.setSphere([1.5, 1, 1], 0.2)
    vis.add("sphere", sphere)
    vis.setColor("sphere", 0, 0, 1, 0.5)

    box = klampt.GeometricPrimitive()
    box.setAABB([-1, -1, 0], [-0.9, -0.9, 0.2])
    g = klampt.Geometry3D(box)
    vis.add("box", g)
    vis.setColor("box", 0, 0, 1, 0.5)

    vis.setWindowTitle("Basic visualization test")
    if not MULTITHREADED:
        print("Running vis loop in single-threaded mode with vis.loop()")

        #single-threaded code
        def callback():
            #TODO: you may modify the world here.
            pass

        vis.loop(setup=vis.show, callback=callback)
    else:
        print("Running vis loop in multithreaded mode")
        #multithreaded code
        vis.show()
        while vis.shown():
            vis.lock()
            #TODO: you may modify the world here.  Do not modify the internal state of any
            #visualization items outside of the lock
            vis.unlock()
            #outside of the lock you can use any vis.X functions, including vis.setItemConfig()
            #to modify the state of objects
            time.sleep(0.01)
    #quit the visualization thread nicely
    vis.kill()
コード例 #23
0
ファイル: main.py プロジェクト: tcrapse/adaptive_simulation
def update_simulation(world, sim):
    # this code manually updates the visualization
    vis.add("world", world)
    vis.show()
    t0 = time.time()
    while vis.shown():
        vis.lock()
        sim.simulate(0.01)
        sim.updateWorld()
        vis.unlock()
        t1 = time.time()
        time.sleep(max(0.01 - (t1 - t0), 0.001))
        t0 = t1
    return
コード例 #24
0
 def run(self):
     """Standardized interface for running program"""
     vp = vis.getViewport()
     #Square screen
     #vp.w,vp.h = 800,800
     #For saving HD quality movies
     vp.w, vp.h = 1024, 768
     vp.clippingplanes = self.clippingplanes
     vis.setViewport(vp)
     #vis.run(program)
     vis.setPlugin(self)
     vis.show()
     while vis.shown():
         time.sleep(0.1)
     vis.setPlugin(None)
     vis.kill()
コード例 #25
0
def vis_interaction_test(world):
    """Run some tests of visualization module interacting with the resource module"""
    print("Showing robot in modal dialog box")
    vis.add("robot", world.robot(0))
    vis.add("ee", world.robot(0).link(11).getTransform())
    vis.dialog()

    config = resource.get("resourcetest1.config",
                          description="Should show up without a hitch...",
                          doedit=True,
                          editor='visual',
                          world=world)

    import time
    if MULTITHREADED:
        print(
            "Showing threaded visualization (this will fail on GLUT or Mac OS)"
        )
        vis.show()
        for i in range(3):
            vis.lock()
            q = world.robot(0).getConfig()
            q[9] = 3.0
            world.robot(0).setConfig(q)
            vis.unlock()
            time.sleep(1.0)
            if not vis.shown():
                break
            vis.lock()
            q = world.robot(0).getConfig()
            q[9] = -1.0
            world.robot(0).setConfig(q)
            vis.unlock()
            time.sleep(1.0)
            if not vis.shown():
                break
        print("Hiding visualization window")
        vis.show(False)
    else:
        print("Showing single-threaded visualization for 5s")
        vis.spin(5.0)

    config = resource.get("resourcetest1.config",
                          description="Should show up without a hitch...",
                          doedit=True,
                          editor='visual',
                          world=world)
コード例 #26
0
    def visualize(self):
        world = robotsim.WorldModel()
        vis.add("world", world)
        vis.add("coordinates", coordinates.manager())
        vis.setWindowTitle("PointCloud World")
        vp = vis.getViewport()
        vp.w, vp.h = 800, 800
        vis.setViewport(vp)
        # vis.autoFitCamera()
        vis.show()

        vis.lock()
        vis.unlock()

