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244 lines
9.5 KiB
Python
244 lines
9.5 KiB
Python
6 years ago
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"""
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from https://github.com/tinue/APA102_Pi
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This is the main driver module for APA102 LEDs
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"""
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import spidev
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from math import ceil
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RGB_MAP = { 'rgb': [3, 2, 1], 'rbg': [3, 1, 2], 'grb': [2, 3, 1],
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'gbr': [2, 1, 3], 'brg': [1, 3, 2], 'bgr': [1, 2, 3] }
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class APA102:
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"""
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Driver for APA102 LEDS (aka "DotStar").
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(c) Martin Erzberger 2016-2017
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My very first Python code, so I am sure there is a lot to be optimized ;)
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Public methods are:
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- set_pixel
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- set_pixel_rgb
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- show
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- clear_strip
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- cleanup
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Helper methods for color manipulation are:
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- combine_color
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- wheel
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The rest of the methods are used internally and should not be used by the
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user of the library.
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Very brief overview of APA102: An APA102 LED is addressed with SPI. The bits
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are shifted in one by one, starting with the least significant bit.
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An LED usually just forwards everything that is sent to its data-in to
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data-out. While doing this, it remembers its own color and keeps glowing
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with that color as long as there is power.
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An LED can be switched to not forward the data, but instead use the data
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to change it's own color. This is done by sending (at least) 32 bits of
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zeroes to data-in. The LED then accepts the next correct 32 bit LED
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frame (with color information) as its new color setting.
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After having received the 32 bit color frame, the LED changes color,
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and then resumes to just copying data-in to data-out.
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The really clever bit is this: While receiving the 32 bit LED frame,
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the LED sends zeroes on its data-out line. Because a color frame is
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32 bits, the LED sends 32 bits of zeroes to the next LED.
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As we have seen above, this means that the next LED is now ready
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to accept a color frame and update its color.
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So that's really the entire protocol:
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- Start by sending 32 bits of zeroes. This prepares LED 1 to update
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its color.
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- Send color information one by one, starting with the color for LED 1,
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then LED 2 etc.
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- Finish off by cycling the clock line a few times to get all data
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to the very last LED on the strip
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The last step is necessary, because each LED delays forwarding the data
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a bit. Imagine ten people in a row. When you yell the last color
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information, i.e. the one for person ten, to the first person in
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the line, then you are not finished yet. Person one has to turn around
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and yell it to person 2, and so on. So it takes ten additional "dummy"
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cycles until person ten knows the color. When you look closer,
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you will see that not even person 9 knows its own color yet. This
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information is still with person 2. Essentially the driver sends additional
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zeroes to LED 1 as long as it takes for the last color frame to make it
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down the line to the last LED.
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"""
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# Constants
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MAX_BRIGHTNESS = 0b11111 # Safeguard: Set to a value appropriate for your setup
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LED_START = 0b11100000 # Three "1" bits, followed by 5 brightness bits
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def __init__(self, num_led, global_brightness=MAX_BRIGHTNESS,
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order='rgb', bus=0, device=1, max_speed_hz=8000000):
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self.num_led = num_led # The number of LEDs in the Strip
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order = order.lower()
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self.rgb = RGB_MAP.get(order, RGB_MAP['rgb'])
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# Limit the brightness to the maximum if it's set higher
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if global_brightness > self.MAX_BRIGHTNESS:
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self.global_brightness = self.MAX_BRIGHTNESS
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else:
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self.global_brightness = global_brightness
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self.leds = [self.LED_START,0,0,0] * self.num_led # Pixel buffer
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self.spi = spidev.SpiDev() # Init the SPI device
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self.spi.open(bus, device) # Open SPI port 0, slave device (CS) 1
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# Up the speed a bit, so that the LEDs are painted faster
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if max_speed_hz:
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self.spi.max_speed_hz = max_speed_hz
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def clock_start_frame(self):
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"""Sends a start frame to the LED strip.
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This method clocks out a start frame, telling the receiving LED
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that it must update its own color now.
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"""
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self.spi.xfer2([0] * 4) # Start frame, 32 zero bits
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def clock_end_frame(self):
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"""Sends an end frame to the LED strip.
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As explained above, dummy data must be sent after the last real colour
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information so that all of the data can reach its destination down the line.
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The delay is not as bad as with the human example above.
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It is only 1/2 bit per LED. This is because the SPI clock line
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needs to be inverted.
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Say a bit is ready on the SPI data line. The sender communicates
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this by toggling the clock line. The bit is read by the LED
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and immediately forwarded to the output data line. When the clock goes
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down again on the input side, the LED will toggle the clock up
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on the output to tell the next LED that the bit is ready.
