Example #1
0
enableRepaint(False)
while not isDisposed():
    if eState == "UPWARD":
        clear()
        drawImage(img1)
        if getY() > 0:
            delay(random.randint(1000, 5000))
            eState = "UPWARD1"
        repaint()
        forward(4)
        delay(50)             
    if eState == "UPWARD1":
        clear()
        drawImage(img2)
        if getY() > 200:
            server.sendMessage("Go")
            eState = "DOWNWARD"
        repaint()
        forward(4)
        delay(50)             
    elif eState == "DOWNWARD":
        clear()
        drawImage(img0)
        repaint()
        back(20)             
        delay(50)             
        if getY() < -200:
            eState = "STOPPED"
    elif eState == "STOPPED":
        delay(1000)
Example #2
0
gear = Gear()
gear.setSpeed(25)
irLeft = InfraredSensor(IR_LINE_LEFT)
irRight = InfraredSensor(IR_LINE_RIGHT)
irCenter = InfraredSensor(IR_CENTER)
r = 0.1
port = 5000
server = TCPServer(port, stateChanged=onStateChanged)
start = time.time()
isWaiting = True
while not isEscapeHit():
    if isWaiting:
        continue
    vL = irLeft.getValue()
    vR = irRight.getValue()
    vC = irCenter.getValue()
    if vL == 1 and vR == 0:
        gear.forward()
    elif vL == 0 and vR == 0:
        gear.leftArc(r)
    elif vL == 1 and vR == 1:
        gear.rightArc(r)
    if vC == 1 and time.time() - start > 5:
        server.sendMessage("go")
        display.showText("stop")
        gear.stop()
        isWaiting = True

server.terminate()
robot.exit()
                            R_flip * R_tc)

                        #print(x_rot,y_rot,z_rot)

                        if (x_rot < -2 and z_rot > 2):
                            #print("SOUTH")
                            south += 1
                        elif (x_rot < 0):
                            #print("NORTH")
                            north += 1
                    i = i + 1

            cv.imshow('frame', frame)  #display the frame

            key = cv.waitKey(1) & 0xFF  #press q to quit
            if key == ord('q'):
                video.release()
                cv.destroyAllWindows()
                break
        elif (time.time() - start > 25):
            # match finished
            if (north > south):
                server.sendMessage("NORTH")
            else:
                server.sendMessage("SOUTH")
            matchStarted = False
            server.terminate()
            video.release()
            cv.destroyAllWindows()
            break
Example #4
0
    elif state == "CONNECTED":
        print "Server:-- Connected to", msg


def readData(port=0):
    if port == 0:
        adc_address = 0x48
    elif port == 1:
        adc_address = 0x4D
    rd = bus.read_word_data(adc_address, 0)
    data = ((rd & 0xFF) << 8) | ((rd & 0xFF00) >> 8)
    data = data >> 2
    return data


def setup():
    GPIO.setmode(GPIO.BOARD)
    GPIO.setup(P_BUTTON, GPIO.IN)


print "starting..."
setup()
bus = smbus.SMBus(1)
server = TCPServer(port, stateChanged=onStateChanged)
while GPIO.input(P_BUTTON) == GPIO.LOW:
    if server.isConnected():
        v = readData()
        server.sendMessage(str(v))
        time.sleep(dt)
server.terminate()
print "Server terminated"
Example #5
0
    global isGameServerRunning
    isGameServerRunning = False


readyForNextTurn = False
isMouseEnabled = False
makeTurtle(mouseHit=onMouseHit, closeClicked=onCloseClicked)
addStatusBar(30)
hideTurtle()
setCustomCursor("sprites/cathead.png")
port = 5000
server = TCPServer(port, stateChanged=onStateChanged)

