Preferring Python? I just released jled-circuitpython, a JLed implementation for CircuitPython and MicroPython. |
An embedded C++ library to control LEDs. It uses a non-blocking approach and can control LEDs in simple (on/off) and complex (blinking, breathing and more) ways in a time-driven manner.
JLed got some coverage on Hackaday and someone did a video tutorial for JLed - Thanks!
JLed in action | Interactive JLed playground |
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// breathe LED (on gpio 9) 6 times for 1500ms, waiting for 500ms after each run
#include <jled.h>
auto led_breathe = JLed(9).Breathe(1500).Repeat(6).DelayAfter(500);
void setup() { }
void loop() {
led_breathe.Update();
}
- Features
- Cheat Sheet
- Installation
- Usage * Output pipeline
- Framework notes
- Platform notes
- Example sketches
- Extending
- Unit tests
- Contributing
- FAQ
- Author and Copyright
- License
- non-blocking
- effects: simple on/off, breathe, blink, candle, fade-on, fade-off, user-defined (e.g. morse)
- supports inverted polarity of LED
- easy configuration using fluent interface
- can control groups of LEDs sequentially or in parallel
- Portable: Arduino, ESP8266, ESP32, Mbed, Raspberry Pi Pico and more platforms compatible, runs even in the browser
- supports Arduino, mbed, Raspberry Pi Pico and ESP32 ESP-IDF SDK's
- well tested
In the main menu of the Arduino IDE, select Sketch
> Include Library
>
Manage Libraries...
and search for jled
, then press install
.
Add jled
to your library dependencies in your platformio.ini
project file,
e.g.
...
[env:nanoatmega328]
platform = atmelavr
board = nanoatmega328
framework = arduino
lib_deps=jled
...
First, the LED object is constructed and configured, then the state is updated
with subsequent calls to the Update()
method, typically from the loop()
function. While the effect is active, Update
returns true
, otherwise
false
.
The constructor takes the pin, to which the LED is connected to as
the only argument. Further configuration of the LED object is done using a fluent
interface, e.g. JLed led = JLed(13).Breathe(2000).DelayAfter(1000).Repeat(5)
.
See the examples section below for further details.
First the configured effect (e.g. Fade
) is evaluated for the current time
t
. JLed internally uses unsigned bytes to represent brightness values,
ranging from 0 to 255. Next, the value is scaled to the limits set by
MinBrightness
and MaxBrightness
(optionally). When the effect is configured
for a low-active LED using LowActive
, the brightness value will be inverted,
i.e., the value will be subtracted from 255. Finally the value is passed to the
hardware abstraction, which might scale it to the resolution used by the actual
device (e.g. 10 bits for an ESP8266). Finally the brightness value is written
out to the configure GPIO.
┌───────────┐ ┌────────────┐ ┌─────────┐ ┌────────┐ ┌─────────┐ ┌────────┐
│ Evaluate │ │ Scale to │ │ Low │YES │ Invert │ │Scale for│ │Write to│
│ effect(t) ├───►│ [min, max] ├───►│ active? ├───►│ signal ├───►│Hardware ├───►│ GPIO │
└───────────┘ └────────────┘ └────┬────┘ └────────┘ └───▲─────┘ └────────┘
│ NO │
└───────────────────────────┘
Calling On(uint16_t period=1)
turns the LED on. To immediately turn a LED on,
make a call like JLed(LED_BUILTIN).On().Update()
. The period
is optional
and defaults to 1ms.
Off()
works like On()
, except that it turns the LED off, i.e., it sets the
brightness to 0.
Use the Set(uint8_t brightness, uint16_t period=1)
method to set the
brightness to the given value, i.e., Set(255)
is equivalent to calling On()
and Set(0)
is equivalent to calling Off()
.
Technically, Set
, On
and Off
are effects with a default period of 1ms, that
set the brightness to a constant value. Specifying a different period has an
effect on when the Update()
method will be done updating the effect and
return false (like for any other effects). This is important when for example
in a JLedSequence
the LED should stay on for a given amount of time.
#include <jled.h>
// turn builtin LED on after 1 second.
auto led = JLed(LED_BUILTIN).On().DelayBefore(1000);
void setup() { }
void loop() {
led.Update();
}
In blinking mode, the LED cycles through a given number of on-off cycles, on-
and off-cycle durations are specified independently. The Blink()
method takes
the duration for the on- and off cycle as arguments.
