Exemplo n.º 1
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 def set_time(TestStorage, value):
     wanted_time = rospy.Time(value)
     c = Clock()
     c.clock = wanted_time
     while rospy.Time.now() != wanted_time:
         TestStorage.pub.publish(c)
         time.sleep(0.01)
Exemplo n.º 2
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    def default(self, ci='unused'):
        """ Publish the simulator clock as a Clock ROS message """
        msg = Clock()
        msg.clock = rospy.Time.from_sec(self._sim_time)
        self._sim_time += self._sim_step

        self.publish(msg)
    def _publishClock(self, clockRate):
        print 'Starting to publish simulated time on /clock and setting /use_sim_time to true.'
        print 'Simulated time is running at %fx speed.' % clockRate
        clockPublisher = rospy.Publisher( "/clock", Clock, queue_size=1 )

        if self.timingMode == LogfilePublisher.TimingMode.use_timestamps:
            while isinf(self._earliestTimestamp):
                time.sleep(0.01)
            currentSecs = self._earliestTimestamp - 0.5
        else:
            currentSecs = time.time()

        lastRealTime = time.time()
        while not rospy.is_shutdown():
            currentRealTime = time.time()
            elapsedRealTime = currentRealTime - lastRealTime
            lastRealTime = currentRealTime
            
            if not self._paused or self._singleStep:
                currentSecs += elapsedRealTime * clockRate

            clock = Clock()
            clock.clock = rospy.Time.from_sec(currentSecs) 
            try:
                clockPublisher.publish(clock)
            except Exception:
                print 'Publisher closed' 
            time.sleep(0.01)
Exemplo n.º 4
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    def _publishClock(self, clockRate):
        print 'Starting to publish simulated time on /clock and setting /use_sim_time to true.'
        print 'Simulated time is running at %fx speed.' % clockRate
        clockPublisher = rospy.Publisher( "/clock", Clock, queue_size=1 )

        if self.timingMode == LogfilePublisher.TimingMode.use_timestamps:
            while isinf(self._earliestTimestamp):
                time.sleep(0.01)
            currentSecs = self._earliestTimestamp - 0.5
        else:
            currentSecs = time.time()

        lastRealTime = time.time()
        while not rospy.is_shutdown():
            currentRealTime = time.time()
            elapsedRealTime = currentRealTime - lastRealTime
            lastRealTime = currentRealTime
            
            if not self._paused or self._singleStep:
                currentSecs += elapsedRealTime * clockRate

            clock = Clock()
            clock.clock = rospy.Time.from_sec(currentSecs) 
            try:
                clockPublisher.publish(clock)
            except Exception:
                print 'Publisher closed' 
            time.sleep(0.01)
Exemplo n.º 5
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class ClockReceiver:
    def __init__(self, host, port=8888):
        rospy.init_node('clock_receiver', anonymous=False)
        rospy.on_shutdown(self.__shutdown)
        if rospy.has_param("use_sim_time"):
            # print "use_sim_time: {}".format(rospy.get_param("use_sim_time"))
            rospy.delete_param("use_sim_time")
        rospy.set_param("use_sim_time", 1)

        self.time_tcpCliSock = socket(AF_INET, SOCK_STREAM)

        addr = (host, port)
        self.time_tcpCliSock.connect(addr)
        print "time_tcp连接成功"

        # clock pub
        self.clock_pub = rospy.Publisher("clock", Clock, queue_size=1000)
        self.clock = Clock()

        self.isStop = False

    def run(self):
        while not self.isStop:
            try:
                data = self.time_tcpCliSock.recv(8)
            except Exception, msg:
                print msg
                continue
            try:
                self.clock.deserialize(data)
                self.clock_pub.publish(self.clock)
            except genpy.DeserializationError:
                print rospy.loginfo("deserialize time failed!")
Exemplo n.º 6
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 def set_time(TestStorage, value):
     wanted_time = rospy.Time(value)
     c = Clock()
     c.clock = wanted_time
     while rospy.Time.now() != wanted_time:
         TestStorage.pub.publish(c)
         time.sleep(0.01)
Exemplo n.º 7
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	def tick_and_tock(self):
		self.sim.pre_update()
		self.sim.physics_update()
		self.time += self.time_step
		cmsg = ClockMsg()
		cmsg.clock = self.time
		self.clock_pub.publish(cmsg)
		self.sim.post_update()
Exemplo n.º 8
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 def publish_rosbag_info(self):
     rosbag_start_time = Clock()
     rosbag_start_time.clock.secs = int(self.rosbag_start_time)
     rosbag_start_time.clock.nsecs = int(
         (self.rosbag_start_time % 1) * (10**9))
     rosbag_end_time = Clock()
     rosbag_end_time.clock.secs = int(self.rosbag_end_time)
     rosbag_end_time.clock.nsecs = int((self.rosbag_end_time % 1) * (10**9))
     self.start_time_publisher.publish(rosbag_start_time)
     self.end_time_publisher.publish(rosbag_end_time)
    def run(self):
        rospy.loginfo('Starting with the send rate ' + str(self.clockSendRate))

