def on_init(self):
        pygame.init()
        print(__doc__)
        time.sleep(3)
        self._display_surf = pygame.display.set_mode(
            self.size, pygame.HWSURFACE | pygame.DOUBLEBUF)
        logging.debug('Started the PyGame Library')
        self._running = True
        self.step = 0
        self.prev_step = 0
        self.prev_time = time.time()

        self.carla = CARLA(self.host, self.port)

        positions = self.carla.loadConfigurationFile(self.config)
        self.num_pos = len(positions)
        print("Staring Episode on Position ", self.num_pos)
        self.carla.newEpisode(np.random.randint(self.num_pos))
        self.prev_restart_time = time.time()
        # Adding Joystick controls here
        self.js = pygame.joystick.Joystick(0)
        self.js.init()
        axis = self.js.get_axis(1)
        jsInit = self.js.get_init()
        jsId = self.js.get_id()
        print("Joystick ID: %d Init status: %s Axis(1): %d" % (jsId, jsInit, axis))
    def start(self):

        # You start with some configurationpath

        self.carla = CARLA(self._host, self._port)
        self.positions = self.carla.loadConfigurationFile(self._config_path)

        self._current_goal = random.randint(0, len(self.positions) - 1)
        position_reset = random.randint(0, len(self.positions) - 1)

        self.carla.newEpisode(position_reset)

        self._target = random.randint(0, len(self.positions))
        self._start_time = time.time()
Пример #3
0
    def on_init(self):
        pygame.init()
        print(__doc__)
        time.sleep(3)
        self._display_surf = pygame.display.set_mode(
            self.size, pygame.HWSURFACE | pygame.DOUBLEBUF)
        logging.debug('Started the PyGame Library')
        self._running = True
        self.step = 0
        self.prev_step = 0
        self.prev_time = time.time()

        self.carla = CARLA(self.host, self.port)

        positions = self.carla.loadConfigurationFile(self.config)
        self.num_pos = len(positions)
        print("Staring Episode on Position ", self.num_pos)
        self.carla.newEpisode(np.random.randint(self.num_pos))
        self.prev_restart_time = time.time()
Пример #4
0
    def on_init(self):
        pygame.init()
        print (" \n \n \n Welcome to CARLA manual control \n USE ARROWS for control \n Press R for reset \n"\
        +"STARTING in a few seconds...")
        time.sleep(3)
        self._display_surf = pygame.display.set_mode(
            self.size, pygame.HWSURFACE | pygame.DOUBLEBUF)
        logging.debug('Started the PyGame Library')
        self._running = True
        self.step = 0
        self.prev_step = 0
        self.prev_time = time.time()

        self.carla = CARLA(self.host, self.port)

        positions = self.carla.loadConfigurationFile(self.config)
        self.num_pos = len(positions)
        print("Staring Episode on Position ", self.num_pos)
        self.carla.newEpisode(np.random.randint(self.num_pos))
        self.prev_restart_time = time.time()
Пример #5
0
    def on_init(self):
        pygame.init()
        print (" \n \n \n Welcome to CARLA manual control \n USE ARROWS for control \n Press R for reset \n"\
        +"STARTING in a few seconds...")
        time.sleep(3)
        self._display_surf = pygame.display.set_mode(self.size, pygame.HWSURFACE | pygame.DOUBLEBUF)
        logging.debug('Started the PyGame Library')
        self._running = True
        self.step = 0
        self.prev_step = 0
        self.prev_time = time.time()

        self.carla =CARLA(self.host, self.port)

        positions = self.carla.loadConfigurationFile(self.config)
        self.num_pos = len(positions)
        print ("Staring Episode on Position ",self.num_pos)
        self.carla.newEpisode(np.random.randint(self.num_pos))
        self.prev_restart_time = time.time()
Пример #6
0
class App:
    def __init__(self, port=2000, host='127.0.0.1', config='./CarlaSettings.ini',\
     resolution=(2400,600),verbose=True):
        self._running = True
        self._display_surf = None
        self.port = port
        self.host = host
        self.config = config
        self.verbose = verbose
        self.resolution = resolution
        self.size = self.weight, self.height = resolution

    def on_init(self):
        pygame.init()
        print (" \n \n \n Welcome to CARLA manual control \n USE ARROWS for control \n Press R for reset \n"\
        +"STARTING in a few seconds...")
        time.sleep(3)
        self._display_surf = pygame.display.set_mode(
            self.size, pygame.HWSURFACE | pygame.DOUBLEBUF)
        logging.debug('Started the PyGame Library')
        self._running = True
        self.step = 0
        self.prev_step = 0
        self.prev_time = time.time()

        self.carla = CARLA(self.host, self.port)

