class TouchPiano:
"""
As you touch one of the touch inputs, A1 - A7, a note will be played.
"""
def __init__(self):
# 7 musical note frequencies - starting at middle c
self.the_notes = [440, 493, 523, 587, 659, 698, 784]
# instantiate pymatacpx
self.p = PyMataCpx()
# turn on all touch pads 1-7
for touch_pad in range(1, 8):
self.p.cpx_cap_touch_start(touch_pad, self.play_notes)
# self.p.cpx_cap_touch_start(4, self.play_notes)
self.max = 0
print()
print('Touch one of the touch pads, A1 - A7, and a note will play.')
while True:
# just kill time waiting for a light data to arrive
try:
time.sleep(.001)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_close_and_exit()
def play_notes(self, data):
# determine if the pad was touched or released
if data[2]:
# get the note
try:
note = self.the_notes[data[1] - 1]
except IndexError:
print(data[1])
raise
# play the note
self.p.cpx_tone(note, 0)
else:
# touch pad released - turn off the note
self.p.cpx_tone_off()
def __init__(self,
*subscriber_list,
back_plane_ip_address=None,
subscriber_port='43125',
publisher_port='43124',
process_name='CpxGateway',
publisher_topic=None,
log=False):
"""
:param subscriber_list: a tuple or list of subscription topics.
:param back_plane_ip_address:
:param subscriber_port:
:param publisher_port:
:param process_name:
"""
# initialize parent
super(CpxGateway,
self).__init__(subscriber_list=subscriber_list,
back_plane_ip_address=back_plane_ip_address,
subscriber_port=subscriber_port,
publisher_port=publisher_port,
process_name=process_name)
self.log = log
if self.log:
fn = str(pathlib.Path.home()) + "/cpxgw.log"
self.logger = logging.getLogger(__name__)
logging.basicConfig(filename=fn, filemode='w', level=logging.DEBUG)
sys.excepthook = self.my_handler
self.publisher_topic = publisher_topic
self.cpx = PyMataCpx()
atexit.register(self.shutdown)
# hold the time of the last analog data to be received.
# use to determine if connectivity is gone.
self.last_analog_data_time = None
# start up all the sensors
self.cpx.cpx_accel_start(self.tilt_callback)
self.cpx.cpx_button_a_start(self.switch_callback)
self.cpx.cpx_button_b_start(self.switch_callback)
self.cpx.cpx_slide_switch_start(self.switch_callback)
self.cpx.cpx_light_sensor_start(self.analog_callback)
self.cpx.cpx_microphone_start(self.analog_callback)
self.cpx.cpx_temperature_start(self.analog_callback)
for touch_pad in range(1, 8):
self.cpx.cpx_cap_touch_start(touch_pad, self.touchpad_callback)
threading.Thread.__init__(self)
self.daemon = True
# start the watchdog thread
self.start()
# start the banyan receive loop
try:
self.receive_loop()
except:
pass
def __init__(self):
self.p = PyMataCpx()
print('Clap your hands loudly to stop the neopixels from moving.')
print('Clap again, to start them up')
self.p.cpx_microphone_start(self.listen)
self.go = True
while True:
try:
# run the light show
for neopixel in range(0, 10):
if self.go:
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
r = random.randint(0, 254)
g = random.randint(0, 254)
b = random.randint(0, 254)
self.p.cpx_pixel_set(neopixel, r, g, b)
self.p.cpx_pixels_show()
time.sleep(.2)
else:
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
time.sleep(.001)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
self.p.cpx_close_and_exit()
def __init__(self):
# a dictionary of pixels as the key and
# associated rgb color values
self.pix_d = {
0: [153, 76, 0],
1: [153, 0, 0],
2: [153, 153, 0],
3: [204, 204, 0],
4: [0, 153, 0],
5: [0, 153, 153],
6: [0, 0, 233],
7: [153, 0, 153],
8: [255, 0, 255],
9: [255, 255, 255],
}
# save the previous pixel number that was illuminated
self.last_pixel_used = 0
# save the first temperature read as the ambient temperature
# and use that as the basis of comparison.
self.ambient = 0
# instantiate pymatacpx
self.p = PyMataCpx()
# clear the pixels before monitoring the light
# sensor values
self.p.cpx_pixels_clear()
# set pixel 0 to be the initial pixel and set its rgb
# from the dictionary
self.p.cpx_pixel_set(0, *self.pix_d[0])
self.p.cpx_pixels_show()
# enable the temperature sensor and provide a callback.
self.p.cpx_temperature_start(self.temp_callback)
print()
print('Touch the temperature sensor. As the temperature changes')
print('Different neopixels will light up.')