        while vis.shown():
            time.sleep(0.01)
        vis.kill()
コード例 #27
0
ファイル: problem1.py プロジェクト: pranavburugula/CS498IR
        def loop_through_sensors(world=world,sensor=sensor,
            world_camera_viewpoints=world_camera_viewpoints,
            index=index,counters=counters):
            viewno = counters[0]
            variation = counters[1]
            total_count = counters[2]
            print("Generating data for sensor view",viewno,"variation",variation)
            sensor_xform = world_camera_viewpoints[viewno]
            sensing.set_sensor_xform(sensor,sensor_xform)
            rgb_filename = "image_dataset/color_%04d_var%04d.png"%(total_count,variation)
            depth_filename = "image_dataset/depth_%04d_var%04d.png"%(total_count,variation)
            grasp_filename = "image_dataset/grasp_%04d.png"%(total_count,)
            if PROBLEM=='1b':
                sensor.kinematicReset()
                sensor.kinematicSimulate(world,0.01)
                print("Done with kinematic simulate")

                rgb,depth = sensing.camera_to_images(sensor)
                print("Saving to",rgb_filename,depth_filename)
                Image.fromarray(rgb).save(rgb_filename)
                depth_scale = 8000
                depth_quantized = (depth * depth_scale).astype(np.uint32)
                Image.fromarray(depth_quantized).save(depth_filename)
                
                with open("image_dataset/metadata.csv",'a') as f:
                    line = "{},{},{},{},{},{},{}\n".format(index,viewno,loader.write(sensor_xform,'RigidTransform'),os.path.basename(rgb_filename),os.path.basename(depth_filename),os.path.basename(grasp_filename),variation)
                    f.write(line)
            
            if PROBLEM=='1c' and variation==0:
                #calculate grasp map and save it
                grasp_map = make_grasp_map(world)
                grasp_map_quantized = (grasp_map*255).astype(np.uint8)
                channels = ['score','opening','axis_heading','axis_elevation']
                for i,c in enumerate(channels):
                    base,ext=os.path.splitext(grasp_filename)
                    fn = base+'_'+c+ext
                    Image.fromarray(grasp_map_quantized[:,:,i]).save(fn)
        
            #loop through variations and views
            counters[1] += 1
            if counters[1] >= max_variations:  
                counters[1] = 0
                counters[0] += 1
                if counters[0] >= len(world_camera_viewpoints):
                    vis.show(False)
                counters[2] += 1
コード例 #28
0
def robot_move(mode,world,robot,link,point_ee,point_world,maxDev,IKErrorTolerence,
				EEZLimit,collider,robotControlApi=None,ServoTime=9999.0,dt=1.0,
				use_const = True,vis=vis,use_collision_detect = False,use_ik_detect = False):

	robotCurrentConfig=klampt_2_controller(robot.getConfig())
	goal=ik.objective(link,local=point_ee,world=point_world)
	res=ik.solve_nearby(goal,maxDeviation=maxDev,tol=0.00001)
	#res=ik.solve_global(goal,tol=0.00001)

	if res:
		# collision detect
		if check_collision_linear(robot,collider,controller_2_klampt(robot,robotCurrentConfig),robot.getConfig(),10):
			print "[!]Warning: collision detected!"
			if use_collision_detect == True:
				vis.show()
				if input('continue?') != 1:
					exit()
		else:
			pass

		# cal difference
		
		diff=np.max(np.absolute((np.array(vectorops.sub(robotCurrentConfig[0:5],klampt_2_controller(robot.getConfig())[0:5])))))
		EEZPos=link.getTransform()[1]
		if diff<IKErrorTolerence and EEZPos>EEZLimit:  #126 degrees
			if mode == 'debugging':
				pass
			elif mode == 'physical':
				if use_const:
					constantVServo(robotControlApi,ServoTime,klampt_2_controller(robot.getConfig()),dt)
				else:
					robotControlApi.setConfig(klampt_2_controller(robot.getConfig()))
		else:
			print "[!]IK too far away"
			if use_ik_detect == True:
				if input('continue?') != 1:
					exit()
	else:
		diff = 9999.0
		print "[!]IK failture"
		if use_ik_detect == True:
			vis.show()
			if input('continue?') != 1:
				exit()

	return robot, diff
コード例 #29
0
ファイル: PRM.py プロジェクト: dtbinh/PRM_multipleRobots
    def visRoadMap(self):

        vis.show()

        edgeList = self.G.edges()
        cnt = 0
        for e in edgeList:
            n1 = e[0]
            n2 = e[1]
            tr = trajectory.Trajectory()
            tr.milestones.append([n1.x, n1.y, n1.z])
            tr.milestones.append([n2.x, n2.y, n2.z])