        positions = self.carla.loadConfigurationFile(self.config)
        self.num_pos = len(positions)
        print("Staring Episode on Position ", self.num_pos)
        self.carla.newEpisode(np.random.randint(self.num_pos))
        self.prev_restart_time = time.time()

    def on_event(self, event):
        if event.type == pygame.QUIT:
            self._running = False

    def on_loop(self):
        self.step += 1
        keys = pygame.key.get_pressed()
        gas = 0
        steer = 0
        restart = False
        pressed_keys = []
        if keys[K_LEFT]:
            steer = -1.
            pressed_keys.append('left')
        if keys[K_RIGHT]:
            pressed_keys.append('right')
            steer = 1.
        if keys[K_UP]:
            pressed_keys.append('up')
            gas = 1.
        if keys[K_DOWN]:
            pressed_keys.append('down')
            gas = -1.
        if keys[K_r]:
            pressed_keys.append('r')
            if time.time() - self.prev_restart_time > 2.:
                self.prev_restart_time = time.time()
                restart = True
        if time.time() - self.prev_restart_time < 2.:
            gas = 0.
            steer = 0.

        control = Control()
        control.throttle = gas
        control.steer = steer
        self.carla.sendCommand(control)
        measurements = self.carla.getMeasurements()
        pack = measurements['PlayerMeasurements']
        self.img_vec = measurements['BGRA']
        self.depth_vec = measurements['Depth']
        self.labels_vec = measurements['Labels']

        if time.time() - self.prev_time > 1.:
            print(
                'Step', self.step, 'FPS',
                float(self.step - self.prev_step) /
                (time.time() - self.prev_time))


            print('speed', pack.forward_speed, 'collision', pack.collision_other, \
            'collision_car', pack.collision_vehicles, 'colision_ped', pack.collision_pedestrians, 'pressed:', pressed_keys)
            self.prev_step = self.step
            self.prev_time = time.time()

        if restart:
            print('\n *** RESTART *** \n')

            player_pos = np.random.randint(self.num_pos)

            print('  Player pos %d \n' % (player_pos))
            self.carla.newEpisode(player_pos)

    """
        The render method plots the First RGB, the First Depth and First Semantic Segmentation Camera
    """

    def on_render(self):

        pos_x = 0

        if len(self.depth_vec) > 0:
            self.depth_vec[0] = self.depth_vec[0][:, :, :3]
            self.depth_vec[0] = self.depth_vec[0][:, :, ::-1]
            self.depth_vec[0] = convert_depth(self.depth_vec[0])
            surface = pygame.surfarray.make_surface(
                np.transpose(self.depth_vec[0], (1, 0, 2)))
            self._display_surf.blit(surface, (pos_x, 0))
            pos_x += self.depth_vec[0].shape[1]

        if len(self.img_vec) > 0:
            self.img_vec[0] = self.img_vec[0][:, :, :3]
            self.img_vec[0] = self.img_vec[0][:, :, ::-1]
            surface = pygame.surfarray.make_surface(
                np.transpose(self.img_vec[0], (1, 0, 2)))
            self._display_surf.blit(surface, (pos_x, 0))
            pos_x += self.img_vec[0].shape[1]

        if len(self.labels_vec) > 0:
            self.labels_vec[0] = join_classes(self.labels_vec[0][:, :, 2])
            surface = pygame.surfarray.make_surface(
                np.transpose(self.labels_vec[0], (1, 0, 2)))
            self._display_surf.blit(surface, (pos_x, 0))
            pos_x += self.labels_vec[0].shape[1]

        pygame.display.flip()

    def on_cleanup(self):
        self.carla.closeConections()
        pygame.quit()

    def on_execute(self):
        if self.on_init() == False:
            self._running = False

        frequency = 10
        rate = rospy.Rate(frequency)

        while not rospy.is_shutdown():
            try:

                for event in pygame.event.get():
                    self.on_event(event)
                self.on_loop()
                self.on_render()

                rate.sleep()

            except Exception as e:
                logging.exception(e)
                self._running = False
                break

        self.on_cleanup()
Пример #7
0
def use_example(ini_file,
                port=2000,
                host='127.0.0.1',
                print_measurements=True,
                images_to_disk=False):

    frequency = 10
    rate = rospy.Rate(frequency)

    # We assume the CARLA server is already waiting for a client to connect at
    # host:port. To create a connection we can use the CARLA
    # constructor, it creates a CARLA client object and starts the
    # connection. It will throw an exception if something goes wrong.

    carla = CARLA(host, port)
    """ As a first step, Carla must have a configuration file loaded. This will load a map in the server
		with the properties specified by the ini file. It returns all the posible starting positions on the map
		in a vector.
	"""
    positions = carla.loadConfigurationFile(ini_file)
    """ 
		Ask Server for a new episode starting on position of index zero in the positions vector
	"""
    carla.newEpisode(0)

    capture = time.time()
    # General iteratior
    i = 1
    # Iterator that will go over the positions on the map after each episode
    iterator_start_positions = 1

    while not rospy.is_shutdown():
        try:
            """
				User get the measurements dictionary from the server. 
				Measurements contains:
				* WallTime: Current time on Wall from server machine.
				* GameTime: Current time on Game. Restarts at every episode
				* PlayerMeasurements : All information and events that happens to player
				* Agents : All non-player agents present on the map information such as cars positions, traffic light states
				* BRGA : BGRA optical images
				* Depth : Depth Images
				* Labels : Images containing the semantic segmentation. NOTE: the semantic segmentation must be
					previously activated on the server. See documentation for that. 