print()
print('The current temperature and pixel selected will be shown on the console.')
print()
while True:
# just kill time waiting for a light data to arrive
try:
time.sleep(.1)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_close_and_exit()
def __init__(self):
# a dictionary of pixels as the key and
# associated rgb color values
self.pix_d = {
0: [153, 76, 0],
1: [153, 0, 0],
2: [153, 153, 0],
3: [204, 204, 0],
4: [0, 153, 0],
5: [0, 153, 153],
6: [0, 0, 233],
7: [153, 0, 153],
8: [255, 0, 255],
9: [255, 255, 255],
}
# save the previous pixel number that was illuminated
self.last_pixel_used = 0
# instantiate pymatacpx
self.p = PyMataCpx()
# clear the pixels before monitoring the light
# sensor values
self.p.cpx_pixels_clear()
# set pixel 0 to be the initial pixel and set its rgb
# from the dictionary
self.p.cpx_pixel_set(0, *self.pix_d[0])
self.p.cpx_pixels_show()
# enable the light sensor and provide a callback.
# Note: the callback is a member of this class.
self.p.cpx_light_sensor_start(self.light_sensor_callback)
print()
print(
'Move a light source near the light sensor, and depending upon the'
)
print(
'intensity of the light, an associated pixel will be illuminated.')
print()
while True:
# just kill time waiting for a light data to arrive
try:
time.sleep(.1)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_close_and_exit()
def __init__(self, verbose=True):
# PyMata is an old style class so you can't use super.
PyMataCpx.__init__(self, verbose)
# Setup handler for response data.
# Note that the data length (1) appears to be unused for these sysex
# responses.
self._command_handler.command_dispatch.update(
{CP_COMMAND: [self._response_handler, 1]})
# Setup configured callbacks to null.
self._accel_callback = None
self._tap_callback = None
self._temp_callback = None
self._cap_callback = None
self._sensecolor_callback = None
self._implemenation_version_callback = None
def __init__(self):
# instantiate pymatacpx
self.p = PyMataCpx()
# start the accelerometer
self.p.cpx_accel_start(self.accel_callback)
# create a variable to remember the last position
self.last_position = 'flat'
print()
print('Move the circuit playground express and watch its position')
print('reported to the console.')
while True:
# just kill time waiting for a light data to arrive
try:
time.sleep(.001)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_close_and_exit()
def __init__(self):
# create an instance of the API
self.p = PyMataCpx()
print('Tap the playground express to stop the neopixels from moving.')
print('Tap again, to start them up')
print('The tap state will be printed to the console')
# Start monitoring for tap events and
# send event notifications to the tapped method.
self.p.cpx_tap_start(self.tapped)
self.go = True
while True:
try:
# run the light show
for neopixel in range(0, 10):
if self.go:
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
r = random.randint(0, 254)
g = random.randint(0, 254)
b = random.randint(0, 254)
self.p.cpx_pixel_set(neopixel, r, g, b)
self.p.cpx_pixels_show()
time.sleep(.2)
else:
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
time.sleep(.001)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
self.p.cpx_close_and_exit()
def __init__(self):
# 7 musical note frequencies - starting at middle c
self.the_notes = [440, 493, 523, 587, 659, 698, 784]
# instantiate pymatacpx
self.p = PyMataCpx()
# turn on all touch pads 1-7
for touch_pad in range(1, 8):
self.p.cpx_cap_touch_start(touch_pad, self.play_notes)
# self.p.cpx_cap_touch_start(4, self.play_notes)
self.max = 0
print()
print('Touch one of the touch pads, A1 - A7, and a note will play.')
while True:
# just kill time waiting for a light data to arrive
try:
time.sleep(.001)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_close_and_exit()
class TheTapper():
"""
Illuminate the neopixels in a counter-clockwise fashion with randomly generated colors.
When you tap the playground express, the neopixels will stop changing and the
program pauses. Tap again and the neopixels will start again.