# Game Supervisor
isGameServerRunning = True
serverReady = False
clientReady = False
while isGameServerRunning:
    if serverReady and clientReady:
        time.sleep(4)
        serverReady = False
        clientReady = False
        xPrey = random.randint(-300, 300)
        yPrey = random.randint(-300, 300)
        server.sendMessage("setPos(" + str(xPrey) + ", " + str(yPrey) + ")")
        setPos(xPrey, yPrey)
        drawImage("sprites/mouse.gif")
        startTime = time.time()
        isMouseEnabled = True
server.terminate()
dispose()
Example #6
0
    se3.setEditable(False)
    pane1 = EntryPane(se1, se2, se3)
    btn = ButtonEntry("Send")
    pane2 = EntryPane(btn)
    dlg = EntryDialog(pane1, pane2)
    dlg.setTitle("Server's Chat Dialog")
    dlg.show()


def onStateChanged(state, msg):
    if state == TCPServer.PORT_IN_USE:
        se3.setValue("Port " + str(port) + " in use")
    elif state == TCPServer.LISTENING:
        se3.setValue("Waiting for a client on port " + str(port))
        se1.setValue("")
        se2.setValue("")
    elif state == TCPServer.CONNECTED:
        se3.setValue("Client connected. Enter your message!")
    elif state == TCPServer.MESSAGE:
        se2.setValue(msg)


port = 5000
server = TCPServer(port, stateChanged=onStateChanged)
showChatDialog()
while not dlg.isDisposed():
    if btn.isTouched():
        server.sendMessage(se1.getValue())
        se1.setValue("")
server.terminate()
Example #7
0
class Toddler:
    __version = '2018a'

    def __init__(self, IO):
        print('[Toddler] I am toddler {} playing in a sandbox'.format(
            Toddler.__version))

        # Start up all the External IO stuff
        self.camera = IO.camera.initCamera('pi', 'low')
        self.getInputs = IO.interface_kit.getInputs
        self.getSensors = IO.interface_kit.getSensors
        self.mc = IO.motor_control
        self.sc = IO.servo_control
        self.motor_control = MotorMover()

        # Get the config from the file
        self.config = ConfigParser.ConfigParser()
        self.config.read('/home/student/config.txt')

        # Set up servers and client
        self.server_port = 5010
        self.client_port = int(
            self.config.get(
                "DELIVERAI",
                'WEB_SERVER_COMM_PORT'
            ))
        self.client_connect_address = self.config.get(
            "DELIVERAI",
            'WEB_SERVER_IP'
        )

        self.server = TCPServer(
            self.server_port,
            stateChanged=self.on_server_msg,
            isVerbose=False
        )
        self.client = TCPClient(
            self.client_connect_address,
            self.client_port,
            stateChanged=self.on_client_msg
        )
        self.connected = False
        self.try_connect()

        # Set up robot state
        self.not_sent_stop = [True, True, True, True]
        self.mode = "READY"
        self.pick_from = (0, 0)
        self.deliver_to = (0, 0)
        self.current_movment_bearing = 0
        self.alarm = False
        self.box_open = False
        self.mode_debug_on = False
        self.box_timeout = None
        self.sleep_time = 0.05

        # Set up sensor + motor values
        self.accel = LSM303()
        self.acc_counter = [0, 0, 0]
        self.calibrated = 0
        self.base_accel = np.zeros(3)  # will be set during calibration
        self.accel_val_num = 20
        self.last_accels = deque()
        self.accel_data = deque(
            [-1] * self.accel_val_num
        )  # accelerometer array used for smoothing
        self.vel = np.zeros(3)
        self.pos = np.zeros(3)
        self.last_accel = np.zeros(3)
        self.last_vel = np.zeros(3)
        self.door_mech_motor = 2
        self.lock_motor = 3
        self.motor_speed = 40

    def __del__(self):
        print("[__del__] Cleaning Up...")
        self.client.disconnect()
        threading.cleanup_stop_thread()

    # CONTROL THREAD
    def control(self):
        self.detect_obstacle()
        self.accel_alarm()  # needs improvement to be used again
        self.box_alarm()
        time.sleep(self.sleep_time)