			"""

            measurements = carla.getMeasurements()

            ego_x = measurements['PlayerMeasurements'].transform.location.x
            ego_y = measurements['PlayerMeasurements'].transform.location.y
            ego_z = measurements['PlayerMeasurements'].transform.location.z
            ego_ox = measurements['PlayerMeasurements'].transform.orientation.x
            ego_oy = measurements['PlayerMeasurements'].transform.orientation.y
            ego_oz = measurements['PlayerMeasurements'].transform.orientation.z

            # Print all the measurements... Will write images to disk
            if print_measurements:
                print_pack(measurements, i, images_to_disk)
            """
				Sends a control command to the server
				This control structue contains the following fields:
				* throttle : goes from 0 to -1
				* steer : goes from -1 to 1
				* brake : goes from 0 to 1
				* hand_brake : Activate or desactivate the Hand Brake.
				* reverse: Activate or desactive the reverse gear.

			"""

            control = Control()
            control.throttle = 0.9
            control.steer = (random.random() * 2) - 1

            carla.sendCommand(control)

            rate.sleep()

            i += 1

            if i % RESET_FREQUENCY == 0:

                print('Fps for this episode : ',
                      (1.0 / ((time.time() - capture) / 100.0)))
                """ 
					Starts another new episode, the episode will have the same configuration as the previous
					one. In order to change configuration, the loadConfigurationFile could be called at any
					time.
				"""
                if iterator_start_positions < len(positions):
                    carla.newEpisode(iterator_start_positions)
                    iterator_start_positions += 1
                else:
                    carla.newEpisode(0)
                    iterator_start_positions = 1

                print("Now Starting on Position: ",
                      iterator_start_positions - 1)
                capture = time.time()

        except Exception as e:

            logging.exception('Exception raised to the top')
            time.sleep(1)
class App(object):
    def __init__(
            self,
            port=2000,
            host='127.0.0.1',
            config='./CarlaSettings.ini',
            resolution=(2400, 600),
            verbose=True):
        self._running = True
        self._display_surf = None
        self.port = port
        self.host = host
        self.config = config
        self.verbose = verbose
        self.resolution = resolution
        self.size = self.weight, self.height = resolution
        self.reverse_gear = False

    def on_init(self):
        pygame.init()
        print(__doc__)
        time.sleep(3)
        self._display_surf = pygame.display.set_mode(
            self.size, pygame.HWSURFACE | pygame.DOUBLEBUF)
        logging.debug('Started the PyGame Library')
        self._running = True
        self.step = 0
        self.prev_step = 0
        self.prev_time = time.time()

        self.carla = CARLA(self.host, self.port)

        positions = self.carla.loadConfigurationFile(self.config)
        self.num_pos = len(positions)
        print("Staring Episode on Position ", self.num_pos)
        self.carla.newEpisode(np.random.randint(self.num_pos))
        self.prev_restart_time = time.time()
        # Adding Joystick controls here
        self.js = pygame.joystick.Joystick(0)
        self.js.init()
        axis = self.js.get_axis(1)
        jsInit = self.js.get_init()
        jsId = self.js.get_id()
        print("Joystick ID: %d Init status: %s Axis(1): %d" % (jsId, jsInit, axis))

    def on_event(self, event):
        if event.type == pygame.QUIT:
            self._running = False

    def on_loop(self):
        self.step += 1
        keys = pygame.key.get_pressed()

        numAxes = self.js.get_numaxes()
        jsInputs = [ float(self.js.get_axis(i)) for i in range(numAxes)]

        print('Js inputs [%s]' % ', '.join(map(str, jsInputs)))
        restart = False

        control = Control()