        # Get the current time
        startWallclockTime = time.time()
        currentWallclockTime = startWallclockTime

        # Set the current simulation time to now
        startSimulationTime = startWallclockTime
        currentSimulationTime = startSimulationTime

        # Sleep period - self is how long to sleep before sending out
        # the next clock message
        sleepWallclockPeriod = 1.0 / float(self.clockSendRate)

        # Simulation time increment with each message
        simulationTimeIncrement = self.timeScaleFactor * sleepWallclockPeriod

        # Get the next sleep time and seed it
        sleepUntilWallclockTime = startWallclockTime + sleepWallclockPeriod

        # Message to send
        clockMessage = Clock()

        # Next debug message time to print
        debugMessageWallclockTime = currentWallclockTime

        while not rospy.is_shutdown():

            # Publish the simulation time
            clockMessage.clock = rospy.Time.from_sec(currentSimulationTime)
            self.clockPublisher.publish(clockMessage)

            # Print debug message if required
            if (debugMessageWallclockTime <= currentWallclockTime):
                rospy.loginfo('Real duration=' + str(currentWallclockTime - startSimulationTime) \
                              + '; simulated duration=' + str(currentSimulationTime - startSimulationTime))
                debugMessageWallclockTime += 2

            # Work out how long to sleep for. If we've missed a sleep
            # period, thrown a warning and skip it
            currentWallclockTime = time.time()
            timeToSleep = sleepUntilWallclockTime - currentWallclockTime
            if (timeToSleep < 0):
                rospy.logwarn('Cannot keep up; timeToSleep=' +
                              str(timeToSleep) + '; skipping sleep step')
                sleepUntilWallclockTime = currentWallclockTime
            else:
                time.sleep(timeToSleep)

            # Work out when the next sleep time will be
            sleepUntilWallclockTime += sleepWallclockPeriod

            # Advance the simulation time
            currentSimulationTime += simulationTimeIncrement
Exemplo n.º 10
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    def clockLoop(self):
        while not rospy.is_shutdown():
            enabledNow = self.enabled
            if enabledNow != self.wasEnabled:
                if enabledNow:
                    rospy.loginfo(
                        "Starting to publish simulated time on /clock")
                    if self.loop:
                        rospy.loginfo(
                            "Simulated time will be reset to start time after %.1f seconds"
                            % self.simulationLength)
                    rospy.loginfo(
                        "Setting ROS parameter /use_sim_time to TRUE")
                    self.lastWallTime = time.time()
                    self.currentSimulationOffset = 0.0
                    self.wasSimTimeEnabled = rospy.get_param(
                        "/use_sim_time", False)
                    rospy.set_param("/use_sim_time", True)
                else:
                    rospy.loginfo(
                        "Stopping to publish simulated time on /clock")
                    rospy.set_param("/use_sim_time", self.wasSimTimeEnabled)
                    rospy.loginfo("Resetting ROS parameter /use_sim_time to " +
                                  str(self.wasSimTimeEnabled).upper())

                self.wasEnabled = enabledNow

            if enabledNow:
                currentWallTime = time.time()
                wallTimePassed = currentWallTime - self.lastWallTime

                if not self.paused:
                    self.currentSimulationOffset += wallTimePassed * self.simulationRate

                if self.currentSimulationOffset > self.simulationLength:
                    if self.loop:
                        self.currentSimulationOffset %= self.simulationLength
                        rospy.loginfo(
                            "Maximum simulation length (%.1f sec) reached, restarting simulation"
                            % self.simulationLength)
                    else:
                        self.simulationEnded = True

                clock = Clock()
                clock.clock = rospy.Time(self.simulationStart +
                                         self.currentSimulationOffset)

                try:
                    self.clockPublisher.publish(clock)
                except rospy.exceptions.ROSException as e:
                    pass

                self.lastWallTime = currentWallTime
                time.sleep(1.0 / 100)
 def increment_time(self):
     self.current_sim_time += self.args.dt
     if self.args.no_ros:
         pass
     else:
         cmsg = Clock()
         cmsg.clock = self.get_sim_time()
         self.clockpub.publish(cmsg)
     # store the moment the simulation was started
     if self.sim_start_walltime is None:
         self.sim_start_walltime = self.get_walltime()
Exemplo n.º 12
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def post_clock(self, component_instance):
    """ Publish the simulator clock as a Clock ROS msg

