Beispiel #1
0
class PiWS281X(DriverBase):
    """
    Driver for controlling WS281X LEDs via the rpi_ws281x C-extension.
    Only supported on the Raspberry Pi 2 & 3
    """
    def __init__(self, num, gamma=gamma.NEOPIXEL, c_order=ChannelOrder.RGB, gpio=18,
                 ledFreqHz=800000, ledDma=5, ledInvert=False, **kwds):
        """
        num - Number of LED pixels.
        gpio - GPIO pin connected to the pixels (must support PWM! GPIO 13 or 18 (pins 33 or 12) on RPi 3).
        ledFreqHz - LED signal frequency in hertz (800khz or 400khz)
        ledDma - DMA channel to use for generating signal (Between 1 and 14)
        ledInvert - True to invert the signal (when using NPN transistor level shift)
        """
        super().__init__(num, c_order=c_order, gamma=gamma, **kwds)
        self.gamma = gamma
        self._strip = Adafruit_NeoPixel(num, gpio, ledFreqHz,
                                        ledDma, ledInvert, 255, 0, 0x081000)
        # Intialize the library (must be called once before other functions).
        self._strip.begin()

    def set_brightness(self, brightness):
        self._strip.setBrightness(brightness)
        return True

    def _compute_packet(self):
        self._render()
        data = self._buf
        self._packet = [tuple(data[(p * 3):(p * 3) + 3]) for p in range(len(data) // 3)]

    def _send_packet(self):
        for i, p in enumerate(self._packet):
            self._strip.setPixelColor(i, NeoColor(*p))

        self._strip.show()
Beispiel #2
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class LEDStrip(object):
    def __init__(self, array: TileArray):
        from neopixel import Adafruit_NeoPixel
        # Create NeoPixel object with appropriate configuration.
        self.strip = Adafruit_NeoPixel(array.size(), LED_PIN, LED_FREQ_HZ, LED_DMA, LED_INVERT, LED_BRIGHTNESS,
                                       LED_CHANNEL)
        # Intialize the library (must be called once before other functions).
        self.strip.begin()
        self.array = array

    def draw(self, image: np.ndarray, delay: float = 0.001):
        """
        Draws a matrix of color values to the dancefloor tiles. Handles the math of calculating what pixels
        correspond to which LEDs in the chain of LED strips. The input image should have a shape of
        (height, width, 3) where height is the LEDs in the vertical direction and width is the total LEDs in
        the horizontal direction.
        :param image: Matrix of colors to display on the dancefloor
        :param delay: Seconds to wait after finishing writing to the LED strips
        """
        from neopixel import Color
        start = time.time()
        for y in range(image.shape[0]):
            for x in range(image.shape[1]):
                idx = self.array.index(x, y)
                r = int(image[y][x][0])
                g = int(image[y][x][1])
                b = int(image[y][x][2])
                color = Color(g, r, b)
                self.strip.setPixelColor(idx, color)
        self.strip.show()
        end = time.time()
        delta = end - start
        if delay > delta:
            time.sleep(delay - delta)
Beispiel #3
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class StripController:
  def __init__(self):
    self.ledCount_ = 100
    self.height_ = 10
    self.neopixel_ = Adafruit_NeoPixel(
        self.ledCount_,  # LED count
        18,  # LED pin
        800000,  # LED signal frequency (Hz)
        10,  # DMA channel
        False,  # Invert signal
        100,  # Brightness (0, 255)
        0)  # LED channel
    self.neopixel_.begin()

  def set(self, index, color):
    if index >= self.ledCount_:
      raise Exception('setting out of bounds pixel', index)
    self.neopixel_.setPixelColor(index, color)

  def show(self):
    self.neopixel_.show()

  def cleanUpGrid(self):
    width = self.ledCount_ / self.height_
    return [[BLACK] * width] * self.height_
Beispiel #4
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class LEDStripPWM(LEDStrip):
    def __init__(self, array: TileArray):
        super().__init__(array)
        from neopixel import Adafruit_NeoPixel
        # Create NeoPixel object with appropriate configuration.
        self.strip = Adafruit_NeoPixel(array.size(), LED_PIN, LED_FREQ_HZ,
                                       LED_DMA, LED_INVERT, LED_BRIGHTNESS,
                                       LED_CHANNEL)
        # Intialize the library (must be called once before other functions).
        self.strip.begin()

    def draw(self, image: np.ndarray, delay: float = 0.001):
        from neopixel import Color
        start = time.time()
        for y in range(image.shape[0]):
            for x in range(image.shape[1]):
                idx = self.array.index(x, y)
                r = int(image[y][x][0])
                g = int(image[y][x][1])
                b = int(image[y][x][2])
                color = Color(g, r, b)
                self.strip.setPixelColor(idx, color)
        self.strip.show()
        end = time.time()
        delta = end - start
        if delay > delta:
            time.sleep(delay - delta)
Beispiel #5
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class DriverPiWS281X(DriverBase):

    def __init__(self, num, gamma=gamma.NEOPIXEL, c_order=ChannelOrder.RGB, ledPin=18, ledFreqHz=800000, ledDma=5, ledInvert=False):
        """
        num - Number of LED pixels.
        ledPin - GPIO pin connected to the pixels (must support PWM! pin 13 or 18 on RPi 3).
        ledFreqHz - LED signal frequency in hertz (800khz or 400khz)
        ledDma - DMA channel to use for generating signal (Between 1 and 14)
        ledInvert - True to invert the signal (when using NPN transistor level shift)
        """
        super(DriverPiWS281X, self).__init__(num, c_order=c_order, gamma=gamma)
        self.gamma = gamma
        self._strip = Adafruit_NeoPixel(num, ledPin, ledFreqHz, ledDma, ledInvert, 255, 0, 0x081000)
        # Intialize the library (must be called once before other functions).
        self._strip.begin()

    # Set Brightness of the strip. A brightness of 0 is the darkest and 255 is
    # the brightest
    def setMasterBrightness(self, brightness):
        self._strip.setBrightness(brightness)

    # Push new data
    def update(self, data):
        # handle channel order and gamma correction
        self._fixData(data)
        data = self._buf

        pixels = [tuple(data[(p * 3):(p * 3) + 3])
                  for p in range(len(data) / 3)]

        for i in range(len(data) / 3):
            self._strip.setPixelColor(i, NeoColor(pixels[i][0], pixels[i][1], pixels[i][2]))

        self._strip.show()
Beispiel #6
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class Matrix:
    def __init__(self):
        # LED strip configuration:
        self.led_count = 256  # Number of LED pixels.
        self.led_pin = 18  # GPIO pin connected to the pixels (18 uses PWM!).
        self.led_freq_hz = 800000  # LED signal frequency in hertz (usually 800khz)
        self.led_dma = 10  # DMA channel to use for generating signal (try 10)
        self.led_brightness = 15  # Set to 0 for darkest and 255 for brightest
        self.led_invert = False  # True to invert the signal (when using NPN transistor level shift)
        self.led_channel = 0  # set to '1' for GPIOs 13, 19, 41, 45 or 53

        self.matrix = Adafruit_NeoPixel(self.led_count, self.led_pin,
                                        self.led_freq_hz, self.led_dma,
                                        self.led_invert, self.led_brightness,
                                        self.led_channel)

        self.matrix.begin()
        self.frame = Frame(rows=8, cols=32)

    def color_wipe(self, color: Color = Color()):
        for x, y, pixel in self.frame.fill():
            pixel.color = color

    def display_text(self, color: Color = Color(), row_1=""):
        t = Text(row_1)
        t = t.array

        for i in range(self.frame.cols()):
            for x, y, pixel in self.frame.fill():
                if t[x][y]:
                    pixel.color = color

    def scrolling_text(self,
                       color: Color = Color(),
                       repetitions=1,
                       row_1="",
                       row_2=""):
        t = Text(row_1)
        t = t.array

        for rep in range(repetitions):
            for i in range(len(t)):
                for x, y, pixel in self.frame.fill():
                    if t[y][x]:
                        pixel.color = color
                self.render()
                t[i].append(t[i].pop(0))
                time.sleep(1)
                self.cleanup()

    def render(self):
        for position, color in self.frame.canvas():
            self.matrix.setPixelColor(position, color)
        self.matrix.show()

    def cleanup(self):
        self.color_wipe()
class LEDStrip:
    axis = None

    green = None
    red = None
    blue = None

    neopixel_Object = None
    LED_COUNT = 38  # Number of LED pixels.
    LED_PIN = None  # GPIO pin connected to the pixels (18 uses PWM!).
    LED_FREQ_HZ = 800000  # LED signal frequency in hertz (usually 800khz)
    LED_DMA = 10  # DMA channel to use for generating signal (try 10)
    LED_BRIGHTNESS = 255  # Set to 0 for darkest and 255 for brightest
    LED_INVERT = False  # True to invert the signal (when using NPN transistor level shift)
    LED_CHANNEL = 0  # set to '1' for GPIOs 13, 19, 41, 45 or 53
    limitHeight = LED_COUNT

    def __init__(self, axis, GPIO_Pin, LED_COUNT=38, LED_FREQ_HZ=800000, LED_DMA=10, LED_BRIGHTNESS=255,
                 LED_INVERT=False, LED_CHANNEL=0):
        print("Initializing LED Strip on GPIO Pin " + str(GPIO_Pin))
        from neopixel import Adafruit_NeoPixel
        self.LED_COUNT = LED_COUNT
        self.LED_PIN = GPIO_Pin
        self.LED_FREQ_HZ = LED_FREQ_HZ
        self.LED_DMA = LED_DMA
        self.LED_BRIGHTNESS = LED_BRIGHTNESS
        self.LED_INVERT = LED_INVERT
        self.LED_CHANNEL = LED_CHANNEL
        self.green = 0
        self.red = 0
        self.blue = 0
        self.neopixel_Object = Adafruit_NeoPixel(self.LED_COUNT, self.LED_PIN, self.LED_FREQ_HZ, self.LED_DMA,
                                                 self.LED_INVERT, self.LED_BRIGHTNESS,
                                                 self.LED_CHANNEL)
        self.neopixel_Object.begin()
        updateColorsThread = Thread(target=self.updateColors)
        updateColorsThread.start()
        print("Started updateColors Thread")

    def updateColors(self):
        oldGreen = self.green
        oldRed = self.red
        oldBlue = self.blue
        limit = 40
        while True:
            if self.green != oldGreen or self.red != oldRed or self.blue != oldBlue:
                oldGreen = self.green
                oldRed = self.red
                oldBlue = self.blue
                print("Green: " + "{:>3}".format(str(self.green)) + ", Red: " + "{:>3}".format(
                    str(self.red)) + ", Blue: " + "{:>3}".format(str(self.blue)) + "\n")
                color = Color(self.green, self.red, self.blue)
                for i in range(self.neopixel_Object.numPixels()):
                    if i < self.limitHeight:
                        self.neopixel_Object.setPixelColor(i, color)
                self.neopixel_Object.show()
                time.sleep(50 / 1000.0)
class Lightstrip(object):
    def __init__(self, cfg):
        nps = cfg['neopixel']
        self.strip = Adafruit_NeoPixel(nps['led-count'], \
         nps['led-pin'], nps['led-freq-hz'], nps['led-dma'], \
         nps['led-invert'], nps['led-brightness'], nps['led-channel'])

        self.reversed = cfg['custom']['reversed']

        self.strip.begin()

    def _cleanup(self):
        self.strip._cleanup()

    def show(self):
        self.strip.show()