            fName = "a" + str(cnt)
            vis.add(fName, tr)
            vis.hideLabel(fName)
            vis.setAttribute(fName, "width", 0.5)
            vis.setColor(fName, 0.4940, 0.1840, 0.5560)
            cnt = cnt + 1
        self.rmCnt = cnt
コード例 #30
0
ファイル: vis_template.py プロジェクト: Hu-i/Klampt-examples
def coordinates_template(world):
    """Tests integration with the coordinates module."""
    #add the world to the visualizer
    vis.add("world", world)
    coordinates.setWorldModel(world)
    #add the coordinate Manager to the visualizer
    vis.add("coordinates", coordinates.manager())

    vis.setWindowTitle("Coordinates visualiation test")
    if MANUAL_EDITING:
        #manually adds a poser, and adds a callback whenever the widget changes
        widgets = GLWidgetPlugin()
        widgets.addWidget(RobotPoser(world.robot(0)))
        #update the coordinates every time the widget changes
        widgets.widgetchangefunc = (lambda self: coordinates.updateFromWorld())
        vis.pushPlugin(widgets)
        if not MULTITHREADED:
            vis.loop(callback=None, setup=vis.show)
        else:
            vis.show()
            while vis.shown():
                time.sleep(0.01)
    else:
        vis.edit(("world", world.robot(0).getName()))
        if not MULTITHREADED:

            def callback(coordinates=coordinates):
                coordinates.updateFromWorld()

            vis.loop(callback=callback, setup=vis.show)
        else:
            vis.show()
            while vis.shown():
                vis.lock()
                #reads the coordinates from the world
                coordinates.updateFromWorld()
                vis.unlock()
                time.sleep(0.01)

    #quit the visualization thread nicely
    vis.kill()
コード例 #31
0
ファイル: pile.py プロジェクト: krishauser/Klampt
def make_object_pile(world,container,objects,container_wall_thickness=0.01,randomize_orientation=True,
    visualize=False,verbose=0):
    """For a given container and a list of objects in the world, drops the objects inside the container and simulates until stable.

    Args:
        world (WorldModel): the world containing the objects and obstacles
        container: the container RigidObject / Terrain in world into which
            objects should be spawned.  Assumed axis-aligned.
        objects (list of RigidObject): a list of RigidObjects in the world,
            at arbitrary locations.  They are placed in order.
        container_wall_thickness (float, optional): a margin subtracted from
            the container's outer dimensions into which the objects are spawned.
        randomize_orientation (bool or str, optional): if True, the orientation
            of the objects are completely randomized.  If 'z', only the z
            orientation is randomized.  If False or None, the orientation is
            unchanged
        visualize (bool, optional): if True, pops up a visualization window to
            show the progress of the pile
        verbose (int, optional): if > 0, prints progress of the pile.
    
    Side effect: the positions of objects in world are modified

    Returns:
        (tuple): (world,sim), containing

            - world (WorldModel): the original world
            - sim (Simulator): the Simulator instance at the state used to obtain
              the stable placement of the objects.

    Note:
        Since world is modified in-place, if you wish to make multiple worlds with
        piles of the same objects, you should use world.copy() to store the
        configuration of the objects. You may also wish to randomize the object
        ordering using random.shuffle(objects) between instances.
    """
    container_outer_bb = _get_bound(container)
    container_inner_bb = (vectorops.add(container_outer_bb[0],[container_wall_thickness]*3),vectorops.sub(container_outer_bb[1],[container_wall_thickness]*3))
    spawn_area = (container_inner_bb[0][:],container_inner_bb[1][:])
    collision_margin = 0.0025
    if visualize:
        from klampt import vis
        from klampt.model import config
        import time
        oldwindow = vis.getWindow()
        newwindow = vis.createWindow("make_object_pile dynamic visualization")
        vis.setWindow(newwindow)
        vis.show()
        visworld = world.copy()
        vis.add("world",visworld)