    # VISION THREAD
    def vision(self):
        # Block vision branch for now because we don't use it
        time.sleep(0.05)

    def open_box_motor(self):
        self.open_lock()
        self.motor_control.motor_move(self.door_mech_motor, self.motor_speed)
        # Open lid until bump switched is pressed
        while (self.getInputs()[1] == 1):
            time.sleep(0.01)
        self.mc.stopMotor(self.door_mech_motor)
        # If the close command does not get sent after 60 seconds the box will
        # close its self
        self.box_timeout = threading.Timer(60.0, self.auto_close_box)
        self.box_timeout.start()

    def auto_close_box(self):
        self.server.sendMessage("AUTOCLOSE")
        time.sleep(10)
        self.close_box_motor()

    def close_box_motor(self):
        self.motor_control.motor_move(self.door_mech_motor, -self.motor_speed)
        # Close lid until bump switched is pressed
        while (self.getInputs()[2] == 1):
            time.sleep(0.01)
        self.mc.stopMotor(self.door_mech_motor)
        self.close_lock()
        time.sleep(1)
        if (self.state == "PICKINGUP"):
            self.state = "DELIVERING"
            self.send_robot_to(self.deliver_to[0], self.deliver_to[1])
        if (self.state == "DELIVERING"):
            self.state = "READY"
            self.client.sendMessage("READY")

    def open_lock(self):
        self.box_open = True
        self.mc.stopMotor(self.lock_motor)

    def close_lock(self):
        self.mc.setMotor(self.lock_motor, 100)
        self.box_open = False

    def on_server_msg(self, state, msg):
        if state == "LISTENING":
            print("[on_server_msg] Server:-- Listening...")
        elif state == "CONNECTED":
            print("[on_server_msg] Server:-- Connected to" + msg)
        elif state == "MESSAGE":
            print("[on_server_msg] Server:-- Message received:" + msg)
            self.process_server_message(msg)
            self.server.sendMessage("OK")

    def on_client_msg(self, state, msg):
        if (state == "CONNECTED"):
            print("[on_client_msg] Sucess - Connected to Server :" + msg)
        elif (state == "DISCONNECTED"):
            print(
                "[on_client_msg] Disconnected from Server - Trying to "
                "connect again...")
            self.try_connect()
        elif (state == "MESSAGE"):
            print("[on_client_msg] Message Received from server")
            self.process_client_message(msg)

    def try_connect(self):
        while not (self.connected):
            conn = self.client.connect()
            if conn:
                self.connected = True
            else:
                self.connected = False
                time.sleep(10)

    def process_server_message(self, msg):
        print("[process_server_message] Processing Msg Received")
        broken_msg = msg.split("$")
        if (broken_msg[0] == "ARRIVED"):
            print("[process_server_message] Arrived at dest requested")
            if (self.state == "GOINGHOME"):
                print("[process_server_message] At home awaiting command...")
                # do nothing
            elif (self.state == "PICKINGUP" or self.state == "DELIVERING"):
                print("[process_server_message] Waiting for authorisation")
                self.request_authentication()
        elif (broken_msg[0] == "BEARING"):
            print("bearing recved " + broken_msg[1])
            self.current_movment_bearing = int(broken_msg[1])

    def process_client_message(self, msg):
        print("[process_client_message] Processing Msg Recived")
        broken_msg = msg.split("$")
        if (self.mode_debug_on):
            print("[process_client_message] Debug Msg Received")
            self.process_debug_msg(msg)
        elif (broken_msg[0] == "GOHOME"):
            self.state = "GOINGHOME"
            self.send_robot_to(0, 0)
        elif (broken_msg[0] == "PICKUP"):
            self.state = "PICKINGUP"
            self.pick_from = (int(broken_msg[1]), int(broken_msg[2]))
            self.deliver_to = (int(broken_msg[4]), int(broken_msg[5]))
            self.send_robot_to(self.pick_from[0], self.pick_from[1])
        elif (broken_msg[0] == "OPEN"):
            self.open_box_motor()
        elif (broken_msg[0] == "CLOSE"):
            self.box_timeout.cancel()  # Cancel the auto-close
            self.close_box_motor()
        elif (broken_msg[0] == "ALARMSTOP"):
            self.server.sendMessage("ALARMSTOP")
            self.alarm = False
        elif (broken_msg[0] == "DEBUGMODEON"):
            self.mode_debug_on = True
        elif (broken_msg[0] == "TESTCONNEV3"):
            self.test_conn_ev3()
        elif (broken_msg[0] == "UPDATEMAP"):
            self.server.sendMessage("UPDATEMAP")
        elif (broken_msg[0] == "BEARING"):
            self.current_movment_bearing = int(broken_msg[1])
        elif (broken_msg[0] == "POWEROFF"):
            self.server.sendMessage("POWEROFF")
            self.client.disconnect()
            time.sleep(5)
            os.system("sudo poweroff")

