コード例 #1
0
class URSimDoorOpening(robot_gazebo_env_goal.RobotGazeboEnv):
    def __init__(self):
        rospy.logdebug("Starting URSimDoorOpening Class object...")

        # Init GAZEBO Objects
        self.set_obj_state = rospy.ServiceProxy('/gazebo/set_model_state', SetModelState)
        self.get_world_state = rospy.ServiceProxy('/gazebo/get_world_properties', GetWorldProperties)

        # Subscribe joint state and target pose
        rospy.Subscriber("/ft_sensor_topic", WrenchStamped, self.wrench_stamped_callback)
        rospy.Subscriber("/joint_states", JointState, self.joints_state_callback)
        rospy.Subscriber("/gazebo/link_states", LinkStates, self.link_state_callback)

        # Gets training parameters from param server
        self.desired_pose = Pose()
        self.running_step = rospy.get_param("/running_step")
        self.max_height = rospy.get_param("/max_height")
        self.min_height = rospy.get_param("/min_height")
        self.observations = rospy.get_param("/observations")
        
        # Joint limitation
        shp_max = rospy.get_param("/joint_limits_array/shp_max")
        shp_min = rospy.get_param("/joint_limits_array/shp_min")
        shl_max = rospy.get_param("/joint_limits_array/shl_max")
        shl_min = rospy.get_param("/joint_limits_array/shl_min")
        elb_max = rospy.get_param("/joint_limits_array/elb_max")
        elb_min = rospy.get_param("/joint_limits_array/elb_min")
        wr1_max = rospy.get_param("/joint_limits_array/wr1_max")
        wr1_min = rospy.get_param("/joint_limits_array/wr1_min")
        wr2_max = rospy.get_param("/joint_limits_array/wr2_max")
        wr2_min = rospy.get_param("/joint_limits_array/wr2_min")
        wr3_max = rospy.get_param("/joint_limits_array/wr3_max")
        wr3_min = rospy.get_param("/joint_limits_array/wr3_min")
        self.joint_limits = {"shp_max": shp_max,
                             "shp_min": shp_min,
                             "shl_max": shl_max,
                             "shl_min": shl_min,
                             "elb_max": elb_max,
                             "elb_min": elb_min,
                             "wr1_max": wr1_max,
                             "wr1_min": wr1_min,
                             "wr2_max": wr2_max,
                             "wr2_min": wr2_min,
                             "wr3_max": wr3_max,
                             "wr3_min": wr3_min
                             }

        shp_init_value0 = rospy.get_param("/init_joint_pose0/shp")
        shl_init_value0 = rospy.get_param("/init_joint_pose0/shl")
        elb_init_value0 = rospy.get_param("/init_joint_pose0/elb")
        wr1_init_value0 = rospy.get_param("/init_joint_pose0/wr1")
        wr2_init_value0 = rospy.get_param("/init_joint_pose0/wr2")
        wr3_init_value0 = rospy.get_param("/init_joint_pose0/wr3")
        self.init_joint_pose0 = [shp_init_value0, shl_init_value0, elb_init_value0, wr1_init_value0, wr2_init_value0, wr3_init_value0]

        shp_init_value1 = rospy.get_param("/init_joint_pose1/shp")
        shl_init_value1 = rospy.get_param("/init_joint_pose1/shl")
        elb_init_value1 = rospy.get_param("/init_joint_pose1/elb")
        wr1_init_value1 = rospy.get_param("/init_joint_pose1/wr1")
        wr2_init_value1 = rospy.get_param("/init_joint_pose1/wr2")
        wr3_init_value1 = rospy.get_param("/init_joint_pose1/wr3")
        self.init_joint_pose1 = [shp_init_value1, shl_init_value1, elb_init_value1, wr1_init_value1, wr2_init_value1, wr3_init_value1]
#	print("[init_joint_pose1]: ", [shp_init_value1, shl_init_value1, elb_init_value1, wr1_init_value1, wr2_init_value1, wr3_init_value1])

        shp_init_value2 = rospy.get_param("/init_joint_pose2/shp")
        shl_init_value2 = rospy.get_param("/init_joint_pose2/shl")
        elb_init_value2 = rospy.get_param("/init_joint_pose2/elb")
        wr1_init_value2 = rospy.get_param("/init_joint_pose2/wr1")
        wr2_init_value2 = rospy.get_param("/init_joint_pose2/wr2")
        wr3_init_value2 = rospy.get_param("/init_joint_pose2/wr3")
        self.init_joint_pose2 = [shp_init_value2, shl_init_value2, elb_init_value2, wr1_init_value2, wr2_init_value2, wr3_init_value2]
#	print("[init_joint_pose2]: ", [shp_init_value2, shl_init_value2, elb_init_value2, wr1_init_value2, wr2_init_value2, wr3_init_value2])

        shp_after_rotate = rospy.get_param("/eelink_pose_after_rotate/shp")
        shl_after_rotate = rospy.get_param("/eelink_pose_after_rotate/shl")
        elb_after_rotate = rospy.get_param("/eelink_pose_after_rotate/elb")
        wr1_after_rotate = rospy.get_param("/eelink_pose_after_rotate/wr1")
        wr2_after_rotate = rospy.get_param("/eelink_pose_after_rotate/wr2")
        wr3_after_rotate = rospy.get_param("/eelink_pose_after_rotate/wr3")
        self.after_rotate = [shp_after_rotate, shl_after_rotate, elb_after_rotate, wr1_after_rotate, wr2_after_rotate, wr3_after_rotate]

        shp_after_pull = rospy.get_param("/eelink_pose_after_pull/shp")
        shl_after_pull = rospy.get_param("/eelink_pose_after_pull/shl")
        elb_after_pull = rospy.get_param("/eelink_pose_after_pull/elb")
        wr1_after_pull = rospy.get_param("/eelink_pose_after_pull/wr1")
        wr2_after_pull = rospy.get_param("/eelink_pose_after_pull/wr2")
        wr3_after_pull = rospy.get_param("/eelink_pose_after_pull/wr3")
        self.after_pull = [shp_after_pull, shl_after_pull, elb_after_pull, wr1_after_pull, wr2_after_pull, wr3_after_pull]

        r_drv_value1 = rospy.get_param("/init_grp_pose1/r_drive")
        l_drv_value1 = rospy.get_param("/init_grp_pose1/l_drive")
        r_flw_value1 = rospy.get_param("/init_grp_pose1/r_follower")
        l_flw_value1 = rospy.get_param("/init_grp_pose1/l_follower")
        r_spr_value1 = rospy.get_param("/init_grp_pose1/r_spring")
        l_spr_value1 = rospy.get_param("/init_grp_pose1/l_spring")

        r_drv_value2 = rospy.get_param("/init_grp_pose2/r_drive")
        l_drv_value2 = rospy.get_param("/init_grp_pose2/l_drive")
        r_flw_value2 = rospy.get_param("/init_grp_pose2/r_follower")
        l_flw_value2 = rospy.get_param("/init_grp_pose2/l_follower")
        r_spr_value2 = rospy.get_param("/init_grp_pose2/r_spring")
        l_spr_value2 = rospy.get_param("/init_grp_pose2/l_spring")

        self.init_grp_pose1 = [r_drv_value1, l_drv_value1, r_flw_value1, l_flw_value1, r_spr_value1, l_spr_value1]
        self.init_grp_pose2 = [r_drv_value2, l_drv_value2, r_flw_value2, l_flw_value2, r_spr_value2, l_spr_value2]

        # Fill in the Done Episode Criteria list
        self.episode_done_criteria = rospy.get_param("/episode_done_criteria")
        
        # stablishes connection with simulator
        self._gz_conn = GazeboConnection()
        self._ctrl_conn = ControllersConnection(namespace="")
        
        # Controller type for ros_control
        self._ctrl_type =  rospy.get_param("/control_type")
        self.pre_ctrl_type =  self._ctrl_type

	# Get the force and troque limit
        self.force_limit = rospy.get_param("/force_limit")
        self.torque_limit = rospy.get_param("/torque_limit")

        # We init the observations
        self.base_orientation = Quaternion()
        self.imu_link = Quaternion()
        self.door = Quaternion()
        self.quat = Quaternion()
        self.imu_link_rpy = Vector3()
        self.door_rpy = Vector3()
        self.link_state = LinkStates()
        self.wrench_stamped = WrenchStamped()
        self.joints_state = JointState()
        self.end_effector = Point() 
        self.previous_action =[]
        self.counter = 0
        self.max_rewards = 1

        # Arm/Control parameters
        self._ik_params = setups['UR5_6dof']['ik_params']
        
        # ROS msg type
        self._joint_pubisher = JointPub()
        self._joint_traj_pubisher = JointTrajPub()

        # Gym interface and action
        self.action_space = spaces.Discrete(6)
        self.observation_space = 21 #np.arange(self.get_observations().shape[0])
##        self.observation_space = 15 #np.arange(self.get_observations().shape[0])
        self.reward_range = (-np.inf, np.inf)
        self._seed()

        # Change the controller type 
        set_joint_pos_server = rospy.Service('/set_position_controller', SetBool, self._set_pos_ctrl)
        set_joint_traj_pos_server = rospy.Service('/set_trajectory_position_controller', SetBool, self._set_traj_pos_ctrl)
        set_joint_vel_server = rospy.Service('/set_velocity_controller', SetBool, self._set_vel_ctrl)
        set_joint_traj_vel_server = rospy.Service('/set_trajectory_velocity_controller', SetBool, self._set_traj_vel_ctrl)
#        set_gripper_server = rospy.Service('/set_gripper_controller', SetBool, self._set_grp_ctrl)

        self.pos_traj_controller = ['joint_state_controller',
                            'gripper_controller',
                            'pos_traj_controller']
        self.pos_controller = ["joint_state_controller",
                                "gripper_controller",
                                "ur_shoulder_pan_pos_controller",
                                "ur_shoulder_lift_pos_controller",
                                "ur_elbow_pos_controller",
                                "ur_wrist_1_pos_controller",
                                "ur_wrist_2_pos_controller",
                                "ur_wrist_3_pos_controller"]
        self.vel_traj_controller = ['joint_state_controller',
                            'gripper_controller',
                            'vel_traj_controller']
        self.vel_controller = ["joint_state_controller",
                                "gripper_controller",
                                "ur_shoulder_pan_vel_controller",
                                "ur_shoulder_lift_vel_controller",
                                "ur_elbow_vel_controller",
                                "ur_wrist_1_vel_controller",
                                "ur_wrist_2_vel_controller",
                                "ur_wrist_3_vel_controller"]

        # Helpful False
        self.stop_flag = False
        stop_trainning_server = rospy.Service('/stop_training', SetBool, self._stop_trainnig)
        start_trainning_server = rospy.Service('/start_training', SetBool, self._start_trainnig)

    def check_stop_flg(self):
        if self.stop_flag is False:
            return False
        else:
            return True

    def _start_trainnig(self, req):
        rospy.logdebug("_start_trainnig!!!!")
        self.stop_flag = False
        return SetBoolResponse(True, "_start_trainnig")

    def _stop_trainnig(self, req):
        rospy.logdebug("_stop_trainnig!!!!")
        self.stop_flag = True
        return SetBoolResponse(True, "_stop_trainnig")

    def _set_pos_ctrl(self, req):
        rospy.wait_for_service('set_position_controller')
        self._ctrl_conn.stop_controllers(self.pos_traj_controller)
        self._ctrl_conn.start_controllers(self.pos_controller)
        self._ctrl_type = 'pos'
        return SetBoolResponse(True, "_set_pos_ctrl")

    def _set_traj_pos_ctrl(self, req):
        rospy.wait_for_service('set_trajectory_position_controller')
        self._ctrl_conn.stop_controllers(self.pos_controller)
        self._ctrl_conn.start_controllers(self.pos_traj_controller)    
        self._ctrl_type = 'traj_pos'
        return SetBoolResponse(True, "_set_traj_pos_ctrl")  

    def _set_vel_ctrl(self, req):
        rospy.wait_for_service('set_velocity_controller')
        self._ctrl_conn.stop_controllers(self.vel_traj_controller)
        self._ctrl_conn.start_controllers(self.vel_controller)
        self._ctrl_type = 'vel'
        return SetBoolResponse(True, "_set_vel_ctrl")

    def _set_traj_vel_ctrl(self, req):
        rospy.wait_for_service('set_trajectory_velocity_controller')
        self._ctrl_conn.stop_controllers(self.vel_controller)
        self._ctrl_conn.start_controllers(self.vel_traj_controller)    
        self._ctrl_type = 'traj_vel'
        return SetBoolResponse(True, "_set_traj_vel_ctrl")  

