An adjustable, compact, event-driven button library for Arduino platforms.
This library provides classes which accept inputs from a mechanical button connected to a digital input pin on the Arduino. The library should be able to handle momentary buttons, maintained buttons, and switches, but it was designed primarily for momentary buttons.
The library is named "AceButton" because:
- many configurations of the button are adjustable, either at compile-time or run-time
- the library is optimized to create compact objects which take up a minimal amount of static memory
- the library detects changes in the button state and sends events to
a user-defined
EventHandler
callback function
Most of the features of the library can be accessed through 2 classes, 1 callback function, and 1 interface:
AceButton
(class)ButtonConfig
(class)EventHandler
(typedef)IEventHandler
(interface)
The AceButton
class contains the logic for debouncing and determining if a
particular event has occurred.
The ButtonConfig
class holds various timing parameters, the event handler,
code for reading the button, and code for getting the internal clock.
The EventHandler
is a user-defined callback function with a specific signature
which is registered with the ButtonConfig
object. When the library detects
interesting events, the callback function is called by the library, allowing the
client code to handle the event.
The IEventHandler
is an interface (pure abstract class) that provides an
alternative to the EventHandler
. Instead of using a callback function, an
object of type IEventHandler
can be used to handle the button events.
The supported events are:
AceButton::kEventPressed
AceButton::kEventReleased
AceButton::kEventClicked
AceButton::kEventDoubleClicked
AceButton::kEventLongPressed
AceButton::kEventRepeatPressed
AceButton::kEventLongReleased
(v1.8)
The basic ButtonConfig
class assumes that each button is connected to a single
digital input pin. In some situations, the number of buttons that we want is
greater than the number of input pins available. This library provides
2 subclasses of ButtonConfig
which may be useful:
EncodedButtonConfig
- Supports binary encoded buttons, to read
2^N - 1
buttons usingN
pins (e.g. 7 buttons using 3 digital pins).
- Supports binary encoded buttons, to read
LadderButtonConfig
- Supports 1-8 buttons (maybe more) on a single analog pin through a
resistor ladder. The
analogRead()
method is used to read the different voltage levels corresponding to each button.
- Supports 1-8 buttons (maybe more) on a single analog pin through a
resistor ladder. The
Both EncodedButtonConfig
and LadderButtonConfig
support all 7 events listed
above (e.g. kEventClicked
and kEventDoubleClicked
).
Version: 1.9.1 (2021-08-10)
Changelog: CHANGELOG.md
- Features
- HelloButton
- Installation
- Documentation
- Usage
- Advanced Topics
- Resource Consumption
- System Requirements
- Background Motivation
- License
- Feedback and Support
- Author
Here are the high-level features of the AceButton library:
- debounces the mechanical contact
- supports both pull-up and pull-down wiring
- event-driven through a user-defined
EventHandler
callback function - event-driven through an object-based
IEventHandler
(>= v1.6) - supports 7 event types:
kEventPressed
kEventReleased
kEventClicked
kEventDoubleClicked
kEventLongPressed
kEventRepeatPressed
kEventLongReleased
- adjustable configurations at runtime or compile-time
- timing parameters
digitalRead()
button read function can be overriddenmillis()
clock function can be overridden
- small memory footprint
- each
AceButton
consumes 14 bytes (8-bit) or 16 bytes (32-bit) - each
ButtonConfig
consumes 18 bytes (8-bit) or 24 bytes (32-bit) - one System
ButtonConfig
instance created automatically by the library - 970-2180 bytes of flash memory for the simple case of 1 AceButton and 1 ButtonConfig, depending on 8-bit or 32-bit processors
- each
- supports multiple buttons on shared pins using various circuits
- Binary Encoded buttons (e.g. 7 buttons using 3 pins)
- Resistor Ladder buttons (e.g. 5 buttons on a single analog pin)
- only 13-15 microseconds (on 16MHz ATmega328P) per polling call to
AceButton::check()
- extensive testing
- thoroughly unit tested using AUnit
- tested on Arduino AVR (UNO, Nano, Micro etc), Teensy ARM (LC and 3.2), SAMD21 (Arduino Zero compatible), ESP8266 and ESP32
Compared to other Arduino button libraries, I think the unique or exceptional features of the AceButton library are:
- many supported event types (e.g. LongPressed and RepeatPressed)
- able to distinguish between Clicked and DoubleClicked
- small memory usage
- thorough unit testing
- support for multiple buttons using Binary Encoding or a Resistor Ladder
Here is a simple program (see examples/HelloButton) which controls the builtin LED on the Arduino board using a momentary button connected to PIN 2.