    """
    msg = Clock()
    msg.clock = rospy.Time.from_sec(self._sim_time)
    self._sim_time += self._sim_step

    for topic in self._topics:
        # publish the message on the correct topic
        if str(topic.name) == str("/" + component_instance.blender_obj.name):
            topic.publish(msg)
Exemplo n.º 13
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def post_clock(self, component_instance):
    """ Publish the simulator clock as a Clock ROS msg

    """
    msg = Clock()
    msg.clock = rospy.Time.from_sec(self._sim_time)
    self._sim_time += self._sim_step

    for topic in self._topics:
        # publish the message on the correct topic
        if str(topic.name) == str("/" + component_instance.blender_obj.name):
            topic.publish(msg)
Exemplo n.º 14
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def simtime_talker():
    pub1 = rospy.Publisher('clock',Clock, queue_size=10)
    rospy.init_node('talker', anonymous=True)
    rate = rospy.Rate(10) # 10hz
    sim_speed_multiplier = 1    
    sim_clock = Clock()
    zero_time = rospy.get_time()

    while not rospy.is_shutdown():
       print('sss')
       sim_clock.clock = rospy.Time.from_sec(sim_speed_multiplier*(rospy.get_time() - zero_time))
       rospy.loginfo(sim_clock)
       pub1.publish(sim_clock)
       rate.sleep()
Exemplo n.º 15
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    def stepSimulator(self):
        current_time = datetime.datetime.now()
        elapsed = current_time - self.prev_time
        self.sim_time += elapsed * self.sim_factor
        msg = Clock()
        msg.clock = rospy.Time.from_sec(getTimestamp(self.sim_time))
        self.clock_pub.publish(msg)
        self.prev_time = current_time

        if self.sim_time > self.future_roms.date:
            print "ROMS Rollover"
            #Increment Simulator
            self.past_roms = self.future_roms
            self.future_roms = ROMSSnapshot(self.past_roms.idx + 1,
                                            self.roms_dates, self.roms_files)
Exemplo n.º 16
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 def output(self, **inputs):
     t = inputs['t']
     time = Clock()
     time.clock.secs = int(t)
     time.clock.nsecs = int(float(t - int(t)) * 1000000000)
     self.clockpub.publish(time)
     return {}
Exemplo n.º 17
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    def run(self, running):

        self.init()

        start = self.start_time - self.pre_roll
        end = self.end_time + self.post_roll

        # start value
        clock_msg = Clock(clock=start)

        # timing details, should be moved to constructor parameters
        updates_hz = 2000.0
        rate = rospy.Rate(updates_hz)
        # this assumes close to real-time playback
        update = rospy.Duration(1.0 / updates_hz)

        # wait for the signal to start
        self.event.wait()

        while running.value and clock_msg.clock <= end:

            # update time
            clock_msg.clock += update

            # publish time
            self.clock_pub.publish(clock_msg)

            rate.sleep()

        rospy.logdebug('Playback clock finished')
        running.value = False
 def handle_real_time(self, time):
     # real unix time stamp at which the measurements were performed in [ms]
     msg = Clock()
     msg.clock.secs = time // 1000
     msg.clock.nsecs = (time % 1000) * 10 ** 6
     # if self.base_frame == 'robot1':
     self.pub_server_time_clock.publish(msg)
    def __init__(self, ros_active=False, mode='normal'):
        # requires WEBOTS_ROBOT_NAME to be set to "amy" or "rory"
        self.ros_active = ros_active
        self.time = 0
        self.clock_msg = Clock()

        self.supervisor = Supervisor()
        self.amy_node = self.supervisor.getFromDef("amy")
        self.rory_node = self.supervisor.getFromDef("rory")
        self.jack_node = self.supervisor.getFromDef("jack")
        self.donna_node = self.supervisor.getFromDef("donna")
        self.melody_node = self.supervisor.getFromDef("melody")

        if mode == 'normal':
            self.supervisor.simulationSetMode(
                Supervisor.SIMULATION_MODE_REAL_TIME)
        elif mode == 'paused':
            self.supervisor.simulationSetMode(Supervisor.SIMULATION_MODE_PAUSE)
        elif mode == 'fast':
            self.supervisor.simulationSetMode(Supervisor.SIMULATION_MODE_FAST)
        else:
            self.supervisor.simulationSetMode(
                Supervisor.SIMULATION_MODE_REAL_TIME)

        self.motors = []
        self.sensors = []
        self.timestep = int(self.supervisor.getBasicTimeStep())