    # Sets the pixel without updating the strip
    #  Allows reversal of direction of the strip
    #  Ensures bounded pixel index from [0, numPixels)
    def setPixel(self, n, color):
        pixelNum = self.strip.numPixels() - 1 - n if self.reversed else n
        pixelNum %= self.strip.numPixels()
        self.strip.setPixelColor(pixelNum, color)

    # Sets the pixel and immediately updates the lightstrip visually
    def setPixelUpdate(self, n, color):
        self.setPixel(n, color)
        self.show()

    def setBrightness(self, n):
        self.strip.setBrightness(n)

    def getBrightness(self):
        self.strip.getBrightness()

    def setReversed(self, rev):
        self.reversed = rev

    def getReversed(self):
        return self.reversed

    def numPixels(self):
        return self.strip.numPixels()

    # The only animation I am baking into the lightstrip class because
    #  it has pretty universal importance among other animations and
    #  the runner class too
    def clear(self):
        for i in range(self.strip.numPixels()):
            self.setPixel(i, Color(0, 0, 0))
        self.show()

    def clearPixel(self, n):
        self.setPixel(n, Color(0, 0, 0))
Beispiel #9
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    class __Instance:

        # LED strip configuration:
        LED_COUNT = 150 - 27  # Number of LED pixels.
        LED_PIN = 18  # GPIO pin connected to the pixels (must support PWM!).
        LED_FREQ_HZ = 800000  # LED signal frequency in hertz (usually 800khz)
        LED_DMA = 5  # DMA channel to use for generating signal (try 5)
        LED_BRIGHTNESS = 255  # Set to 0 for darkest and 255 for brightest
        LED_INVERT = False  # True to invert the signal (when using NPN transistor level shift)

        def __init__(self):
            random.seed()

            self.__strip = Adafruit_NeoPixel(self.LED_COUNT, self.LED_PIN,
                                             self.LED_FREQ_HZ, self.LED_DMA,
                                             self.LED_INVERT,
                                             self.LED_BRIGHTNESS)
            self.__strip.begin()

        LIT_COUNT = 10
        last = [0] * LIT_COUNT

        def twinkle(self):
            while True:
                for i in range(0, self.LIT_COUNT):
                    self.__strip.setPixelColor(self.last[i], color.Black())
                    self.last[i] = random.randint(0, self.__strip.numPixels())

                    self.__strip.setPixelColor(self.last[i], color.Random())

                self.__strip.show()
                util.delay(150)

        def walk(self):
            while True:
                for i in range(0, self.__strip.numPixels()):
                    self.__strip.setPixelColor(i, color.Random())
                    self.__strip.show()
                    util.delay(100.0)

                util.delay(750.0)

        def set_color(self, color):
            for i in range(0, self.__strip.numPixels()):
                self.__strip.setPixelColor(i, color)

            self.__strip.show()

        def cylon(self):
            red = 0
            for i in range(0, self.__strip.numPixels()):
                self.__strip.setPixelColor(i, color.Color(red, 0, 0))
                red += 1

            self.__strip.show()
Beispiel #10
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def _get_strip():
    strip = Adafruit_NeoPixel(LED_COUNT, LED_PIN, LED_FREQ_HZ, LED_DMA,
                              LED_INVERT, LED_BRIGHTNESS)

    strip.begin()

    for i in range(0, strip.numPixels(), 1):
        strip.setPixelColor(i, Color(0, 0, 0))

    strip.setBrightness(100)

    return strip
Beispiel #11
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class LightController(object):
    LED_COUNT = 43  # Number of LED pixels.
    LED_PIN = 18  # GPIO pin connected to the pixels (must support PWM!).
    LED_FREQ_HZ = 800000  # LED signal frequency in hertz (usually 800khz)
    LED_DMA = 5  # DMA channel to use for generating signal (try 5)
    LED_BRIGHTNESS = 255  # Set to 0 for darkest and 255 for brightest
    LED_INVERT = False  # True to invert the signal (when using NPN transistor level shift)

    def __init__(self):
        self.led_count = 43
        self.led_pin = 18
        self.leds = Adafruit_NeoPixel(self.LED_COUNT, self.LED_PIN,
                                      self.LED_FREQ_HZ, self.LED_DMA,
                                      self.LED_INVERT, self.LED_BRIGHTNESS)

    def cut_light_ranges(self, hue, disable_range):
        x = disable_range[0] * 255. / (255 - disable_range[1] +
                                       disable_range[0])
        if hue < x:
            hue *= (255 - disable_range[1] + disable_range[0]) / 255.
        else:
            hue = disable_range[1] + ((hue - x) *
                                      (255. - disable_range[1])) / (255. - x)
        return hue

    def cb_light(self, msg):
        disabled_range = [30, 100]
        hue = self.cut_light_ranges(msg.data, disabled_range)
        hue = hue / 255.  # Hue between (0., 1.)
        #r, g, b = map(int, hsv_to_rgb(hue, 1, 255))
        r, g, b = map(int, hsv_to_rgb(0, 0, msg.data))
        self.set_all(r, g, b)

    def set_all(self, r, g, b):
        for i in range(self.LED_COUNT):
            self.leds.setPixelColor(i, Color(g, r, b))
        self.leds.show()

    def run(self):
        try:
            self.leds.begin()
        except RuntimeError as e:
            raise RuntimeError(
                repr(e) +
                "\nAre you running this script with root permissions?")
        else:
            self.set_all(0, 0, 0)
            rospy.Subscriber("apex_playground/environment/light", UInt8,
                             self.cb_light)
            rospy.spin()
Beispiel #12
0
class PiWS281X(DriverBase):
    """
    Driver for controlling WS281X LEDs via the rpi_ws281x C-extension.
    Only supported on the Raspberry Pi 2 & 3
    """
    def __init__(self,
                 num,
                 gamma=gamma.NEOPIXEL,
                 c_order=ChannelOrder.RGB,
                 gpio=18,
                 ledFreqHz=800000,
                 ledDma=5,
                 ledInvert=False,
                 **kwds):
        """
        num - Number of LED pixels.
        gpio - GPIO pin connected to the pixels (must support PWM! GPIO 13 or 18 (pins 33 or 12) on RPi 3).
        ledFreqHz - LED signal frequency in hertz (800khz or 400khz)
        ledDma - DMA channel to use for generating signal (Between 1 and 14)
        ledInvert - True to invert the signal (when using NPN transistor level shift)
        """
        super().__init__(num, c_order=c_order, gamma=gamma, **kwds)
        self.gamma = gamma
        if gpio not in PIN_CHANNEL.keys():
            raise ValueError('{} is not a valid gpio option!')
        self._strip = Adafruit_NeoPixel(num, gpio, ledFreqHz, ledDma,
                                        ledInvert, 255, PIN_CHANNEL[gpio],
                                        0x081000)
        # Intialize the library (must be called once before other functions).
        self._strip.begin()

    def set_brightness(self, brightness):
        self._strip.setBrightness(brightness)
        return True

    def _compute_packet(self):
        self._render()
        data = self._buf
        self._packet = [
            tuple(data[(p * 3):(p * 3) + 3]) for p in range(len(data) // 3)
        ]

    def _send_packet(self):
        for i, p in enumerate(self._packet):
            self._strip.setPixelColor(i, NeoColor(*p))

        self._strip.show()
def main():
	global radien
	global streifen
	global pix
	global T
	n = 0			#Zählervariable
	neuesBild(path)
	gp.setmode(gp.BCM)          # Welche Nummern für die Pins verwendet werden
	gp.setwarnings(False)       # Keine Warnungen
	gp.setup(MAGNET_PIN, gp.IN) # Anschluss

	
	#Erschaffen des Led-Streifen-Objekts
	streifen = Adafruit_NeoPixel(LED_COUNT, LED_PIN, LED_FREQ_HZ, LED_DMA, 
								 LED_INVERT, LED_BRIGHTNESS)


	streifen.begin()    #initialisieren des LED-Streifens
	startPrint()        #Drucken der Anfangseinstellungen



	while True:                             
		t1 = time()		#Startzeit der Umdrehung t1
		
		if gp.input(MAGNET_PIN) == False:	#Zeitmessung einmal je Umdrehung
			
			w = 2 * pi / T 	#Berrechnen der Aktuellen Winkelgeschwindigkeit
			
			while gp.input(MAGNET_PIN) == False:
				t = time() - t1 			#Ausrechnen der größe des Zeitabschnitts

				if t < 5:
					streifenBedienen(t, w)
					streifen.show()
				else:
					for i in range(0, LED_COUNT):
						streifen.setPixelColor(i, Color(0,0,0))
						streifen.show()
			n +=1
			if n > 3:				#jede dritte Umdrehung wird das bild neu in den Zwischenspeicher gepackt
				n = 0
				neuesBild("/home/pi/Bilder/Bild.")

			print("\b\b\b\b\b\b\b" + str(int(w * 0.3*3.6)) + " km/h")
			T = time() - t1              #Ausrechnen von T nach T = t2 - t1
class NeopixelSequencePlayer(SequencePlayer):
    def __init__(self):
        super().__init__()

        self.strip = Adafruit_NeoPixel(cfg.LED_COUNT, cfg.LED_DATA_PIN,
                                       cfg.LED_FREQ_HZ, cfg.LED_DMA,
                                       cfg.LED_INVERT, cfg.LED_BRIGHTNESS,
                                       cfg.LED_CHANNEL, cfg.LED_STRIP)
        self.strip.begin()

    def setrangecolor(self, start, end, color, write=True):
        super().setrangecolor(start, end, color, write)
        if write:
            self.strip.show()

    def setcolor(self, led, color, write=True):
        self.strip.setPixelColor(led, color.topixel())
        if write:
            self.strip.show()
Beispiel #15
0
def main():
    global radien
    global streifen
    global pix
    global T
    n = 0  #Zählervariable
    neuesBild(path)
    gp.setmode(gp.BCM)  # Welche Nummern für die Pins verwendet werden
    gp.setwarnings(False)  # Keine Warnungen
    gp.setup(MAGNET_PIN, gp.IN)  # Anschluss