"""
def __init__(self):
# create an instance of the API
self.p = PyMataCpx()
print('Tap the playground express to stop the neopixels from moving.')
print('Tap again, to start them up')
print('The tap state will be printed to the console')
# Start monitoring for tap events and
# send event notifications to the tapped method.
self.p.cpx_tap_start(self.tapped)
self.go = True
while True:
try:
# run the light show
for neopixel in range(0, 10):
if self.go:
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
r = random.randint(0, 254)
g = random.randint(0, 254)
b = random.randint(0, 254)
self.p.cpx_pixel_set(neopixel, r, g, b)
self.p.cpx_pixels_show()
time.sleep(.2)
else:
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
time.sleep(.001)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
self.p.cpx_close_and_exit()
def tapped(self, data):
"""
:param data: data[0] = data type (analog = 2, digital =32)
data[1] = pin for device 27
data[2] = tap data - list of booleans.
First value for 1 tap
Second value for 2 taps
"""
# for any taps, toggle the go flag
# print out the current tap state
if data[2] != [False, False]:
self.go = not self.go
print(self.go)
class LightMeter:
"""
Using the light sensor, select and
illuminate pixels based on the current light sensor reading.
As the light sensor values increase, the pixels will be lit
in a clockwise fashion.
"""
def __init__(self):
# a dictionary of pixels as the key and
# associated rgb color values
self.pix_d = {
0: [153, 76, 0],
1: [153, 0, 0],
2: [153, 153, 0],
3: [204, 204, 0],
4: [0, 153, 0],
5: [0, 153, 153],
6: [0, 0, 233],
7: [153, 0, 153],
8: [255, 0, 255],
9: [255, 255, 255],
}
# save the previous pixel number that was illuminated
self.last_pixel_used = 0
# instantiate pymatacpx
self.p = PyMataCpx()
# clear the pixels before monitoring the light
# sensor values
self.p.cpx_pixels_clear()
# set pixel 0 to be the initial pixel and set its rgb
# from the dictionary
self.p.cpx_pixel_set(0, *self.pix_d[0])
self.p.cpx_pixels_show()
# enable the light sensor and provide a callback.
# Note: the callback is a member of this class.
self.p.cpx_light_sensor_start(self.light_sensor_callback)
print()
print(
'Move a light source near the light sensor, and depending upon the'
)
print(
'intensity of the light, an associated pixel will be illuminated.')
print()
while True:
# just kill time waiting for a light data to arrive
try:
time.sleep(.1)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_close_and_exit()
# This is the callback to process light sensor data
def light_sensor_callback(self, data):
"""
Light sensor data processor
:param data: data[2] contains the current light sensor reading
:return:
"""
# get the currently reported level
level = data[2]
# the level is in the range of 0-1000.
# adjust the level to map into a valid pixel number
if level in range(0, 99):
pixel = 0
elif level in range(100, 199):
pixel = 1
elif level in range(200, 299):
pixel = 2
elif level in range(300, 399):
pixel = 3
elif level in range(400, 499):
pixel = 4
elif level in range(500, 599):
pixel = 5
elif level in range(600, 699):
pixel = 6
elif level in range(700, 799):
pixel = 7
elif level in range(800, 899):
pixel = 8
else:
pixel = 9
# get the rgb value for the pixel
rgb = self.pix_d[pixel]
# if this is not the same pixel as the last one enabled
# then manipulate the pixels.
# turn off the current pixel and turn on the new one.
if pixel != self.last_pixel_used:
# extinguish the previous pixel
self.p.cpx_pixel_set(self.last_pixel_used, 0, 0, 0)
# set the new pixel
self.p.cpx_pixel_set(pixel, *rgb)
# control the pixels
self.p.cpx_pixels_show()
self.last_pixel_used = pixel
class Thermometer:
"""
Touch the temperature sensor on the playground express.
As the temperature increases, pixels will illuminate to
indicate the temperature.