        # resolve the node for corresponding name
        self.robot_names = ["amy", "rory", "jack", "donna", "melody"]
        self.robot_nodes = {}
        self.translation_fields = {}
        self.rotation_fields = {}

        # check if None
        for name in self.robot_names:
            node = self.supervisor.getFromDef(name)
            if node is not None:
                self.robot_nodes[name] = node
                self.translation_fields[name] = node.getField("translation")
                self.rotation_fields[name] = node.getField("rotation")

        if self.ros_active:
            rospy.init_node("webots_ros_supervisor", argv=['clock:=/clock'])
            self.clock_publisher = rospy.Publisher("/clock",
                                                   Clock,
                                                   queue_size=1)
            self.model_state_publisher = rospy.Publisher("/model_states",
                                                         ModelStates,
                                                         queue_size=1)
            self.reset_service = rospy.Service("reset", Empty, self.reset)
            self.initial_poses_service = rospy.Service("initial_pose", Empty,
                                                       self.set_initial_poses)
            self.set_robot_position_service = rospy.Service(
                "set_robot_position", SetRobotPose, self.robot_pose_callback)
            self.reset_ball_service = rospy.Service("reset_ball", Empty,
                                                    self.reset_ball)

        self.world_info = self.supervisor.getFromDef("world_info")
        self.ball = self.supervisor.getFromDef("ball")
Exemplo n.º 20
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    def __init__(self, launchfile):
        self.last_clock_msg = Clock()

        self.port = os.environ.get("ROS_PORT_SIM", "11311")
        ros_path = os.path.dirname(
            subprocess.check_output(["which", "roscore"]))

        # NOTE: It doesn't make sense to launch a roscore because it will be done when spawing Gazebo, which also need
        #   to be the first node in order to initialize the clock.
        # # start roscore with same python version as current script
        # self._roscore = subprocess.Popen([sys.executable, os.path.join(ros_path, b"roscore"), "-p", self.port])
        # time.sleep(1)
        # print ("Roscore launched!")

        if launchfile.startswith("/"):
            fullpath = launchfile
        else:
            fullpath = os.path.join(os.path.dirname(__file__), "assets",
                                    "launch", launchfile)
        if not os.path.exists(fullpath):
            raise IOError("File " + fullpath + " does not exist")

        self._roslaunch = subprocess.Popen([
            sys.executable,
            os.path.join(ros_path, b"roslaunch"), "-p", self.port, fullpath
        ])
        print("Gazebo launched!")
        time.sleep(5)

        self.gzclient_pid = 0

        # Launch the simulation with the given launchfile name
        rospy.init_node('gym', anonymous=True)
    def __init__(self):
        # Launch the simulation with the given launchfile name
        gazebo_env.GazeboEnv.__init__(self, "GazeboProject.launch")
        self.vel_pub = rospy.Publisher('/cmd_vel', Twist, queue_size=5)
        #self.before_pose = rospy.Publisher('/gazebo/before_model_states', Pose, queue_size=5)
        rospy.Subscriber('/gazebo/model_states', ModelStates, self.update_pose)
        rospy.Subscriber('/clock', Clock, self.sim_time)
        self.unpause = rospy.ServiceProxy('/gazebo/unpause_physics', Empty)
        self.pause = rospy.ServiceProxy('/gazebo/pause_physics', Empty)
        self.reset_proxy = rospy.ServiceProxy('/gazebo/reset_simulation',
                                              Empty)

        self.action_space = spaces.Discrete(4)  #F,L,R,B
        self.reward_range = (-np.inf, np.inf)

        self.sim_time = Clock()
        self.action_time = 0.00000
        self.pose = Pose()
        self.goalpose = Pose()
        self.beforepose = Pose()
        self.startpose = Pose()

        self._seed()