    def process_debug_msg(self, msg):
        if (msg == "DEBUGMODEOFF"):
            self.mode_debug_on = False
        f = open("cmd_recved.txt", "a+")
        f.write(msg + "\n")

    def send_robot_to(self, x, y):
        print("[send_robot_to] Sending Robot to " + str(x) + ", " + str(y))
        self.server.sendMessage("GOTO$" + str(x) + "$" + str(y))

    def request_authentication(self):
        self.client.sendMessage("AUTHENTICATE")

    # Detect obstacle within the range of min_dist
    def detect_obstacle(self):
        min_dist = 20
        an_input = self.getSensors()
        ir_input = [an_input[i] for i in range(4)]
        dist = [self.input_to_cm(x) for x in ir_input]
        for i in range(4):
            if dist[i] != -1 and dist[i] < min_dist:
                self.stop(i)
            else:
                self.continue_path(i)

    # Function for reacting according to obstacle in direction dir where dir=
    # 0 - Front, 1 - Right, 2 - Back, 3 - Left
    def stop(self, dir):
        # If the dirrection is NOT (current_movment_bearing + 2 mod 4) i.e.
        # behind us - we can send stop
        if (dir != ((self.current_movment_bearing + 2) % 4)):
            # print("[stop] Obstacle in {} - currently facing {}".format(
            # dir, self.current_movment_bearing))  # noqa: E501
            self.not_sent_stop[dir] = False
            self.server.sendMessage("STOP")

    def continue_path(self, i):
        if not (self.not_sent_stop[i]):
            print("[continue_path] Obstacle in %d cleared!" % i)
            self.not_sent_stop[i] = True
            if (reduce(operator.and_, self.not_sent_stop, True)):
                self.server.sendMessage("CONT")

    # Convert analog input from IR sensor to cm
    # Formula taken from:
    # https://www.phidgets.com/?tier=3&catid=5&pcid=3
    # &prodid=70#Voltage_Ratio_Input
    # IR sensor model used: GD2D12 - range: 10-80cm
    def input_to_cm(self, an_input):
        # Input has to be adapted as the input differs from the value range on
        # the website by a factor of 1000
        voltageRatio = an_input / 1000.0
        if voltageRatio > 0.08 and voltageRatio < 0.53:  # from the website
            dist = 4.8 / (voltageRatio - 0.02)
        else:
            dist = -1
        return dist

    # Checks for unauthorized opening of the box - using bump sensor
    def box_alarm(self):
        box_alarm = self.getInputs()[2]  # Get sensor value from bump switch
        if box_alarm == 1 and not (self.box_open):
            self.send_alarm()
            print("[box_alarm] Box Open - Not Due to be")

    def send_alarm(self):
        self.server.sendMessage("ALARM")

    def integrate_accel(self, accel, last_accel):

        last_accel = np.array(last_accel)
        delta_vel = (accel + ((accel - last_accel) / 2.0)) * self.sleep_time
        self.vel = np.array(delta_vel) + self.vel

    # Check if no accel in any direction and increase corresponding counter
        for i in range(len(accel)):
            if accel[i] == 0:
                self.acc_counter[i] += 1
            else:
                self.acc_counter[i] = 0