#    def _set_grp_ctrl(self, req):
#        rospy.wait_for_service('set_gripper_controller')
#        self._ctrl_conn.start_controllers(self.gripper_controller)    
#        return SetBoolResponse(True, "_set_grp_ctrl")  

    # A function to initialize the random generator
    def _seed(self, seed=None):
        self.np_random, seed = seeding.np_random(seed)
        return [seed]
        
    def link_state_callback(self, msg):
        self.link_state = msg
        self.end_effector = self.link_state.pose[12]
        self.imu_link = self.link_state.pose[5]
        self.door = self.link_state.pose[2]

#    def target_point_callback(self, msg):
#        self.target_point = msg

    def check_all_systems_ready(self):
        """
        We check that all systems are ready
        :return:
        """
        joint_states_msg = None
        while joint_states_msg is None and not rospy.is_shutdown():
            try:
                joint_states_msg = rospy.wait_for_message("/joint_states", JointState, timeout=0.1)
                self.joints_state = joint_states_msg
                rospy.logdebug("Current joint_states READY")
            except Exception as e:
                self._ctrl_conn.start_controllers(controllers_on="joint_state_controller")                
                rospy.logdebug("Current joint_states not ready yet, retrying==>"+str(e))
        
        link_states_msg = None
        while link_states_msg is None and not rospy.is_shutdown():
            try:
                link_states_msg = rospy.wait_for_message("/gazebo/link_states", LinkStates, timeout=0.1)
                self.link_states = link_states_msg
                rospy.logdebug("Reading link_states READY")
            except Exception as e:
                rospy.logdebug("Reading link_states not ready yet, retrying==>"+str(e))

        rospy.logdebug("ALL SYSTEMS READY")

    def get_xyz(self, q):
        """Get x,y,z coordinates 
        Args:
            q: a numpy array of joints angle positions.
        Returns:
            xyz are the x,y,z coordinates of an end-effector in a Cartesian space.
        """
        mat = ur_utils.forward(q, self._ik_params)
        xyz = mat[:3, 3]
        return xyz

    def get_current_xyz(self):
        """Get x,y,z coordinates according to currrent joint angles
        Returns:
        xyz are the x,y,z coordinates of an end-effector in a Cartesian space.
        """
        joint_states = self.joints_state
        shp_joint_ang = joint_states.position[0]
        shl_joint_ang = joint_states.position[1]
        elb_joint_ang = joint_states.position[2]
        wr1_joint_ang = joint_states.position[3]
        wr2_joint_ang = joint_states.position[4]
        wr3_joint_ang = joint_states.position[5]
        
        q = [shp_joint_ang, shl_joint_ang, elb_joint_ang, wr1_joint_ang, wr2_joint_ang, wr3_joint_ang]
        mat = ur_utils.forward(q, self._ik_params)
        xyz = mat[:3, 3]
        return xyz
            
    def get_orientation(self, q):
        """Get Euler angles 
        Args:
            q: a numpy array of joints angle positions.
        Returns:
            xyz are the x,y,z coordinates of an end-effector in a Cartesian space.
        """
        mat = ur_utils.forward(q, self._ik_params)
        orientation = mat[0:3, 0:3]
        roll = -orientation[1, 2]
        pitch = orientation[0, 2]
        yaw = -orientation[0, 1]
        
        return Vector3(roll, pitch, yaw)


    def cvt_quat_to_euler(self, quat):
        euler_rpy = Vector3()
        euler = euler_from_quaternion([self.quat.x, self.quat.y, self.quat.z, self.quat.w])

        euler_rpy.x = euler[0]
        euler_rpy.y = euler[1]
        euler_rpy.z = euler[2]
        return euler_rpy

    def init_joints_pose(self, init_pos):
        """
        We initialise the Position variable that saves the desired position where we want our
        joints to be
        :param init_pos:
        :return:
        """
        self.current_joint_pose =[]
        self.current_joint_pose = copy.deepcopy(init_pos)
#	print("[current_joint_pose]:", self.current_joint_pose, type(self.current_joint_pose))
        return self.current_joint_pose

    def get_euclidean_dist(self, p_in, p_pout):
        """
        Given a Vector3 Object, get distance from current position
        :param p_end:
        :return:
        """
        a = numpy.array((p_in.x, p_in.y, p_in.z))
        b = numpy.array((p_pout.x, p_pout.y, p_pout.z))

        distance = numpy.linalg.norm(a - b)

        return distance

    def joints_state_callback(self,msg):
        self.joints_state = msg

    def wrench_stamped_callback(self,msg):
        self.wrench_stamped = msg

    def get_observations(self):
        """
        Returns the state of the robot needed for OpenAI QLearn Algorithm
        The state will be defined by an array
        :return: observation
        """
        joint_states = self.joints_state
        self.force = self.wrench_stamped.wrench.force
        self.torque = self.wrench_stamped.wrench.torque
#        print("[force]", self.force.x, self.force.y, self.force.z)
#        print("[torque]", self.torque.x, self.torque.y, self.torque.z)

        shp_joint_ang = joint_states.position[2]
        shl_joint_ang = joint_states.position[1]
        elb_joint_ang = joint_states.position[0]
        wr1_joint_ang = joint_states.position[9]
        wr2_joint_ang = joint_states.position[10]
        wr3_joint_ang = joint_states.position[11]

        shp_joint_vel = joint_states.velocity[2]
        shl_joint_vel = joint_states.velocity[1]
        elb_joint_vel = joint_states.velocity[0]
        wr1_joint_vel = joint_states.velocity[9]
        wr2_joint_vel = joint_states.velocity[10]
        wr3_joint_vel = joint_states.velocity[11]

        q = [shp_joint_ang, shl_joint_ang, elb_joint_ang, wr1_joint_ang, wr2_joint_ang, wr3_joint_ang]
        eef_x, eef_y, eef_z = self.get_xyz(q)

        observation = []
#        rospy.logdebug("List of Observations==>"+str(self.observations))
        for obs_name in self.observations:
            if obs_name == "shp_joint_ang":
                observation.append(shp_joint_ang)
            elif obs_name == "shl_joint_ang":
                observation.append(shl_joint_ang)
            elif obs_name == "elb_joint_ang":
                observation.append(elb_joint_ang)
            elif obs_name == "wr1_joint_ang":
                observation.append(wr1_joint_ang)
            elif obs_name == "wr2_joint_ang":
                observation.append(wr2_joint_ang)
            elif obs_name == "wr3_joint_ang":
                observation.append(wr3_joint_ang)
            elif obs_name == "shp_joint_vel":
                observation.append(shp_joint_vel)
            elif obs_name == "shl_joint_vel":
                observation.append(shl_joint_vel)
            elif obs_name == "elb_joint_vel":
                observation.append(elb_joint_vel)
            elif obs_name == "wr1_joint_vel":
                observation.append(wr1_joint_vel)
            elif obs_name == "wr2_joint_vel":
                observation.append(wr2_joint_vel)
            elif obs_name == "wr3_joint_vel":
                observation.append(wr3_joint_vel)
            elif obs_name == "eef_x":
                observation.append(eef_x)
            elif obs_name == "eef_y":
                observation.append(eef_y)
            elif obs_name == "eef_z":
                observation.append(eef_z)
            elif obs_name == "force_x":
                observation.append(self.force.x)
            elif obs_name == "force_y":
                observation.append(self.force.y)
            elif obs_name == "force_z":
                observation.append(self.force.z)
            elif obs_name == "torque_x":
                observation.append(self.torque.x)
            elif obs_name == "torque_y":
                observation.append(self.torque.y)
            elif obs_name == "torque_z":
                observation.append(self.torque.z)
            else:
                raise NameError('Observation Asked does not exist=='+str(obs_name))

        return observation

    def clamp_to_joint_limits(self):
        """
        clamps self.current_joint_pose based on the joint limits
        self._joint_limits
        {
         "shp_max": shp_max,
         "shp_min": shp_min,
         ...
         }
        :return:
        """

        rospy.logdebug("Clamping current_joint_pose>>>" + str(self.current_joint_pose))
        shp_joint_value = self.current_joint_pose[0]
        shl_joint_value = self.current_joint_pose[1]
        elb_joint_value = self.current_joint_pose[2]
        wr1_joint_value = self.current_joint_pose[3]
        wr2_joint_value = self.current_joint_pose[4]
        wr3_joint_value = self.current_joint_pose[5]

        self.current_joint_pose[0] = max(min(shp_joint_value, self._joint_limits["shp_max"]), self._joint_limits["shp_min"])
        self.current_joint_pose[1] = max(min(shl_joint_value, self._joint_limits["shl_max"]), self._joint_limits["shl_min"])
        self.current_joint_pose[2] = max(min(elb_joint_value, self._joint_limits["elb_max"]), self._joint_limits["elb_min"])
        self.current_joint_pose[3] = max(min(wr1_joint_value, self._joint_limits["wr1_max"]), self._joint_limits["wr1_min"])
        self.current_joint_pose[4] = max(min(wr2_joint_value, self._joint_limits["wr2_max"]), self._joint_limits["wr2_min"])
        self.current_joint_pose[5] = max(min(wr3_joint_value, self._joint_limits["wr3_max"]), self._joint_limits["wr3_min"])

        rospy.logdebug("DONE Clamping current_joint_pose>>>" + str(self.current_joint_pose))

    # Resets the state of the environment and returns an initial observation.
    def reset(self):

	# Go to initial position
	self._gz_conn.unpauseSim()
        rospy.logdebug("set_init_pose init variable...>>>" + str(self.init_joint_pose0))
        init_pos0 = self.init_joints_pose(self.init_joint_pose0)
        self.arr_init_pos0 = np.array(init_pos0, dtype='float32')
        init_pos1 = self.init_joints_pose(self.init_joint_pose1)
        self.arr_init_pos1 = np.array(init_pos1, dtype='float32')
        init_g_pos1 = self.init_joints_pose(self.init_grp_pose1)
        arr_init_g_pos1 = np.array(init_g_pos1, dtype='float32')

        jointtrajpub = JointTrajPub()
        for update in range(500):
        	jointtrajpub.GrpCommand(arr_init_g_pos1)
        time.sleep(2)
        for update in range(1000):
        	jointtrajpub.jointTrajectoryCommand(self.arr_init_pos1)
        time.sleep(0.3)
        for update in range(1000):
        	jointtrajpub.jointTrajectoryCommand(self.arr_init_pos0)
        time.sleep(0.3)

        # 0st: We pause the Simulator
        rospy.logdebug("Pausing SIM...")
        self._gz_conn.pauseSim()

        # 1st: resets the simulation to initial values
        rospy.logdebug("Reset SIM...")
        self._gz_conn.resetSim()

        # 2nd: We Set the gravity to 0.0 so that we dont fall when reseting joints
        # It also UNPAUSES the simulation
        rospy.logdebug("Remove Gravity...")
        self._gz_conn.change_gravity_zero()

        # EXTRA: Reset JoinStateControlers because sim reset doesnt reset TFs, generating time problems
        rospy.logdebug("reset_ur_joint_controllers...")
        self._ctrl_conn.reset_ur_joint_controllers(self._ctrl_type)

        # 3rd: resets the robot to initial conditions
        rospy.logdebug("set_init_pose init variable...>>>" + str(self.init_joint_pose1))
        rospy.logdebug("set_init_pose init variable...>>>" + str(self.init_joint_pose2))

        # We save that position as the current joint desired position
#	print("[init_joint_pose1]:", self.init_joint_pose1, type(self.init_joint_pose1))

        init_pos2 = self.init_joints_pose(self.init_joint_pose2)
        self.arr_init_pos2 = np.array(init_pos2, dtype='float32')
        after_rotate = self.init_joints_pose(self.after_rotate)
        self.arr_after_rotate = np.array(after_rotate, dtype='float32')
        after_pull = self.init_joints_pose(self.after_pull)
        self.arr_after_pull = np.array(after_pull, dtype='float32')

        init_g_pos2 = self.init_joints_pose(self.init_grp_pose2)
        arr_init_g_pos2 = np.array(init_g_pos2, dtype='float32')

        # 4th: We Set the init pose to the jump topic so that the jump control can update
        # We check the jump publisher has connection

        if self._ctrl_type == 'traj_pos':
            self._joint_traj_pubisher.check_publishers_connection()
        elif self._ctrl_type == 'pos':
            self._joint_pubisher.check_publishers_connection()
        elif self._ctrl_type == 'traj_vel':
            self._joint_traj_pubisher.check_publishers_connection()
        elif self._ctrl_type == 'vel':
            self._joint_pubisher.check_publishers_connection()
        else:
            rospy.logwarn("Controller type is wrong!!!!")
        