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After one LED the clock is inverted, and after two LEDs it is in sync
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again, but one cycle behind. Therefore, for every two LEDs, one bit
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of delay gets accumulated. For 300 LEDs, 150 additional bits must be fed to
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the input of LED one so that the data can reach the last LED.
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Ultimately, we need to send additional numLEDs/2 arbitrary data bits,
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in order to trigger numLEDs/2 additional clock changes. This driver
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sends zeroes, which has the benefit of getting LED one partially or
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fully ready for the next update to the strip. An optimized version
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of the driver could omit the "clockStartFrame" method if enough zeroes have
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been sent as part of "clockEndFrame".
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"""
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self.spi.xfer2([0xFF] * 4)
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# Round up num_led/2 bits (or num_led/16 bytes)
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#for _ in range((self.num_led + 15) // 16):
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# self.spi.xfer2([0x00])
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def clear_strip(self):
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""" Turns off the strip and shows the result right away."""
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for led in range(self.num_led):
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self.set_pixel(led, 0, 0, 0)
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self.show()
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def set_pixel(self, led_num, red, green, blue, bright_percent=100):
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"""Sets the color of one pixel in the LED stripe.
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The changed pixel is not shown yet on the Stripe, it is only
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written to the pixel buffer. Colors are passed individually.
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If brightness is not set the global brightness setting is used.
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"""
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if led_num < 0:
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return # Pixel is invisible, so ignore
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if led_num >= self.num_led:
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return # again, invisible
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# Calculate pixel brightness as a percentage of the
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# defined global_brightness. Round up to nearest integer
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# as we expect some brightness unless set to 0
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brightness = int(ceil(bright_percent*self.global_brightness/100.0))
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# LED startframe is three "1" bits, followed by 5 brightness bits
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ledstart = (brightness & 0b00011111) | self.LED_START
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start_index = 4 * led_num
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self.leds[start_index] = ledstart
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self.leds[start_index + self.rgb[0]] = red
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self.leds[start_index + self.rgb[1]] = green
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self.leds[start_index + self.rgb[2]] = blue
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def set_pixel_rgb(self, led_num, rgb_color, bright_percent=100):
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"""Sets the color of one pixel in the LED stripe.
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The changed pixel is not shown yet on the Stripe, it is only
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written to the pixel buffer.
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Colors are passed combined (3 bytes concatenated)
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If brightness is not set the global brightness setting is used.
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"""
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self.set_pixel(led_num, (rgb_color & 0xFF0000) >> 16,
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(rgb_color & 0x00FF00) >> 8, rgb_color & 0x0000FF,
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bright_percent)
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def rotate(self, positions=1):
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""" Rotate the LEDs by the specified number of positions.
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Treating the internal LED array as a circular buffer, rotate it by
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the specified number of positions. The number could be negative,
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which means rotating in the opposite direction.
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"""
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cutoff = 4 * (positions % self.num_led)
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self.leds = self.leds[cutoff:] + self.leds[:cutoff]
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def show(self):
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"""Sends the content of the pixel buffer to the strip.
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Todo: More than 1024 LEDs requires more than one xfer operation.
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"""
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self.clock_start_frame()
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# xfer2 kills the list, unfortunately. So it must be copied first
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# SPI takes up to 4096 Integers. So we are fine for up to 1024 LEDs.
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data = list(self.leds)
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while data:
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self.spi.xfer2(data[:32])
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data = data[32:]
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self.clock_end_frame()
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def cleanup(self):
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"""Release the SPI device; Call this method at the end"""
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self.spi.close() # Close SPI port
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@staticmethod
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def combine_color(red, green, blue):
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"""Make one 3*8 byte color value."""
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return (red << 16) + (green << 8) + blue
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def wheel(self, wheel_pos):
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"""Get a color from a color wheel; Green -> Red -> Blue -> Green"""
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if wheel_pos > 255:
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wheel_pos = 255 # Safeguard
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if wheel_pos < 85: # Green -> Red
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return self.combine_color(wheel_pos * 3, 255 - wheel_pos * 3, 0)
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if wheel_pos < 170: # Red -> Blue
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wheel_pos -= 85
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return self.combine_color(255 - wheel_pos * 3, 0, wheel_pos * 3)
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# Blue -> Green
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wheel_pos -= 170
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return self.combine_color(0, wheel_pos * 3, 255 - wheel_pos * 3)
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def dump_array(self):
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"""For debug purposes: Dump the LED array onto the console."""
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print(self.leds)
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