        self.goal = False
        self.randomstart = False

        self.goalpose.x = 2.000  # map0: 1.5, map1: 1.25, map2: 2.0
        self.goalpose.y = -0.250  # map0,1: 0.0, map2: -0.25
        self.get_pose(self.beforepose)
Exemplo n.º 22
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 def test_clock(self):
     """
     Tests clock
     """
     rospy.init_node('test_node', anonymous=True)
     clock_msg = rospy.wait_for_message("/clock", Clock, timeout=TIMEOUT)
     self.assertNotEqual(Clock(), clock_msg)
Exemplo n.º 23
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 def step(self, ms):
     if self.get_parameter('use_joint_state_publisher').value:
         self.jointStatePublisher.publish()
     if self.__device_manager:
         self.__device_manager.step()
     if self.robot is None or self.get_parameter('synchronization').value:
         return
     # Robot step
     if self.robot.step(ms) < 0.0:
         del self.robot
         self.robot = None
         sys.exit(0)
     # Update time
     msg = Clock()
     msg.clock = Time(seconds=self.robot.getTime()).to_msg()
     self.clockPublisher.publish(msg)
Exemplo n.º 24
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    def __init__(self, launchfile):
        self.last_clock_msg = Clock()

        random_number = random.randint(10000, 15000)
        self.port = str(random_number)  #os.environ["ROS_PORT_SIM"]
        self.port_gazebo = str(random_number + 1)  #os.environ["ROS_PORT_SIM"]

        os.environ["ROS_MASTER_URI"] = "http://localhost:" + self.port
        os.environ[
            "GAZEBO_MASTER_URI"] = "http://localhost:" + self.port_gazebo
        # self.ros_master_uri = os.environ["ROS_MASTER_URI"];

        print("ROS_MASTER_URI=http://localhost:" + self.port + "\n")
        print("GAZEBO_MASTER_URI=http://localhost:" + self.port_gazebo + "\n")

        # self.port = os.environ.get("ROS_PORT_SIM", "11311")
        ros_path = os.path.dirname(
            subprocess.check_output(["which", "roscore"]))
        if launchfile.startswith("/"):
            fullpath = launchfile
        else:
            fullpath = os.path.join(os.path.dirname(__file__), "assets",
                                    "launch", launchfile)
        if not os.path.exists(fullpath):
            raise IOError("File " + fullpath + " does not exist")

        self._roslaunch = subprocess.Popen([
            sys.executable,
            os.path.join(ros_path, b"roslaunch"), "-p", self.port, fullpath
        ])
        print("Gazebo launched!")

        self.gzclient_pid = 0
Exemplo n.º 25
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	def tick(self, timer_event):
		self.time += self.time_step
		cmsg = ClockMsg()
		cmsg.clock = self.time
		self.clock_pub.publish(cmsg)
		super(AFAPSimulator, self).tick(None)
		now = time()
		if self.__last_tick != None:
			deltaT = now - self.__last_tick
			ratio  = self.time_step.to_sec() / deltaT
			sys.stdout.write(self.terminal.move(self.terminal.height,  0))
			msg = u'Simulation Factor: {}'.format(ratio)
			self.__last_msg_len = len(msg)
			sys.stdout.write(msg)
			sys.stdout.flush()
		self.__last_tick = now
Exemplo n.º 26
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def offline(args):
    from rosgraph_msgs.msg import Clock
    from bruce_slam.utils import io

    io.offline = True
    cimgs = []
    logwarn("Press s to save image")

    clock_pub = rospy.Publisher("/clock", Clock, queue_size=100)
    for topic, msg in read_bag(args.file, args.start, args.duration):
        while not rospy.is_shutdown():
            if callback_lock_event.wait(1.0):
                break
        if rospy.is_shutdown():
            break

        if topic == SONAR_TOPIC:
            node.sonar_sub.callback(msg)
            if node.feature_img is not None:
                cv2.imshow("feature image", node.feature_img)
                key = cv2.waitKey()
                if key == 27:
                    break
                elif key == ord("s"):
                    loginfo("Save current frame")
                    cimgs.append(node.cimg)
                else:
                    continue

        clock_pub.publish(Clock(msg.header.stamp))

    if cimgs:
        np.savez("cimgs.npz", cimgs=cimgs)
    def __init__(self):
        # Launch the simulation with the given launchfile name
        gazebo_env.GazeboEnv.__init__(self, "GazeboProject.launch")
        self.vel_pub = rospy.Publisher('/cmd_vel', Twist, queue_size=5)
        rospy.Subscriber('/gazebo/model_states', ModelStates, self.update_pose)
        rospy.Subscriber('/clock', Clock, self.sim_time)
        self.unpause = rospy.ServiceProxy('/gazebo/unpause_physics', Empty)
        self.pause = rospy.ServiceProxy('/gazebo/pause_physics', Empty)
        self.reset_proxy = rospy.ServiceProxy('/gazebo/reset_simulation',
                                              Empty)

        self.reward_range = (-np.inf, np.inf)