        # 5th: Check all subscribers work.
        # Get the state of the Robot defined by its RPY orientation, distance from
        # desired point, contact force and JointState of the three joints
        rospy.logdebug("check_all_systems_ready...")
        self.check_all_systems_ready()

        # 6th: We restore the gravity to original
        rospy.logdebug("Restore Gravity...")
        self._gz_conn.adjust_gravity()

        for update in range(1000):
        	jointtrajpub.jointTrajectoryCommand(self.arr_init_pos1)
        time.sleep(0.3)
        for update in range(1000):
        	jointtrajpub.jointTrajectoryCommand(self.arr_init_pos2)
        time.sleep(0.3)
        for update in range(50):
        	jointtrajpub.GrpCommand(arr_init_g_pos2)
        time.sleep(2)

        # 7th: pauses simulation
        rospy.logdebug("Pause SIM...")
        self._gz_conn.pauseSim()

        # 8th: Get the State Discrete Stringuified version of the observations
        rospy.logdebug("get_observations...")
       	observation = self.get_observations()
#        print("[observations]", observation)

        return observation

    def _act(self, action):
        if self._ctrl_type == 'traj_pos':
            self.pre_ctrl_type = 'traj_pos'
            self._joint_traj_pubisher.jointTrajectoryCommand(action)
        elif self._ctrl_type == 'pos':
            self.pre_ctrl_type = 'pos'
            self._joint_pubisher.move_joints(action)
        elif self._ctrl_type == 'traj_vel':
            self.pre_ctrl_type = 'traj_vel'
            self._joint_traj_pubisher.jointTrajectoryCommand(action)
        elif self._ctrl_type == 'vel':
            self.pre_ctrl_type = 'vel'
            self._joint_pubisher.move_joints(action)
        else:
            self._joint_pubisher.move_joints(action)
        
    def training_ok(self):
        rate = rospy.Rate(1)
        while self.check_stop_flg() is True:                  
            rospy.logdebug("stop_flag is ON!!!!")
            self._gz_conn.unpauseSim()

            if self.check_stop_flg() is False:
                break 
            rate.sleep()
                
    def step(self, action):
        '''
        ('action: ', array([ 0.,  0. , -0., -0., -0. , 0. ], dtype=float32))        
        '''
        rospy.logdebug("UR step func")	# define the logger
        self.training_ok()

        # Given the action selected by the learning algorithm,
        # we perform the corresponding movement of the robot
        # Act
        self._gz_conn.unpauseSim()

        action = action + self.arr_init_pos2
        self._act(action)
#	print("[action]", action)

        self.wrench_stamped
        self.force = self.wrench_stamped.wrench.force
        self.torque = self.wrench_stamped.wrench.torque
#	print("wrench", self.wrench_stamped, type(self.wrench_stamped)) 	#<class 'geometry_msgs.msg._WrenchStamped.WrenchStamped'>
#        print("[force]", self.force.x, self.force.y, self.force.z)
#        print("[torque]", self.torque.x, self.torque.y, self.torque.z)

        '''
        if self.force_limit < self.force.x or self.force.x < -self.force_limit:
        	self._act(self.previous_action)
#        	print("force.x over the limit")
#        	print("[previous_action]", self.previous_action)
        elif self.force_limit < self.force.y or self.force.y < -self.force_limit:
        	self._act(self.previous_action)
#        	print("force.y over the limit")
#        	print("[previous_action]", self.previous_action)
        elif self.force_limit < self.force.z or self.force.z < -self.force_limit:
        	self._act(self.previous_action)
#        	print("force.z over the limit")
#        	print("[previous_action]", self.previous_action)
        elif self.torque_limit < self.torque.x or self.torque.x < -self.torque_limit:
        	self._act(self.previous_action)
#        	print("torque.x over the limit")
#        	print("[previous_action]", self.previous_action)
        elif self.torque_limit < self.torque.y or self.torque.y < -self.torque_limit:
        	self._act(self.previous_action)
#        	print("torque.y over the limit")
#        	print("[previous_action]", self.previous_action)
        elif self.torque_limit < self.torque.z or self.torque.z < -self.torque_limit:
        	self._act(self.previous_action)
#        	print("torque.z over the limit")
#        	print("[previous_action]", self.previous_action)
        else:
        	self.previous_action = copy.deepcopy(action)
#        	print("[action]", action)
        '''
    
        # Then we send the command to the robot and let it go for running_step seconds
        time.sleep(self.running_step)
        self._gz_conn.pauseSim()

        # We now process the latest data saved in the class state to calculate
        # the state and the rewards. This way we guarantee that they work
        # with the same exact data.
        # Generate State based on observations
        observation = self.get_observations()
#        print("[observations]", observation)

        # finally we get an evaluation based on what happened in the sim
        reward = self.compute_dist_rewards()
        done = self.check_done()

        return observation, reward, done, {}

    def compute_dist_rewards(self):
        self.quat = self.door.orientation
        self.door_rpy = self.cvt_quat_to_euler(self.quat)
        self.quat = self.imu_link.orientation
        self.imu_link_rpy = self.cvt_quat_to_euler(self.quat)
        compute_rewards = 0

#        self.rpy = self.cvt_quat_to_euler(Quaternion(0.0, 0.0, 0.7071, 0.7071))
        #print ("[self.target_point]: ", [self.target_point.x, self.target_point.y, self.target_point.z])
        #print ("(self.get_current_xyz(): ", self.get_current_xyz())
        #end_effector_pos = np.array([self.end_effector.position.x, self.end_effector.position.y, self.end_effector.position.z])
        #self.distance = np.linalg.norm(end_effector_pos - [self.target_point.x, self.target_point.y, self.target_point.z], axis=0)

#        print ("[door]: ", [self.door.orientation.x, self.door.orientation.y, self.door.orientation.z, self.door.orientation.w])
#        print ("[imu_link]: ", [self.imu_link.orientation.x, self.imu_link.orientation.y, self.imu_link.orientation.z, self.imu_link.orientation.w])
#        print ("[door_rpy]: ", [self.door_rpy.x, self.door_rpy.y, self.door_rpy.z])			# [-3.141590232638843, 4.64637166410168e-06, 3.1407993185850303]
													# => [-3.141587417428544, 6.811796590263218e-05, 2.8971100347923704]
#        print ("[self.imu_link_rpy]: ", [self.imu_link_rpy.x, self.imu_link_rpy.y, self.imu_link_rpy.z])	# [-5.017238272290064e-06, 2.560885641286913e-07, 1.5707993173228965]
													# => [1.2205817198134408, -4.341035340318689e-06, 1.3270298472237638]
#        print ("[type]: ", type(self.door_rpy), type(self.end_effector.position))
#        print ("[rpy]: ", [self.rpy.x, self.rpy.y, self.rpy.z])

#	self.counter = self.counter + 1

#        return self.imu_link_rpy.x + 1.5708061 - self.imu_link_rpy.z  # for door opening
        compute_rewards = self.imu_link_rpy.x + 1.5708061 - self.imu_link_rpy.z

        return compute_rewards  # for door opening

# close
#('[door_rpy]: ', [-3.141589494723927, 5.371950050444065e-06, 3.140803800525111])
#('[self.imu_link_rpy]: ', [-5.406752832019292e-06, 6.896590419417709e-06, 1.5708061011106662])

# open
#('[door_rpy]: ', [3.1374584007550737, -0.0018131747911100536, 2.764050391990123(delta=0.3768)])
#('[self.imu_link_rpy]: ', [1.0934212049101757(delta=1.0934), -0.004085577221111396, 1.1941435185763472(delta=0.3768)])

    def check_done(self):
#        if 3.1408 - self.door_rpy.z > 3.14 / 180 * 10: # for door opening
        if self.imu_link_rpy.x + 1.5708061 - self.imu_link_rpy.z > 3000: # for door opening
            print("done")
            return True
        else :
        	return False
コード例 #2
0
class URSimEnv(robot_gazebo_env_goal.RobotGazeboEnv):
    def __init__(self):
        # We assume that a ROS node has already been created before initialising the environment

        # Gets training parameters from param server
        self.desired_pose = Pose()
        self.desired_pose.position.x = rospy.get_param("/desired_pose/x")
        self.desired_pose.position.y = rospy.get_param("/desired_pose/y")
        self.desired_pose.position.z = rospy.get_param("/desired_pose/z")
        self.running_step = rospy.get_param("/running_step")
        self.max_incl = rospy.get_param("/max_incl")
        self.max_height = rospy.get_param("/max_height")
        self.min_height = rospy.get_param("/min_height")
        self.joint_increment_value = rospy.get_param("/joint_increment_value")
        self.done_reward = rospy.get_param("/done_reward")
        self.alive_reward = rospy.get_param("/alive_reward")
        self.desired_force = rospy.get_param("/desired_force")
        self.desired_yaw = rospy.get_param("/desired_yaw")

        self.list_of_observations = rospy.get_param("/list_of_observations")

        haa_max = rospy.get_param("/joint_limits_array/haa_max")
        haa_min = rospy.get_param("/joint_limits_array/haa_min")
        hfe_max = rospy.get_param("/joint_limits_array/hfe_max")
        hfe_min = rospy.get_param("/joint_limits_array/hfe_min")
        kfe_max = rospy.get_param("/joint_limits_array/kfe_max")
        kfe_min = rospy.get_param("/joint_limits_array/kfe_min")
        self.joint_limits = {
            "haa_max": haa_max,
            "haa_min": haa_min,
            "hfe_max": hfe_max,
            "hfe_min": hfe_min,
            "kfe_max": kfe_max,
            "kfe_min": kfe_min
        }

        self.discrete_division = rospy.get_param("/discrete_division")

        self.maximum_base_linear_acceleration = rospy.get_param(
            "/maximum_base_linear_acceleration")
        self.maximum_base_angular_velocity = rospy.get_param(
            "/maximum_base_angular_velocity")
        self.maximum_joint_effort = rospy.get_param("/maximum_joint_effort")

        self.weight_r1 = rospy.get_param("/weight_r1")
        self.weight_r2 = rospy.get_param("/weight_r2")
        self.weight_r3 = rospy.get_param("/weight_r3")
        self.weight_r4 = rospy.get_param("/weight_r4")
        self.weight_r5 = rospy.get_param("/weight_r5")

        haa_init_value = rospy.get_param("/init_joint_pose/haa")
        hfe_init_value = rospy.get_param("/init_joint_pose/hfe")
        kfe_init_value = rospy.get_param("/init_joint_pose/kfe")
        self.init_joint_pose = [haa_init_value, hfe_init_value, kfe_init_value]

        # Fill in the Done Episode Criteria list
        self.episode_done_criteria = rospy.get_param("/episode_done_criteria")

        # Jump Increment Value in Radians
        self.jump_increment = rospy.get_param("/jump_increment")

        # stablishes connection with simulator
        self.gazebo = GazeboConnection()
        self.controllers_object = ControllersConnection(namespace="ur")

        self.ur_state_object = URState(
            max_height=self.max_height,
            min_height=self.min_height,
            abs_max_roll=self.max_incl,
            abs_max_pitch=self.max_incl,
            joint_increment_value=self.joint_increment_value,
            list_of_observations=self.list_of_observations,
            joint_limits=self.joint_limits,
            episode_done_criteria=self.episode_done_criteria,
            done_reward=self.done_reward,
            alive_reward=self.alive_reward,
            desired_force=self.desired_force,
            desired_yaw=self.desired_yaw,
            weight_r1=self.weight_r1,
            weight_r2=self.weight_r2,
            weight_r3=self.weight_r3,
            weight_r4=self.weight_r4,
            weight_r5=self.weight_r5,
            discrete_division=self.discrete_division,
            maximum_base_linear_acceleration=self.
            maximum_base_linear_acceleration,
            maximum_base_angular_velocity=self.maximum_base_angular_velocity,
            maximum_joint_effort=self.maximum_joint_effort,
            jump_increment=self.jump_increment)

        self.ur_state_object.set_desired_world_point(
            self.desired_pose.position.x, self.desired_pose.position.y,
            self.desired_pose.position.z)

        self.ur_joint_pubisher_object = JointPub()
        """
        For this version, we consider 5 actions
        1-2) Increment/Decrement haa_joint
        3-4) Increment/Decrement hfe_joint
        5) Dont Move
        6) Perform One Jump
        """
        self.action_space = spaces.Discrete(6)
        self.reward_range = (-np.inf, np.inf)

        self._seed()

