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python-gpiozero/gpiozero/tools.py
Dave Jones c2a9392ea5 Make tests work reliably on the Pi 
While the tests work well on a PC or Travis, the Pi (where I ought to be
running them!) has some issues with the timing tests. Need to relax the
tolerance of the "assert_states_and_times" method to 0.05 seconds
otherwise it periodically fails even on something reasonably quick like
a Pi 2 (less failures on a Pi 3 but still occasionally).

Also reduced default fps to 25; if the default timing occasionally fails
on a Pi 2 it's evidently too fast for a Pi 1 and shouldn't be the
default; 25 also doesn't look any different to me on a pulsing LED.

There's also a bunch of miscellaneous fixes in here; last minute typos
and chart re-gens for the 1.2 release.
2016-04-08 23:11:14 +01:00

297 lines
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# vim: set fileencoding=utf-8:
from __future__ import (
unicode_literals,
print_function,
absolute_import,
division,
)
str = type('')
from random import random
from time import sleep
try:
from itertools import izip as zip
except ImportError:
pass
from itertools import cycle
from math import sin, cos, radians
try:
from statistics import mean
except ImportError:
from .compat import mean
def negated(values):
"""
Returns the negation of the supplied values (``True`` becomes ``False``,
and ``False`` becomes ``True``). For example::
from gpiozero import Button, LED, negated
from signal import pause
led = LED(4)
btn = Button(17)
led.source = negated(btn.values)
pause()
"""
for v in values:
yield not v
def inverted(values):
"""
Returns the inversion of the supplied values (1 becomes 0, 0 becomes 1,
0.1 becomes 0.9, etc.). For example::
from gpiozero import MCP3008, PWMLED, inverted
from signal import pause
led = PWMLED(4)
pot = MCP3008(channel=0)
led.source = inverted(pot.values)
pause()
"""
for v in values:
yield 1 - v
def scaled(values, range_min, range_max, domain_min=0, domain_max=1):
"""
Returns *values* scaled from *range_min* to *range_max*, assuming that all
items in *values* lie between *domain_min* and *domain_max* (which default
to 0 and 1 respectively). For example, to control the direction of a motor
(which is represented as a value between -1 and 1) using a potentiometer
(which typically provides values between 0 and 1)::
from gpiozero import Motor, MCP3008, scaled
from signal import pause
motor = Motor(20, 21)
pot = MCP3008(channel=0)
motor.source = scaled(pot.values, -1, 1)
pause()
"""
domain_size = domain_max - domain_min
range_size = range_max - range_min
for v in values:
yield (((v - domain_min) / domain_size) * range_size) + range_min
def clamped(values, range_min=0, range_max=1):
"""
Returns *values* clamped from *range_min* to *range_max*, i.e. any items
less than *range_min* will be returned as *range_min* and any items
larger than *range_max* will be returned as *range_max* (these default to
0 and 1 respectively). For example::
from gpiozero import PWMLED, MCP3008, clamped
from signal import pause
led = PWMLED(4)
pot = MCP3008(channel=0)
led.source = clamped(pot.values, 0.5, 1.0)
pause()
"""
for v in values:
yield min(max(v, range_min), range_max)
def quantized(values, steps, range_min=0, range_max=1):
"""
Returns *values* quantized to *steps* increments. All items in *values* are
assumed to be between *range_min* and *range_max* (use :func:`scaled` to
ensure this if necessary).
For example, to quantize values between 0 and 1 to 5 "steps" (0.0, 0.25,
0.5, 0.75, 1.0)::
from gpiozero import PWMLED, MCP3008, quantized
from signal import pause
led = PWMLED(4)
pot = MCP3008(channel=0)
led.source = quantized(pot.values, 4)
pause()
"""
range_size = range_max - range_min
for v in scaled(values, 0, 1, range_min, range_max):
yield ((int(v * steps) / steps) * range_size) + range_min
def conjunction(*values):
"""
Returns the `logical conjunction`_ of all supplied values (the result is
only ``True`` if and only if all input values are simultaneously ``True``).
One or more *values* can be specified. For example, to light an