        self.sim_time = Clock()
        self.action_time = 0.00000
        self.pose = Pose()
        self.goalpose = Pose()
        self.beforepose = Pose()
        self.startpose = Pose()

        self.before_avg_data = 0

        self._seed()

        self.goal = False

        self.goalpose.x = 15.000  # map0: 1.5, map1: 1.25, map2: 2.0
        self.goalpose.y = 0.000  # map0,1: 0.0, map2: -0.25
        self.get_pose(self.beforepose)
        self.subgoal_as_dist_to_goal = 1000  # max. lidar's value
Exemplo n.º 28
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def offline(args):
    from localization_node import LocalizationNode
    from rosgraph_msgs.msg import Clock
    from bruce_slam.utils import io

    io.offline = True

    loc_node = LocalizationNode()
    loc_node.init_node("/bruce/localization/")
    clock_pub = rospy.Publisher("/clock", Clock, queue_size=100)
    for topic, msg in read_bag(args.file,
                               args.start,
                               args.duration,
                               progress=True):
        while not rospy.is_shutdown():
            if callback_lock_event.wait(1.0):
                break
        if rospy.is_shutdown():
            break

        if topic == IMU_TOPIC:
            loc_node.imu_sub.callback(msg)
        elif topic == DVL_TOPIC:
            loc_node.dvl_sub.callback(msg)
        elif topic == DEPTH_TOPIC:
            loc_node.depth_sub.callback(msg)
        elif topic == SONAR_TOPIC:
            node.sonar_sub.callback(msg)
        clock_pub.publish(Clock(msg.header.stamp))
Exemplo n.º 29
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    def __init__(self):
        '''
        Initialization of the class.
        '''

        self.start_flag = False  # flag indicates if the first measurement is received
        self.config_start = False  # flag indicates if the config callback is called for the first time
        self.euler_mv = Vector3()  # measured euler angles
        self.euler_sp = Vector3(0, 0, 0)  # euler angles referent values

        self.w_sp = 0  # referent value for motor velocity - it should be the output of height controller

        self.euler_rate_mv = Vector3()  # measured angular velocities

        self.clock = Clock()

        self.pid_roll = PID()  # roll controller
        self.pid_pitch = PID()  # pitch controller

        ##################################################################
        ##################################################################
        # Add your PID params here

        self.pid_roll.set_kp(5.0)
        self.pid_roll.set_ki(6.0)
        self.pid_roll.set_kd(0.0)

        self.pid_pitch.set_kp(5.0)
        self.pid_pitch.set_ki(6.0)
        self.pid_pitch.set_kd(0.0)

        self.joint0 = [0, -45, -45, 0, -45, -45, 0, -45, -45, 0, -45, -45]

        self.joint_ref = copy.deepcopy(self.joint0)
        self.joint_msg = JointState()

        ##################################################################
        ##################################################################

        self.rate = 20.0
        self.ros_rate = rospy.Rate(self.rate)  # attitude control at 20 Hz

        self.t_old = 0

        rospy.Subscriber('imu', Imu, self.ahrs_cb)
        rospy.Subscriber('euler_ref', Vector3, self.euler_ref_cb)
        rospy.Subscriber('/clock', Clock, self.clock_cb)

        self.pub_joint_references = rospy.Publisher('aquashoko_chatter',
                                                    JointState,
                                                    queue_size=1)
        self.pub_pid_roll = rospy.Publisher('pid_roll',
                                            PIDController,
                                            queue_size=1)
        self.pub_pid_pitch = rospy.Publisher('pid_pitch',
                                             PIDController,
                                             queue_size=1)
        self.cfg_server = Server(AttitudeControlParamsConfig,
                                 self.cfg_callback)
Exemplo n.º 30
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    def _publishClock(self, clockRate):
        print 'Starting to publish simulated time on /clock and setting /use_sim_time to true.'
        print 'Simulated time is running at %fx speed.' % clockRate
        clockPublisher = rospy.Publisher( "/clock", Clock )
        currentSecs = time.time()

        while not rospy.is_shutdown():
            if not self._paused or self._singleStep:
                currentSecs += 0.01 * clockRate

            clock = Clock()
            clock.clock = rospy.Time.from_sec(currentSecs) 
            try:
                clockPublisher.publish(clock)
            except Exception:
                print 'Publisher closed' 
            time.sleep(0.01)
Exemplo n.º 31
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    def _publishClock(self, clockRate):
        print 'Starting to publish simulated time on /clock and setting /use_sim_time to true.'
        print 'Simulated time is running at %fx speed.' % clockRate
        clockPublisher = rospy.Publisher("/clock", Clock)
        currentSecs = time.time()