    #Erschaffen des Led-Streifen-Objekts
    streifen = Adafruit_NeoPixel(LED_COUNT, LED_PIN, LED_FREQ_HZ, LED_DMA,
                                 LED_INVERT, LED_BRIGHTNESS)

    streifen.begin()  #initialisieren des LED-Streifens
    startPrint()  #Drucken der Anfangseinstellungen

    while True:
        t1 = time()  #Startzeit der Umdrehung t1

        if gp.input(MAGNET_PIN) == False:  #Zeitmessung einmal je Umdrehung

            w = 2 * pi / T  #Berrechnen der Aktuellen Winkelgeschwindigkeit

            while gp.input(MAGNET_PIN) == False:
                t = time() - t1  #Ausrechnen der größe des Zeitabschnitts

                if t < 5:
                    streifenBedienen(t, w)
                    streifen.show()
                else:
                    for i in range(0, LED_COUNT):
                        streifen.setPixelColor(i, Color(0, 0, 0))
                        streifen.show()
            n += 1
            if n > 3:  #jede dritte Umdrehung wird das bild neu in den Zwischenspeicher gepackt
                n = 0
                neuesBild("/home/pi/Bilder/Bild.")

            print("\b\b\b\b\b\b\b" + str(int(w * 0.3 * 3.6)) + " km/h")
            T = time() - t1  #Ausrechnen von T nach T = t2 - t1
Beispiel #16
0
class Control:
    def __init__(self):
        self.strip = Adafruit_NeoPixel(LED_COUNT, LED_PIN, LED_FREQ_HZ,
                                       LED_DMA, LED_INVERT, LED_BRIGHTNESS, 0,
                                       ws.WS2812_STRIP)
        self.strip.begin()
        self.running = True

    def color_temp(self, temp, brightness=1.0):
        r, g, b = convert_K_to_RGB(temp)
        r = int(r * brightness)
        g = int(g * brightness)
        b = int(b * brightness)

        self.color(r, g, b)

    def color(self, r, g, b):
        color = Color(r, g, b)
        for i in range(self.strip.numPixels()):
            self.strip.setPixelColor(i, color)

        while True:
            self.strip.show()
            if self.running:
                time.sleep(20 / 1000.0)
            else:
                return

    def rainbow(self):
        while True:
            for j in range(256):
                for i in range(self.strip.numPixels()):
                    self.strip.setPixelColor(i, wheel((i + j) & 255))

                self.strip.show()
                if self.running:
                    time.sleep(20 / 1000.0)
                else:
                    return

    def rainbow_onecolor(self):
        while True:
            for j in range(256):
                for i in range(self.strip.numPixels()):
                    self.strip.setPixelColor(i, wheel(j & 255))

                self.strip.show()
                if self.running:
                    time.sleep(20 / 1000.0)
                else:
                    return
Beispiel #17
0
class LTSmart:

    mensaje = 'POSTE'
    contador_pantalla = -8
    contador_pantalla_max = 0
    contador_barra = 0

    def __init__(self, pin, channel, cintas, longitud, longitud_baliza):

        # ARREGLO LINEAL LED
        self.long_baliza = longitud_baliza
        self.Longitud = longitud  # Longitud de cada cinta Led
        self.Numero = cintas  # Numero de cintas Leds
        self.LED_COUNT = longitud * cintas + longitud_baliza  # Number of LED pixels.
        self.LED_PIN = pin  # GPIO pin connected to the pixels (must support PWM!).
        self.LED_FREQ_HZ = 800000  # LED signal frequency in hertz (usually 800khz)
        self.LED_DMA = 10  # DMA channel to use for generating signal (try 10)
        self.LED_BRIGHTNESS = 150  # Set to 0 for darkest and 255 for brightest
        self.LED_INVERT = False  # True to invert the signal (when using NPN transistor level shift)
        self.LED_CHANNEL = channel

        self.strip = Adafruit_NeoPixel(self.LED_COUNT, self.LED_PIN,
                                       self.LED_FREQ_HZ, self.LED_DMA,
                                       self.LED_INVERT, self.LED_BRIGHTNESS,
                                       self.LED_CHANNEL)
        self.strip.begin()

        self.ConvBin2 = [0, 0, 0, 0, 0, 0, 0, 0]  #Vector Conversor a Binario
        self.mensaje_anterior = 'POSTE'
        self.contador_dp = 0  # Contador para los dos puntos

    #---------------------------------------------------------------------------#
    #		Escribir pantalla													#
    #---------------------------------------------------------------------------#
    def screen(self, msg, Rojo, Verde, Azul, sentido, brillo, activar_barra,
               variable, lim_sup, lim_inf, n1, n2, n3):

        self.strip.setBrightness(brillo)
        self.mensaje = msg

        if self.mensaje_anterior != self.mensaje:
            self.contador_pantalla = -8

        self.CleanScreen(Color(0, 0, 0))

        if activar_barra == 0:
            # La barra está desactivada, muestra el texto completo en la pantalla
            if sentido == 0:
                # El texto se muestra estático
                self.contador_pantalla = self.Longitud - 10
                self.Message(self.mensaje, self.contador_pantalla,
                             Color(Verde, Rojo, Azul))
                self.strip.show()  # Mostrar el programa
            else:
                # El texto se desplaza hacia arriba
                self.contador_pantalla_max = len(
                    self.mensaje) * 8 + self.Longitud
                if self.contador_pantalla < len(
                        self.mensaje) * 8 + self.Longitud:
                    self.CleanScreen(Color(0, 0, 0))
                    self.Message(self.mensaje, self.contador_pantalla,
                                 Color(Verde, Rojo, Azul))
                    self.strip.show()  # Mostrar el programa
                else:
                    self.contador_pantalla = -8
        else:
            # La barra está activada, quita el último metro de la pantalla
            if sentido == 0:
                # El texto se muestra estático
                self.nivel(variable, lim_sup, lim_inf, n1, n2, n3)
                self.contador_pantalla = self.Longitud - 10 - 61
                self.Message(self.mensaje, self.contador_pantalla,
                             Color(Verde, Rojo, Azul))
                self.strip.show()  # Mostrar el programa
            else:
                # El texto se desplaza hacia arriba
                self.contador_pantalla_max = len(
                    self.mensaje) * 8 + self.Longitud - 50
                if self.contador_pantalla < len(
                        self.mensaje) * 8 + self.Longitud - 50:
                    self.CleanScreen(Color(0, 0, 0))
                    self.Message(self.mensaje, self.contador_pantalla,
                                 Color(Verde, Rojo, Azul))
                    self.CleanBarra(self.Longitud - 61, self.Longitud - 1)
                    self.nivel(variable, lim_sup, lim_inf, n1, n2, n3)
                    self.strip.show()  #Mostrar el programa
                else:
                    self.contador_pantalla = -8

        self.contador_pantalla += 1
        self.mensaje_anterior = self.mensaje

    #---------------------------------------------------------------------------#
    #		Apagar pantalla														#
    #---------------------------------------------------------------------------#
    def apagar(self):
        self.CleanAll(Color(0, 0, 0))
        self.strip.show()  # Mostrar el programa

    #---------------------------------------------------------------------------#
    #		Mostrar barra														#
    #---------------------------------------------------------------------------#
    def nivel(self, variable, lim_sup, lim_inf, n1, n2, n3):
        # self.CleanScreen(Color(0, 0, 0))
        j = self.Longitud - 60
        self.line(j, Color(255, 0, 255))
        j = self.Longitud - 59
        self.line(j, Color(255, 0, 255))
        j = self.Longitud - 3
        self.line(j, Color(255, 0, 255))
        j = self.Longitud - 2
        self.line(j, Color(255, 0, 255))

        led_nivel = int(round(variable * 56 / (lim_sup - lim_inf)))
        # print(led_nivel)
        grb = [0, 0, 0]

        for k in range(self.Longitud - 58, self.Longitud - 60 + led_nivel - 1):
            if variable < 1:
                grb = [0, 0, 0]
            elif variable < n1:
                grb = [255, 0, 0]
            elif variable < n2:
                grb = [255, 255, 0]
            elif variable < n3:
                grb = [100, 255, 0]
            else:
                grb = [0, 255, 0]

            self.line(k, Color(grb[0], grb[1], grb[2]))

        if self.contador_barra < k:
            self.contador_barra = k + 1
        elif self.contador_barra != k:
            self.contador_barra = self.contador_barra - 1

        self.line(self.contador_barra, Color(255, 255, 255))

    #---------------------------------------------------------------------------#
    #		Mostrar baliza														#
    #---------------------------------------------------------------------------#
    def nivel_baliza(self, variable, lim_sup, lim_inf, n1, n2, n3):
        grb = [0, 0, 0]
        if variable < 1:
            grb = [0, 0, 0]
        elif variable < n1:
            grb = [255, 0, 0]
        elif variable < n2:
            grb = [255, 255, 0]
        elif variable < n3:
            grb = [100, 255, 0]
        else:
            grb = [0, 255, 0]

        for k in range(self.LED_COUNT - self.long_baliza, self.LED_COUNT):
            self.strip.setPixelColor(k, Color(grb[0], grb[1], grb[2]))

    #---------------------------------------------------------------------------#
    #		Binario convertido a Leds	(Se usa en el medio)					#
    #---------------------------------------------------------------------------#
    def Bin2Led_medio(self, hexa, posicion, color, direccion):
        ConvBin = bin(hexa)
        if direccion == 0:
            for i in range(2, len(ConvBin)):
                if ConvBin[i] == '0':
                    self.strip.setPixelColor(posicion + len(ConvBin) - i,
                                             Color(0, 0, 0))
                else:
                    self.strip.setPixelColor(posicion + len(ConvBin) - i,
                                             color)
        else:
            for i in range(2, len(ConvBin)):
                if ConvBin[i] == '0':
                    self.strip.setPixelColor(posicion - len(ConvBin) + i,
                                             Color(0, 0, 0))
                else:
                    self.strip.setPixelColor(posicion - len(ConvBin) + i,
                                             color)

    #---------------------------------------------------------------------------#
    #		Binario convertido a Leds2	(Se usa en el borde superior)			#
    #---------------------------------------------------------------------------#
    def Bin2Led_superior(self, hexa, posicion, color, direccion, dif):
        ConvBin = bin(hexa)

        if len(ConvBin) != 10:
            self.ConvBin2 = ['0', '0', '0', '0', '0', '0', '0', '0']
            for j in range(2, len(ConvBin)):
                self.ConvBin2[10 - len(ConvBin) + j - 2] = ConvBin[j]
        else:
            for i in range(0, 7):
                self.ConvBin2[i] = ConvBin[i + 2]
        # Los leds en la misma dirección
        if direccion == 0:
            for i in range(0, dif):
                if self.ConvBin2[8 - dif + i] == '0':
                    self.strip.setPixelColor(posicion + dif - i,
                                             Color(0, 0, 0))
                else:
                    self.strip.setPixelColor(posicion + dif - i, color)
        # Los leds en dirección opuesta
        else:
            for i in range(0, dif):
                if self.ConvBin2[8 - dif + i] == '0':
                    self.strip.setPixelColor(posicion - dif + i,
                                             Color(0, 0, 0))
                else:
                    self.strip.setPixelColor(posicion - dif + i, color)