:class:`LED` only when *both* buttons are pressed::
from gpiozero import LED, Button, conjunction
from signal import pause
led = LED(4)
btn1 = Button(20)
btn2 = Button(21)
led.source = conjunction(btn1.values, btn2.values)
pause()
.. _logical conjunction: https://en.wikipedia.org/wiki/Logical_conjunction
"""
for v in zip(*values):
yield all(v)
def disjunction(*values):
"""
Returns the `logical disjunction`_ of all supplied values (the result is
``True`` if any of the input values are currently ``True``). One or more
*values* can be specified. For example, to light an :class:`LED` when
*any* button is pressed::
from gpiozero import LED, Button, conjunction
from signal import pause
led = LED(4)
btn1 = Button(20)
btn2 = Button(21)
led.source = disjunction(btn1.values, btn2.values)
pause()
.. _logical disjunction: https://en.wikipedia.org/wiki/Logical_disjunction
"""
for v in zip(*values):
yield any(v)
def averaged(*values):
"""
Returns the mean of all supplied values. One or more *values* can be
specified. For example, to light a :class:`PWMLED` as the average of
several potentiometers connected to an :class:`MCP3008` ADC::
from gpiozero import MCP3008, PWMLED, averaged
from signal import pause
pot1 = MCP3008(channel=0)
pot2 = MCP3008(channel=1)
pot3 = MCP3008(channel=2)
led = PWMLED(4)
led.source = averaged(pot1.values, pot2.values, pot3.values)
pause()
"""
for v in zip(*values):
yield mean(v)
def queued(values, qsize):
"""
Queues up readings from *values* (the number of readings queued is
determined by *qsize*) and begins yielding values only when the queue is
full. For example, to "cascade" values along a sequence of LEDs::
from gpiozero import LEDBoard, Button, queued
from signal import pause
leds = LEDBoard(5, 6, 13, 19, 26)
btn = Button(17)
for i in range(4):
leds[i].source = queued(leds[i + 1].values, 5)
leds[i].source_delay = 0.01
leds[4].source = btn.values
pause()
"""
q = []
it = iter(values)
for i in range(qsize):
q.append(next(it))
for i in cycle(range(qsize)):
yield q[i]
try:
q[i] = next(it)
except StopIteration:
break
def pre_delayed(values, delay):
"""
Waits for *delay* seconds before returning each item from *values*.
"""
for v in values:
sleep(delay)
yield v
def post_delayed(values, delay):
"""
Waits for *delay* seconds after returning each item from *values*.
"""
for v in values:
yield v
sleep(delay)
def random_values():
"""
Provides an infinite source of random values between 0 and 1. For example,
to produce a "flickering candle" effect with an LED::
from gpiozero import PWMLED, random_values
from signal import pause
led = PWMLED(4)
led.source = random_values()
pause()
If you require a wider range than 0 to 1, see :func:`scaled`.
"""
while True:
yield random()
def sin_values():
"""
Provides an infinite source of values representing a sine wave (from -1 to
+1), calculated as the result of applying sign to a simple degrees counter
that increments by one for each requested value. For example, to produce a
"siren" effect with a couple of LEDs::
from gpiozero import PWMLED, sin_values, scaled, inverted
from signal import pause
red = PWMLED(2)
blue = PWMLED(3)
red.source_delay = 0.1
blue.source_delay = 0.1
red.source = scaled(sin_values(), 0, 1, -1, 1)
blue.source = inverted(red.values)
pause()
If you require a wider range than 0 to 1, see :func:`scaled`.
"""
for d in cycle(range(360)):
yield sin(radians(d))
def cos_values():
"""
Provides an infinite source of values representing a cosine wave (from -1
to +1), calculated as the result of applying sign to a simple degrees
counter that increments by one for each requested value. For example, to
produce a "siren" effect with a couple of LEDs::
from gpiozero import PWMLED, cos_values, scaled, inverted
from signal import pause
red = PWMLED(2)
blue = PWMLED(3)
red.source = scaled(cos_values(), 0, 1, -1, 1)
blue.source = inverted(red.values)
pause()
If you require a wider range than 0 to 1, see :func:`scaled`.
"""
for d in cycle(range(360)):
yield cos(radians(d))
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