    sim = Simulator(world)
    sim.setSetting("maxContacts","20")
    sim.setSetting("adaptiveTimeStepping","0")
    Tfar = (so3.identity(),[0,0,-100000])
    for object in objects:
        R,t = object.getTransform()
        object.setTransform(R,Tfar[1])
        sim.body(object).setTransform(*Tfar)
        sim.body(object).enable(False)
    if verbose: 
        print("Spawn area",spawn_area)
    if visualize:
        vis.lock()
        config.setConfig(visworld,config.getConfig(world))
        vis.unlock()
    for index in range(len(objects)):
        #always spawn above the current height of the pile 
        if index > 0:
            objects_bound = _get_bound(objects[:index])
            if verbose: 
                print("Existing objects bound:",objects_bound)
            zshift = max(0.0,objects_bound[1][2] - spawn_area[0][2])
            spawn_area[0][2] += zshift
            spawn_area[1][2] += zshift
        object = objects[index]
        obb = _get_bound(object)
        zmin = obb[0][2]
        R0,t0 = object.getTransform()
        feasible = False
        for sample in range(1000):
            R,t = R0[:],t0[:]
            if randomize_orientation == True:
                R = so3.sample()
            t[2] = spawn_area[1][2] - zmin + t0[2] + collision_margin
            object.setTransform(R,t)
            xy_randomize(object,spawn_area[0],spawn_area[1])
            if verbose: 
                print("Sampled position of",object.getName(),object.getTransform()[1])
            if not randomize_orientation:
                _,t = object.getTransform()
                object.setTransform(R,t)

            #object spawned, now settle
            sobject = sim.body(object)
            sobject.enable(True)
            sobject.setTransform(*object.getTransform())
            res = sim.checkObjectOverlap()
            if len(res[0]) == 0:
                feasible = True
                #get it low as possible without overlapping
                R,t = object.getTransform()
                for lower in range(100):
                    sobject.setTransform(R,vectorops.add(t,[0,0,-(lower+1)*0.01]))
                    res = sim.checkObjectOverlap()
                    if len(res[0]) != 0:
                        if verbose: 
                            print("Terminated lowering at",lower,"cm lower")
                        sobject.setTransform(R,vectorops.add(t,[0,0,-lower*0.01]))
                        res = sim.checkObjectOverlap()
                        break
                sim.updateWorld()
                break
        if not feasible:
            if verbose: 
                print("Failed to place object",object.getName())
            return None
        if visualize:
            vis.lock()
            config.setConfig(visworld,config.getConfig(world))
            vis.unlock()
            time.sleep(0.1)
    
    if verbose: 
        print("Beginning to simulate")
    #start letting everything  fall
    for firstfall in range(10):
        sim.simulate(0.01)
        if visualize:
            vis.lock()
            config.setConfig(visworld,config.getConfig(world))
            vis.unlock()
            time.sleep(0.01)
    maxT = 5.0
    dt = 0.01
    t = 0.0
    wdamping = -0.01
    vdamping = -0.1
    while t < maxT:
        settled = True
        for object in objects:
            sobject = sim.body(object)
            w,v = sobject.getVelocity()
            sobject.applyWrench(vectorops.mul(v,vdamping),vectorops.mul(w,wdamping))
            if vectorops.norm(w) + vectorops.norm(v) > 1e-4:
                #settled
                settled=False
                break
        if settled:
            break
        if visualize:
            t0 = time.time()
        sim.simulate(dt)
        if visualize:
            vis.lock()
            config.setConfig(visworld,config.getConfig(world))
            vis.unlock()
            time.sleep(max(0.0,dt-(time.time()-t0)))
        t += dt
    if visualize:
        vis.show(False)
        vis.setWindow(oldwindow)
    return (world,sim)
コード例 #32
0
def launch_simple(robotname,object_set,objectname,use_box=False):
	"""Launches a very simple program that simulates a robot grasping an object from one of the
	databases. It first allows a user to position the robot's free-floating base in a GUI. 
	Then, it sets up a simulation with those initial conditions, and launches a visualization.
	The controller closes the hand, and then lifts the hand upward.  The output of the robot's
	tactile sensors are printed to the console.

	If use_box is True, then the test object is placed inside a box.
	"""
	world = WorldModel()
	world.loadElement("data/terrains/plane.env")
	robot = make_moving_base_robot(robotname,world)
	object = make_object(object_set,objectname,world)
	if use_box:
		box = make_box(world,*box_dims)
		object.setTransform(*se3.mul((so3.identity(),[0,0,0.01]),object.getTransform()))
	doedit = True
	xform = resource.get("%s/default_initial_%s.xform"%(object_set,robotname),description="Initial hand transform",default=robot.link(5).getTransform(),world=world)
	set_moving_base_xform(robot,xform[0],xform[1])
	xform = resource.get("%s/initial_%s_%s.xform"%(object_set,robotname,objectname),description="Initial hand transform",default=robot.link(5).getTransform(),world=world,doedit=False)
	if xform:
		set_moving_base_xform(robot,xform[0],xform[1])
	xform = resource.get("%s/initial_%s_%s.xform"%(object_set,robotname,objectname),description="Initial hand transform",default=robot.link(5).getTransform(),world=world,doedit=doedit)
	if not xform:
		print "User quit the program"
		return
	#this sets the initial condition for the simulation
	set_moving_base_xform(robot,xform[0],xform[1])