    #---------------------------------------------------------------------------#
    #		Binario convertido a Leds2	(Se usa en el borde inferior)			#
    #---------------------------------------------------------------------------#
    def Bin2Led_inferior(self, hexa, posicion, color, direccion, dif):
        ConvBin = bin(hexa)

        if len(ConvBin) != 10:
            self.ConvBin2 = ['0', '0', '0', '0', '0', '0', '0', '0']
            for j in range(2, len(ConvBin)):
                self.ConvBin2[10 - len(ConvBin) + j - 2] = ConvBin[j]
        else:
            for i in range(0, 7):
                self.ConvBin2[i] = ConvBin[i + 2]
        # Los leds en la misma dirección
        if direccion == 0:
            for i in range(0, dif):
                #print(8 - dif + i)
                if self.ConvBin2[i] == '0':
                    self.strip.setPixelColor(posicion + 8 - i, Color(0, 0, 0))
                else:
                    self.strip.setPixelColor(posicion + 8 - i, color)
        # Los leds en dirección opuesta
        else:
            for i in range(0, dif):
                if self.ConvBin2[i] == '0':
                    self.strip.setPixelColor(posicion - 8 + i, Color(0, 0, 0))
                else:
                    self.strip.setPixelColor(posicion - 8 + i, color)

    #---------------------------------------------------------------------------#
    #		Letras convertidas a Leds											#
    #---------------------------------------------------------------------------#
    def Letras2Led(self, posicion2, color, hexa):
        # Borde superior
        if posicion2 > self.Longitud - 9:
            dif = self.Longitud - 1 - posicion2
            if dif > 0:
                self.Bin2Led_superior(hexa[4], posicion2, color, 0, dif)
                self.Bin2Led_superior(hexa[3],
                                      2 * self.Longitud - posicion2 - 1, color,
                                      1, dif)
                self.Bin2Led_superior(hexa[2], 2 * self.Longitud + posicion2,
                                      color, 0, dif)
                self.Bin2Led_superior(hexa[1],
                                      4 * self.Longitud - posicion2 - 1, color,
                                      1, dif)
                self.Bin2Led_superior(hexa[0], 4 * self.Longitud + posicion2,
                                      color, 0, dif)
        # Borde inferior
        elif posicion2 < -1:
            dif2 = 9 - posicion2 * -1
            self.Bin2Led_inferior(hexa[4], posicion2, color, 0, dif2)
            self.Bin2Led_inferior(hexa[3], 2 * self.Longitud - posicion2 - 1,
                                  color, 1, dif2)
            self.Bin2Led_inferior(hexa[2], 2 * self.Longitud + posicion2,
                                  color, 0, dif2)
            self.Bin2Led_inferior(hexa[1], 4 * self.Longitud - posicion2 - 1,
                                  color, 1, dif2)
            self.Bin2Led_inferior(hexa[0], 4 * self.Longitud + posicion2,
                                  color, 0, dif2)

        # El centro de la pantalla
        else:
            self.Bin2Led_medio(hexa[4], posicion2, color, 0)
            self.Bin2Led_medio(hexa[3], 2 * self.Longitud - posicion2 - 1,
                               color, 1)
            self.Bin2Led_medio(hexa[2], 2 * self.Longitud + posicion2, color,
                               0)
            self.Bin2Led_medio(hexa[1], 4 * self.Longitud - posicion2 - 1,
                               color, 1)
            self.Bin2Led_medio(hexa[0], 4 * self.Longitud + posicion2, color,
                               0)

    #---------------------------------------------------------------------------#
    #		Limpiar pantalla													#
    #---------------------------------------------------------------------------#
    def CleanScreen(self, color):
        for i in range(self.LED_COUNT - self.long_baliza):
            self.strip.setPixelColor(i, color)

    #---------------------------------------------------------------------------#
    #		Limpiar pantalla y baliza											#
    #---------------------------------------------------------------------------#
    def CleanAll(self, color):
        for i in range(self.LED_COUNT):
            self.strip.setPixelColor(i, color)

    #---------------------------------------------------------------------------#
    #		Limpiar barra														#
    #---------------------------------------------------------------------------#
    def CleanBarra(self, j, k):
        for i in range(j, k):
            self.line(i, Color(0, 0, 0))

    #---------------------------------------------------------------------------#
    #		Dibujar una línea													#
    #---------------------------------------------------------------------------#
    def line(self, i, color):
        self.strip.setPixelColor(i, color)
        self.strip.setPixelColor((2 * self.Longitud - i) - 1, color)
        self.strip.setPixelColor(2 * self.Longitud + i, color)
        self.strip.setPixelColor((4 * self.Longitud - i) - 1, color)
        self.strip.setPixelColor(4 * self.Longitud + i, color)

    #---------------------------------------------------------------------------#
    #		Mensaje convertido a cada letra, numero o simbolo 					#
    #---------------------------------------------------------------------------#

    def tabla(self, valor, posicion3, color, i):

        switcher = {
            # MAYUSCULAS
            "A":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x3E, 0x48, 0x88, 0x48, 0x3E]),
            "B":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x6C, 0x92, 0x92, 0x92, 0xFE]),
            "C":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x44, 0x82, 0x82, 0x82, 0x7C]),
            "D":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x7C, 0x82, 0x82, 0x82, 0xFE]),
            "E":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x82, 0x92, 0x92, 0x92, 0xFE]),
            "F":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x80, 0x90, 0x90, 0x90, 0xFE]),
            "G":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xCE, 0x8A, 0x82, 0x82, 0x7C]),
            "H":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xFE, 0x10, 0x10, 0x10, 0xFE]),
            "I":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x82, 0xFE, 0x82, 0x00]),
            "J":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x80, 0xFC, 0x82, 0x02, 0x04]),
            "K":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x82, 0x44, 0x28, 0x10, 0xFE]),
            "L":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x02, 0x02, 0x02, 0x02, 0xFE]),
            "M":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xFE, 0x40, 0x38, 0x40, 0xFE]),
            "N":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xFE, 0x08, 0x10, 0x20, 0xFE]),
            #"Ñ": lambda: self.Letras2Led(posicion3 - 8 * i, color, [0xBE,0x84,0x88,0x90,0xBE]),
            "O":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x7C, 0x82, 0x82, 0x82, 0x7C]),
            "P":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x60, 0x90, 0x90, 0x90, 0xFE]),
            "Q":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x7A, 0x84, 0x8A, 0x82, 0x7C]),
            "R":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x62, 0x94, 0x98, 0x90, 0xFE]),
            "S":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x4C, 0x92, 0x92, 0x92, 0x64]),
            "T":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xC0, 0x80, 0xFE, 0x80, 0xC0]),
            "U":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xFC, 0x02, 0x02, 0x02, 0xFC]),
            "V":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xF8, 0x04, 0x02, 0x04, 0xF8]),
            "W":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xFE, 0x02, 0x1C, 0x02, 0xFE]),
            "X":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xC6, 0x28, 0x10, 0x28, 0xC6]),
            "Y":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xC0, 0x20, 0x1E, 0x20, 0xC0]),
            "Z":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xC2, 0xB2, 0x92, 0x9A, 0x86]),

            # MINUSCULAS
            "a":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x02, 0x1E, 0x2A, 0x2A, 0x04]),
            "b":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x1C, 0x22, 0x22, 0x14, 0xFE]),
            "c":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x14, 0x22, 0x22, 0x22, 0x1C]),
            "d":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xFE, 0x14, 0x22, 0x22, 0x1C]),
            "e":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x18, 0x2A, 0x2A, 0x2A, 0x1C]),
            "f":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x40, 0x90, 0x7E, 0x10, 0x00]),
            "g":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x3C, 0x72, 0x4A, 0x4A, 0x30]),
            "h":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x1E, 0x20, 0x20, 0x10, 0xFE]),
            "i":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x02, 0xBE, 0x22, 0x00]),
            "j":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0xBC, 0x02, 0x02, 0x04]),
            "k":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x22, 0x14, 0x08, 0xFE]),
            "l":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x02, 0xFE, 0x82, 0x00]),
            "m":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x3E, 0x20, 0x1E, 0x20, 0x3E]),
            "n":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x1E, 0x20, 0x20, 0x10, 0x3E]),
            "o":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x1C, 0x22, 0x22, 0x22, 0x1C]),
            "p":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x30, 0x48, 0x48, 0x30, 0x7E]),
            "q":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x7E, 0x30, 0x48, 0x48, 0x30]),
            "r":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x10, 0x20, 0x20, 0x10, 0x3E]),
            "s":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x24, 0x2A, 0x2A, 0x2A, 0x12]),
            "t":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x24, 0x12, 0xFC, 0x20, 0x20]),
            "u":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x3E, 0x04, 0x02, 0x02, 0x3C]),
            "v":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x38, 0x04, 0x02, 0x04, 0x38]),
            "w":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x3C, 0x02, 0x0C, 0x02, 0x3C]),
            "x":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x22, 0x14, 0x08, 0x14, 0x22]),
            "y":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x7C, 0x12, 0x12, 0x12, 0x64]),
            "z":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x22, 0x32, 0x2A, 0x26, 0x22]),

            # NUMEROS
            "0":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x7C, 0xA2, 0x92, 0x8A, 0x7C]),
            "1":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x02, 0xFE, 0x42, 0x00]),
            "2":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x62, 0x92, 0x92, 0x92, 0x4E]),
            "3":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xCC, 0xB2, 0x92, 0x82, 0x84]),
            "4":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x08, 0xFE, 0x48, 0x28, 0x18]),
            "5":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x9C, 0xA2, 0xA2, 0xA2, 0xE4]),
            "6":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x8C, 0x92, 0x92, 0x52, 0x3C]),
            "7":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xE0, 0x90, 0x88, 0x84, 0x82]),
            "8":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x6C, 0x92, 0x92, 0x92, 0x6C]),
            "9":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x78, 0x94, 0x92, 0x92, 0x62]),