        pressed_keys = []
        if keys[K_LEFT] or keys[K_a]:
            control.steer = -1.0
            pressed_keys.append('left')
        if keys[K_RIGHT] or keys[K_d]:
            control.steer = 1.0
            pressed_keys.append('right')
        if keys[K_UP] or keys[K_w]:
            control.throttle = 1.0
            pressed_keys.append('reverse' if self.reverse_gear else 'forward')
        if keys[K_DOWN] or keys[K_s]:
            control.brake = 1.0
            pressed_keys.append('brake')
        if keys[K_SPACE]:
            control.hand_brake = True
            pressed_keys.append('hand-brake')
        if keys[K_q]:
            self.reverse_gear = not self.reverse_gear
            pressed_keys.append('toggle reverse')
        if keys[K_r]:
            pressed_keys.append('reset')
            if time.time() - self.prev_restart_time > 2.:
                self.prev_restart_time = time.time()
                restart = True

        if time.time() - self.prev_restart_time < 2.:
            control.throttle = 0.0
            control.steer = 0.0

        control.steer = jsInputs[0]

        brakeCmd = (((jsInputs[1] - (-1)) * (1.0 - 0)) / (1.0 - (-1.0))) + 0
        throttleCmd = (((jsInputs[2] - (-1)) * (1.0 - 0)) / (1.0 - (-1.0))) + 0

        control.brake = brakeCmd
        control.throttle = throttleCmd

        control.reverse = self.reverse_gear
        self.carla.sendCommand(control)

        measurements = self.carla.getMeasurements()
        pack = measurements['PlayerMeasurements']
        self.img_vec = measurements['BGRA']
        self.depth_vec = measurements['Depth']
        self.labels_vec = measurements['Labels']

        if time.time() - self.prev_time > 1.:
            message = 'Step {step} ({fps:.1f} FPS): '
            message += '{speed:.2f} km/h, '
            message += '{other_lane:.0f}% other lane, {offroad:.0f}% off-road'
            message += ': pressed [%s]' % ', '.join(pressed_keys)

            message = message.format(
                step=self.step,
                fps=float(self.step - self.prev_step) / (time.time() - self.prev_time),
                speed=pack.forward_speed,
                other_lane=100 * pack.intersection_otherlane,
                offroad=100 * pack.intersection_offroad)

            empty_space = max(0, get_terminal_width() - len(message))
            sys.stdout.write('\r' + message + empty_space * ' ')
            sys.stdout.flush()

            self.prev_step = self.step
            self.prev_time = time.time()

        if restart:
            print('\n *** RESTART *** \n')
            player_pos = np.random.randint(self.num_pos)
            print('  Player pos %d \n' % (player_pos))
            self.carla.newEpisode(player_pos)


    def on_render(self):
        """
        The render method plots the First RGB, the First Depth and First
        Semantic Segmentation Camera.
        """
        pos_x = 0

        if self.depth_vec:
            self.depth_vec[0] = self.depth_vec[0][:, :, :3]
            self.depth_vec[0] = self.depth_vec[0][:, :, ::-1]
            self.depth_vec[0] = convert_depth(self.depth_vec[0])
            surface = pygame.surfarray.make_surface(
                np.transpose(self.depth_vec[0], (1, 0, 2)))
            self._display_surf.blit(surface, (pos_x, 0))
            pos_x += self.depth_vec[0].shape[1]

        if self.img_vec:
            self.img_vec[0] = self.img_vec[0][:, :, :3]
            self.img_vec[0] = self.img_vec[0][:, :, ::-1]
            surface = pygame.surfarray.make_surface(
                np.transpose(self.img_vec[0], (1, 0, 2)))
            self._display_surf.blit(surface, (pos_x, 0))
            pos_x += self.img_vec[0].shape[1]

        if self.labels_vec:
            self.labels_vec[0] = join_classes(self.labels_vec[0][:, :, 2])
            surface = pygame.surfarray.make_surface(
                np.transpose(self.labels_vec[0], (1, 0, 2)))
            self._display_surf.blit(surface, (pos_x, 0))
            pos_x += self.labels_vec[0].shape[1]

        pygame.display.flip()

    def on_cleanup(self):
        self.carla.closeConections()
        pygame.quit()

    def on_execute(self):
        if self.on_init() == False:
            self._running = False

        while(self._running):
            try:

                for event in pygame.event.get():
                    self.on_event(event)
                self.on_loop()
                self.on_render()

            except Exception as e:
                logging.exception(e)
                self._running = False
                break

        self.on_cleanup()
class VirtualElektraMachine(Driver):


    def __init__(self,gpu_number="0",experiment_name ='None',driver_conf=None,memory_fraction=0.9,\
      trained_manager =None,session =None,config_input=None):