#include <jled.h>
// blink internal LED every second; 1 second on, 0.5 second off.
auto led = JLed(LED_BUILTIN).Blink(1000, 500).Forever();
void setup() { }
void loop() {
led.Update();
}
In breathing mode, the LED smoothly changes the brightness using PWM. The
Breathe()
method takes the period of the effect as an argument.
#include <jled.h>
// connect LED to pin 13 (PWM capable). LED will breathe with period of
// 2000ms and a delay of 1000ms after each period.
auto led = JLed(13).Breathe(2000).DelayAfter(1000).Forever();
void setup() { }
void loop() {
led.Update();
}
It is also possible to specify fade-on, on- and fade-off durations for the breathing mode to customize the effect.
// LED will fade-on in 500ms, stay on for 1000ms, and fade-off in 500ms.
// It will delay for 1000ms afterwards and continue the pattern.
auto led = JLed(13).Breathe(500, 1000, 500).DelayAfter(1000).Forever();
In candle mode, the random flickering of a candle or fire is simulated.
The builder method has the following signature:
Candle(uint8_t speed, uint8_t jitter, uin16_t period)
speed
- controls the speed of the effect. 0 for fastest, increasing speed divides into halve per increment. The default value is 7.jitter
- the amount of jittering. 0 none (constant on), 255 maximum. Default value is 15.period
- Period of effect in ms. The default value is 65535 ms.
The default settings simulate a candle. For a fire effect for example use
call the method with Candle(5 /*speed*/, 100 /* jitter*/)
.
#include <jled.h>
// Candle on LED pin 13 (PWM capable).
auto led = JLed(13).Candle();
void setup() { }
void loop() {
led.Update();
}
In FadeOn mode, the LED is smoothly faded on to 100% brightness using PWM. The
FadeOn()
method takes the period of the effect as an argument.
The brightness function uses an approximation of this function (example with period 1000):
#include <jled.h>
// LED is connected to pin 9 (PWM capable) gpio
auto led = JLed(9).FadeOn(1000).DelayBefore(2000);
void setup() { }
void loop() {
led.Update();
}
In FadeOff mode, the LED is smoothly faded off using PWM. The fade starts at
100% brightness. Internally it is implemented as a mirrored version of the
FadeOn function, i.e., FadeOff(t) = FadeOn(period-t). The FadeOff()
method
takes the period of the effect as argument.
The Fade effect allows to fade from any start value from
to any target value
to
with the given duration. Internally it sets up a FadeOn
or FadeOff
effect and MinBrightness
and MaxBrightness
values properly. The Fade
method take three arguments: from
, to
and duration
.
#include <jled.h>
// fade from 100 to 200 with period 1000
auto led = JLed(9).Fade(100, 200, 1000);
void setup() { }
void loop() {
led.Update();
}
It is also possible to provide a user defined brightness evaluator. The class
must be derived from the jled::BrightnessEvaluator
class and implement
two methods:
uint8_t Eval(uint32_t t) const
- the brightness evaluation function that calculates a brightness for the given timet
. The brightness must be returned as an unsigned byte, where 0 means LED off and 255 means full brightness.uint16_t Period() const
- period of the effect.
All time values are specified in milliseconds.
The user_func example demonstrates a simple user provided brightness function, while the morse example shows how a more complex application, allowing you to send morse codes (not necessarily with an LED), can be realized.
The example uses a user provided function to calculate the brightness.
class UserEffect : public jled::BrightnessEvaluator {
public:
uint8_t Eval(uint32_t t) const override {
// this function changes between 0 and 255 and
// vice versa every 250 ms.
return 255*((t/250)%2);
}
// duration of effect: 5 seconds.
uint16_t Period() const override { return 5000; }
};
Use the DelayBefore()
method to specify a delay before the first effect starts.
The default value is 0 ms.
Use the DelayAfter()
method to specify a delay after each repetition of
an effect. The default value is 0 ms.
Use the Repeat()
method to specify the number of repetitions. The default
value is 1 repetition. The Forever()
methods sets to repeat the effect
forever. Each repetition includes a full period of the effect and the time
specified by DelayAfter()
method.
Call Update(int16_t *pLast=nullptr)
or Update(uint32_t t, int16_t *pLast=nullptr)
to periodically update the state of the LED.
Update
returns true
, if the effect is active, or false
when it finished.