            # SIMBOLOS
            "=":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x28, 0x28, 0x28, 0x28, 0x28]),
            "(":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x82, 0x44, 0x38, 0x00]),
            ")":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x38, 0x44, 0x82, 0x00]),
            ":":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x00, 0x28, 0x00, 0x00]),
            ";":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x00, 0x2C, 0x02, 0x00]),
            " ":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x00, 0x00, 0x00, 0x00]),
            ",":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x00, 0x0C, 0x02, 0x00]),
            "?":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x60, 0x90, 0x9A, 0x80, 0x40]),
            ".":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x0C, 0x0C, 0x00, 0x00]),
            "%":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x46, 0x26, 0x10, 0xC8, 0xC4]),
            "/":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x04, 0x08, 0x10, 0x20, 0x40]),
            "@":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x7E, 0x81, 0x8F, 0x89, 0x46]),  #Tipo 1
            #"@": lambda: self.Letras2Led(posicion3 - 8 * i, color, [0x72,0xB1,0xB1,0x81,0x7E]), # Tipo 2
            "*":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x50, 0xE0, 0x50, 0x00]),  #Tipo 1
            #"*": lambda: self.Letras2Led(posicion3 - 8 * i, color, [0x14,0x08,0x3E,0x08,0x14]), # Tipo 2
            "$":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x44, 0x4A, 0xFF, 0x4A, 0x32]),
            "!":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x00, 0xFA, 0x00, 0x00]),
            "#":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x44, 0xFF, 0x44, 0xFF, 0x44]),
            "+":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x10, 0x10, 0x7C, 0x10, 0x10]),
            "-":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x10, 0x10, 0x10, 0x00]),
            "_":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x01, 0x01, 0x01, 0x01, 0x01]),

            # ESPECIALES

            # Unidades
            "\x80":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x22, 0x41, 0x22, 0xDC, 0xC0]),  # °C
            "\x81":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x00, 0x00, 0x00, 0xC0, 0xC0
            ]),  # ° pequeño
            "\x82":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x00, 0x00, 0xE0, 0xA0, 0xE0
            ]),  # ° grande
            "\x83":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x78, 0x04, 0x04, 0x7F, 0x00
            ]),  # u letra griega

            # Simbolos
            "\x84":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x00, 0x00, 0x10, 0x00, 0x00
            ]),  # Punto centro Pequeño
            "\x85":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x00, 0x1C, 0x1C, 0x1C, 0x00
            ]),  # Punto centro Grande

            # Iconos
            "\x86":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x30, 0x78, 0x3C, 0x78, 0x30
            ]),  # Corazón relleno
            "\x87":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x30, 0x48, 0x24, 0x48, 0x30
            ]),  # Corazón blanco
            "\x88":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x38, 0xE4, 0x27, 0xE4, 0x38
            ]),  # Conector
            "\x89":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x00, 0x00, 0xFF, 0x00, 0x00]),  # Cable	
            "\x90":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0xFC, 0x4C, 0x20, 0x1F, 0x03
            ]),  # Nota musical
            "\x91":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0xFF, 0x4F, 0x4F, 0x4F, 0x7F]),  # Celular
            "\x92":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x08, 0x78, 0xFA, 0x78, 0x08]),  # Campana
            "\x93":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x08, 0x44, 0x14, 0x44, 0x08
            ]),  # Cara feliz

            #Animaciones
            "\x94":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x7C, 0x3E, 0x1E, 0x3E, 0x7C
            ]),  # Pacman abierto
            "\x95":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x7C, 0xFE, 0xFE, 0xFE, 0x7C
            ]),  # Pacman cerrado
            "\x96":
            lambda: self.Letras2Led(posicion3 - 8 * i, color,
                                    [0x7C, 0xCF, 0xFE, 0xCF, 0x7C]),  # Fantom1
            "\x97":
            lambda: self.Letras2Led(posicion3 - 8 * i, color, [
                0x7F, 0xCC, 0xFF, 0xCC, 0x7F
            ]),  # Fantom2		
        }.get(valor, lambda: None)()

    def Message(self, mensaje, posicion3, color):
        for i in range(len(mensaje)):

            self.tabla(mensaje[i], posicion3, color, i)

    #---------------------------------------------------------------------------#
    #		Reiniciar contador de Pantalla 		 								#
    #---------------------------------------------------------------------------#

    def reiniciar(self):
        self.contador_pantalla = -8
class Controller:

    LEDS = None

    NEOPIXEL_GPIO_PIN = None
    NEOPIXEL_FREQUENCY = None
    NEOPIXEL_DMA = None
    NEOPIXEL_INVERT = None
    NEOPIXEL_BRIGHTNESS = None
    NEOPIXEL_CHANNEL = None
    NEOPIXEL_STRIP = None

    neopixel = None

    thread = None

    effect = None

    def __init__(self, leds, neopixel_gpio_pin, neopixel_frequency, neopixel_dma, neopixel_invert, neopixel_brightness, neopixel_channel, neopixel_strip):
        print("[Neopixel][info] Initialising NeoPixel")

        self.LEDS = leds
        self.NEOPIXEL_GPIO_PIN = neopixel_gpio_pin
        self.NEOPIXEL_FREQUENCY = neopixel_frequency
        self.NEOPIXEL_DMA = neopixel_dma
        self.NEOPIXEL_INVERT = neopixel_invert
        self.NEOPIXEL_BRIGHTNESS = neopixel_brightness
        self.NEOPIXEL_CHANNEL = neopixel_channel
        self.NEOPIXEL_STRIP = neopixel_strip

        self.neopixel = Adafruit_Neopixel(
            self.LEDS,
            self.NEOPIXEL_GPIO_PIN,
            self.NEOPIXEL_FREQUENCY,
            self.NEOPIXEL_DMA,
            self.NEOPIXEL_INVERT,
            self.NEOPIXEL_BRIGHTNESS,
            self.NEOPIXEL_CHANNEL,
            self.NEOPIXEL_STRIP
        )

        try:
            self.neopixel.begin()
        except AttributeError:
            print("[Neopixel][error] An error occurred initialising NeoPixel")

    def pixel_color(self, pixel, color):
        print("[Controller][info] Setting color: '%s' to NeoPixel pixel '%d'" % (color.get_hex(), pixel))

        try:
            self.neopixel.setPixelColor(pixel, color.get_bit())
            self.neopixel.show()
        except AttributeError:
            print("[Controller][error] An error occurred setting color to NeoPixel pixel")

    def color_wheel(self, pos):
        print("[Controller][info] Generation a color wheel")

        if pos < 85:
            return Color(pos * 3, 255 - pos * 3, 0)
        elif pos < 170:
            pos -= 85

            return Color(255 - pos * 3, 0, pos * 3)
        else:
            pos -= 170

            return Color(0, pos * 3, 255 - pos * 3)

    def brightness(self, brightness):
        print("[Controller][info] Setting brightness: '%d' to NeoPixel pixels" % (brightness))

        try:
            self.neopixel.setBrightness(brightness)
            self.neopixel.show()
        except AttributeError:
            print("[Neopixel][error] An error occurred setting brightness on NeoPixel")

    def color(self, color):
        print("[Controller][info] Setting color: '%s' to NeoPixel pixels" % (color.get_hex()))

        try:
            for i in range(self.LEDS):
                self.pixel_color(i, color)

            self.neopixel.show()
        except AttributeError:
            print("[Controller][error] An error occurred setting color to NeoPixel pixels")

    def start_effect(self, effect, color):
        print("[Controller][info] Starting effect: '%s' to NeoPixel pixels" % (effect))

        try:
            self.effect = eval(effect + '.' + effect.replace('_', ' ').title().replace(' ', ''))(self)

            self.thread = threading.Thread(target=self.effect.run, args=(color,))
            self.thread.daemon = True
            self.thread.start()
        except AttributeError:
            print("[Controller][error] An error occurred starting effect to NeoPixel pixels")

    def stop_effect(self):
        print("[Controller][info] Stopping effect to NeoPixel pixels")

        try:
            if self.effect is not None:
                self.effect.stop()
        except AttributeError:
            print("[Controller][error] An error occurred stopping effect to NeoPixel pixels")

    def quit_effect(self):
        print("[Controller][info] Quitting effect to NeoPixel pixels")

        try:
            if self.effect is not None:
                self.thread.terminate()
        except AttributeError:
            print("[Controller][error] An error occurred quitting effect to NeoPixel pixels")

    def effects(self):
        print("[Controller][info] Getting a list of NeoPixel effects")

        try:
            effects = [file for file in os.listdir('./neopixelcontroller/lib/effects') if not file.startswith('.') and not file.startswith('__init__') and not file.endswith('.pyc') and not file.startswith('effect_test')]

            return [effect.replace('.py', '') for effect in effects]
        except AttributeError:
            print("[Controller][error] An error occurred get NeoPixel effects")

    def clear(self):
        print("[Controller][info] Clearing pixels on NeoPixel")

        try:
            self.stop_effect()
            self.quit_effect()
            self.color(Color(0, 0, 0))
            self.brightness(0)
        except AttributeError:
            print("[Controller][error] An error occurred clearing all pixels on NeoPixel")

    def cleanup(self):
        print("[Controller][info] NeoPixel clean up")

        self.clear()

    def __exit__(self):
        print("[Controller][info] NeoPixel exit")

        self.cleanup()
class wordclock_display:
    """
    Class to display any content on the wordclock display
    Depends on the (individual) wordclock layout/wiring
    """

    def __init__(self, config, wci):
        """
        Initialization
        """
        # Get the wordclocks wiring-layout
        self.wcl = wiring.wiring(config)
        self.wci = wci
        try:
            default_brightness = config.getint('wordclock_display', 'brightness')
        except:
            default_brightness = 255
            print(
                'WARNING: Default brightness value not set in config-file: '
                'To do so, add a "brightness" between 1..255 to the [wordclock_display]-section.')

        if config.getboolean('wordclock', 'developer_mode'):
            from GTKstrip import GTKstrip
            self.strip = GTKstrip(wci)
            self.default_font = os.path.join('/usr/share/fonts/TTF/',
                                             config.get('wordclock_display', 'default_font') + '.ttf')
        else:
            try:
                from neopixel import Adafruit_NeoPixel, ws
                self.strip = Adafruit_NeoPixel(self.wcl.LED_COUNT, self.wcl.LED_PIN, self.wcl.LED_FREQ_HZ,
                                               self.wcl.LED_DMA, self.wcl.LED_INVERT, default_brightness , 0,
                                               ws.WS2811_STRIP_GRB)
            except:
                print('Update deprecated external dependency rpi_ws281x. '
                      'For details see also https://github.com/jgarff/rpi_ws281x/blob/master/python/README.md')

            self.default_font = os.path.join('/usr/share/fonts/truetype/freefont/',
                                             config.get('wordclock_display', 'default_font') + '.ttf')

        # Initialize the NeoPixel object
        self.strip.begin()

        self.default_fg_color = wcc.WWHITE
        self.default_bg_color = wcc.BLACK
        self.base_path = config.get('wordclock', 'base_path')