    # A function to initialize the random generator
    def _seed(self, seed=None):
        self.np_random, seed = seeding.np_random(seed)
        return [seed]

    # Resets the state of the environment and returns an initial observation.
    def _reset(self):
        # 0st: We pause the Simulator
        rospy.logdebug("Pausing SIM...")
        self.gazebo.pauseSim()

        # 1st: resets the simulation to initial values
        rospy.logdebug("Reset SIM...")
        self.gazebo.resetSim()

        # 2nd: We Set the gravity to 0.0 so that we dont fall when reseting joints
        # It also UNPAUSES the simulation
        rospy.logdebug("Remove Gravity...")
        self.gazebo.change_gravity(0.0, 0.0, 0.0)

        # EXTRA: Reset JoinStateControlers because sim reset doesnt reset TFs, generating time problems
        rospy.logdebug("reset_ur_joint_controllers...")
        self.controllers_object.reset_ur_joint_controllers()

        # 3rd: resets the robot to initial conditions
        rospy.logdebug("set_init_pose init variable...>>>" +
                       str(self.init_joint_pose))
        # We save that position as the current joint desired position
        init_pos = self.ur_state_object.init_joints_pose(self.init_joint_pose)

        # 4th: We Set the init pose to the jump topic so that the jump control can update
        rospy.logdebug("Publish init_pose for Jump Control...>>>" +
                       str(init_pos))
        # We check the jump publisher has connection
        self.ur_joint_pubisher_object.check_publishers_connection()
        # We move the joints to position, no jump
        do_jump = False
        self.ur_joint_pubisher_object.move_joints_jump(init_pos, do_jump)

        # 5th: Check all subscribers work.
        # Get the state of the Robot defined by its RPY orientation, distance from
        # desired point, contact force and JointState of the three joints
        rospy.logdebug("check_all_systems_ready...")
        self.ur_state_object.check_all_systems_ready()

        # 6th: We restore the gravity to original
        rospy.logdebug("Restore Gravity...")
        self.gazebo.change_gravity(0.0, 0.0, -9.81)

        # 7th: pauses simulation
        rospy.logdebug("Pause SIM...")
        self.gazebo.pauseSim()

        # 8th: Get the State Discrete Stringuified version of the observations
        rospy.logdebug("get_observations...")
        observation = self.ur_state_object.get_observations()
        state = self.get_state(observation)

        return state

    def _step(self, action):

        # Given the action selected by the learning algorithm,
        # we perform the corresponding movement of the robot

        # 1st, decide which action corresponds to which joint is incremented
        next_action_position, do_jump = self.ur_state_object.get_action_to_position(
            action)

        # We move it to that pos
        self.gazebo.unpauseSim()
        self.ur_joint_pubisher_object.move_joints_jump(next_action_position,
                                                       do_jump)
        # Then we send the command to the robot and let it go
        # for running_step seconds
        time.sleep(self.running_step)
        self.gazebo.pauseSim()

        # We now process the latest data saved in the class state to calculate
        # the state and the rewards. This way we guarantee that they work
        # with the same exact data.
        # Generate State based on observations
        observation = self.ur_state_object.get_observations()

        # finally we get an evaluation based on what happened in the sim
        reward, done = self.ur_state_object.process_data()

        # Get the State Discrete Stringuified version of the observations
        state = self.get_state(observation)

        return state, reward, done, {}

    def get_state(self, observation):
        """
        We retrieve the Stringuified-Discrete version of the given observation
        :return: state
        """
        return self.ur_state_object.get_state_as_string(observation)
コード例 #3
0
class URSimReaching(robot_gazebo_env_goal.RobotGazeboEnv):
    def __init__(self):
        rospy.logdebug("Starting URSimReaching Class object...")

        # Init GAZEBO Objects
        self.set_obj_state = rospy.ServiceProxy('/gazebo/set_model_state',
                                                SetModelState)
        self.get_world_state = rospy.ServiceProxy(
            '/gazebo/get_world_properties', GetWorldProperties)

        # Subscribe joint state and target pose
        rospy.Subscriber("/joint_states", JointState,
                         self.joints_state_callback)
        rospy.Subscriber("/target_blocks_pose", Point, self.target_point_cb)

        # Gets training parameters from param server
        self.desired_pose = Pose()
        self.desired_pose.position.x = rospy.get_param("/desired_pose/x")
        self.desired_pose.position.y = rospy.get_param("/desired_pose/y")
        self.desired_pose.position.z = rospy.get_param("/desired_pose/z")
        self.running_step = rospy.get_param("/running_step")
        self.max_height = rospy.get_param("/max_height")
        self.min_height = rospy.get_param("/min_height")
        self.observations = rospy.get_param("/observations")

        # Joint limitation
        shp_max = rospy.get_param("/joint_limits_array/shp_max")
        shp_min = rospy.get_param("/joint_limits_array/shp_min")
        shl_max = rospy.get_param("/joint_limits_array/shl_max")
        shl_min = rospy.get_param("/joint_limits_array/shl_min")
        elb_max = rospy.get_param("/joint_limits_array/elb_max")
        elb_min = rospy.get_param("/joint_limits_array/elb_min")
        wr1_max = rospy.get_param("/joint_limits_array/wr1_max")
        wr1_min = rospy.get_param("/joint_limits_array/wr1_min")
        wr2_max = rospy.get_param("/joint_limits_array/wr2_max")
        wr2_min = rospy.get_param("/joint_limits_array/wr2_min")
        wr3_max = rospy.get_param("/joint_limits_array/wr3_max")
        wr3_min = rospy.get_param("/joint_limits_array/wr3_min")
        self.joint_limits = {
            "shp_max": shp_max,
            "shp_min": shp_min,
            "shl_max": shl_max,
            "shl_min": shl_min,
            "elb_max": elb_max,
            "elb_min": elb_min,
            "wr1_max": wr1_max,
            "wr1_min": wr1_min,
            "wr2_max": wr2_max,
            "wr2_min": wr2_min,
            "wr3_max": wr3_max,
            "wr3_min": wr3_min
        }

        shp_init_value = rospy.get_param("/init_joint_pose/shp")
        shl_init_value = rospy.get_param("/init_joint_pose/shl")
        elb_init_value = rospy.get_param("/init_joint_pose/elb")
        wr1_init_value = rospy.get_param("/init_joint_pose/wr1")
        wr2_init_value = rospy.get_param("/init_joint_pose/wr2")
        wr3_init_value = rospy.get_param("/init_joint_pose/wr3")
        self.init_joint_pose = [
            shp_init_value, shl_init_value, elb_init_value, wr1_init_value,
            wr2_init_value, wr3_init_value
        ]

        # Fill in the Done Episode Criteria list
        self.episode_done_criteria = rospy.get_param("/episode_done_criteria")

        # stablishes connection with simulator
        self._gz_conn = GazeboConnection()
        self._ctrl_conn = ControllersConnection(namespace="")

        # Controller type for ros_control
        self._ctrl_type = sys.argv[1]
        self.pre_ctrl_type = self._ctrl_type

        # We init the observations
        self.base_orientation = Quaternion()
        self.target_point = Point()
        self.joints_state = JointState()

        # Arm/Control parameters
        self._ik_params = setups['UR5_6dof']['ik_params']

        # ROS msg type
        self._joint_pubisher = JointPub()
        self._joint_traj_pubisher = JointTrajPub()

        # Gym interface and action
        self.action_space = spaces.Discrete(6)
        self.reward_range = (-np.inf, np.inf)
        self._seed()

    # A function to initialize the random generator
    def _seed(self, seed=None):
        self.np_random, seed = seeding.np_random(seed)
        return [seed]

    def target_point_cb(self, msg):
        self.target_point = msg

    def check_all_systems_ready(self):
        """
        We check that all systems are ready
        :return:
        """
        joint_states_msg = None
        while joint_states_msg is None and not rospy.is_shutdown():
            try:
                joint_states_msg = rospy.wait_for_message("/joint_states",
                                                          JointState,
                                                          timeout=0.1)
                self.joints_state = joint_states_msg
                rospy.logdebug("Current joint_states READY")
            except Exception as e:
                rospy.logdebug(
                    "Current joint_states not ready yet, retrying==>" + str(e))

        target_pose_msg = None
        while target_pose_msg is None and not rospy.is_shutdown():
            try:
                target_pose_msg = rospy.wait_for_message("/target_blocks_pose",
                                                         Point,
                                                         timeout=0.1)
                self.target_point = target_pose_msg
                rospy.logdebug("Reading target pose READY")
            except Exception as e:
                rospy.logdebug(
                    "Reading target pose not ready yet, retrying==>" + str(e))

        rospy.logdebug("ALL SYSTEMS READY")

    def get_xyz(self, q):
        """Get x,y,z coordinates 
        Args:
            q: a numpy array of joints angle positions.
        Returns:
            xyz are the x,y,z coordinates of an end-effector in a Cartesian space.
        """
        mat = ur_utils.forward(q, self._ik_params)
        xyz = mat[:3, 3]
        return xyz

    def get_orientation(self, q):
        """Get Euler angles 
        Args:
            q: a numpy array of joints angle positions.
        Returns:
            xyz are the x,y,z coordinates of an end-effector in a Cartesian space.
        """
        mat = ur_utils.forward(q, self._ik_params)
        orientation = mat[0:3, 0:3]
        roll = -orientation[1, 2]
        pitch = orientation[0, 2]
        yaw = -orientation[0, 1]

        return Vector3(roll, pitch, yaw)

    def cvt_quat_to_euler(self, quat):
        euler_rpy = Vector3()
        euler = tf.transformations.euler_from_quaternion(
            [self.quat.x, self.quat.y, self.quat.z, self.quat.w])

        euler_rpy.x = euler[0]
        euler_rpy.y = euler[1]
        euler_rpy.z = euler[2]
        return euler_rpy

    def init_joints_pose(self, init_pos):
        """
        We initialise the Position variable that saves the desired position where we want our
        joints to be
        :param init_pos:
        :return:
        """
        self.current_joint_pose = []
        self.current_joint_pose = copy.deepcopy(init_pos)
        return self.current_joint_pose

    def get_euclidean_dist(self, p_in, p_pout):
        """
        Given a Vector3 Object, get distance from current position
        :param p_end:
        :return:
        """
        a = numpy.array((p_in.x, p_in.y, p_in.z))
        b = numpy.array((p_pout.x, p_pout.y, p_pout.z))

        distance = numpy.linalg.norm(a - b)

        return distance

    def joints_state_callback(self, msg):
        self.joints_state = msg

    def get_observations(self):
        """
        Returns the state of the robot needed for OpenAI QLearn Algorithm
        The state will be defined by an array
        :return: observation
        """
        joint_states = self.joints_state
        shp_joint_ang = joint_states.position[0]
        shl_joint_ang = joint_states.position[1]
        elb_joint_ang = joint_states.position[2]
        wr1_joint_ang = joint_states.position[3]
        wr2_joint_ang = joint_states.position[4]
        wr3_joint_ang = joint_states.position[5]

        shp_joint_vel = joint_states.velocity[0]
        shl_joint_vel = joint_states.velocity[1]
        elb_joint_vel = joint_states.velocity[2]
        wr1_joint_vel = joint_states.velocity[3]
        wr2_joint_vel = joint_states.velocity[4]
        wr3_joint_vel = joint_states.velocity[5]