        Driver.__init__(self)

        if trained_manager == None:

            conf_module = __import__(experiment_name)
            self._config = conf_module.configInput()

            config_gpu = tf.ConfigProto()
            config_gpu.gpu_options.visible_device_list = gpu_number

            config_gpu.gpu_options.per_process_gpu_memory_fraction = memory_fraction
            self._sess = tf.Session(config=config_gpu)

            self._train_manager = load_system(conf_module.configTrain())

            self._sess.run(tf.global_variables_initializer())
            saver = tf.train.Saver(tf.global_variables())
            cpkt = restore_session(self._sess, saver, self._config.models_path)

        else:
            self._train_manager = trained_manager
            self._sess = session
            self._config = config_input

        if self._train_manager._config.control_mode == 'goal':
            self._select_goal = conf_module.configTrain().select_goal

        self._control_function = getattr(
            machine_output_functions, self._train_manager._config.control_mode)

        self._image_cut = driver_conf.image_cut

        # load a manager to deal with test data
        self.use_planner = driver_conf.use_planner
        if driver_conf.use_planner:
            self.planner = Planner('drive_interfaces/carla_interface/' + driver_conf.city_name  + '.txt',\
              'drive_interfaces/carla_interface/' + driver_conf.city_name + '.png')

        self._host = driver_conf.host
        self._port = driver_conf.port
        self._config_path = driver_conf.carla_config
        self._resolution = driver_conf.resolution

        self._straight_button = False
        self._left_button = False
        self._right_button = False
        self._recording = False

    def start(self):

        # You start with some configurationpath

        self.carla = CARLA(self._host, self._port)
        self.positions = self.carla.loadConfigurationFile(self._config_path)

        self._current_goal = random.randint(0, len(self.positions) - 1)
        position_reset = random.randint(0, len(self.positions) - 1)

        self.carla.newEpisode(position_reset)

        self._target = random.randint(0, len(self.positions))
        self._start_time = time.time()

    def _get_direction_buttons(self):
        #with suppress_stdout():if keys[K_LEFT]:
        keys = pygame.key.get_pressed()

        if (keys[K_s]):

            self._left_button = False
            self._right_button = False
            self._straight_button = False

        if (keys[K_a]):

            self._left_button = True
            self._right_button = False
            self._straight_button = False

        if (keys[K_d]):
            self._right_button = True
            self._left_button = False
            self._straight_button = False

        if (keys[K_w]):

            self._straight_button = True
            self._left_button = False
            self._right_button = False

        return [self._left_button, self._right_button, self._straight_button]

    def compute_goal(self, pos, ori):  #Return the goal selected
        pos, point = self.planner.get_defined_point(
            pos, ori, (self.positions[self._target][0],
                       self.positions[self._target][1], 22),
            (1.0, 0.02, -0.001), 1 + self._select_goal)
        return convert_to_car_coord(point[0], point[1], pos[0], pos[1], ori[0],
                                    ori[1])

    def compute_direction(
            self, pos,
            ori):  # This should have maybe some global position... GPS stuff

        if self._train_manager._config.control_mode == 'goal':
            return self.compute_goal(pos, ori)

        elif self.use_planner:

            command, made_turn, completed = self.planner.get_next_command(
                pos, ori, (self.positions[self._target].location.x,
                           self.positions[self._target].location.y, 22),
                (1.0, 0.02, -0.001))
            return command

        else:
            # BUtton 3 has priority
            if 'Control' not in set(self._config.inputs_names):
                return None

            button_vec = self._get_direction_buttons()
            if sum(button_vec) == 0:  # Nothing
                return 2
            elif button_vec[0] == True:  # Left
                return 3
            elif button_vec[1] == True:  # RIght
                return 4
            else:
                return 5

    def get_recording(self):

        return False

    def get_reset(self):
        return False

    def new_episode(self, initial_pos, target, cars, pedestrians, weather):

        config = ConfigParser()

        config.read(self._config_path)
        config.set('CARLA/LevelSettings', 'NumberOfVehicles', cars)

        config.set('CARLA/LevelSettings', 'NumberOfPedestrians', pedestrians)

        config.set('CARLA/LevelSettings', 'WeatherId', weather)

        # Write down a temporary init_file to be used on the experiments
        temp_f_name = 's' +str(initial_pos)+'_e'+ str(target) + "_p" +\
         str(pedestrians)+'_c' + str(cars)+"_w" + str(weather) +\
         '.ini'

        with open(temp_f_name, 'w') as configfile:
            config.write(configfile)

        positions = self.carla.requestNewEpisode(temp_f_name)

        self.carla.newEpisode(initial_pos)
        self._target = target

    def get_all_turns(self, data, target):
        rewards = data[0]
        sensor = data[2][0]
        speed = rewards.speed
        return self.planner.get_all_commands((rewards.player_x,rewards.player_y,22),(rewards.ori_x,rewards.ori_y,rewards.ori_z),\
          (target[0],target[1],22),(1.0,0.02,-0.001))