	#now the simulation is launched
	program = GLSimulationProgram(world)
	sim = program.sim

	#setup some simulation parameters
	visPreshrink = True   #turn this to true if you want to see the "shrunken" models used for collision detection
	for l in range(robot.numLinks()):
		sim.body(robot.link(l)).setCollisionPreshrink(visPreshrink)
	for l in range(world.numRigidObjects()):
		sim.body(world.rigidObject(l)).setCollisionPreshrink(visPreshrink)

	#create a hand emulator from the given robot name
	module = importlib.import_module('plugins.'+robotname)
	#emulator takes the robot index (0), start link index (6), and start driver index (6)
	hand = module.HandEmulator(sim,0,6,6)
	sim.addEmulator(0,hand)

	#the result of simple_controller.make() is now attached to control the robot
	import simple_controller
	sim.setController(robot,simple_controller.make(sim,hand,program.dt))

	#the next line latches the current configuration in the PID controller...
	sim.controller(0).setPIDCommand(robot.getConfig(),robot.getVelocity())
	
	#this code uses the GLSimulationProgram structure, which gives a little more control over the visualization
	"""
	program.simulate = True
	vis.setPlugin(program)
	vis.show()
	while vis.shown():
		time.sleep(0.1)
	return
	"""
	
	#this code manually updates the visualization
	vis.add("world",world)
	vis.show()
	t0 = time.time()
	while vis.shown():
		vis.lock()
		sim.simulate(0.01)
		sim.updateWorld()
		vis.unlock()
		t1 = time.time()
		time.sleep(max(0.01-(t1-t0),0.001))
		t0 = t1
	return
コード例 #33
0
def launch_balls(robotname,num_balls=10):
	"""Launches a very simple program that simulates a robot grasping an object from one of the
	databases. It first allows a user to position the robot's free-floating base in a GUI. 
	Then, it sets up a simulation with those initial conditions, and launches a visualization.
	The controller closes the hand, and then lifts the hand upward.  The output of the robot's
	tactile sensors are printed to the console.
	"""
	world = WorldModel()
	world.loadElement("data/terrains/plane.env")
	maxlayer = 16
	numlayers = int(math.ceil(float(num_balls)/float(maxlayer)))
	for layer in xrange(numlayers):
		if layer + 1 == numlayers:
			ballsperlayer = num_balls%maxlayer
		else:
			ballsperlayer = maxlayer
		w = int(math.ceil(math.sqrt(ballsperlayer)))
		h = int(math.ceil(float(ballsperlayer)/float(w)))
		for i in xrange(ballsperlayer):
			bid = world.loadElement("data/objects/sphere_10cm.obj")
			if bid < 0:
				raise RuntimeError("data/objects/sphere_10cm.obj couldn't be loaded")
			ball = world.rigidObject(world.numRigidObjects()-1)
			R = so3.identity()
			x = i % w
			y = i / w
			x = (x - (w-1)*0.5)*box_dims[0]*0.7/(w-1)
			y = (y - (h-1)*0.5)*box_dims[1]*0.7/(h-1)
			t = [x,y,0.08 + layer*0.11]
			t[0] += random.uniform(-0.005,0.005)
			t[1] += random.uniform(-0.005,0.005)
			ball.setTransform(R,t)
	robot = make_moving_base_robot(robotname,world)
	box = make_box(world,*box_dims)
	box2 = make_box(world,*box_dims)
	box2.geometry().translate((0.7,0,0))
	xform = resource.get("balls/default_initial_%s.xform"%(robotname,),description="Initial hand transform",default=robot.link(5).getTransform(),world=world,doedit=True)
	if not xform:
		print "User quit the program"
		return
	#this sets the initial condition for the simulation
	set_moving_base_xform(robot,xform[0],xform[1])

	#now the simulation is launched
	program = GLSimulationProgram(world)  
	sim = program.sim