        while not rospy.is_shutdown():
            if not self._paused or self._singleStep:
                currentSecs += 0.01 * clockRate

            clock = Clock()
            clock.clock = rospy.Time.from_sec(currentSecs)
            try:
                clockPublisher.publish(clock)
            except Exception:
                print 'Publisher closed'
            time.sleep(0.01)
Exemplo n.º 32
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def offline(args):
    from rosgraph_msgs.msg import Clock
    from localization_node import LocalizationNode
    from feature_extraction_node import FeatureExtractionNode
    from mapping_node import MappingNode
    from bruce_slam.utils import io

    io.offline = True
    node.save_fig = False
    node.save_data = False

    loc_node = LocalizationNode()
    loc_node.init_node(SLAM_NS + "localization/")
    fe_node = FeatureExtractionNode()
    fe_node.init_node(SLAM_NS + "feature_extraction/")
    mp_node = MappingNode()
    mp_node.init_node(SLAM_NS + "mapping/")
    clock_pub = rospy.Publisher("/clock", Clock, queue_size=100)

    for topic, msg in read_bag(args.file,
                               args.start,
                               args.duration,
                               progress=True):
        while not rospy.is_shutdown():
            if callback_lock_event.wait(1.0):
                break
        if rospy.is_shutdown():
            break

        if topic == IMU_TOPIC:
            loc_node.imu_sub.callback(msg)
        elif topic == DVL_TOPIC:
            loc_node.dvl_sub.callback(msg)
        elif topic == DEPTH_TOPIC:
            loc_node.depth_sub.callback(msg)
        elif topic == SONAR_TOPIC:
            fe_node.sonar_sub.callback(msg)
            if node.sonar_sub.callback:
                node.sonar_sub.callback(msg)
            mp_node.sonar_sub.callback(msg)
        clock_pub.publish(Clock(msg.header.stamp))

        # Publish map to world so we can visualize all in a z-down frame in rviz.
        node.tf.sendTransform((0, 0, 0), [1, 0, 0, 0], msg.header.stamp, "map",
                              "world")

    # Save trajectory and point cloud
    import os
    import datetime

    stamp = datetime.datetime.now()
    name = os.path.basename(args.file).split(".")[0]

    np.savez(
        "run-{}@{}.npz".format(name, stamp),
        poses=node.get_states(),
        points=np.c_[node.get_points(return_keys=True)],
    )
Exemplo n.º 33
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 def update_clock(self):
     self.sim_time += rospy.Duration.from_sec(self.wallclock_time_step *
                                              self.time_factor)
     c = Clock(self.sim_time)
     self.clock_publisher.publish(c)
     if not rospy.is_shutdown():
         clock_timer = threading.Timer(self.wallclock_time_step,
                                       self.update_clock)
         clock_timer.start()
Exemplo n.º 34
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    def TimeStampPublisher(self, ):
        t = rospy.Time.from_sec(self.timestamps[self.timestamp_idx][1])
        time_msg = Clock()
        time_msg.clock = t
        info_str = "publishing index %d" % self.timestamp_idx
        rospy.loginfo(info_str + " stamp= " +
                      str(self.timestamps[self.timestamp_idx][1]))
        label_file = self.timestamps[self.timestamp_idx][0].split('/')[-1]
        label_file = label_file.split('.')[0]
        label_file_path = self.labels_base_dir + "/" + self.sequence + "/" + label_file + ".txt"
        bboxes_msg = self.GetBBoxesMsg(label_file_path)
        bboxes_msg.header.stamp = t
        #print(t)

        # also publish bounding boxes

        self.timestamp_pub.publish(time_msg)
        self.gt_boundingbox_pub.publish(bboxes_msg)
Exemplo n.º 35
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    def step_physics(self, event):
        self.clock += self.physics_dt
        self.clock_pub.publish(Clock(clock=rospy.Time(self.clock)))
        self.clock += self.physics_dt

        self.physics_world.step()
        if self.draw:
            for rendered, physical in self.entity_pairs:
                rendered.set_pose(physical.pose)
Exemplo n.º 36
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def talker():
    pub = rospy.Publisher('clock', Clock, queue_size=10)
    rospy.init_node('clock_server', anonymous=True)

    print "publishing.."