        q = [
            shp_joint_ang, shl_joint_ang, elb_joint_ang, wr1_joint_ang,
            wr2_joint_ang, wr3_joint_ang
        ]
        eef_x, eef_y, eef_z = self.get_xyz(q)

        observation = []
        rospy.logdebug("List of Observations==>" + str(self.observations))
        for obs_name in self.observations:
            if obs_name == "shp_joint_ang":
                observation.append(shp_joint_ang)
            elif obs_name == "shl_joint_ang":
                observation.append(shl_joint_ang)
            elif obs_name == "elb_joint_ang":
                observation.append(elb_joint_ang)
            elif obs_name == "wr1_joint_ang":
                observation.append(wr1_joint_ang)
            elif obs_name == "wr2_joint_ang":
                observation.append(wr2_joint_ang)
            elif obs_name == "wr3_joint_ang":
                observation.append(wr3_joint_ang)
            elif obs_name == "shp_joint_vel":
                observation.append(shp_joint_vel)
            elif obs_name == "shl_joint_vel":
                observation.append(shl_joint_vel)
            elif obs_name == "elb_joint_vel":
                observation.append(elb_joint_vel)
            elif obs_name == "wr1_joint_vel":
                observation.append(wr1_joint_vel)
            elif obs_name == "wr2_joint_vel":
                observation.append(wr2_joint_vel)
            elif obs_name == "wr3_joint_vel":
                observation.append(wr3_joint_vel)
            elif obs_name == "eef_x":
                observation.append(eef_x)
            elif obs_name == "eef_y":
                observation.append(eef_y)
            elif obs_name == "eef_z":
                observation.append(eef_z)
            else:
                raise NameError('Observation Asked does not exist==' +
                                str(obs_name))

        return observation

    def clamp_to_joint_limits(self):
        """
        clamps self.current_joint_pose based on the joint limits
        self._joint_limits
        {
         "shp_max": shp_max,
         "shp_min": shp_min,
         ...
         }
        :return:
        """

        rospy.logdebug("Clamping current_joint_pose>>>" +
                       str(self.current_joint_pose))
        shp_joint_value = self.current_joint_pose[0]
        shl_joint_value = self.current_joint_pose[1]
        elb_joint_value = self.current_joint_pose[2]
        wr1_joint_value = self.current_joint_pose[3]
        wr2_joint_value = self.current_joint_pose[4]
        wr3_joint_value = self.current_joint_pose[5]

        self.current_joint_pose[0] = max(
            min(shp_joint_value, self._joint_limits["shp_max"]),
            self._joint_limits["shp_min"])
        self.current_joint_pose[1] = max(
            min(shl_joint_value, self._joint_limits["shl_max"]),
            self._joint_limits["shl_min"])
        self.current_joint_pose[2] = max(
            min(elb_joint_value, self._joint_limits["elb_max"]),
            self._joint_limits["elb_min"])
        self.current_joint_pose[3] = max(
            min(wr1_joint_value, self._joint_limits["wr1_max"]),
            self._joint_limits["wr1_min"])
        self.current_joint_pose[4] = max(
            min(wr2_joint_value, self._joint_limits["wr2_max"]),
            self._joint_limits["wr2_min"])
        self.current_joint_pose[5] = max(
            min(wr3_joint_value, self._joint_limits["wr3_max"]),
            self._joint_limits["wr3_min"])

        rospy.logdebug("DONE Clamping current_joint_pose>>>" +
                       str(self.current_joint_pose))

    # Resets the state of the environment and returns an initial observation.
    def reset(self):
        # 0st: We pause the Simulator
        rospy.logdebug("Pausing SIM...")
        self._gz_conn.pauseSim()

        # 1st: resets the simulation to initial values
        rospy.logdebug("Reset SIM...")
        self._gz_conn.resetSim()

        # 2nd: We Set the gravity to 0.0 so that we dont fall when reseting joints
        # It also UNPAUSES the simulation
        rospy.logdebug("Remove Gravity...")
        self._gz_conn.change_gravity(0.0, 0.0, 0.0)

        # EXTRA: Reset JoinStateControlers because sim reset doesnt reset TFs, generating time problems
        rospy.logdebug("reset_ur_joint_controllers...")
        self._ctrl_conn.reset_ur_joint_controllers(self._ctrl_type)

        # 3rd: resets the robot to initial conditions
        rospy.logdebug("set_init_pose init variable...>>>" +
                       str(self.init_joint_pose))
        # We save that position as the current joint desired position
        init_pos = self.init_joints_pose(self.init_joint_pose)
        print("init_pos")

        # 4th: We Set the init pose to the jump topic so that the jump control can update
        # We check the jump publisher has connection

        if self._ctrl_type == 'traj_vel':
            self._joint_traj_pubisher.check_publishers_connection()
        elif self._ctrl_type == 'vel':
            self._joint_pubisher.check_publishers_connection()
        else:
            rospy.logwarn("Controller type is wrong!!!!")
        print("check_publishers_connection ")

        # 5th: Check all subscribers work.
        # Get the state of the Robot defined by its RPY orientation, distance from
        # desired point, contact force and JointState of the three joints
        rospy.logdebug("check_all_systems_ready...")
        self.check_all_systems_ready()

        # 6th: We restore the gravity to original
        rospy.logdebug("Restore Gravity...")
        self._gz_conn.change_gravity(0.0, 0.0, -9.81)

        # 7th: pauses simulation
        rospy.logdebug("Pause SIM...")
        self._gz_conn.pauseSim()
        # self._init_obj_pose()

        # 8th: Get the State Discrete Stringuified version of the observations
        rospy.logdebug("get_observations...")
        observation = self.get_observations()

        print('Reset final')
        return observation

    def _act(self, action):
        if self._ctrl_type == 'traj_vel':
            self.pre_ctrl_type = 'traj_vel'
            self._joint_traj_pubisher.move_joints(action)
        elif self._ctrl_type == 'vel':
            self.pre_ctrl_type = 'vel'
            self._joint_pubisher.move_joints(action)
        else:
            self._joint_pubisher.move_joints(action)

    def step(self, action):
        rospy.logdebug("UR step func")

        # Given the action selected by the learning algorithm,
        # we perform the corresponding movement of the robot

        # Act
        self._gz_conn.unpauseSim()
        self._act(action)

        # Then we send the command to the robot and let it go
        # for running_step seconds
        time.sleep(self.running_step)
        self._gz_conn.pauseSim()

        # We now process the latest data saved in the class state to calculate
        # the state and the rewards. This way we guarantee that they work
        # with the same exact data.
        # Generate State based on observations
        observation = self.get_observations()

        # finally we get an evaluation based on what happened in the sim
        reward = self.compute_dist_rewards()
        done = self.check_done()

        return observation, reward, done, {}

    def compute_dist_rewards(self):
        return 0

    def check_done(self):
        return True
コード例 #4
0
class URSimDoorOpening(robot_gazebo_env_goal.RobotGazeboEnv):
    def __init__(self):
        #        rospy.logdebug("Starting URSimDoorOpening Class object...")

        # Init GAZEBO Objects
        self.set_obj_state = rospy.ServiceProxy('/gazebo/set_model_state',
                                                SetModelState)
        self.get_world_state = rospy.ServiceProxy(
            '/gazebo/get_world_properties', GetWorldProperties)

        # Subscribe joint state and target pose
        rospy.Subscriber("/ft_sensor_topic", WrenchStamped,
                         self.wrench_stamped_callback)
        rospy.Subscriber("/joint_states", JointState,
                         self.joints_state_callback)
        rospy.Subscriber("/gazebo/link_states", LinkStates,
                         self.link_state_callback)
        rospy.Subscriber("/robotiq/rightcam/image_raw_right", Image,
                         self.r_image_callback)
        rospy.Subscriber("/robotiq/leftcam/image_raw_left", Image,
                         self.l_image_callback)

        # Gets training parameters from param server
        self.running_step = rospy.get_param("/running_step")
        self.observations = rospy.get_param("/observations")

        # Joint limitation
        shp_max = rospy.get_param("/joint_limits_array/shp_max")
        shp_min = rospy.get_param("/joint_limits_array/shp_min")
        shl_max = rospy.get_param("/joint_limits_array/shl_max")
        shl_min = rospy.get_param("/joint_limits_array/shl_min")
        elb_max = rospy.get_param("/joint_limits_array/elb_max")
        elb_min = rospy.get_param("/joint_limits_array/elb_min")
        wr1_max = rospy.get_param("/joint_limits_array/wr1_max")
        wr1_min = rospy.get_param("/joint_limits_array/wr1_min")
        wr2_max = rospy.get_param("/joint_limits_array/wr2_max")
        wr2_min = rospy.get_param("/joint_limits_array/wr2_min")
        wr3_max = rospy.get_param("/joint_limits_array/wr3_max")
        wr3_min = rospy.get_param("/joint_limits_array/wr3_min")
        self.joint_limits = {
            "shp_max": shp_max,
            "shp_min": shp_min,
            "shl_max": shl_max,
            "shl_min": shl_min,
            "elb_max": elb_max,
            "elb_min": elb_min,
            "wr1_max": wr1_max,
            "wr1_min": wr1_min,
            "wr2_max": wr2_max,
            "wr2_min": wr2_min,
            "wr3_max": wr3_max,
            "wr3_min": wr3_min
        }

        shp_init_value0 = rospy.get_param("/init_joint_pose0/shp")
        shl_init_value0 = rospy.get_param("/init_joint_pose0/shl")
        elb_init_value0 = rospy.get_param("/init_joint_pose0/elb")
        wr1_init_value0 = rospy.get_param("/init_joint_pose0/wr1")
        wr2_init_value0 = rospy.get_param("/init_joint_pose0/wr2")
        wr3_init_value0 = rospy.get_param("/init_joint_pose0/wr3")
        self.init_joint_pose0 = [
            shp_init_value0, shl_init_value0, elb_init_value0, wr1_init_value0,
            wr2_init_value0, wr3_init_value0
        ]

        shp_init_value1 = rospy.get_param("/init_joint_pose1/shp")
        shl_init_value1 = rospy.get_param("/init_joint_pose1/shl")
        elb_init_value1 = rospy.get_param("/init_joint_pose1/elb")
        wr1_init_value1 = rospy.get_param("/init_joint_pose1/wr1")
        wr2_init_value1 = rospy.get_param("/init_joint_pose1/wr2")
        wr3_init_value1 = rospy.get_param("/init_joint_pose1/wr3")
        self.init_joint_pose1 = [
            shp_init_value1, shl_init_value1, elb_init_value1, wr1_init_value1,
            wr2_init_value1, wr3_init_value1
        ]

        shp_init_value2 = rospy.get_param("/init_joint_pose2/shp")
        shl_init_value2 = rospy.get_param("/init_joint_pose2/shl")
        elb_init_value2 = rospy.get_param("/init_joint_pose2/elb")
        wr1_init_value2 = rospy.get_param("/init_joint_pose2/wr1")
        wr2_init_value2 = rospy.get_param("/init_joint_pose2/wr2")
        wr3_init_value2 = rospy.get_param("/init_joint_pose2/wr3")
        self.init_joint_pose2 = [
            shp_init_value2, shl_init_value2, elb_init_value2, wr1_init_value2,
            wr2_init_value2, wr3_init_value2
        ]

        r_drv_value1 = rospy.get_param("/init_grp_pose1/r_drive")
        l_drv_value1 = rospy.get_param("/init_grp_pose1/l_drive")
        r_flw_value1 = rospy.get_param("/init_grp_pose1/r_follower")
        l_flw_value1 = rospy.get_param("/init_grp_pose1/l_follower")
        r_spr_value1 = rospy.get_param("/init_grp_pose1/r_spring")
        l_spr_value1 = rospy.get_param("/init_grp_pose1/l_spring")

        r_drv_value2 = rospy.get_param("/init_grp_pose2/r_drive")
        l_drv_value2 = rospy.get_param("/init_grp_pose2/l_drive")
        r_flw_value2 = rospy.get_param("/init_grp_pose2/r_follower")
        l_flw_value2 = rospy.get_param("/init_grp_pose2/l_follower")
        r_spr_value2 = rospy.get_param("/init_grp_pose2/r_spring")
        l_spr_value2 = rospy.get_param("/init_grp_pose2/l_spring")

        init_pos0 = self.init_joints_pose(self.init_joint_pose0)
        self.arr_init_pos0 = np.array(init_pos0, dtype='float32')
        init_pos1 = self.init_joints_pose(self.init_joint_pose1)
        self.arr_init_pos1 = np.array(init_pos1, dtype='float32')
        init_pos2 = self.init_joints_pose(self.init_joint_pose2)
        self.arr_init_pos2 = np.array(init_pos2, dtype='float32')

        self.init_grp_pose1 = [
            r_drv_value1, l_drv_value1, r_flw_value1, l_flw_value1,
            r_spr_value1, l_spr_value1
        ]
        self.init_grp_pose2 = [
            r_drv_value2, l_drv_value2, r_flw_value2, l_flw_value2,
            r_spr_value2, l_spr_value2
        ]

        init_g_pos1 = self.init_joints_pose(self.init_grp_pose1)
        self.arr_init_g_pos1 = np.array(init_g_pos1, dtype='float32')
        init_g_pos2 = self.init_joints_pose(self.init_grp_pose2)
        self.arr_init_g_pos2 = np.array(init_g_pos2, dtype='float32')

