コード例 #1
0
    def update_state(self):
        # TODO: apply this directly from observations
        # No use applying this to base confs
        self.base_conf = FConf(self.world.robot,
                               self.world.base_joints,
                               init=True)
        arm_conf = FConf(self.world.robot, self.world.arm_joints, init=True)
        if (self.arm_conf is None) or not are_confs_close(
                arm_conf, self.arm_conf, tol=ARM_TOLERANCE):
            self.arm_conf = arm_conf
        else:
            print('At anticipated arm conf')
        gripper_conf = FConf(self.world.robot,
                             self.world.gripper_joints,
                             init=True)
        if (self.gripper_conf is None) or not are_confs_close(
                gripper_conf, self.gripper_conf, tol=GRIPPER_TOLERANCE):
            self.gripper_conf = gripper_conf
        else:
            print('At anticipated gripper conf')

        # TODO: do I still need to test if the current values are equal to the last ones?
        for joint in self.world.kitchen_joints:
            name = get_joint_name(self.world.kitchen, joint)
            position = get_joint_position(self.world.kitchen, joint)
            self.update_door_conf(name, position)
            self.update_door_conf(name, position)
        #wait_for_user()
        return self.check_consistent()
コード例 #2
0
def get_limits(robot, joint, limits):
    if limits is False:
        return get_joint_limits(robot, joint)
    elif limits is None:
        torso_value = get_joint_position(robot, joint)
        return torso_value, torso_value
    return limits
コード例 #3
0
def test_kinematic(robot, door, target_x):
    wait_if_gui('Begin?')
    robot_joints = get_movable_joints(robot)[:3]
    joint = robot_joints[0]
    start_x = get_joint_position(robot, joint)
    num_steps = int(math.ceil(abs(target_x - start_x) / 1e-2))
    for x in interpolate(start_x, target_x, num_steps=num_steps):
        set_joint_position(robot, joint=joint, value=x)
        #with LockRenderer():
        solve_collision_free(door, robot, draw=False)
        wait_for_duration(duration=1e-2)
        #wait_if_gui()
    wait_if_gui('Finish?')
コード例 #4
0
    def fn(body, pose, grasp):
        obstacles = [body] + fixed
        gripper_pose = end_effector_from_body(pose.pose, grasp.grasp_pose)
        approach_pose = approach_from_grasp(grasp.approach_pose, gripper_pose)

        draw_pose(get_tool_pose(robot, ARM), length=0.04)
        draw_pose(approach_pose, length=0.04)
        draw_pose(gripper_pose, length=0.04)
        # print(movable_joints)
        # print(torso_arm)
        # wait_for_interrupt()

        # TODO: gantry_x_joint
        # TODO: proper inverse reachability
        base_link = link_from_name(robot, IK_BASE_FRAMES[ARM])
        base_pose = get_link_pose(robot, base_link)
        body_point_in_base = point_from_pose(multiply(invert(base_pose), pose.pose))
        y_joint = joint_from_name(robot, '{}_gantry_y_joint'.format(prefix_from_arm(ARM)))
        initial_y = get_joint_position(robot, y_joint)
        ik_y = initial_y + SIGN_FROM_ARM[ARM]*body_point_in_base[1]
        set_joint_position(robot, y_joint, ik_y)

        for _ in range(num_attempts):
            if USE_IKFAST:
                q_approach = sample_tool_ik(robot, ARM, approach_pose)
                if q_approach is not None:
                    set_joint_positions(robot, torso_arm, q_approach)
            else:
                set_joint_positions(robot, torso_arm, sample_fn()) # Random seed
                q_approach = inverse_kinematics(robot, grasp.link, approach_pose)
            if (q_approach is None) or any(pairwise_collision(robot, b) for b in obstacles):
                print('- ik for approaching fails!')
                continue
            conf = BodyConf(robot, joints=arm_joints)

            if USE_IKFAST:
                q_grasp = sample_tool_ik(robot, ARM, gripper_pose, closest_only=True)
                if q_grasp is not None:
                    set_joint_positions(robot, torso_arm, q_grasp)
            else:
                conf.assign()
                q_grasp = inverse_kinematics(robot, grasp.link, gripper_pose)
            if (q_grasp is None) or any(pairwise_collision(robot, b) for b in obstacles):
                print('- ik for grasp fails!')
                continue