        # If the last 25 values for 1 direction have been 0, set velocity to 0
        for i in range(len(self.acc_counter)):
            if self.acc_counter[i] > 15:
                self.vel[i] = 0

        return np.array(self.vel)

    def integrate_vel(self, vel, last_vel):
        vel = np.array(vel)
        last_vel = np.array(last_vel)

        delta_pos = (vel + ((vel - last_vel) / 2.0)) * self.sleep_time
        self.pos = np.array(delta_pos + self.pos)
        return np.array(self.pos)

    # Checks for unexpected movement/robot being stolen - using accelerometer
    def accel_alarm(self):
        if self.calibrated < 3:
            self.calibrate_accel()
            return

        cur_accel = self.read_smooth_accel()

        # If we haven't had enough readings for averaging - don't continue
        if (cur_accel == -1):
            return

        accel = np.array(cur_accel)
        vel = self.integrate_accel(accel, self.last_accel)
        pos = self.integrate_vel(vel, self.last_vel)
        print("--------------------------------------------------------------")
        print("Accel: x:%.2f   y:%.2f  z:%.2f" % (
            accel[0], accel[1], accel[2]))
        print("Vel: x:%.2f   y:%.2f  z:%.2f" % (vel[0], vel[1], vel[2]))
        print("Pos: x:%.2f   y:%.2f  z:%.2f" % (pos[0], pos[1], pos[2]))

        if abs(vel[2]) > 6 or abs(vel[1]) > 10 or abs(vel[0]) > 10:
            if not (self.alarm):
                self.send_alarm()
                self.alarm = True
                print("[accel_alarm] ALARM STATE -- X: %.2f -- Y: %.2f -- Z: %.2f " % (vel[0], vel[1], vel[2]))  # noqa E501

        self.last_accel = accel
        self.last_vel = vel

    # Smooth accelerometer output by taking the average of the last n values
    # where n = len(self.accel_data)
    def read_smooth_accel(self):
        #        print(self.base_accel)
        cur_accel, _ = self.accel.read()
        # calibrate input
        cur_accel = (np.array(cur_accel) - self.base_accel).tolist()

        # To filter out mechanical noise
        for i in range(len(cur_accel)):
            if cur_accel[i] > -30 and cur_accel[i] < 30:
                cur_accel[i] = 0

            self.accel_data.pop()
            self.accel_data.appendleft(cur_accel)
            # For the first len(accel_data) values the average is not
            # representative - return -1 to represent that
            if -1 in self.accel_data:
                return -1

            av_accel = [sum(i) / float(len(i)) for i in zip(*self.accel_data)]

        for i in range(len(av_accel)):
            if av_accel[i] < 20 and av_accel[i] > -20:
                av_accel[i] = 0

            return av_accel

    def calibrate_accel(self):
        cur_accel, _ = self.accel.read()
        if -1 in self.accel_data:
            self.accel_data.pop()
            self.accel_data.appendleft(cur_accel)
        else:
            av_accel = [sum(i) / float(len(i)) for i in zip(*self.accel_data)]
            self.base_accel = np.array(av_accel)
            self.calibrated = self.calibrated + 1
            self.accel_data = deque([-1] * self.accel_val_num)
            # reset data_accel deque

    def test_conn_ev3(self):
        self.server.sendMessage("DEBUGMODEON")
        time.sleep(2)
        file_in = open("cmds_to_send.txt", "r")
        lines = file_in.readlines()
        for l in lines:
            self.server.sendMessage(l)
Example #8
0
import RPi.GPIO as GPIO


def onStateChanged(state, msg):
    print "State:", state, "Msg:", msg


P_BUTTON1 = 16  # Switch pin number
dt = 1  # 1 s period
port = 5000  # IP port

GPIO.setmode(GPIO.BOARD)
GPIO.setwarnings(False)
GPIO.setup(P_BUTTON1, GPIO.IN, GPIO.PUD_UP)
server = TCPServer(port, stateChanged=onStateChanged)
n = 0
while True:
    if server.isConnected():
        rc = GPIO.input(P_BUTTON1)
        if rc == 0:
            server.sendMessage("pressed")
            n += 1
            if n == 3:
                break
        else:
            server.sendMessage("released")
            n = 0
        time.sleep(dt)
server.terminate()
print "Server terminated"