"""
def __init__(self):
# a dictionary of pixels as the key and
# associated rgb color values
self.pix_d = {
0: [153, 76, 0],
1: [153, 0, 0],
2: [153, 153, 0],
3: [204, 204, 0],
4: [0, 153, 0],
5: [0, 153, 153],
6: [0, 0, 233],
7: [153, 0, 153],
8: [255, 0, 255],
9: [255, 255, 255],
}
# save the previous pixel number that was illuminated
self.last_pixel_used = 0
# save the first temperature read as the ambient temperature
# and use that as the basis of comparison.
self.ambient = 0
# instantiate pymatacpx
self.p = PyMataCpx()
# clear the pixels before monitoring the light
# sensor values
self.p.cpx_pixels_clear()
# set pixel 0 to be the initial pixel and set its rgb
# from the dictionary
self.p.cpx_pixel_set(0, *self.pix_d[0])
self.p.cpx_pixels_show()
# enable the temperature sensor and provide a callback.
self.p.cpx_temperature_start(self.temp_callback)
print()
print('Touch the temperature sensor. As the temperature changes')
print('Different neopixels will light up.')
print()
print('The current temperature and pixel selected will be shown on the console.')
print()
while True:
# just kill time waiting for a light data to arrive
try:
time.sleep(.1)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_close_and_exit()
# This is the callback to process light sensor data
def temp_callback(self, data):
"""
Light sensor data processor
:param data: data[0] = 2 analog mode
data[1] = pin 0
data[2] = temp in degrees C
"""
# the current temperature
the_current_temperature = data[2]
# save the temperature the first time
# through as ambient
if not self.ambient:
self.ambient = the_current_temperature
# select the pixel based on the current temperature
if self.ambient < the_current_temperature < (self.ambient + .6):
pixel = 0
elif (self.ambient + 0.6) < the_current_temperature < (self.ambient + 1.2):
pixel = 1
elif (self.ambient < the_current_temperature + 1.2) < the_current_temperature < (self.ambient + 1.8):
pixel = 2
elif (self.ambient < the_current_temperature + 1.8) < the_current_temperature < (self.ambient + 2.4):
pixel = 3
elif (self.ambient < the_current_temperature + 2.4) < the_current_temperature < (self.ambient + 3.0):
pixel = 4
elif (self.ambient < the_current_temperature + 3.0) < the_current_temperature < (self.ambient + 3.6):
pixel = 5
elif (self.ambient < the_current_temperature + 3.6) < the_current_temperature < (self.ambient + 4.2):
pixel = 6
elif (self.ambient < the_current_temperature + 4.2) < the_current_temperature < (self.ambient + 4.8):
pixel = 7
elif (self.ambient < the_current_temperature + 4.8) < the_current_temperature < (self.ambient + 5.4):
pixel = 8
else:
pixel = 9
# get the rgb value for the pixel
rgb = self.pix_d[pixel]
# if this is not the same pixel as the last one enabled
# then manipulate the pixels.
# turn off the current pixel and turn on the new one.
if pixel != self.last_pixel_used:
# extinguish the previous pixel
self.p.cpx_pixel_set(self.last_pixel_used, 0, 0, 0)
# set the new pixel
self.p.cpx_pixel_set(pixel, *rgb)
# control the pixels
self.p.cpx_pixels_show()
self.last_pixel_used = pixel
print('ambient: {} current: {} pixel{}'.format(round(self.ambient, 3),
round(the_current_temperature, 3),
pixel))
class Tilted:
"""
Tilt the playground express and see its position written to the
console. The position will be written only when it changes.
"""
def __init__(self):
# instantiate pymatacpx
self.p = PyMataCpx()
# start the accelerometer
self.p.cpx_accel_start(self.accel_callback)
# create a variable to remember the last position
self.last_position = 'flat'
print()
print('Move the circuit playground express and watch its position')
print('reported to the console.')
while True:
# just kill time waiting for a light data to arrive
try:
time.sleep(.001)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_close_and_exit()
def accel_callback(self, data):
"""
Take the raw xyz data and transform it to
positional strings.
:param data: data [0] = data mode 32 is analog.
data[1] = the pin number - this is a pseudo pin number
data[2] = x value
data[3] = y value
data[4] = z value
"""
x = data[2]
y = data[3]
z = data[4]
# Convert raw Accelerometer values to degrees
x_angle = (math.atan2(y, z) + math.pi) * (180 / math.pi)
y_angle = (math.atan2(z, x) + math.pi) * (180 / math.pi)
position = ""
if 175 < x_angle < 185:
position = 'flat'
elif 186 < x_angle < 360:
position = 'up'
elif 90 < x_angle < 185:
position = 'down'
if position != 'flat':
if 275 < y_angle < 360:
position = position + ' right'
elif 180 < y_angle < 270:
position = position + ' left'
if self.last_position != position:
self.last_position = position
print(position)
class CpxGateway(GatewayBase, threading.Thread):
"""
This class is the interface class for the Circuit Playground
Express supporting Scratch 3.