        # Fill in the Done Episode Criteria list
        self.episode_done_criteria = rospy.get_param("/episode_done_criteria")

        # stablishes connection with simulator
        self._gz_conn = GazeboConnection()
        self._ctrl_conn = ControllersConnection(namespace="")

        # Controller type for ros_control
        self._ctrl_type = rospy.get_param("/control_type")
        self.pre_ctrl_type = self._ctrl_type

        # Get the force and troque limit
        self.force_limit = rospy.get_param("/force_limit")
        self.torque_limit = rospy.get_param("/torque_limit")

        # Get tolerances of door_frame
        self.tolerances = rospy.get_param("/door_frame_tolerances")

        # Get observation parameters
        self.joint_n = rospy.get_param("/obs_params/joint_n")
        self.eef_n = rospy.get_param("/obs_params/eef_n")
        self.eef_rpy_n = rospy.get_param("/obs_params/eef_rpy_n")
        self.force_n = rospy.get_param("/obs_params/force_n")
        self.torque_n = rospy.get_param("/obs_params/torque_n")
        self.image_n = rospy.get_param("/obs_params/image_n")
        self.min_static_limit = rospy.get_param("/min_static_limit")
        self.max_static_limit = rospy.get_param("/max_static_limit")

        # We init the observations
        self.base_orientation = Quaternion()
        self.imu_link = Quaternion()
        self.door = Quaternion()
        self.door_frame = Point()
        self.quat = Quaternion()
        self.imu_link_rpy = Vector3()
        self.door_rpy = Vector3()
        self.link_state = LinkStates()
        self.wrench_stamped = WrenchStamped()
        self.joints_state = JointState()
        self.right_image = Image()
        self.right_image_ini = []
        self.left_image = Image()
        self.lift_image_ini = []
        self.end_effector = Point()
        self.previous_action = copy.deepcopy(self.arr_init_pos2)
        self.counter = 0
        self.max_rewards = 1

        # Arm/Control parameters
        self._ik_params = setups['UR5_6dof']['ik_params']

        # ROS msg type
        self._joint_pubisher = JointPub()
        self._joint_traj_pubisher = JointTrajPub()

        # Gym interface and action
        self.action_space = spaces.Discrete(n_act)
        self.observation_space = obs_dim  #np.arange(self.get_observations().shape[0])
        self.reward_range = (-np.inf, np.inf)
        self._seed()

        # Change the controller type
        set_joint_pos_server = rospy.Service('/set_position_controller',
                                             SetBool, self._set_pos_ctrl)
        set_joint_traj_pos_server = rospy.Service(
            '/set_trajectory_position_controller', SetBool,
            self._set_traj_pos_ctrl)
        set_joint_vel_server = rospy.Service('/set_velocity_controller',
                                             SetBool, self._set_vel_ctrl)
        set_joint_traj_vel_server = rospy.Service(
            '/set_trajectory_velocity_controller', SetBool,
            self._set_traj_vel_ctrl)

        self.pos_traj_controller = [
            'joint_state_controller', 'gripper_controller',
            'pos_traj_controller'
        ]
        self.pos_controller = [
            "joint_state_controller", "gripper_controller",
            "ur_shoulder_pan_pos_controller",
            "ur_shoulder_lift_pos_controller", "ur_elbow_pos_controller",
            "ur_wrist_1_pos_controller", "ur_wrist_2_pos_controller",
            "ur_wrist_3_pos_controller"
        ]
        self.vel_traj_controller = [
            'joint_state_controller', 'gripper_controller',
            'vel_traj_controller'
        ]
        self.vel_controller = [
            "joint_state_controller", "gripper_controller",
            "ur_shoulder_pan_vel_controller",
            "ur_shoulder_lift_vel_controller", "ur_elbow_vel_controller",
            "ur_wrist_1_vel_controller", "ur_wrist_2_vel_controller",
            "ur_wrist_3_vel_controller"
        ]

        # Helpful False
        self.stop_flag = False
        stop_trainning_server = rospy.Service('/stop_training', SetBool,
                                              self._stop_trainnig)
        start_trainning_server = rospy.Service('/start_training', SetBool,
                                               self._start_trainnig)

    def check_stop_flg(self):
        if self.stop_flag is False:
            return False
        else:
            return True

    def _start_trainnig(self, req):
        rospy.logdebug("_start_trainnig!!!!")
        self.stop_flag = False
        return SetBoolResponse(True, "_start_trainnig")

    def _stop_trainnig(self, req):
        rospy.logdebug("_stop_trainnig!!!!")
        self.stop_flag = True
        return SetBoolResponse(True, "_stop_trainnig")

    def _set_pos_ctrl(self, req):
        rospy.wait_for_service('set_position_controller')
        self._ctrl_conn.stop_controllers(self.pos_traj_controller)
        self._ctrl_conn.start_controllers(self.pos_controller)
        self._ctrl_type = 'pos'
        return SetBoolResponse(True, "_set_pos_ctrl")

    def _set_traj_pos_ctrl(self, req):
        rospy.wait_for_service('set_trajectory_position_controller')
        self._ctrl_conn.stop_controllers(self.pos_controller)
        self._ctrl_conn.start_controllers(self.pos_traj_controller)
        self._ctrl_type = 'traj_pos'
        return SetBoolResponse(True, "_set_traj_pos_ctrl")

    def _set_vel_ctrl(self, req):
        rospy.wait_for_service('set_velocity_controller')
        self._ctrl_conn.stop_controllers(self.vel_traj_controller)
        self._ctrl_conn.start_controllers(self.vel_controller)
        self._ctrl_type = 'vel'
        return SetBoolResponse(True, "_set_vel_ctrl")

    def _set_traj_vel_ctrl(self, req):
        rospy.wait_for_service('set_trajectory_velocity_controller')
        self._ctrl_conn.stop_controllers(self.vel_controller)
        self._ctrl_conn.start_controllers(self.vel_traj_controller)
        self._ctrl_type = 'traj_vel'
        return SetBoolResponse(True, "_set_traj_vel_ctrl")

    # A function to initialize the random generator
    def _seed(self, seed=None):
        self.np_random, seed = seeding.np_random(seed)
        return [seed]

    def check_all_systems_ready(self):
        """
        We check that all systems are ready
        :return:
        """
        joint_states_msg = None
        while joint_states_msg is None and not rospy.is_shutdown():
            try:
                joint_states_msg = rospy.wait_for_message("/joint_states",
                                                          JointState,
                                                          timeout=0.1)
                self.joints_state = joint_states_msg
                rospy.logdebug("Current joint_states READY")
            except Exception as e:
                self._ctrl_conn.start_controllers(
                    controllers_on="joint_state_controller")
                rospy.logdebug(
                    "Current joint_states not ready yet, retrying==>" + str(e))

        link_states_msg = None
        while link_states_msg is None and not rospy.is_shutdown():
            try:
                link_states_msg = rospy.wait_for_message("/gazebo/link_states",
                                                         LinkStates,
                                                         timeout=0.1)
                self.link_states = link_states_msg
                rospy.logdebug("Reading link_states READY")
            except Exception as e:
                rospy.logdebug(
                    "Reading link_states not ready yet, retrying==>" + str(e))

        rospy.logdebug("ALL SYSTEMS READY")

    def get_xyz(self, q):
        """Get x,y,z coordinates 
        Args:
            q: a numpy array of joints angle positions.
        Returns:
            xyz are the x,y,z coordinates of an end-effector in a Cartesian space.
        """
        mat = ur_utils.forward(q, self._ik_params)
        xyz = mat[:3, 3]
        return xyz

    def get_current_xyz(self):
        """Get x,y,z coordinates according to currrent joint angles
        Returns:
        xyz are the x,y,z coordinates of an end-effector in a Cartesian space.
        """
        joint_states = self.joints_state
        shp_joint_ang = joint_states.position[0]
        shl_joint_ang = joint_states.position[1]
        elb_joint_ang = joint_states.position[2]
        wr1_joint_ang = joint_states.position[3]
        wr2_joint_ang = joint_states.position[4]
        wr3_joint_ang = joint_states.position[5]

        q = [
            shp_joint_ang, shl_joint_ang, elb_joint_ang, wr1_joint_ang,
            wr2_joint_ang, wr3_joint_ang
        ]
        mat = ur_utils.forward(q, self._ik_params)
        xyz = mat[:3, 3]
        return xyz

    def get_orientation(self, q):
        """Get Euler angles 
        Args:
            q: a numpy array of joints angle positions.
        Returns:
            xyz are the x,y,z coordinates of an end-effector in a Cartesian space.
        """
        mat = ur_utils.forward(q, self._ik_params)
        orientation = mat[0:3, 0:3]
        roll = -orientation[1, 2]
        pitch = orientation[0, 2]
        yaw = -orientation[0, 1]

        return Vector3(roll, pitch, yaw)

    def cvt_quat_to_euler(self, quat):
        euler_rpy = Vector3()
        euler = euler_from_quaternion(
            [self.quat.x, self.quat.y, self.quat.z, self.quat.w])

        euler_rpy.x = euler[0]
        euler_rpy.y = euler[1]
        euler_rpy.z = euler[2]
        return euler_rpy

    def init_joints_pose(self, init_pos):
        """
        We initialise the Position variable that saves the desired position where we want our
        joints to be
        :param init_pos:
        :return:
        """
        self.current_joint_pose = []
        self.current_joint_pose = copy.deepcopy(init_pos)
        return self.current_joint_pose

    def get_euclidean_dist(self, p_in, p_pout):
        """
        Given a Vector3 Object, get distance from current position
        :param p_end:
        :return:
        """
        a = numpy.array((p_in.x, p_in.y, p_in.z))
        b = numpy.array((p_pout.x, p_pout.y, p_pout.z))

        distance = numpy.linalg.norm(a - b)

        return distance

    def joints_state_callback(self, msg):
        self.joints_state = msg

    def wrench_stamped_callback(self, msg):
        self.wrench_stamped = msg

    def link_state_callback(self, msg):
        self.link_state = msg
        self.end_effector = self.link_state.pose[12]
        self.imu_link = self.link_state.pose[5]
        self.door_frame = self.link_state.pose[1]
        self.door = self.link_state.pose[2]

    def r_image_callback(self, msg):
        self.right_image = msg

    def l_image_callback(self, msg):
        self.left_image = msg

    def get_observations(self):
        """
        Returns the state of the robot needed for OpenAI QLearn Algorithm
        The state will be defined by an array
        :return: observation
        """
        joint_states = self.joints_state
        eef_rpy = Vector3()

        self.force = self.wrench_stamped.wrench.force
        self.torque = self.wrench_stamped.wrench.torque
        #        print("[force]", self.force.x, self.force.y, self.force.z)
        #        print("[torque]", self.torque.x, self.torque.y, self.torque.z)

        shp_joint_ang = joint_states.position[2]
        shl_joint_ang = joint_states.position[1]
        elb_joint_ang = joint_states.position[0]
        wr1_joint_ang = joint_states.position[9]
        wr2_joint_ang = joint_states.position[10]
        wr3_joint_ang = joint_states.position[11]

        shp_joint_vel = joint_states.velocity[2]
        shl_joint_vel = joint_states.velocity[1]
        elb_joint_vel = joint_states.velocity[0]
        wr1_joint_vel = joint_states.velocity[9]
        wr2_joint_vel = joint_states.velocity[10]
        wr3_joint_vel = joint_states.velocity[11]