Update()
is a shortcut to call Update(uint32_t t)
with the current time in
milliseconds.
To obtain the value of the last written brightness value (after applying min-
and max-brightness transformations), pass an additional optional pointer
*pLast
, where this value will be stored, when it was written. Example:
int16_t lastVal = -1;
led.Update(&lastVal);
if (lastVal != -1) {
// the LED was updated with the brightness value now stored in lastVal
...
}
Most of the time just calling Update()
without any parameters is what you want.
See last_brightness example for a working example.
IsRunning()
returns true
if the current effect is running, else false
.
A call to Reset()
brings the JLed object to its initial state. Use it when
you want to start-over an effect.
Call Stop()
to immediately turn the LED off and stop any running effects.
Further calls to Update()
will have no effect, unless the Led is reset using
Reset()
or a new effect is activated. By default, Stop()
sets the current
brightness level to MinBrightness
.
Stop()
takes an optional argument mode
of type JLed::eStopMode
:
- if set to
JLed::eStopMode::KEEP_CURRENT
, the LEDs current level will be kept - if set to
JLed::eStopMode::FULL_OFF
the level of the LED is set to0
, regardless of whatMinBrightness
is set to, effectively turning the LED off - if set to
JLed::eStopMode::TO_MIN_BRIGHTNESS
(default behavior), the LED will set to the value ofMinBrightness
// stop the effect and set the brightness level to 0, regardless of min brightness
led.Stop(JLed::eStopMode::FULL_OFF);
Use the LowActive()
method when the connected LED is low active. All output
will be inverted by JLed (i.e., instead of x, the value of 255-x will be set).
The MaxBrightness(uint8_t level)
method is used to set the maximum brightness
level of the LED. A level of 255 (the default) is full brightness, while 0
effectively turns the LED off. In the same way, the MinBrightness(uint8_t level)
method sets the minimum brightness level. The default minimum level is 0. If
minimum or maximum brightness levels are set, the output value is scaled to be
within the interval defined by [minimum brightness, maximum brightness]
: a
value of 0 will be mapped to the minimum brightness level, a value of 255 will
be mapped to the maximum brightness level.
The uint_8 MaxBrightness() const
method returns the current maximum
brightness level. uint8_t MinBrightness() const
returns the current minimum
brightness level.
The JLedSequence
class allows controlling a group of JLed
objects
simultaneously, either in parallel or sequentially, starting the next JLed
effect when the previous finished. The constructor takes the mode (PARALLEL
,
SEQUENCE
), an array of JLed
objects and the size of the array, e.g.
JLed leds[] = {
JLed(4).Blink(750, 250).Repeat(10),
JLed(3).Breathe(2000).Repeat(5);
};
auto sequence = JLedSequence(JLedSequence::eMode::PARALLEL, leds).Repeat(2);
void setup() {
}
void loop() {
sequence.Update();
}
Because the size of the array is known at compile time in this example, it is
not necessary to pass the array size to the constructor. A second constructor
is available in case the JLed
array is created dynamically at runtime:
JLed(eMode mode, JLed* leds, size_t n)
.
The JLedSequence
provides the following methods:
Update()
- updates the activeJLed
objects controlled by the sequence. Like theJLed::Update()
method, it returnstrue
if an effect is running, elsefalse
.- Use the
Repeat(n)
method to specify the number of repetitions. The default value is 1 repetition. TheForever()
methods sets to repeat the sequence forever. Stop()
- turns off allJLed
objects controlled by the sequence and stops the sequence. Further calls toUpdate()
will have no effect.Reset()
- Resets allJLed
objects controlled by the sequence and the sequence, resulting in a start-over.
JLed supports the Arduino and mbed frameworks. When
using platformio, the framework to be used is configured in the platform.ini
file, as shown in the following example, which for example selects the mbed
framework:
[env:nucleo_f401re_mbed]
platform=ststm32
board = nucleo_f401re
framework = mbed
build_flags = -Isrc
src_filter = +<../../src/> +<./>
upload_protocol=stlink
An mbed example is provided here. To compile it for the F401RE, make your plaform.ini look like:
...
[platformio]
default_envs = nucleo_f401re_mbed
src_dir = examples/multiled_mbed
...