"""
def __init__(self,
*subscriber_list,
back_plane_ip_address=None,
subscriber_port='43125',
publisher_port='43124',
process_name='CpxGateway',
publisher_topic=None,
log=False):
"""
:param subscriber_list: a tuple or list of subscription topics.
:param back_plane_ip_address:
:param subscriber_port:
:param publisher_port:
:param process_name:
"""
# initialize parent
super(CpxGateway,
self).__init__(subscriber_list=subscriber_list,
back_plane_ip_address=back_plane_ip_address,
subscriber_port=subscriber_port,
publisher_port=publisher_port,
process_name=process_name)
self.log = log
if self.log:
fn = str(pathlib.Path.home()) + "/cpxgw.log"
self.logger = logging.getLogger(__name__)
logging.basicConfig(filename=fn, filemode='w', level=logging.DEBUG)
sys.excepthook = self.my_handler
self.publisher_topic = publisher_topic
self.cpx = PyMataCpx()
atexit.register(self.shutdown)
# hold the time of the last analog data to be received.
# use to determine if connectivity is gone.
self.last_analog_data_time = None
# start up all the sensors
self.cpx.cpx_accel_start(self.tilt_callback)
self.cpx.cpx_button_a_start(self.switch_callback)
self.cpx.cpx_button_b_start(self.switch_callback)
self.cpx.cpx_slide_switch_start(self.switch_callback)
self.cpx.cpx_light_sensor_start(self.analog_callback)
self.cpx.cpx_microphone_start(self.analog_callback)
self.cpx.cpx_temperature_start(self.analog_callback)
for touch_pad in range(1, 8):
self.cpx.cpx_cap_touch_start(touch_pad, self.touchpad_callback)
threading.Thread.__init__(self)
self.daemon = True
# start the watchdog thread
self.start()
# start the banyan receive loop
try:
self.receive_loop()
except:
pass
# except KeyboardInterrupt:
# except KeyboardInterrupt:
# self.cpx.cpx_close_and_exit()
# sys.exit(0)
# os._exit(1)
def init_pins_dictionary(self):
pass
def play_tone(self, topic, payload):
"""
This method plays a tone on a piezo device connected to the selected
pin at the frequency and duration requested.
Frequency is in hz and duration in milliseconds.
Call set_mode_tone before using this method.
:param topic: message topic
:param payload: {"command": "play_tone", "pin": “PIN”, "tag": "TAG",
“freq”: ”FREQUENCY”, duration: “DURATION”}
"""
self.cpx.cpx_tone(payload['freq'], payload['duration'])
def additional_banyan_messages(self, topic, payload):
if payload['command'] == 'pixel':
self.set_pixel(payload)
def set_pixel(self, payload):
self.cpx.cpx_pixel_set(payload['pixel'], payload['red'],
payload['green'], payload['blue'])
self.cpx.cpx_pixels_show()
def digital_write(self, topic, payload):
"""
This method performs a digital write to the board LED
:param topic: message topic
:param payload: {"command": "digital_write", "pin": “PIN”, "value": “VALUE”}
"""
if payload['value']:
self.cpx.cpx_board_light_on()
else:
self.cpx.cpx_board_light_off()
# The CPX sensor callbacks
def tilt_callback(self, data):
"""
Report the tilt of the express board
Take the raw xyz data and transform it to
positional strings.
:param data: data [0] = data mode 32 is analog.