        q = [
            shp_joint_ang, shl_joint_ang, elb_joint_ang, wr1_joint_ang,
            wr2_joint_ang, wr3_joint_ang
        ]
        eef_x, eef_y, eef_z = self.get_xyz(q)
        eef_x_ini, eef_y_ini, eef_z_ini = self.get_xyz(self.init_joint_pose2)

        eef_rpy = self.get_orientation(q)
        eef_rpy_ini = self.get_orientation(self.init_joint_pose2)
        r_image = self.right_image
        l_image = self.left_image

        observation = []
        #        rospy.logdebug("List of Observations==>"+str(self.observations))
        for obs_name in self.observations:
            if obs_name == "shp_joint_ang":
                observation.append(
                    (shp_joint_ang - self.init_joint_pose2[0]) * self.joint_n)
            elif obs_name == "shl_joint_ang":
                observation.append(
                    (shl_joint_ang - self.init_joint_pose2[1]) * self.joint_n)
            elif obs_name == "elb_joint_ang":
                observation.append(
                    (elb_joint_ang - self.init_joint_pose2[2]) * self.joint_n)
            elif obs_name == "wr1_joint_ang":
                observation.append(
                    (wr1_joint_ang - self.init_joint_pose2[3]) * self.joint_n)
            elif obs_name == "wr2_joint_ang":
                observation.append(
                    (wr2_joint_ang - self.init_joint_pose2[4]) * self.joint_n)
            elif obs_name == "wr3_joint_ang":
                observation.append(
                    (wr3_joint_ang - self.init_joint_pose2[5]) * self.joint_n)
            elif obs_name == "shp_joint_vel":
                observation.append(shp_joint_vel)
            elif obs_name == "shl_joint_vel":
                observation.append(shl_joint_vel)
            elif obs_name == "elb_joint_vel":
                observation.append(elb_joint_vel)
            elif obs_name == "wr1_joint_vel":
                observation.append(wr1_joint_vel)
            elif obs_name == "wr2_joint_vel":
                observation.append(wr2_joint_vel)
            elif obs_name == "wr3_joint_vel":
                observation.append(wr3_joint_vel)
            elif obs_name == "eef_x":
                observation.append((eef_x - eef_x_ini) * self.eef_n)
            elif obs_name == "eef_y":
                observation.append((eef_y - eef_y_ini) * self.eef_n)
            elif obs_name == "eef_z":
                observation.append((eef_z - eef_z_ini) * self.eef_n)
            elif obs_name == "eef_rpy_x":
                observation.append(
                    (eef_rpy.x - eef_rpy_ini.x) * self.eef_rpy_n)
            elif obs_name == "eef_rpy_y":
                observation.append(
                    (eef_rpy.y - eef_rpy_ini.y) * self.eef_rpy_n)
            elif obs_name == "eef_rpy_z":
                observation.append(
                    (eef_rpy.z - eef_rpy_ini.z) * self.eef_rpy_n)
            elif obs_name == "force_x":
                observation.append((self.force.x - self.force_ini.x) /
                                   self.force_limit * self.force_n)
            elif obs_name == "force_y":
                observation.append((self.force.y - self.force_ini.y) /
                                   self.force_limit * self.force_n)
            elif obs_name == "force_z":
                observation.append((self.force.z - self.force_ini.z) /
                                   self.force_limit * self.force_n)
            elif obs_name == "torque_x":
                observation.append((self.torque.x - self.torque_ini.x) /
                                   self.torque_limit * self.torque_n)
            elif obs_name == "torque_y":
                observation.append((self.torque.y - self.torque_ini.y) /
                                   self.torque_limit * self.torque_n)
            elif obs_name == "torque_z":
                observation.append((self.torque.z - self.torque_ini.z) /
                                   self.torque_limit * self.torque_n)
            elif obs_name == "image_data":
                for x in range(0, 28):
                    observation.append(
                        (ord(r_image.data[x]) -
                         ord(self.right_image_ini.data[x])) * self.image_n)
                for x in range(0, 28):
                    observation.append(
                        (ord(l_image.data[x]) -
                         ord(self.left_image_ini.data[x])) * self.image_n)
            else:
                raise NameError('Observation Asked does not exist==' +
                                str(obs_name))
#        print("observation", list(map(round, observation, [3]*len(observation))))

        return observation

    def clamp_to_joint_limits(self):
        """
        clamps self.current_joint_pose based on the joint limits
        self._joint_limits
        {
         "shp_max": shp_max,
         "shp_min": shp_min,
         ...
         }
        :return:
        """

        rospy.logdebug("Clamping current_joint_pose>>>" +
                       str(self.current_joint_pose))
        shp_joint_value = self.current_joint_pose[0]
        shl_joint_value = self.current_joint_pose[1]
        elb_joint_value = self.current_joint_pose[2]
        wr1_joint_value = self.current_joint_pose[3]
        wr2_joint_value = self.current_joint_pose[4]
        wr3_joint_value = self.current_joint_pose[5]

        self.current_joint_pose[0] = max(
            min(shp_joint_value, self._joint_limits["shp_max"]),
            self._joint_limits["shp_min"])
        self.current_joint_pose[1] = max(
            min(shl_joint_value, self._joint_limits["shl_max"]),
            self._joint_limits["shl_min"])
        self.current_joint_pose[2] = max(
            min(elb_joint_value, self._joint_limits["elb_max"]),
            self._joint_limits["elb_min"])
        self.current_joint_pose[3] = max(
            min(wr1_joint_value, self._joint_limits["wr1_max"]),
            self._joint_limits["wr1_min"])
        self.current_joint_pose[4] = max(
            min(wr2_joint_value, self._joint_limits["wr2_max"]),
            self._joint_limits["wr2_min"])
        self.current_joint_pose[5] = max(
            min(wr3_joint_value, self._joint_limits["wr3_max"]),
            self._joint_limits["wr3_min"])

        rospy.logdebug("DONE Clamping current_joint_pose>>>" +
                       str(self.current_joint_pose))

    def first_reset(self):
        #        print("first reset")
        jointtrajpub = JointTrajPub()
        for update in range(500):
            jointtrajpub.jointTrajectoryCommand_reset(self.arr_init_pos0)
        time.sleep(0.5)
        for update in range(300):
            jointtrajpub.jointTrajectoryCommand_reset(self.arr_init_pos1)
        time.sleep(0.5)

    # Resets the state of the environment and returns an initial observation.
    def reset(self):
        self.max_knob_rotation = 0
        self.max_door_rotation = 0
        self.max_wirst3 = 0
        self.min_wirst3 = 0
        self.max_wirst2 = 0
        self.min_wirst2 = 0
        self.max_wirst1 = 0
        self.min_wirst1 = 0
        self.max_elb = 0
        self.min_elb = 0
        self.max_shl = 0
        self.min_shl = 0
        self.max_shp = 0
        self.min_shp = 0
        self.max_force_x = 0
        self.min_force_x = 0
        self.max_force_y = 0
        self.min_force_y = 0
        self.max_force_z = 0
        self.min_force_z = 0
        self.max_torque_x = 0
        self.min_torque_x = 0
        self.max_torque_y = 0
        self.min_torque_y = 0
        self.max_torque_z = 0
        self.min_torque_z = 0
        # Go to initial position
        self._gz_conn.unpauseSim()
        #        rospy.logdebug("set_init_pose init variable...>>>" + str(self.init_joint_pose0))
        jointtrajpub = JointTrajPub()
        for update in range(200):
            jointtrajpub.GrpCommand(self.arr_init_g_pos1)
#        time.sleep(1)
        for update in range(300):
            jointtrajpub.jointTrajectoryCommand_reset(self.arr_init_pos2)
        time.sleep(1)
        for update in range(300):
            jointtrajpub.jointTrajectoryCommand_reset(self.arr_init_pos1)
        time.sleep(1)

        # 0st: We pause the Simulator
        #        rospy.logdebug("Pausing SIM...")
        self._gz_conn.pauseSim()

        # 1st: resets the simulation to initial values
        #        rospy.logdebug("Reset SIM...")
        self._gz_conn.resetSim()

        # 2nd: We Set the gravity to 0.0 so that we dont fall when reseting joints
        # It also UNPAUSES the simulation
        #        rospy.logdebug("Remove Gravity...")
        self._gz_conn.change_gravity_zero()

        # EXTRA: Reset JoinStateControlers because sim reset doesnt reset TFs, generating time problems
        #        rospy.logdebug("reset_ur_joint_controllers...")
        self._ctrl_conn.reset_ur_joint_controllers(self._ctrl_type)

        # 3rd: resets the robot to initial conditions
        #        rospy.logdebug("set_init_pose init variable...>>>" + str(self.init_joint_pose1))
        #        rospy.logdebug("set_init_pose init variable...>>>" + str(self.init_joint_pose2))

        self.force = self.wrench_stamped.wrench.force
        self.torque = self.wrench_stamped.wrench.torque
        #        print("self.force", self.force)
        #        print("self.torque", self.torque)

        self.force_ini = copy.deepcopy(self.force)
        self.torque_ini = copy.deepcopy(self.torque)

        # We save that position as the current joint desired position

        # 4th: We Set the init pose to the jump topic so that the jump control can update
        # We check the jump publisher has connection

        if self._ctrl_type == 'traj_pos':
            self._joint_traj_pubisher.check_publishers_connection()
        elif self._ctrl_type == 'pos':
            self._joint_pubisher.check_publishers_connection()
        elif self._ctrl_type == 'traj_vel':
            self._joint_traj_pubisher.check_publishers_connection()
        elif self._ctrl_type == 'vel':
            self._joint_pubisher.check_publishers_connection()
        else:
            rospy.logwarn("Controller type is wrong!!!!")

        # 5th: Check all subscribers work.
        # Get the state of the Robot defined by its RPY orientation, distance from
        # desired point, contact force and JointState of the three joints
#        rospy.logdebug("check_all_systems_ready...")
        self.check_all_systems_ready()

        # 6th: We restore the gravity to original
        #        rospy.logdebug("Restore Gravity...")
        self._gz_conn.adjust_gravity()

        for update in range(300):
            jointtrajpub.jointTrajectoryCommand_reset(self.arr_init_pos2)
        time.sleep(1)
        for update in range(200):
            jointtrajpub.GrpCommand(self.arr_init_g_pos2)
        time.sleep(1)

        # 7th: pauses simulation
        #        rospy.logdebug("Pause SIM...")
        self._gz_conn.pauseSim()

        self.right_image_ini = copy.deepcopy(self.right_image)
        self.left_image_ini = copy.deepcopy(self.left_image)

        # 8th: Get the State Discrete Stringuified version of the observations
        #        rospy.logdebug("get_observations...")
        observation = self.get_observations()
        #        print("[observations]", observation)

        return observation

    def _act(self, action):
        if self._ctrl_type == 'traj_pos':
            self.pre_ctrl_type = 'traj_pos'
            self._joint_traj_pubisher.jointTrajectoryCommand(action)
        elif self._ctrl_type == 'pos':
            self.pre_ctrl_type = 'pos'
            self._joint_pubisher.move_joints(action)
        elif self._ctrl_type == 'traj_vel':
            self.pre_ctrl_type = 'traj_vel'
            self._joint_traj_pubisher.jointTrajectoryCommand(action)
        elif self._ctrl_type == 'vel':
            self.pre_ctrl_type = 'vel'
            self._joint_pubisher.move_joints(action)
        else:
            self._joint_pubisher.move_joints(action)

    def training_ok(self):
        rate = rospy.Rate(1)
        while self.check_stop_flg() is True:
            rospy.logdebug("stop_flag is ON!!!!")
            self._gz_conn.unpauseSim()

            if self.check_stop_flg() is False:
                break
            rate.sleep()

    def step(self, action, update):
        '''
        ('action: ', array([ 0.,  0. , -0., -0., -0. , 0. ], dtype=float32))        
        '''
        #        rospy.logdebug("UR step func")	# define the logger
        self.training_ok()