            if teleport:
                path = [q_approach, q_grasp]
            else:
                conf.assign()
                #direction, _ = grasp.approach_pose
                #path = workspace_trajectory(robot, grasp.link, point_from_pose(approach_pose), -direction,
                #                                   quat_from_pose(approach_pose))
                path = plan_direct_joint_motion(robot, torso_arm, q_grasp, obstacles=obstacles,
                                                self_collisions=self_collisions)
                if path is None:
                    if DEBUG_FAILURE:
                        print('Approach motion failed')
                    continue
            command = Command([BodyPath(robot, path, joints=torso_arm),
                               Attach(body, robot, grasp.link),
                               BodyPath(robot, path[::-1], joints=torso_arm, attachments=[grasp])])
            return (conf, command)
            # TODO: holding collisions
        return None
コード例 #5
0
ファイル: test.py プロジェクト: ivanjut/push-pybullet
def main():
    # TODO: teleporting kuka arm
    parser = argparse.ArgumentParser()  # Automatically includes help
    parser.add_argument('-viewer', action='store_true', help='enable viewer.')
    args = parser.parse_args()

    client = connect(use_gui=args.viewer)
    add_data_path()

    #planeId = p.loadURDF("plane.urdf")
    table = p.loadURDF("table/table.urdf", 0, 0, 0, 0, 0, 0.707107, 0.707107)
    box = create_box(.07, .05, .15)

    # boxId = p.loadURDF("r2d2.urdf",cubeStartPos, cubeStartOrientation)
    #pr2 = p.loadURDF("pr2_description/pr2.urdf")
    pr2 = p.loadURDF("pr2_description/pr2_fixed_torso.urdf")
    #pr2 = p.loadURDF("/Users/caelan/Programs/Installation/pr2_drake/pr2_local2.urdf",)
    #useFixedBase=0,)
    #flags=p.URDF_USE_SELF_COLLISION)
    #flags=p.URDF_USE_SELF_COLLISION_EXCLUDE_PARENT)
    #flags=p.URDF_USE_SELF_COLLISION_EXCLUDE_ALL_PARENTS)
    #pr2 = p.loadURDF("pr2_drake/urdf/pr2_simplified.urdf", useFixedBase=False)
    initially_colliding = get_colliding_links(pr2)
    print len(initially_colliding)
    origin = (0, 0, 0)
    print p.getNumConstraints()

    # TODO: no way of controlling the base position by itself
    # TODO: PR2 seems to collide with itself frequently
    # real_time = False
    # p.setRealTimeSimulation(real_time)
    # left_joints = [joint_from_name(pr2, name) for name in LEFT_JOINT_NAMES]
    # control_joints(pr2, left_joints, TOP_HOLDING_LEFT_ARM)
    # while True:
    #     control_joints(pr2, left_joints, TOP_HOLDING_LEFT_ARM)
    #     if not real_time:
    #         p.stepSimulation()

    # A CollisionMap robot allows the user to specify self-collision regions indexed by the values of two joints.

    # GetRigidlyAttachedLinks

    print pr2
    # for i in range (10000):
    #    p.stepSimulation()
    #    time.sleep(1./240.)

    #print get_joint_names(pr2)
    print[get_joint_name(pr2, joint) for joint in get_movable_joints(pr2)]
    print get_joint_position(pr2, joint_from_name(pr2, TORSO_JOINT_NAME))
    #open_gripper(pr2, joint_from_name(pr2, LEFT_GRIPPER))
    #print get_joint_limits(pr2, joint_from_name(pr2, LEFT_GRIPPER))
    #print get_joint_position(pr2, joint_from_name(pr2, LEFT_GRIPPER))
    print self_collision(pr2)
    """
    print p.getNumConstraints()
    constraint = fixed_constraint(pr2, -1, box, -1) # table
    p.changeConstraint(constraint)
    print p.getNumConstraints()
    print p.getConstraintInfo(constraint)
    print p.getConstraintState(constraint)
    p.stepSimulation()
    raw_input('Continue?')

    set_point(pr2, (-2, 0, 0))
    p.stepSimulation()
    p.changeConstraint(constraint)
    print p.getConstraintInfo(constraint)
    print p.getConstraintState(constraint)
    raw_input('Continue?')
    print get_point(pr2)
    raw_input('Continue?')
    """