    # how much faster then reallity?
    mult_factor = rospy.get_param("/ctm/clock_mult", 10)

    # in ms
    rate = 10
    # in s
    cur_time = 10000.0
    while not rospy.is_shutdown():
        c = Clock()
        c.clock = rospy.Time.from_sec(cur_time)
        pub.publish(c)
        time.sleep(rate / 1000.0)
        cur_time += rate / 1000.0 * mult_factor
    print "done."
Exemplo n.º 37
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    def default(self, ci='unused'):
        msg = Clock()
        msg.clock = self.get_time()

        self.publish(msg)
Exemplo n.º 38
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 def output(self,**inputs):
     t = inputs['t']
     time = Clock()
     time.clock = rospy.Time.from_sec(t)
     self.clockpub.publish(time)
     return {}
Exemplo n.º 39
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    def default(self, ci="unused"):
        msg = Clock()
        msg.clock = rospy.Time.from_sec(self._sim_time)
        self._sim_time += self._sim_step

        self.publish(msg)
Exemplo n.º 40
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    pubs = {}
    missing = []
    for topic, msg_type in topics.items():
        pytype = get_message_class(msg_type)
        if pytype is None:
            missing.append(msg_type)
            continue
        pubs[topic] = rospy.Publisher(topic, pytype, queue_size=1)
    if missing:
        missing.sort()
        click.echo("Missing message types:\n" + '\n   '.join(missing))
        ctx.exit(2)

    clock_pub = rospy.Publisher('/clock', Clock, queue_size=1)

    clock_msg = Clock()
    for topic, secs, nsecs, raw_msg in msc.messages:
        time = genpy.Time(secs, nsecs)
        clock_msg.clock = time
        clock_pub.publish(clock_msg)

        pub = pubs[topic]
        assert pub.md5sum == raw_msg[2]
        msg = pub.data_class()
        msg.deserialize(raw_msg[1])
        pub.publish(msg)

        if rospy.is_shutdown():
            click.echo('Aborting due to rospy shutdown.')
            ctx.exit(108)
Exemplo n.º 41
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from sensor_msgs.msg import Image, CompressedImage
from sensor_msgs.msg import CameraInfo
print sys.argv[1]
print sys.argv[2]
bag = rosbag.Bag(sys.argv[1])
f = open(sys.argv[2], "r")
lines = f.readlines()
print bag
left_image_topic = '/camera/left/image_rect_color/compressed'
right_image_topic = '/camera/right/image_rect_color/compressed'
left_camera_info_topic = '/camera/left/camera_info'
right_camera_info_topic = '/camera/right/camera_info'
# bag_messages = bag.read_messages(topics=['/scan', left_image_topic , right_image_topic, left_image_topic, left_camera_info_topic])
# print lines
print 'processing trajectory...'
clock = Clock()
clock_msg = Time()
rospy.init_node('recordedFrameSyncPublisher', anonymous=False)
pub_clock   = rospy.Publisher('/clock', Clock)
pub_scan    = rospy.Publisher('/scan',  LaserScan)
pub_right_image = rospy.Publisher(right_image_topic, CompressedImage)
pub_left_image = rospy.Publisher(left_image_topic, CompressedImage)
pub_right_camera_info = rospy.Publisher(right_camera_info_topic, CameraInfo)
pub_left_camera_info = rospy.Publisher(left_camera_info_topic, CameraInfo)
pub_br = tf.TransformBroadcaster()
# for topic, msg, t in bag.read_messages(topics=['/scan', '/odom_pose_do_not_subscribe', '/tf']):
#first message
# (topic,msg,t) = bag_messages.next()
# clock.clock = msg.header.stamp
# clock_msg.data = msg.header.stamp
count_msgs  = 0
Exemplo n.º 42
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#!/usr/bin/env python
"""
publish rospy.Time.now on /clock @ 10Hz
usage:
rosrun explore_beego fake_clock.py
"""

import roslib
roslib.load_manifest('rospy')
roslib.load_manifest('rosgraph_msgs')
import rospy
from rosgraph_msgs.msg import Clock

if __name__ == '__main__':
    rospy.init_node('fake_clock')
    msg = Clock()
    publisher = rospy.Publisher('/clock', Clock)
    while not rospy.is_shutdown():
        msg.clock = rospy.Time.now()
        publisher.publish(msg)
        rospy.sleep(.1)

Exemplo n.º 43
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#!/usr/bin/env python

import rospy
from rosgraph_msgs.msg import Clock
from std_msgs.msg import String

rospy.init_node('sim_clock', disable_rostime=True)
pub = rospy.Publisher('/clock', Clock, queue_size=10)
r = rospy.Rate(30)
print "Simulation Clock node initialized"

while not rospy.is_shutdown():
    t = rospy.Time.now()
    msg = Clock()
    msg.clock = t
    pub.publish(msg)
    r.sleep()