data[1] = the pin number - this is a pseudo pin number
data[2] = x value
data[3] = y value
data[4] = z value
"""
x = data[2]
y = data[3]
z = data[4]
# Convert raw Accelerometer values to degrees
x_angle = int((math.atan2(y, z) + math.pi) * (180 / math.pi))
y_angle = int((math.atan2(z, x) + math.pi) * (180 / math.pi))
h = v = -1
if 175 < x_angle < 185 and 265 < y_angle < 275:
h = v = 0 # 'flat'
elif h or v:
if 180 <= x_angle <= 270:
v = 1 # up
elif 90 <= x_angle <= 180:
v = 2 # down
if 180 <= y_angle <= 270:
h = 3 # left
elif 270 <= y_angle <= 360:
h = 4 # right
payload = {'report': 'tilted', 'value': [v, h]}
self.publish_payload(payload, 'from_cpx_gateway')
def switch_callback(self, data):
"""
This handles switches a, b, and slide
:param data: data[1] - a=4 b=5, slice=7,
"""
if data[1] == 4:
switch = 'a'
elif data[1] == 5:
switch = 'b'
else:
# 0 = right, 1 = left
switch = 'slide'
payload = {'report': switch, 'value': data[2]}
self.publish_payload(payload, 'from_cpx_gateway')
def analog_callback(self, data):
"""
This handles the light, temperature and sound sensors.
It also sets up a "watchdog timer" and if there is no activity
for > 1 second will exit.
:param data: data[1] - 8 = light, temp = 9, 10 = sound,
"""
self.last_analog_data_time = time.time()
if data[1] == 8:
sensor = 'light'
elif data[1] == 9:
sensor = 'temp'
else:
sensor = 'sound'
payload = {'report': sensor, 'value': round(data[2], 2)}
self.publish_payload(payload, 'from_cpx_gateway')
def touchpad_callback(self, data):
"""
Build and send a banyan message for the pad and value
:param data: data[1] = touchpad and data[2] = boolean value
"""
payload = {'report': 'touch' + str(data[1]), 'value': int(data[2])}
self.publish_payload(payload, 'from_cpx_gateway')
def shutdown(self):
try:
self.cpx.cpx_close_and_exit()
sys.exit(0)
except serial.serialutil.SerialException:
pass
def my_handler(self, xtype, value, tb):
"""
for logging uncaught exceptions
:param xtype:
:param value:
:param tb:
:return:
"""
self.logger.exception("Uncaught exception: {0}".format(str(value)))
def run(self):
if not self.last_analog_data_time:
self.last_analog_data_time = time.time()
while True:
if time.time() - self.last_analog_data_time > 1.0:
print('Watchdog timed out - exiting.')
os._exit(1)
time.sleep(1)
print('Switch on right side')
# turn pixel 6 blue and pixel 3 off
p.cpx_pixel_set(6, 0, 0, 255)
p.cpx_pixel_set(3, 0, 0, 0)
p.cpx_pixels_show()
else:
print('Unknown switch id: ', the_switch)
# flash the board LED
p.cpx_board_light_on()
time.sleep(.2)
p.cpx_board_light_off()
# create a cpx instance
p = PyMataCpx()
# enable all switches and attach all to the same callback
p.cpx_button_a_start(buttons_callback)
p.cpx_button_b_start(buttons_callback)
p.cpx_slide_switch_start(buttons_callback)
# Set pixel 6 initially on and 3 off.
# If the switch is set to the left at start up
# it will be detected and pixel 3 will be turned
# on and pixel 6 turned off.
p.cpx_pixel_set(6, 0, 0, 255)
p.cpx_pixel_set(3, 0, 0, 0)
p.cpx_pixels_show()
print()
class TheClapper:
"""
Turn LEDs in a counter-clockwise fashion with randomly generated colors.
When you clap your hand loudly, the pixels will stop changing and the
program exits. Clap again and they start moving again.
"""
def __init__(self):
self.p = PyMataCpx()
print('Clap your hands loudly to stop the neopixels from moving.')
print('Clap again, to start them up')
self.p.cpx_microphone_start(self.listen)
self.go = True
while True:
try:
# run the light show
for neopixel in range(0, 10):
if self.go:
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
r = random.randint(0, 254)
g = random.randint(0, 254)
b = random.randint(0, 254)
self.p.cpx_pixel_set(neopixel, r, g, b)
self.p.cpx_pixels_show()
time.sleep(.2)
else:
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
time.sleep(.001)
except KeyboardInterrupt:
# If you press control-C, cleanly exit
self.p.cpx_pixels_clear()
self.p.cpx_pixels_show()
self.p.cpx_close_and_exit()
def listen(self, data):
"""
Turn off the light show and exit
:param data: data[0] = 2 indicating this is analog data
data[1] = pin attached to mic- pin 4
data[3] = readings from microphone
"""
if data[2] > 600:
# self.p.cpx_pixels_clear()
# self.p.cpx_pixels_show()
self.go = not self.go