    # TODO: would be good if we could set the joint directly
    print set_joint_position(pr2, joint_from_name(pr2, TORSO_JOINT_NAME),
                             0.2)  # Updates automatically
    print get_joint_position(pr2, joint_from_name(pr2, TORSO_JOINT_NAME))
    #return

    left_joints = [joint_from_name(pr2, name) for name in LEFT_JOINT_NAMES]
    right_joints = [joint_from_name(pr2, name) for name in RIGHT_JOINT_NAMES]
    print set_joint_positions(
        pr2, left_joints,
        TOP_HOLDING_LEFT_ARM)  # TOP_HOLDING_LEFT_ARM | SIDE_HOLDING_LEFT_ARM
    print set_joint_positions(
        pr2, right_joints,
        REST_RIGHT_ARM)  # TOP_HOLDING_RIGHT_ARM | REST_RIGHT_ARM

    print get_body_name(pr2)
    print get_body_names()
    # print p.getBodyUniqueId(pr2)
    print get_joint_names(pr2)

    #for joint, value in zip(LEFT_ARM_JOINTS, REST_LEFT_ARM):
    #    set_joint_position(pr2, joint, value)
    # for name, value in zip(LEFT_JOINT_NAMES, REST_LEFT_ARM):
    #     joint = joint_from_name(pr2, name)
    #     #print name, joint, get_joint_position(pr2, joint), value
    #     print name, get_joint_limits(pr2, joint), get_joint_type(pr2, joint), get_link_name(pr2, joint)
    #     set_joint_position(pr2, joint, value)
    #     #print name, joint, get_joint_position(pr2, joint), value
    # for name, value in zip(RIGHT_JOINT_NAMES, REST_RIGHT_ARM):
    #     set_joint_position(pr2, joint_from_name(pr2, name), value)

    print p.getNumJoints(pr2)
    jointId = 0
    print p.getJointInfo(pr2, jointId)
    print p.getJointState(pr2, jointId)

    # for i in xrange(10):
    #     #lower, upper = BASE_LIMITS
    #     #q = np.random.rand(len(lower))*(np.array(upper) - np.array(lower)) + lower
    #     q = np.random.uniform(*BASE_LIMITS)
    #     theta = np.random.uniform(*REVOLUTE_LIMITS)
    #     quat = z_rotation(theta)
    #     print q, theta, quat, env_collision(pr2)
    #     #set_point(pr2, q)
    #     set_pose(pr2, q, quat)
    #     #p.getMouseEvents()
    #     #p.getKeyboardEvents()
    #     raw_input('Continue?') # Stalls because waiting for input
    #
    # # TODO: self collisions
    # for i in xrange(10):
    #     for name in LEFT_JOINT_NAMES:
    #         joint = joint_from_name(pr2, name)
    #         value = np.random.uniform(*get_joint_limits(pr2, joint))
    #         set_joint_position(pr2, joint, value)
    #     raw_input('Continue?')

    #start = (-2, -2, 0)
    #set_base_values(pr2, start)
    # #start = get_base_values(pr2)
    # goal = (2, 2, 0)
    # p.addUserDebugLine(start, goal, lineColorRGB=(1, 1, 0)) # addUserDebugText
    # print start, goal
    # raw_input('Plan?')
    # path = plan_base_motion(pr2, goal)
    # print path
    # if path is None:
    #     return
    # print len(path)
    # for bq in path:
    #     set_base_values(pr2, bq)
    #     raw_input('Continue?')

    # left_joints = [joint_from_name(pr2, name) for name in LEFT_JOINT_NAMES]
    # for joint in left_joints:
    #     print joint, get_joint_name(pr2, joint), get_joint_limits(pr2, joint), \
    #         is_circular(pr2, joint), get_joint_position(pr2, joint)
    #
    # #goal = np.zeros(len(left_joints))
    # goal = []
    # for name, value in zip(LEFT_JOINT_NAMES, REST_LEFT_ARM):
    #     joint = joint_from_name(pr2, name)
    #     goal.append(wrap_joint(pr2, joint, value))
    #
    # path = plan_joint_motion(pr2, left_joints, goal)
    # print path
    # for q in path:s
    #     set_joint_positions(pr2, left_joints, q)
    #     raw_input('Continue?')

    print p.JOINT_REVOLUTE, p.JOINT_PRISMATIC, p.JOINT_FIXED, p.JOINT_POINT2POINT, p.JOINT_GEAR  # 0 1 4 5 6

    movable_joints = get_movable_joints(pr2)
    print len(movable_joints)
    for joint in xrange(get_num_joints(pr2)):
        if is_movable(pr2, joint):
            print joint, get_joint_name(pr2, joint), get_joint_type(
                pr2, joint), get_joint_limits(pr2, joint)

    #joints = [joint_from_name(pr2, name) for name in LEFT_JOINT_NAMES]
    #set_joint_positions(pr2, joints, sample_joints(pr2, joints))
    #print get_joint_positions(pr2, joints) # Need to print before the display updates?