        # Given the action selected by the learning algorithm,
        # we perform the corresponding movement of the robot
        # Act
        self._gz_conn.unpauseSim()

        if self.max_wirst3 < action[5]:
            self.max_wirst3 = action[5]
        if self.min_wirst3 > action[5]:
            self.min_wirst3 = action[5]
        if self.max_wirst2 < action[4]:
            self.max_wirst2 = action[4]
        if self.min_wirst2 > action[4]:
            self.min_wirst2 = action[4]
        if self.max_wirst1 < action[3]:
            self.max_wirst1 = action[3]
        if self.min_wirst1 > action[3]:
            self.min_wirst1 = action[3]
        if self.max_elb < action[2]:
            self.max_elb = action[2]
        if self.min_elb > action[2]:
            self.min_elb = action[2]
        if self.max_shl < action[1]:
            self.max_shl = action[1]
        if self.min_shl > action[1]:
            self.min_shl = action[1]
        if self.max_shp < action[0]:
            self.max_shp = action[0]
        if self.min_shp > action[0]:
            self.min_shp = action[0]

#        print("action", action)

        action = action + self.arr_init_pos2
        #        action = [1.488122534496775, -1.4496597816566892, 2.4377209990850974, 2.168370898415174, -1.4670589583209175, 1.4]
        self._act(action)

        self.wrench_stamped
        self.force = self.wrench_stamped.wrench.force
        self.torque = self.wrench_stamped.wrench.torque
        #        print("force", self.force)
        #        print("torque", self.torque)

        if self.max_force_x < self.force.x:
            self.max_force_x = self.force.x
        if self.min_force_x > self.force.x:
            self.min_force_x = self.force.x
        if self.max_force_y < self.force.y:
            self.max_force_y = self.force.y
        if self.min_force_y > self.force.y:
            self.min_force_y = self.force.y
        if self.max_force_z < self.force.z:
            self.max_force_z = self.force.z
        if self.min_force_z > self.force.z:
            self.min_force_z = self.force.z
        if self.max_torque_x < self.torque.x:
            self.max_torque_x = self.torque.x
        if self.min_torque_x > self.torque.x:
            self.min_torque_x = self.torque.x
        if self.max_torque_y < self.torque.y:
            self.max_torque_y = self.torque.y
        if self.min_torque_y > self.torque.y:
            self.min_torque_y = self.torque.y
        if self.max_torque_z < self.torque.z:
            self.max_torque_z = self.torque.z
        if self.min_torque_z > self.torque.z:
            self.min_torque_z = self.torque.z

        if self.force_limit < self.force.x or self.force.x < -self.force_limit:
            self._act(self.previous_action)
#        	print("force.x over the limit")
        elif self.force_limit < self.force.y or self.force.y < -self.force_limit:
            self._act(self.previous_action)
#        	print("force.y over the limit")
        elif self.force_limit < self.force.z or self.force.z < -self.force_limit:
            self._act(self.previous_action)
#        	print("force.z over the limit")
        elif self.torque_limit < self.torque.x or self.torque.x < -self.torque_limit:
            self._act(self.previous_action)
#        	print("torque.x over the limit")
        elif self.torque_limit < self.torque.y or self.torque.y < -self.torque_limit:
            self._act(self.previous_action)
#        	print("torque.y over the limit")
        elif self.torque_limit < self.torque.z or self.torque.z < -self.torque_limit:
            self._act(self.previous_action)
#        	print("torque.z over the limit")
        else:
            self.previous_action = copy.deepcopy(action)
#        	print("True")

        self.min_static_taxel0 = 0
        self.min_static_taxel1 = 0
        self.max_static_taxel0 = 0
        self.max_static_taxel1 = 0
        r_image = self.right_image
        l_image = self.left_image

        for x in range(0, 28):
            if self.min_static_taxel0 > (ord(r_image.data[x]) - ord(
                    self.right_image_ini.data[x])) * self.image_n:
                self.min_static_taxel0 = (ord(r_image.data[x]) - ord(
                    self.right_image_ini.data[x])) * self.image_n
            if self.min_static_taxel1 > (ord(l_image.data[x]) - ord(
                    self.left_image_ini.data[x])) * self.image_n:
                self.min_static_taxel1 = (ord(l_image.data[x]) - ord(
                    self.left_image_ini.data[x])) * self.image_n
            if self.max_static_taxel0 < (ord(r_image.data[x]) - ord(
                    self.right_image_ini.data[x])) * self.image_n:
                self.max_static_taxel0 = (ord(r_image.data[x]) - ord(
                    self.right_image_ini.data[x])) * self.image_n
            if self.max_static_taxel1 < (ord(l_image.data[x]) - ord(
                    self.left_image_ini.data[x])) * self.image_n:
                self.max_static_taxel1 = (ord(l_image.data[x]) - ord(
                    self.left_image_ini.data[x])) * self.image_n
#        print("min, max taxel", self.min_static_taxel0, self.max_static_taxel0, self.min_static_taxel1, self.max_static_taxel1)

# Then we send the command to the robot and let it go for running_step seconds
        time.sleep(self.running_step)
        self._gz_conn.pauseSim()

        # We now process the latest data saved in the class state to calculate
        # the state and the rewards. This way we guarantee that they work
        # with the same exact data.
        # Generate State based on observations
        observation = self.get_observations()

        # finally we get an evaluation based on what happened in the sim
        reward = self.compute_dist_rewards(action, update)
        done = self.check_done(update)

        return observation, reward, done, {}

    def compute_dist_rewards(self, action, update):
        self.quat = self.door.orientation
        self.door_rpy = self.cvt_quat_to_euler(self.quat)
        self.quat = self.imu_link.orientation
        self.imu_link_rpy = self.cvt_quat_to_euler(self.quat)
        compute_rewards = 0

        knob_c = 100  #1 rotation of knob(+)
        knob_bonus_c = 10  #2 bonus of knob rotation(+)
        panel_c = 50  #3 door panel open(+)
        panel_b_c = 50  #4 door panel before open(-)
        tolerances_c = 50  #5 movement of door frame(-)
        force_c = 1  #6 over force limit1(-)
        taxel_c = 100  #7 release the knob(-)
        act_0_n = 10  #8 action[0] (-)
        act_1_n = 10  #  action[1] (-)
        act_2_n = 10  #  action[2] (-)
        act_3_n = 10  #  action[3] (-)
        act_4_n = 10  #  action[4] (-)
        act_5_n = 10  #  action[5] (-)

        #1 rotation of knob(+), #2 bonus of knob rotation(+), #3 door panel open(+),
        if self.imu_link_rpy.x < 0.8:
            compute_rewards = self.imu_link_rpy.x * knob_c
            print("reward_knob_rotation", compute_rewards)
            if 0.4 > self.imu_link_rpy.x > 0.2:
                compute_rewards = self.imu_link_rpy.x * knob_c + knob_bonus_c
            elif 0.6 > self.imu_link_rpy.x > 0.4:
                compute_rewards = self.imu_link_rpy.x * knob_c + knob_bonus_c * 2
            elif 0.8 > self.imu_link_rpy.x > 0.6:
                compute_rewards = self.imu_link_rpy.x * knob_c + knob_bonus_c * 3
        else:
            compute_rewards = 0.8 * knob_c + knob_bonus_c * 3 + (
                1.5708061 - self.imu_link_rpy.z) * panel_c

        #5 movement of door frame(-)
        if abs(self.door_frame.position.x + 0.0659) > self.tolerances or abs(
                self.door_frame.position.y -
                0.5649) > self.tolerances or abs(self.door_frame.position.z -
                                                 0.0999) > self.tolerances:
            compute_rewards -= tolerances_c * (n_step -
                                               update) / n_step + tolerances_c
            print("door_frame limit", compute_rewards)

        #6 over force limit1(-)
        if self.force_limit < self.force.x or self.force.x < -self.force_limit:
            compute_rewards -= force_c * (n_step - update) / n_step + force_c
            print("force_x limit", compute_rewards)
        if self.force_limit < self.force.y or self.force.y < -self.force_limit:
            compute_rewards -= force_c * (n_step - update) / n_step + force_c
            print("force_y limit", compute_rewards)
        if self.force_limit < self.force.z or self.force.z < -self.force_limit:
            compute_rewards -= force_c * (n_step - update) / n_step + force_c
            print("force_z limit", compute_rewards)
        if self.torque_limit < self.torque.x or self.torque.x < -self.torque_limit:
            compute_rewards -= force_c * (n_step - update) / n_step + force_c
            print("torque_x limit", compute_rewards)
        if self.torque_limit < self.torque.y or self.torque.y < -self.torque_limit:
            compute_rewards -= force_c * (n_step - update) / n_step + force_c
            print("torque_y limit", compute_rewards)
        if self.torque_limit < self.torque.z or self.torque.z < -self.torque_limit:
            compute_rewards -= force_c * (n_step - update) / n_step + force_c
            print("torque_z limit", compute_rewards)

        #7 release the knob(-)
        if self.min_static_taxel0 < self.min_static_limit and self.min_static_taxel1 < self.min_static_limit:
            compute_rewards -= taxel_c * (n_step - update) / n_step + taxel_c
            print("min_static limit", compute_rewards)
        if self.max_static_taxel0 > self.max_static_limit and self.max_static_taxel1 > self.max_static_limit:
            compute_rewards -= taxel_c * (n_step - update) / n_step + taxel_c
            print("max_static limit", compute_rewards)

        #8 joint(+, -)
        action = action - self.arr_init_pos2
        if action[5] < -0.005:
            compute_rewards -= (-0.005 - action[5]) * act_5_n
            print("action5 limit", compute_rewards)
        elif 1 < action[5]:
            compute_rewards -= (action[5] - 1) * act_5_n
            print("action5 limit", compute_rewards)
        if action[4] < -0.005:
            compute_rewards -= (-0.005 - action[4]) * act_4_n
            print("action4 limit", compute_rewards)
        elif 0.03 < action[4]:
            compute_rewards -= (action[4] - 0.03) * act_4_n
            print("action4 limit", compute_rewards)
        if action[3] < -0.023:
            compute_rewards -= (-0.023 - action[3]) * act_3_n
            print("action3 limit", compute_rewards)
        elif 0.005 < action[3]:
            compute_rewards -= (action[3] - 0.005) * act_3_n
            print("action3 limit", compute_rewards)
        if action[2] < -0.005:
            compute_rewards -= (-0.005 - action[2]) * act_2_n
            print("action2 limit", compute_rewards)
        elif 0.14 < action[2]:
            compute_rewards -= (action[2] - 0.14) * act_2_n
            print("action2 limit", compute_rewards)
        if action[1] < -0.11:
            compute_rewards -= (-0.11 - action[1]) * act_1_n
            print("action1 limit", compute_rewards)
        elif 0.005 < action[1]:
            compute_rewards -= (action[1] - 0.005) * act_1_n
            print("action1 limit", compute_rewards)
        if action[0] < -0.015:
            compute_rewards -= (-0.015 - action[0]) * act_0_n
            print("action0 limit", compute_rewards)
        if 0.005 < action[0]:
            compute_rewards -= (action[0] - 0.005) * act_0_n
            print("action0 limit", compute_rewards)

        if self.max_knob_rotation < self.imu_link_rpy.x:
            self.max_knob_rotation = self.imu_link_rpy.x
        if self.max_door_rotation < 1.5708061 - self.imu_link_rpy.z:
            self.max_door_rotation = 1.5708061 - self.imu_link_rpy.z
#        print("imu_link_rpy", self.imu_link_rpy)
#        print("door_frame", self.door_frame.position.x + 0.0659, self.door_frame.position.y - 0.5649, self.door_frame.position.z - 0.0999)

        return compute_rewards

    def check_done(self, update):
        if update > 1:
            if abs(self.door_frame.position.x + 0.0659
                   ) > self.tolerances or abs(self.door_frame.position.y -
                                              0.5649) > self.tolerances or abs(
                                                  self.door_frame.position.z -
                                                  0.0999) > self.tolerances:
                print(
                    "########## door frame position over the limit ##########",
                    update)
                return True
            elif self.min_static_taxel0 < self.min_static_limit and self.min_static_taxel1 < self.min_static_limit:
                print("########## static_taxles over the min_limit ##########",
                      update)
                return True
            elif self.max_static_taxel0 > self.max_static_limit and self.max_static_taxel1 > self.max_static_limit:
                print("########## static_taxles over the max_limit ##########",
                      update)
                return True
            else:
                return False
        else:
            return False