    #### TO BE DEPRECATED , WE DONT NEED TWO FUNCTIONS ....
    def run_step(self, data, target):

        rewards = data[0]
        sensor = data[2][0]
        speed = rewards.speed
        direction,made_turn,completed = self.planner.get_next_command((rewards.player_x,rewards.player_y,22),(rewards.ori_x,rewards.ori_y,rewards.ori_z),\
          (target[0],target[1],22),(1.0,0.02,-0.001))
        #pos = (rewards.player_x,rewards.player_y,22)
        #ori =(rewards.ori_x,rewards.ori_y,rewards.ori_z)
        #pos,point = self.planner.get_defined_point(pos,ori,(target[0],target[1],22),(1.0,0.02,-0.001),self._select_goal)
        #direction = convert_to_car_coord(point[0],point[1],pos[0],pos[1],ori[0],ori[1])

        capture_time = time.time()

        sensor = sensor[self._image_cut[0]:self._image_cut[1], :, :]

        sensor = scipy.misc.imresize(sensor, [
            self._config.network_input_size[0],
            self._config.network_input_size[1]
        ])

        image_input = sensor.astype(np.float32)

        #print future_image
        #print direction
        #print "2"
        image_input = np.multiply(image_input, 1.0 / 255.0)

        steer, acc, brake = self._control_function(image_input, speed,
                                                   direction, self._config,
                                                   self._sess,
                                                   self._train_manager)

        if brake < 0.1:
            brake = 0.0
        if acc > 2 * brake:
            brake = 0.0

        control = Control()
        control.steer = steer
        control.throttle = acc
        control.brake = brake

        control.hand_brake = 0
        control.reverse = 0

        #### DELETE THIS VERSION NOT COMMITABLE
        made_turn = 0
        completed = 0

        return control, made_turn, completed

    def compute_action(self, sensor, speed, direction=None):

        capture_time = time.time()

        if capture_time - self._start_time > 400:

            self._target = random.randint(0, len(self.positions))
            self._start_time = time.time()

        if direction == None:
            direction = self.compute_direction((0, 0, 0), (0, 0, 0))

        sensor = sensor[self._image_cut[0]:self._image_cut[1], :, :3]
        sensor = sensor[:, :, ::-1]

        sensor = scipy.misc.imresize(sensor, [
            self._config.network_input_size[0],
            self._config.network_input_size[1]
        ])

        image_input = sensor.astype(np.float32)

        #print future_image

        #print "2"

        image_input = np.multiply(image_input, 1.0 / 255.0)

        steer, acc, brake = self._control_function(image_input, speed,
                                                   direction, self._config,
                                                   self._sess,
                                                   self._train_manager)

        control = Control()
        control.steer = steer

        if control.steer > 0.3:
            control.steer = 1.0
        elif control.steer < -0.3:
            control.steer = -1.0
        else:
            control.steer = 0.0

        control.throttle = 1.0
        control.brake = 0.0
        # print brake

        control.hand_brake = 0
        control.reverse = 0

        return control

    # The augmentation should be dependent on speed

    def get_sensor_data(self):
        measurements = self.carla.getMeasurements()
        self._latest_measurements = measurements
        player_data = measurements['PlayerMeasurements']
        pos = [
            player_data.transform.location.x, player_data.transform.location.y,
            22
        ]
        ori = [
            player_data.transform.orientation.x,
            player_data.transform.orientation.y,
            player_data.transform.orientation.z
        ]

        direction = 2.0

        return measurements, direction

    def compute_perception_activations(self, sensor, speed):

        sensor = sensor[self._image_cut[0]:self._image_cut[1], :, :]

        sensor = scipy.misc.imresize(sensor, [
            self._config.network_input_size[0],
            self._config.network_input_size[1]
        ])

        image_input = sensor.astype(np.float32)

        #print future_image

        image_input = image_input - self._mean_image
        #print "2"
        image_input = np.multiply(image_input, 1.0 / 127.0)

        vbp_image = machine_output_functions.vbp(image_input, speed,
                                                 self._config, self._sess,
                                                 self._train_manager)

        min_max_scaler = preprocessing.MinMaxScaler()
        vbp_image = min_max_scaler.fit_transform(np.squeeze(vbp_image))

        # print vbp_image
        #print vbp_image
        #print grayscale_colormap(np.squeeze(vbp_image),'jet')

        vbp_image_3 = np.copy(image_input)
        vbp_image_3[:, :, 0] = vbp_image
        vbp_image_3[:, :, 1] = vbp_image
        vbp_image_3[:, :, 2] = vbp_image
        #print vbp_image

        return 0.4 * grayscale_colormap(np.squeeze(vbp_image),
                                        'inferno') + 0.6 * image_input

    def act(self, action):

        self.carla.sendCommand(action)

    def stop(self):

        self.carla.stop()
Пример #10
0
def use_example(ini_file,port = 2000, host ='127.0.0.1',print_measurements =False,images_to_disk=False):

    # We assume the CARLA server is already waiting for a client to connect at
    # host:port. To create a connection we can use the CARLA
    # constructor, it creates a CARLA client object and starts the
    # connection. It will throw an exception if something goes wrong. 