    # set_base_values(pr2, (1, -1, -np.pi/4))
    # movable_joints = get_movable_joints(pr2)
    # gripper_pose = get_link_pose(pr2, link_from_name(pr2, LEFT_ARM_LINK))
    # print gripper_pose
    # print get_joint_positions(pr2, movable_joints)
    # p.addUserDebugLine(origin, gripper_pose[0], lineColorRGB=(1, 0, 0))
    # p.stepSimulation()
    # raw_input('Pre2 IK')
    # set_joint_positions(pr2, left_joints, SIDE_HOLDING_LEFT_ARM) # TOP_HOLDING_LEFT_ARM | SIDE_HOLDING_LEFT_ARM
    # print get_joint_positions(pr2, movable_joints)
    # p.stepSimulation()
    # raw_input('Pre IK')
    # conf = inverse_kinematics(pr2, gripper_pose) # Doesn't automatically set configuraitons
    # print conf
    # print get_joint_positions(pr2, movable_joints)
    # set_joint_positions(pr2, movable_joints, conf)
    # print get_link_pose(pr2, link_from_name(pr2, LEFT_ARM_LINK))
    # #print get_joint_positions(pr2, movable_joints)
    # p.stepSimulation()
    # raw_input('Post IK')
    # return

    # print pose_from_tform(TOOL_TFORM)
    # gripper_pose = get_link_pose(pr2, link_from_name(pr2, LEFT_ARM_LINK))
    # #gripper_pose = multiply(gripper_pose, TOOL_POSE)
    # #gripper_pose = get_gripper_pose(pr2)
    # for i, grasp_pose in enumerate(get_top_grasps(box)):
    #     grasp_pose = multiply(TOOL_POSE, grasp_pose)
    #     box_pose = multiply(gripper_pose, grasp_pose)
    #     set_pose(box, *box_pose)
    #     print get_pose(box)
    #     raw_input('Grasp {}'.format(i))
    # return

    torso = joint_from_name(pr2, TORSO_JOINT_NAME)
    torso_point, torso_quat = get_link_pose(pr2, torso)

    #torso_constraint = p.createConstraint(pr2, torso, -1, -1,
    #                   p.JOINT_FIXED, jointAxis=[0] * 3,  # JOINT_FIXED
    #                   parentFramePosition=torso_point,
    #                   childFramePosition=torso_quat)

    create_inverse_reachability(pr2, box, table)
    ir_database = load_inverse_reachability()
    print len(ir_database)

    return

    link = link_from_name(pr2, LEFT_ARM_LINK)
    point, quat = get_link_pose(pr2, link)
    print point, quat
    p.addUserDebugLine(origin, point,
                       lineColorRGB=(1, 1, 0))  # addUserDebugText
    raw_input('Continue?')

    current_conf = get_joint_positions(pr2, movable_joints)

    #ik_conf = p.calculateInverseKinematics(pr2, link, point)
    #ik_conf = p.calculateInverseKinematics(pr2, link, point, quat)

    min_limits = [get_joint_limits(pr2, joint)[0] for joint in movable_joints]
    max_limits = [get_joint_limits(pr2, joint)[1] for joint in movable_joints]
    max_velocities = [
        get_max_velocity(pr2, joint) for joint in movable_joints
    ]  # Range of Jacobian
    print min_limits
    print max_limits
    print max_velocities
    ik_conf = p.calculateInverseKinematics(pr2,
                                           link,
                                           point,
                                           quat,
                                           lowerLimits=min_limits,
                                           upperLimits=max_limits,
                                           jointRanges=max_velocities,
                                           restPoses=current_conf)

    value_from_joint = dict(zip(movable_joints, ik_conf))
    print[value_from_joint[joint] for joint in joints]

    #print len(ik_conf), ik_conf
    set_joint_positions(pr2, movable_joints, ik_conf)
    #print len(movable_joints), get_joint_positions(pr2, movable_joints)
    print get_joint_positions(pr2, joints)

    raw_input('Finish?')

    p.disconnect()