        # Choose language
        try:
            language = ''.join(config.get('wordclock_display', 'language'))
        except:
            # For backward compatibility
            language = ''.join(config.get('plugin_time_default', 'language'))

        print('  Setting language to ' + language + '.')
        if language == 'dutch':
            self.taw = time_dutch.time_dutch()
        elif language == 'english':
            self.taw = time_english.time_english()
        elif language == 'german':
            self.taw = time_german.time_german()
        elif language == 'german2':
            self.taw = time_german2.time_german2()
        elif language == 'swabian':
            self.taw = time_swabian.time_swabian()
        elif language == 'swabian2':
            self.taw = time_swabian2.time_swabian2()
        elif language == 'bavarian':
            self.taw = time_bavarian.time_bavarian()
        elif language == 'swiss_german':
            self.taw = time_swiss_german.time_swiss_german()
        elif language == 'swiss_german2':
            self.taw = time_swiss_german2.time_swiss_german2()
        else:
            print('Could not detect language: ' + language + '.')
            print('Choosing default: german')
            self.taw = time_german.time_german()

    def setPixelColor(self, pixel, color):
        """
        Sets the color for a pixel, while considering the brightness, set within the config file
        """
        self.strip.setPixelColor(pixel, color)

    def getBrightness(self):
        """
        Sets the color for a pixel, while considering the brightness, set within the config file
        """
        return self.strip.getBrightness()

    def setBrightness(self, brightness):
        """
        Sets the color for a pixel, while considering the brightness, set within the config file
        """
        self.strip.setBrightness(brightness)
        self.show()

    def setColorBy1DCoordinates(self, *args, **kwargs):
        """
        Sets a pixel at given 1D coordinates
        """
        return self.wcl.setColorBy1DCoordinates(*args, **kwargs)

    def setColorBy2DCoordinates(self, *args, **kwargs):
        """
        Sets a pixel at given 2D coordinates
        """
        return self.wcl.setColorBy2DCoordinates(*args, **kwargs)

    def get_wca_height(self):
        """
        Returns the height of the WCA
        """
        return self.wcl.WCA_HEIGHT

    def get_wca_width(self):
        """
        Returns the height of the WCA
        """
        return self.wcl.WCA_WIDTH

    def get_led_count(self):
        """
        Returns the overall number of LEDs
        """
        return self.wcl.LED_COUNT

    def dispRes(self):
        """
        Returns the resolution of the wordclock array as string
        E.g. to choose the correct resolution of animations and icons
        """
        return str(self.wcl.WCA_WIDTH) + 'x' + str(self.wcl.WCA_HEIGHT)

    def setColorToAll(self, color, includeMinutes=True):
        """
        Sets a given color to all leds
        If includeMinutes is set to True, color will also be applied to the minute-leds.
        """
        if includeMinutes:
            for i in range(self.wcl.LED_COUNT):
                self.setPixelColor(i, color)
        else:
            for i in self.wcl.getWcaIndices():
                self.setPixelColor(i, color)

    def setColorTemperatureToAll(self, temperature, includeMinutes=True):
        """
        Sets a color to all leds based on the provided temperature in Kelvin
        If includeMinutes is set to True, color will also be applied to the minute-leds.
        """
        self.setColorToAll(wcc.color_temperature_to_rgb(temperature), includeMinutes)

    def resetDisplay(self):
        """
        Reset display
        """
        self.setColorToAll(wcc.BLACK, True)

    def showIcon(self, plugin, iconName):
        """
        Dispays an icon with a specified name.
        The icon needs to be provided within the graphics/icons folder.
        """
        self.setImage(
            self.base_path + '/wordclock_plugins/' + plugin + '/icons/' + self.dispRes() + '/' + iconName + '.png')

    def setImage(self, absPathToImage):
        """
        Set image (provided as absolute path) to current display
        """
        img = Image.open(absPathToImage)
        width, height = img.size
        for x in range(0, width):
            for y in range(0, height):
                rgb_img = img.convert('RGB')
                r, g, b = rgb_img.getpixel((x, y))
                self.wcl.setColorBy2DCoordinates(self.strip, x, y, wcc.Color(r, g, b))
        self.show()

    def animate(self, plugin, animationName, fps=10, count=1, invert=False):
        """
        Runs an animation
        plugin: Plugin-name
        num_of_frames: Number of frames to be displayed
        count: Number of runs
        fps: frames per second
        invert: Invert order of animation
        """
        animation_dir = self.base_path + '/wordclock_plugins/' + plugin + '/animations/' + self.dispRes() + '/' + animationName + '/'
        num_of_frames = len([file_count for file_count in os.listdir(animation_dir)])

        if invert:
            animation_range = range(num_of_frames - 1, -1, -1)
        else:
            animation_range = range(0, num_of_frames)

        for _ in range(count):
            for i in animation_range:
                self.setImage(animation_dir + str(i).zfill(3) + '.png')
                if self.wci.waitForExit(1.0 / fps):
                    return

    def showText(self, text, font=None, fg_color=None, bg_color=None, fps=10, count=1):
        """
        Display text on display
        """
        if font is None:
            font = self.default_font
        if fg_color is None:
            fg_color = self.default_fg_color
        if bg_color is None:
            bg_color = self.default_bg_color

        text = '    ' + text + '    '

        fnt = fontdemo.Font(font, self.wcl.WCA_HEIGHT)
        text_width, text_height, text_max_descent = fnt.text_dimensions(text)
        text_as_pixel = fnt.render_text(text)

        # Display text count times
        for i in range(count):

            # Erase previous content
            self.setColorToAll(bg_color, includeMinutes=True)

            # Assure here correct rendering, if the text does not fill the whole display
            render_range = self.wcl.WCA_WIDTH if self.wcl.WCA_WIDTH < text_width else text_width
            for y in range(text_height):
                for x in range(render_range):
                    self.wcl.setColorBy2DCoordinates(self.strip, x, y,
                                                     fg_color if text_as_pixel.pixels[y * text_width + x] else bg_color)

            # Show first frame for 0.5 seconds
            self.show()
            if self.wci.waitForExit(0.5):
                return

            # Shift text from left to right to show all.
            for cur_offset in range(text_width - self.wcl.WCA_WIDTH + 1):
                for y in range(text_height):
                    for x in range(self.wcl.WCA_WIDTH):
                        self.wcl.setColorBy2DCoordinates(self.strip, x, y, fg_color if text_as_pixel.pixels[
                            y * text_width + x + cur_offset] else bg_color)
                self.show()
                if self.wci.waitForExit(1.0 / fps):
                    return

    def setMinutes(self, time, color):
        if time.minute % 5 != 0:
            for i in range(1, time.minute % 5 + 1):
                self.setPixelColor(self.wcl.mapMinutes(i), color)

    def show(self):
        """
        This function provides the current color settings to the LEDs
        """
        self.strip.show()
Beispiel #20
0
class PiWS281X(DriverBase):
    """
    Driver for controlling WS281X LEDs via the rpi_ws281x C-extension.
    Only supported on the Raspberry Pi 2, 3, and Zero

    This driver needs to be run as sudo and requires the rpi_ws281x C extension.

    Install rpi_ws281x with the following shell commands:

        git clone https://github.com/jgarff/rpi_ws281x.git
        cd rpi_ws281x

        sudo apt-get install python-dev swig scons
        sudo scons

        cd python
        # If using default system python3
        sudo python3 setup.py build install
        # If using virtualenv, enter env then run
        python setup.py build install

    Provides the same parameters of :py:class:`.driver_base.DriverBase` as
    well as those below:

    :param int gpio: GPIO pin to output to. Typically 18 or 13
    :param int ledFreqHz: WS2812B base data frequency in Hz. Only change to
        400000 if using very old WS218B LEDs
    :param int ledDma: DMA channel to use for generating signal
                       (between 1 and 14)
    :param bool ledInvert: True to invert the signal
                       (when using NPN transistor level shift)
    """
    def __init__(self,
                 num,
                 gamma=gamma.NEOPIXEL,
                 c_order="RGB",
                 gpio=18,
                 ledFreqHz=800000,
                 ledDma=5,
                 ledInvert=False,
                 color_channels=3,
                 brightness=255,
                 **kwds):

        if not NeoColor:
            raise ValueError(WS_ERROR)
        super().__init__(num, c_order=c_order, gamma=gamma, **kwds)
        self.gamma = gamma
        if gpio not in PIN_CHANNEL.keys():
            raise ValueError('{} is not a valid gpio option!')
        try:
            strip_type = STRIP_TYPES[color_channels]
        except:
            raise ValueError('In PiWS281X, color_channels can only be 3 or 4')

        self._strip = Adafruit_NeoPixel(num, gpio, ledFreqHz, ledDma,
                                        ledInvert, brightness,
                                        PIN_CHANNEL[gpio], strip_type)
        # Intialize the library (must be called once before other functions).
        try:
            self._strip.begin()
        except RuntimeError as e:
            if os.geteuid():
                if os.path.basename(sys.argv[0]) in ('bp', 'bibliopixel'):
                    command = ['bp'] + sys.argv[1:]
                else:
                    command = ['python'] + sys.argv
                error = SUDO_ERROR.format(command=' '.join(command))
                e.args = (error, ) + e.args
            raise

    def set_brightness(self, brightness):
        self._strip.setBrightness(brightness)
        return True

    def _compute_packet(self):
        self._render()
        data = self._buf
        self._packet = [
            tuple(data[(p * 3):(p * 3) + 3]) for p in range(len(data) // 3)
        ]

    def _send_packet(self):
        for i, p in enumerate(self._packet):
            self._strip.setPixelColor(i, NeoColor(*p))

        self._strip.show()
class wordclock_display:
    """
    Class to display any content on the wordclock display
    Depends on the (individual) wordclock layout/wiring
    """
    def __init__(self, config, wci):
        """
        Initialization
        """
        # Get the wordclocks wiring-layout
        self.wcl = wiring.wiring(config)
        self.wci = wci
        self.config = config
        self.base_path = config.get('wordclock', 'base_path')
        max_brightness = 255

        try:
            self.setBrightness(config.getint('wordclock_display',
                                             'brightness'))
        except:
            self.brightness = max_brightness
            print(
                'WARNING: Default brightness value not set in config-file: '
                'To do so, add a "brightness" between 1..255 to the [wordclock_display]-section.'
            )

        if config.getboolean('wordclock', 'developer_mode'):
            from GTKstrip import GTKstrip
            self.strip = GTKstrip(wci)
            self.default_font = 'wcfont.ttf'
        else:
            try:
                from neopixel import Adafruit_NeoPixel, ws
                self.strip = Adafruit_NeoPixel(
                    self.wcl.LED_COUNT, self.wcl.LED_PIN, self.wcl.LED_FREQ_HZ,
                    self.wcl.LED_DMA, self.wcl.LED_INVERT, max_brightness, 0,
                    ws.WS2811_STRIP_GRB)
            except:
                print(
                    'Update deprecated external dependency rpi_ws281x. '
                    'For details see also https://github.com/jgarff/rpi_ws281x/blob/master/python/README.md'
                )

            if config.get('wordclock_display', 'default_font') == 'wcfont':
                self.default_font = self.base_path + '/wcfont.ttf'
            else:
                self.default_font = os.path.join(
                    '/usr/share/fonts/truetype/freefont/',
                    config.get('wordclock_display', 'default_font') + '.ttf')