	carla =CARLA(host,port)
	
	""" As a first step, Carla must have a configuration file loaded. This will load a map in the server
		with the properties specified by the ini file. It returns all the posible starting positions on the map
		in a vector.
	"""
	positions = carla.loadConfigurationFile(ini_file)

	""" 
		Ask Server for a new episode starting on position of index zero in the positions vector
	"""
	carla.newEpisode(0)
	
	capture = time.time()
	# General iteratior
	i = 1
	# Iterator that will go over the positions on the map after each episode
	iterator_start_positions = 1

	while True:
		try:
			"""
				User get the measurements dictionary from the server. 
				Measurements contains:
				* WallTime: Current time on Wall from server machine.
				* GameTime: Current time on Game. Restarts at every episode
				* PlayerMeasurements : All information and events that happens to player
				* Agents : All non-player agents present on the map information such as cars positions, traffic light states
				* BRGA : BGRA optical images
				* Depth : Depth Images
				* Labels : Images containing the semantic segmentation. NOTE: the semantic segmentation must be
					previously activated on the server. See documentation for that. 

			"""


			measurements = carla.getMeasurements()

			# Print all the measurements... Will write images to disk
			if print_measurements:
				print_pack(measurements,i,images_to_disk)

			"""
				Sends a control command to the server
				This control structue contains the following fields:
				* throttle : goes from 0 to -1
				* steer : goes from -1 to 1
				* brake : goes from 0 to 1
				* hand_brake : Activate or desactivate the Hand Brake.
				* reverse: Activate or desactive the reverse gear.

			"""

			control = Control()
			control.throttle = 0.9
			control.steer = (random.random() * 2) - 1

			carla.sendCommand(control)
	
					
			
			i+=1


			if i % RESET_FREQUENCY ==0:
					
				print ('Fps for this episode : ',(1.0/((time.time() -capture)/100.0)))

				
				""" 
					Starts another new episode, the episode will have the same configuration as the previous
					one. In order to change configuration, the loadConfigurationFile could be called at any
					time.
				"""
				if iterator_start_positions < len(positions):
					carla.newEpisode(iterator_start_positions)
					iterator_start_positions+=1
				else :
					carla.newEpisode(0)
					iterator_start_positions = 1

				print("Now Starting on Position: ",iterator_start_positions-1)
				capture = time.time()


		except Exception as e:

			logging.exception('Exception raised to the top')
			time.sleep(1)
Пример #11
0
class App:
    def __init__(self, port=2000, host='127.0.0.1', config='./CarlaSettings.ini',\
     resolution=(2400,600),verbose=True):
        self._running = True
        self._display_surf = None
        self.port = port
        self.host = host
        self.config = config
        self.verbose = verbose
        self.resolution = resolution
        self.size = self.weight, self.height = resolution


 
    def on_init(self):
        pygame.init()
        print (" \n \n \n Welcome to CARLA manual control \n USE ARROWS for control \n Press R for reset \n"\
        +"STARTING in a few seconds...")
        time.sleep(3)
        self._display_surf = pygame.display.set_mode(self.size, pygame.HWSURFACE | pygame.DOUBLEBUF)
        logging.debug('Started the PyGame Library')
        self._running = True
        self.step = 0
        self.prev_step = 0
        self.prev_time = time.time()

        self.carla =CARLA(self.host, self.port)

        positions = self.carla.loadConfigurationFile(self.config)
        self.num_pos = len(positions)
        print ("Staring Episode on Position ",self.num_pos)
        self.carla.newEpisode(np.random.randint(self.num_pos))
        self.prev_restart_time = time.time()
 
    def on_event(self, event):
        if event.type == pygame.QUIT:
            self._running = False


    def on_loop(self):
        self.step += 1
        keys=pygame.key.get_pressed()
        gas = 0
        steer = 0
        restart = False
        pressed_keys = []
        if keys[K_LEFT]:
            steer = -1.
            pressed_keys.append('left')
        if keys[K_RIGHT]:
            pressed_keys.append('right')
            steer = 1.
        if keys[K_UP]:
            pressed_keys.append('up')
            gas = 1.
        if keys[K_DOWN]:
            pressed_keys.append('down')
            gas = -1.
        if keys[K_r]:
            pressed_keys.append('r')
            if time.time() - self.prev_restart_time > 2.:
                self.prev_restart_time = time.time()
                restart = True
        if time.time() - self.prev_restart_time < 2.:
            gas = 0.
            steer = 0.