The DAC of the ESP8266 operates with 10 bits, every value JLed writes out gets automatically scaled to 10 bits, since JLed internally only uses 8 bits. The scaling methods make sure that min/max relationships are preserved, i.e., 0 is mapped to 0 and 255 is mapped to 1023. When using a user-defined brightness function on the ESP8266, 8-bit values must be returned, all scaling is done by JLed transparently for the application, yielding platform-independent code.
When compiling for the ESP32, JLed uses ledc
functions provided by the ESP32
ESP-IDF SDK. (See esspressif
documentation
for details).
The ledc
API connects so-called channels to GPIO pins, enabling them to use
PWM. There are 16 channels available. Unless otherwise specified, JLed
automatically picks the next free channel, starting with channel 0 and wrapping
over after channel 15. To manually specify a channel, the JLed object must be
constructed this way:
auto esp32Led = JLed(jled::Esp32Hal(2, 7)).Blink(1000, 1000).Forever();
The jled::Esp32Hal(pin, chan)
constructor takes the pin number as the first
argument and the ESP32 ledc channel number on the second position. Note that
using the above-mentioned constructor results in non-platform independent code,
so it should be avoided and is normally not necessary.
For completeness, the full signature of the Esp32Hal constructor is
Esp32Hal(PinType pin,
int chan = kAutoSelectChan,
uint16_t freq = 5000,
ledc_timer_t timer = LEDC_TIMER_0)
which also allows to override the default frequency and timer used, when needed.
Since JLed uses the ESP-IDF SDK, JLed can also be directly used in ESP-IDF projects, without the need of using the Arduino Framework (which is also possible). See these repositories for example projects:
- https://github.com/jandelgado/jled-esp-idf-example
- https://github.com/jandelgado/jled-esp-idf-platformio-example
I had success running JLed on a STM32 Nucleo64 F401RE
board using this
STM32 Arduino
core
and compiling examples from the Arduino IDE. Note that the stlink
is
necessary to upload sketches to the microcontroller.
When using JLed on a Raspberry Pi Pico, the Pico-SDK and tools can be used. The Pico supports up to 16 PWM channels in parallel. See the pico-demo for an example and build instructions when the Pico-SDK is used.
A probably easier approach is to use the Arduino platform. See
platformio.ini for details (look for
env:raspberrypi_pico_w
, which targets the Raspberry Pi Pico W.
Example sketches are provided in the examples directory.
- Hello, world
- Turn LED on after a delay
- Breathe effect
- Candle effect
- Fade LED on
- Fade LED off
- Fade from-to effect
- Pulse effect
- Controlling multiple LEDs in parallel
- Controlling multiple LEDs in parallel (mbed)
- Controlling multiple LEDs sequentially
- Simple User provided effect
- Morsecode example
- Last brightness value example
- Custom HAL example
- Custom PCA9685 HAL
- Dynamically switch sequences
- JLed compiled to WASM and running in the browser
- Raspberry Pi Pico Demo
- ESP32 ESP-IDF example
- ESP32 ESP-IDF PlatformIO example
To build an example using the PlatformIO ide, uncomment the example to be built in the platformio.ini project file, e.g.:
[platformio]
; uncomment example to build
src_dir = examples/hello
;src_dir = examples/breathe
To build an example sketch in the Arduino IDE, select an example from
the File
> Examples
> JLed
menu.
JLed uses a very thin hardware abstraction layer (hal) to abstract access to the actual MCU/framework used (e.g. ESP32, ESP8266). The hal object encapsulate access to the GPIO and time functionality of the MCU under the framework being used. During the unit test, mocked hal instances are used, enabling tests to check the generated output. The Custom HAL project provides an example for a user define HAL.
JLed comes with an exhaustive host-based unit test suite. Info on how to run the host-based provided unit tests is provided here.
- fork this repository
- create your feature branch
- add code
- add unit test(s)
- add documentation
- make sure the cpp linter does not
report any problems (run
make lint
). Hint: useclang-format
with the provided settings - commit changes
- submit a PR
- Check the return value of the
JLed::Update
method: the method returnstrue
if the effect is still running, otherwisefalse
. - The
JLed::IsRunning
method returnstrue
if an effect is running, elsefalse
.
Call Reset()
on a JLed
object to start over.
Just 'reconfigure' the JLed
with any of the effect methods (e.g. FadeOn
,
Breathe
, Blink
etc). Time-wise, the effect will start over.
Copyright 2017-2022 by Jan Delgado, jdelgado[at]gmx.net.