        # Initialize the NeoPixel object
        self.strip.begin()

        self.default_fg_color = wcc.WWHITE
        self.default_bg_color = wcc.BLACK

        # Choose language
        try:
            language = ''.join(config.get('wordclock_display', 'language'))
        except:
            # For backward compatibility
            language = ''.join(config.get('plugin_time_default', 'language'))

        print('  Setting language to ' + language + '.')
        if language == 'dutch':
            self.taw = time_dutch.time_dutch()
        elif language == 'english':
            self.taw = time_english.time_english()
        elif language == 'english_c3jr':
            self.taw = time_english_c3jr.time_english()
        elif language == 'german':
            self.taw = time_german.time_german()
        elif language == 'german2':
            self.taw = time_german2.time_german2()
        elif language == 'swabian':
            self.taw = time_swabian.time_swabian()
        elif language == 'swabian2':
            self.taw = time_swabian2.time_swabian2()
        elif language == 'bavarian':
            self.taw = time_bavarian.time_bavarian()
        elif language == 'swiss_german':
            self.taw = time_swiss_german.time_swiss_german()
        elif language == 'swiss_german2':
            self.taw = time_swiss_german2.time_swiss_german2()
        else:
            print('Could not detect language: ' + language + '.')
            print('Choosing default: german')
            self.taw = time_german.time_german()

    def setPixelColor(self, pixel, color):
        """
        Sets the color for a pixel, while considering the brightness, set within the config file
        """
        self.strip.setPixelColor(pixel, color)

    def getBrightness(self):
        """
        Sets the color for a pixel, while considering the brightness, set within the config file
        """
        return self.brightness

    def setBrightness(self, brightness):
        """
        Sets the color for a pixel, while considering the brightness, set within the config file
        """
        brightness_before = self.getBrightness()
        brightness = max(min(255, brightness), 0)

        for i in range(self.wcl.LED_COUNT):
            color = self.getPixelColor(i)
            color = (color / brightness_before) ^ (1 / 2.2) * brightness
            self.setPixelColor(i, color)

        self.brightness = brightness
        self.show()

    def setColorBy1DCoordinates(self, *args, **kwargs):
        """
        Sets a pixel at given 1D coordinates
        """
        return self.wcl.setColorBy1DCoordinates(*args, **kwargs)

    def setColorBy2DCoordinates(self, *args, **kwargs):
        """
        Sets a pixel at given 2D coordinates
        """
        return self.wcl.setColorBy2DCoordinates(*args, **kwargs)

    def get_wca_height(self):
        """
        Returns the height of the WCA
        """
        return self.wcl.WCA_HEIGHT

    def get_wca_width(self):
        """
        Returns the width of the WCA
        """
        return self.wcl.WCA_WIDTH

    def get_led_count(self):
        """
        Returns the overall number of LEDs
        """
        return self.wcl.LED_COUNT

    def dispRes(self):
        """
        Returns the resolution of the wordclock array as string
        E.g. to choose the correct resolution of animations and icons
        """
        return str(self.wcl.WCA_WIDTH) + 'x' + str(self.wcl.WCA_HEIGHT)

    def setColorToAll(self, color, includeMinutes=True):
        """
        Sets a given color to all leds
        If includeMinutes is set to True, color will also be applied to the minute-leds.
        """
        if includeMinutes:
            for i in range(self.wcl.LED_COUNT):
                self.setPixelColor(i, color)
        else:
            for i in self.wcl.getWcaIndices():
                self.setPixelColor(i, color)

    def setColorTemperatureToAll(self, temperature, includeMinutes=True):
        """
        Sets a color to all leds based on the provided temperature in Kelvin
        If includeMinutes is set to True, color will also be applied to the minute-leds.
        """
        self.setColorToAll(wcc.color_temperature_to_rgb(temperature),
                           includeMinutes)

    def resetDisplay(self):
        """
        Reset display
        """
        self.setColorToAll(wcc.BLACK, True)

    def showIcon(self, plugin, iconName):
        """
        Dispays an icon with a specified name.
        The icon needs to be provided within the graphics/icons folder.
        """
        self.setImage(self.base_path + '/wordclock_plugins/' + plugin +
                      '/icons/' + self.dispRes() + '/' + iconName + '.png')

    def setImage(self, absPathToImage):
        """
        Set image (provided as absolute path) to current display
        """
        img = Image.open(absPathToImage)
        width, height = img.size
        for x in range(0, width):
            for y in range(0, height):
                rgb_img = img.convert('RGB')
                r, g, b = rgb_img.getpixel((x, y))
                self.wcl.setColorBy2DCoordinates(self.strip, x, y,
                                                 wcc.Color(r, g, b))
        self.show()

    def animate(self, plugin, animationName, fps=10, count=1, invert=False):
        """
        Runs an animation
        plugin: Plugin-name
        num_of_frames: Number of frames to be displayed
        count: Number of runs
        fps: frames per second
        invert: Invert order of animation
        """
        animation_dir = self.base_path + '/wordclock_plugins/' + plugin + '/animations/' + self.dispRes(
        ) + '/' + animationName + '/'
        num_of_frames = len(
            [file_count for file_count in os.listdir(animation_dir)])

        if invert:
            animation_range = range(num_of_frames - 1, -1, -1)
        else:
            animation_range = range(0, num_of_frames)

        for _ in range(count):
            for i in animation_range:
                self.setImage(animation_dir + str(i).zfill(3) + '.png')
                if self.wci.waitForExit(1.0 / fps):
                    return

    def showText(self,
                 text,
                 font=None,
                 fg_color=None,
                 bg_color=None,
                 fps=10,
                 count=1):
        """
        Display text on display
        """
        if font is None:
            font = self.default_font
        if fg_color is None:
            fg_color = self.default_fg_color
        if bg_color is None:
            bg_color = self.default_bg_color

        text = '    ' + text + '    '

        fnt = fontdemo.Font(font, self.wcl.WCA_HEIGHT)

        text_width, text_height, text_max_descent = fnt.text_dimensions(text)
        text_as_pixel = fnt.render_text(text)

        # Display text count times
        for i in range(count):

            # Erase previous content
            self.setColorToAll(bg_color, includeMinutes=True)

            # Assure here correct rendering, if the text does not fill the whole display
            render_range = self.wcl.WCA_WIDTH if self.wcl.WCA_WIDTH < text_width else text_width
            for y in range(text_height):
                for x in range(render_range):
                    self.wcl.setColorBy2DCoordinates(
                        self.strip, x, y,
                        fg_color if text_as_pixel.pixels[y * text_width +
                                                         x] else bg_color)

            # Show first frame for 0.5 seconds
            self.show()
            if self.wci.waitForExit(0.5):
                return

            # Shift text from left to right to show all.
            for cur_offset in range(text_width - self.wcl.WCA_WIDTH + 1):
                for y in range(text_height):
                    for x in range(self.wcl.WCA_WIDTH):
                        self.wcl.setColorBy2DCoordinates(
                            self.strip, x, y, fg_color
                            if text_as_pixel.pixels[y * text_width + x +
                                                    cur_offset] else bg_color)
                self.show()
                if self.wci.waitForExit(1.0 / fps):
                    return

    def setMinutes(self, time, color):
        if time.minute % 5 != 0:
            for i in range(1, time.minute % 5 + 1):
                self.setPixelColor(self.wcl.mapMinutes(i), color)

    def show(self):
        """
        This function provides the current color settings to the LEDs
        """
        self.strip.show()
Beispiel #22
0
class PiWS281X(DriverBase):
    """
    Driver for controlling WS281X LEDs via the rpi_ws281x C-extension.
    Only supported on the Raspberry Pi 2, 3, and Zero

    This driver needs to be run as sudo and requires the rpi_ws281x C extension.

    Install rpi_ws281x with the following shell commands:

        git clone https://github.com/jgarff/rpi_ws281x.git
        cd rpi_ws281x

        sudo apt-get install python-dev swig scons
        sudo scons

        cd python
        # If using default system python3
        sudo python3 setup.py build install
        # If using virtualenv, enter env then run
        python setup.py build install

    Provides the same parameters of :py:class:`.driver_base.DriverBase` as
    well as those below:

    :param int gpio: GPIO pin to output to. Typically 18 or 13
    :param int ledFreqHz: WS2812B base data frequency in Hz. Only change to
        400000 if using very old WS218B LEDs
    :param int ledDma: DMA channel to use for generating signal (Between 1 and 14)
    :param bool ledInvert: True to invert the signal (when using NPN transistor level shift)
    """
    # Including follow as comment as URLs in docstrings don't play well with sphinx
    # Discussion re: running as sudo
    # https://groups.google.com/d/msg/maniacal-labs-users/6hV-2_-Xmqc/wmWJK709AQAJ
    # https://github.com/jgarff/rpi_ws281x/blob/master/python/neopixel.py#L106

    def __init__(
            self, num, gamma=gamma.NEOPIXEL, c_order="RGB", gpio=18,
            ledFreqHz=800000, ledDma=5, ledInvert=False,
            color_channels=3, brightness=255, **kwds):

        if not NeoColor:
            raise ValueError(WS_ERROR)
        super().__init__(num, c_order=c_order, gamma=gamma, **kwds)
        self.gamma = gamma
        if gpio not in PIN_CHANNEL.keys():
            raise ValueError('{} is not a valid gpio option!')
        try:
            strip_type = STRIP_TYPES[color_channels]
        except:
            raise ValueError('In PiWS281X, color_channels must be either 3 or 4')

        self._strip = Adafruit_NeoPixel(
            num, gpio, ledFreqHz, ledDma, ledInvert, brightness,
            PIN_CHANNEL[gpio], strip_type)
        # Intialize the library (must be called once before other functions).
        try:
            self._strip.begin()
        except RuntimeError as e:
            if os.geteuid():
                if os.path.basename(sys.argv[0]) in ('bp', 'bibliopixel'):
                    command = ['bp'] + sys.argv[1:]
                else:
                    command = ['python'] + sys.argv
                error = SUDO_ERROR.format(command=' '.join(command))
                e.args = (error,) + e.args
            raise

    def set_brightness(self, brightness):
        self._strip.setBrightness(brightness)
        return True

    def _compute_packet(self):
        self._render()
        data = self._buf
        self._packet = [tuple(data[(p * 3):(p * 3) + 3]) for p in range(len(data) // 3)]

    def _send_packet(self):
        for i, p in enumerate(self._packet):
            self._strip.setPixelColor(i, NeoColor(*p))

        self._strip.show()
Beispiel #23
0
    # divides evenly into the number of pixels, or vice versa,
    # the lights won't advance and that's boring to watch.
    # In that case, add a black pixel.
    tot_hits = sum(keywords_found[i] for i in keywords_found)
    if 'flash' in keywords_found:
        tot_hits -= keywords_found['flash']
    if num_pixels % tot_hits == 0 or tot_hits % num_pixels == 0:
        keywords_found['blank'] = 1