        control = Control()
        control.throttle = gas
        control.steer = steer
        self.carla.sendCommand(control)
        measurements = self.carla.getMeasurements()
        pack = measurements['PlayerMeasurements']
        self.img_vec = measurements['BGRA']
        self.depth_vec = measurements['Depth']
        self.labels_vec = measurements['Labels']


        if time.time() - self.prev_time > 1.:
            print('Step', self.step, 'FPS', float(self.step - self.prev_step) / (time.time() - self.prev_time))

            
            print('speed', pack.forward_speed, 'collision', pack.collision_other, \
            'collision_car', pack.collision_vehicles, 'colision_ped', pack.collision_pedestrians, 'pressed:', pressed_keys)            
            self.prev_step = self.step
            self.prev_time = time.time()
            
        if restart:
            print('\n *** RESTART *** \n')

            player_pos = np.random.randint(self.num_pos)

            print('  Player pos %d \n' % (player_pos))
            self.carla.newEpisode(player_pos)
        
        
    """
        The render method plots the First RGB, the First Depth and First Semantic Segmentation Camera
    """
    def on_render(self):

        pos_x =0


        
        if len(self.depth_vec) > 0:
            self.depth_vec[0] = self.depth_vec[0][:,:,:3]
            self.depth_vec[0] = self.depth_vec[0][:,:,::-1]
            self.depth_vec[0] = convert_depth(self.depth_vec[0])
            surface = pygame.surfarray.make_surface(np.transpose(self.depth_vec[0], (1,0,2)))
            self._display_surf.blit(surface,(pos_x,0))
            pos_x += self.depth_vec[0].shape[1]

        if len(self.img_vec) > 0:
            self.img_vec[0] = self.img_vec[0][:,:,:3]
            self.img_vec[0] = self.img_vec[0][:,:,::-1]
            surface = pygame.surfarray.make_surface(np.transpose(self.img_vec[0], (1,0,2)))
            self._display_surf.blit(surface,(pos_x,0))
            pos_x += self.img_vec[0].shape[1]

        if len(self.labels_vec) > 0:
            self.labels_vec[0] = join_classes(self.labels_vec[0][:,:,2])
            surface = pygame.surfarray.make_surface(np.transpose(self.labels_vec[0], (1,0,2)))
            self._display_surf.blit(surface,(pos_x,0))
            pos_x += self.labels_vec[0].shape[1]


            
        pygame.display.flip()

        
    def on_cleanup(self):
        self.carla.closeConections()
        pygame.quit()
 
    def on_execute(self):
        if self.on_init() == False:
            self._running = False
 
        while( self._running ):
            try:

                for event in pygame.event.get():
                    self.on_event(event)
                self.on_loop()
                self.on_render()

            except Exception as e:
                logging.exception(e)
                self._running = False
                break


        self.on_cleanup()
Пример #12
0
    def main_loop(self):
        # Carla Setup
        carla = CARLA(self.host, self.port)
        positions = carla.loadConfigurationFile(self.ini_file)
        carla.newEpisode(0)
        capture = time.time()
        i = 1
        # Iterator that will go over the positions on the map after each episode
        iterator_start_positions = 1

        rate = rospy.Rate(ROS_FREQUENCY)
        while not rospy.is_shutdown():
            try:
                """
					User get the measurements dictionary from the server. 
					Measurements contains:
					* WallTime: Current time on Wall from server machine.
					* GameTime: Current time on Game. Restarts at every episode
					* PlayerMeasurements : All information and events that happens to player
					* Agents : All non-player agents present on the map information such as cars positions, traffic light states
					* BRGA : BGRA optical images
					* Depth : Depth Images
					* Labels : Images containing the semantic segmentation. NOTE: the semantic segmentation must be
						previously activated on the server. See documentation for that. 

				"""
                measurements = carla.getMeasurements()
                self.measurements_process(measurements)
                self.measurements_publish()
                """
					Sends a control command to the server
					This control structue contains the following fields:
					* throttle : goes from 0 to 1
					* steer : goes from -1 to 1
					* brake : goes from 0 to 1
					* hand_brake : Activate or desactivate the Hand Brake.
					* reverse: Activate or desactive the reverse gear.

				"""

                control = Control()
                control.throttle = 0.9
                control.steer = 0
                carla.sendCommand(control)
                rate.sleep()

                i += 1

                if i % RESET_FREQUENCY == 0:

                    print('Fps for this episode : ',
                          (1.0 / ((time.time() - capture) / 100.0)))
                    """ 
						Starts another new episode, the episode will have the same configuration as the previous
						one. In order to change configuration, the loadConfigurationFile could be called at any
						time.
					"""
                    if iterator_start_positions < len(positions):
                        carla.newEpisode(iterator_start_positions)
                        iterator_start_positions += 1
                    else:
                        carla.newEpisode(0)
                        iterator_start_positions = 1

                    print("Now Starting on Position: ",
                          iterator_start_positions - 1)
                    capture = time.time()

            except KeyboardInterrupt:
                pass