	#setup some simulation parameters
	visPreshrink = True   #turn this to true if you want to see the "shrunken" models used for collision detection
	for l in range(robot.numLinks()):
		sim.body(robot.link(l)).setCollisionPreshrink(visPreshrink)
	for l in range(world.numRigidObjects()):
		sim.body(world.rigidObject(l)).setCollisionPreshrink(visPreshrink)

	#create a hand emulator from the given robot name
	module = importlib.import_module('plugins.'+robotname)
	#emulator takes the robot index (0), start link index (6), and start driver index (6)
	hand = module.HandEmulator(sim,0,6,6)
	sim.addEmulator(0,hand)

	#A StateMachineController instance is now attached to control the robot
	import balls_controller
	sim.setController(robot,balls_controller.make(sim,hand,program.dt))

	#the next line latches the current configuration in the PID controller...
	sim.controller(0).setPIDCommand(robot.getConfig(),robot.getVelocity())

	"""
	#this code uses the GLSimulationProgram structure, which gives a little more control over the visualization
	vis.setPlugin(program)
	vis.show()
	while vis.shown():
		time.sleep(0.1)
	return
	"""

	#this code manually updates the visualization
	vis.add("world",world)
	vis.show()
	t0 = time.time()
	while vis.shown():
		vis.lock()
		sim.simulate(0.01)
		sim.updateWorld()
		vis.unlock()
		t1 = time.time()
		time.sleep(max(0.01-(t1-t0),0.001))
		t0 = t1
	return
コード例 #34
0
def launch_shelf(robotname,objects):
	"""Launches the task 2 program that asks the robot to retrieve some set of objects
	packed within a shelf.
	"""
	world = WorldModel()
	world.loadElement("data/terrains/plane.env")
	robot = make_moving_base_robot(robotname,world)
	box = make_box(world,*box_dims)
	shelf = make_shelf(world,*shelf_dims)
	shelf.geometry().translate((0,shelf_offset,shelf_height))
	rigid_objects = []
	for objectset,objectname in objects:
		object = make_object(objectset,objectname,world)
		#TODO: pack in the shelf using x-y translations and z rotations
		object.setTransform(*se3.mul((so3.identity(),[0,shelf_offset,shelf_height + 0.01]),object.getTransform()))
		rigid_objects.append(object)
	xy_jiggle(world,rigid_objects,[shelf],[-0.5*shelf_dims[0],-0.5*shelf_dims[1]+shelf_offset],[0.5*shelf_dims[0],0.5*shelf_dims[1]+shelf_offset],100)

	doedit = True
	xform = resource.get("shelf/default_initial_%s.xform"%(robotname,),description="Initial hand transform",default=robot.link(5).getTransform(),world=world)
	if not xform:
		print "User quit the program"
		return
	set_moving_base_xform(robot,xform[0],xform[1])

	#now the simulation is launched
	program = GLSimulationProgram(world)
	sim = program.sim

	#setup some simulation parameters
	visPreshrink = True   #turn this to true if you want to see the "shrunken" models used for collision detection
	for l in range(robot.numLinks()):
		sim.body(robot.link(l)).setCollisionPreshrink(visPreshrink)
	for l in range(world.numRigidObjects()):
		sim.body(world.rigidObject(l)).setCollisionPreshrink(visPreshrink)

	#create a hand emulator from the given robot name
	module = importlib.import_module('plugins.'+robotname)
	#emulator takes the robot index (0), start link index (6), and start driver index (6)
	hand = module.HandEmulator(sim,0,6,6)
	sim.addEmulator(0,hand)

	#controlfunc is now attached to control the robot
	import shelf_controller
	sim.setController(robot,shelf_controller.make(sim,hand,program.dt))

	#the next line latches the current configuration in the PID controller...
	sim.controller(0).setPIDCommand(robot.getConfig(),robot.getVelocity())
	
	#this code uses the GLSimulationProgram structure, which gives a little more control over the visualization
	vis.setPlugin(program)
	program.reshape(800,600)
	vis.show()
	while vis.shown():
		time.sleep(0.1)
	return
	
	#this code manually updates the vis
	vis.add("world",world)
	vis.show()
	t0 = time.time()
	while vis.shown():
		vis.lock()
		sim.simulate(0.01)
		sim.updateWorld()
		vis.unlock()
		t1 = time.time()
		time.sleep(max(0.01-(t1-t0),0.001))
		t0 = t1
	return