    # Loop over the topics:
    for topic in keywords_found:
        if topic == 'flash':
            totdiv = int(tot_time) / FLASHFRAC
            if totdiv > lastflash:
                lastflash = totdiv
                for i in range(keywords_found[topic]):
                    flash(strip, flashcolor)
                # XXX Add the time we flashed to tot_time
            continue

        # For this topic, keywords_found[topic] is the number of keywords
        # we matched on Twitter. Show that number of pixels.
        # The color for this topic is topiccolors[topic].
        for i in range(keywords_found[topic]):
            strip.setPixelColor(led_number, topiccolors[topic])
            strip.show()

            led_number = (led_number + 1) % num_pixels
            time.sleep(TIME_BETWEEN_PIXELS)
            tot_time += TIME_BETWEEN_PIXELS
Beispiel #24
0
class GpioThread(threading.Thread):

    KEYWORDS = [
        "help", "module", "filter", "transition", "update", "off", "?", "h",
        "m", "f", "t", "u"
    ]

    def __init__(self):
        threading.Thread.__init__(self)

        self.strip = Adafruit_NeoPixel(LED_COUNT, LED_PIN, LED_FREQ_HZ,
                                       LED_DMA, LED_INVERT, LED_BRIGHTNESS)
        self.strip.begin()

        self.exit = False
        self.command = None
        self.reply = None
        self.lock = threading.Condition()

        self.isConnected = False
        self.isConnectedTick = 0

        self.commandId = 0
        logging.info("GpioThread initialized")

    def run(self):

        # self.moduleFactory = DefaultComponents.ColorModule
        self.moduleFactory = Cannon.Cannon
        self.filterFactory = DefaultComponents.NoneFilter
        self.transitionFactory = DefaultComponents.NoneTransition

        self.moduleFactory.configure([])
        self.filterFactory.configure([])
        self.transitionFactory.configure([])

        self.module = self.filterFactory.getinstance(
            self.moduleFactory.getinstance())

        logging.debug("GpioThread started (Thread name={})".format(
            threading.Thread.getName(self)))

        messageNumber = 0

        while True:
            self.lock.acquire()
            if self.exit:
                self.lock.release()
                break

            if self.command is not None:
                messageNumber += 1
                logging.debug("Received message #{}: {}".format(
                    messageNumber, self.command))
                self.reply = self.processCommandT(self.command)
                self.command = None
                # self.lock.notify()
                logging.debug("Notified message #{}: {}".format(
                    messageNumber, self.reply))

            self.lock.release()

            block = self.module.next()

            self.isConnectedTick += 1
            if self.isConnectedTick >= 100:
                if not self.isConnected:
                    block[0] = [255, 0, 0]
                    block[1] = [0, 0, 0]
                self.isConnectedTick = 0
            self.project(block)

        logging.info("GpioThread stopping")

        for i in range(LED_COUNT):
            self.strip.setPixelColor(i, 0x0)
        self.strip.show()

    def processCommandT(self, line):
        """Apply the changes, ane return the reply to the command"""
        chunks = line.split()
        if len(chunks) <= 0:
            return "ERR: Empty command"
        if not chunks[0] in GpioThread.KEYWORDS:
            return "ERR: Unknown keyword {}; use \"help\" or \"?\" for references"

        if chunks[0] in ["help", "h", "?"]:
            if len(chunks) == 1:
                return self.getHelp()
            return self.getHelp(chunks[1:])

        if chunks[0] in ["update", "u"]:
            self.update(
                self.filterFactory.getinstance(
                    self.moduleFactory.getinstance()))
            return "OK: Transition complete"

        if chunks[0] in ["module", "m"]:
            if len(chunks) < 2:
                return self.getHelp(["m"])
            module = Defs.MODULES.get(chunks[1])
            if module is None:
                return "ERR: unknown module \"{}\"".format(chunks[1])
            self.moduleFactory = module
            self.moduleFactory.configure(chunks[2:])
            return "OK: Module set to \"{}\"; use >> update << to apply changes".format(
                chunks[1])

        if chunks[0] in ["filter", "f"]:
            if len(chunks) < 2:
                return self.getHelp(["f"])
            factory = Defs.FILTERS.get(chunks[1])
            if factory is None:
                return "ERR: unknown filter \"{}\"".format(chunks[1])
            self.filterFactory = factory
            self.filterFactory.configure(chunks[2:])
            return "OK: Filter set to \"{}\"; use >> update << to apply changes".format(
                chunks[1])

        if chunks[0] in ["transition", "t"]:
            if len(chunks) < 2:
                return self.getHelp(["t"])
            transition = Defs.TRANSITIONS.get(chunks[1])
            if transition is None:
                return "ERR: unknown transition \"{}\"".format(chunks[1])
            self.transitionFactory = transition
            self.transitionFactory.configure(chunks[2:])
            return "OK: Transition set to \"{}\"; use >> update << to apply changes".format(
                chunks[1])

        if chunks[0] in ["off"]:
            Defs.MODULES.get("color").configure(["0x0"])
            self.update(Defs.MODULES.get("color").getinstance())
            # no filter used
            return "Strand off"

        return "TODO: Process commands"

    def update(self, afterModule):
        logging.info("Starting transition")
        transition = self.transitionFactory.newinstance(
            self.module, afterModule)
        block = transition.next()
        while block is not None:
            self.project(block)
            block = transition.next()
        self.module = afterModule
        logging.info("Transition finished")

    def getHelp(self, topic=[]):
        if len(topic) > 0:
            if topic[0] in ["module", "m"]:
                if len(topic) > 1:
                    name = topic[1]
                    if name in Defs.MODULES.keys():
                        module = Defs.MODULES[name]
                        return Const.APP_NAME + " \"{}\":\n{}".format(
                            module.name, module.help)
                    return Const.APP_NAME + " modules: Unknown name \"{}\"".format(
                        name)
                return Const.APP_NAME + " modules: {}".format(
                    Defs.MODULES.keys())

            if topic[0] in ["filter", "f"]:
                if len(topic) > 1:
                    name = topic[1]
                    if name in Defs.FILTERS.keys():
                        filter = Defs.FILTERS[name]
                        return Const.APP_NAME + " \"{}\":\n{}".format(
                            filter.name, filter.help)
                    return Const.APP_NAME + " filters: Unknown name \"{}\"".format(
                        name)
                return Const.APP_NAME + " filters: {}\n".format(
                    Defs.FILTERS.keys())

            if topic[0] in ["transition", "t"]:
                if len(topic) > 1:
                    name = topic[1]
                    if name in Defs.TRANSITIONS.keys():
                        transition = Defs.TRANSITIONS[name]
                        return Const.APP_NAME + " \"{}\":\n{}".format(
                            transition.name, transition.help)
                    return Const.APP_NAME + " transitions: Unknown name \"{}\"".format(
                        name)
                return Const.APP_NAME + " transitions: {}\n".format(
                    Defs.TRANSITIONS.keys())

        return Const.APP_NAME + " manual. The recognized keywords are\n" \
               "  module/m: graphics painter configuration\n" \
               "  filter/f: display filter configuration; filters are used to display only subsections of the graphics\n" \
               "  transition/t: configure transition used to update to new graphics module or filter\n" \
               "  update/u: execute the configuration changes\n" \
               "  off: turn the strand off (display black)\n" \
               "  help/h/?: display help. use >> help <keyword> << to list available configuration details\n"

    def ctrl(self, command):
        self.lock.acquire()
        self.command = command
        self.commandId += 1
        logging.debug("Setting command #{}: {}".format(self.commandId,
                                                       command))
        self.reply = None

        boo = self.lock.wait(1)
        if not boo:
            logging.warning("Condition timed out. Command={}".format(
                self.command))

        reply = self.reply
        if reply == None:
            logging.warning("Command \"{}\": no reply set!")
            reply = "ERR: no reply received"

        self.lock.release()
        return reply

    def quit(self):
        self.lock.acquire()
        self.exit = True
        logging.info("GpioThread signalled to stop")
        self.lock.release()

    def __adjust(self, num):
        return num * (num >> 2) >> 6
        # return num

    def __toGrbInt(self, tuple):
        ret = (self.__adjust(tuple[1]) << 16) \
              + (self.__adjust(tuple[0]) << 8) \
              + self.__adjust(tuple[2])
        return ret

    def project(self, block):
        # print("Graphics colors={}"
        #       .format(map(hex, map(lambda x: (x[0] << 16) + (x[1] << 8) + x[2], block))))
        for i in range(LED_COUNT):
            self.strip.setPixelColor(i, self.__toGrbInt(block[i]))
        self.strip.show()
Beispiel #25
0
from neopixel import ws, Adafruit_NeoPixel, Color

import config

strip = Adafruit_NeoPixel(
    config.N_PIXELS,
    config.LED_PIN,
    config.LED_FREQ_HZ,
    config.LED_DMA,
    config.LED_INVERT,
    config.BRIGHTNESS,
    config.LED_CHANNEL,
    ws.WS2811_STRIP_GRB
)
strip.begin()
strip.setPixelColor(30, Color(255, 0, 0))
strip.show()
Beispiel #26
0
arg1 = [i for i in range(0, 255, 4)]
arg2 = [i for i in range(0, 255, 4)]
arg3 = [i for i in range(0, 255, 4)]

lst = [1, 2, 3, 4, 5]

lights = [l for i in range(int(round(len(arg1) / len(lst)))) for l in lst]
del lights[-1]

count = 0
while (count < 60):
    for i, li, ar1, ar2, ar3, in zip(range(strip.numPixels()), lights, arg1,
                                     arg2, arg3):
        print(i, li, 'on')
        strip.setPixelColor(li, Color(ar1, ar2, ar3))
        strip.show()
        time.sleep(1)
        strip.setPixelColor(li, Color(ar1, ar2, ar3))
        strip.show()
        time.sleep(1)
        strip.setPixelColor(li, Color(ar1, ar2, ar3))
        strip.show()
        time.sleep(1)
        strip.setPixelColor(li, Color(ar1, ar2, ar3))
        strip.show()
        time.sleep(1)
        strip.setPixelColor(li, Color(ar1, ar2, ar3))
        strip.show()
        time.sleep(1)
        count += 1