#include <AceButton.h>
using namespace ace_button;
const int BUTTON_PIN = 2;
const int LED_ON = HIGH;
const int LED_OFF = LOW;
AceButton button(BUTTON_PIN);
void handleEvent(AceButton*, uint8_t, uint8_t);
void setup() {
pinMode(LED_BUILTIN, OUTPUT);
pinMode(BUTTON_PIN, INPUT_PULLUP);
button.setEventHandler(handleEvent);
}
void loop() {
button.check();
}
void handleEvent(AceButton* /*button*/, uint8_t eventType,
uint8_t /*buttonState*/) {
switch (eventType) {
case AceButton::kEventPressed:
digitalWrite(LED_BUILTIN, LED_ON);
break;
case AceButton::kEventReleased:
digitalWrite(LED_BUILTIN, LED_OFF);
break;
}
}
(The button
and buttonState
parameters are commented out to avoid an unused parameter
warning from the compiler. We can't remove the parameters completely
because the method signature is defined by the EventHandler
typedef.)
The latest stable release is available in the Arduino IDE Library Manager. Search for "AceButton". Click install.
The development version can be installed by cloning the
GitHub repository (https://github.com/bxparks/AceButton), checking out the
develop
branch, then manually copying over the contents to the ./libraries
directory used by the Arduino IDE. (The result is a directory named
./libraries/AceButton
.)
The master
branch contains the tagged stable releases.
The core of the library is self-contained and has no external dependencies.
The some programs in examples/
may depend on:
- AceCommon (https://github.com/bxparks/AceCommon)
The unit tests under tests
depend on:
The source files are organized as follows:
src/AceButton.h
- main header filesrc/ace_button/
- all implementation filessrc/ace_button/testing/
- internal testing filestests/
- unit tests which require AUnitexamples/
- example sketches
- this README.md
- docs/binary_encoding/README.md
- Explanation of reading buttons through binary encoding using the
Encoded4To2ButtonConfig
,Encoded8To3ButtonConfig
,EncodedButtonConfig
classes
- Explanation of reading buttons through binary encoding using the
- docs/resistor_ladder/README.md
- Explanation of reading buttons through a resistor ladder using the
LadderButtonConfig
class
- Explanation of reading buttons through a resistor ladder using the
- Doxygen docs published on GitHub Pages which can help navigate an unfamiliar code base.
The following example sketches are provided:
- Basic Single Button
- HelloButton
- minimal program that reads a switch and control the built-in LED
- SingleButton
- single button wired with an internal pull-up resistor
- SingleButtonPullDown
- same as
SingleButton
but with an external pull-down resistor
- same as
- SingleButtonUsingIEventHandler
- same as
SingleButton
using an object-basedIEventHandler
- same as
- Stopwatch
- measures the speed of
AceButton:check()
with a start/stop/reset - button uses
kFeatureLongPress
- measures the speed of
- HelloButton
- Multiple Buttons
- TwoButtonsUsingOneButtonConfig
- two buttons using one ButtonConfig
- TwoButtonsUsingTwoButtonConfigs
- two buttons using two ButtonConfigs
- ThreeButtonsUsingOneButtonConfig
- three buttons using one ButtonConfig
- used as a reference for
ThreeButtonsUsingOneButtonConfigFast
(below)
- TunerButtons
- implements 5 radio buttons (tune-up, tune-down, and 3 presets)
- shows multiple
ButtonConfig
andEventHandler
instances - shows an example of how to use
getId()
- uses
kFeatureLongPress
,kFeatureRepeatPress
,kFeatureSuppressAfterLongPress
, andkFeatureSuppressAfterRepeatPress
- ArrayButtons
- shows how to define an array of
AceButton
and initialize them using theinit()
method in a loop
- shows how to define an array of
- SimultaneousButtons
- detecting simultaneous button presses of 2 buttons using a custom
IEventHandler
- detecting simultaneous button presses of 2 buttons using a custom
- TwoButtonsUsingOneButtonConfig
- Distinguishing Click versus Double-Click
- ClickVersusDoubleClickUsingReleased
- a way to distinguish between a
kEventClicked
from akEventDoubleClicked
using akEventReleased
instead
- a way to distinguish between a
- ClickVersusDoubleClickUsingSuppression
- another way to dstinguish between a
kEventClicked
from akEventDoubleClicked
using thekFeatureSuppressClickBeforeDoubleClick
flag at the cost of increasing the response time of thekEventClicked
event
- another way to dstinguish between a
- ClickVersusDoubleClickUsingBoth
- an example that combines both the "UsingPressed" and "UsingSuppression" techniques
- ClickVersusDoubleClickUsingReleased
- Distinguishing Pressed and LongPressed
- examples/PressedAndLongPressed
- see also the Distinguishing Pressed and LongPressed subsection below
- CapacitiveButton
- reads a capacitive button using the CapacitiveSensor library
- Binary Encoded Buttons
- Encoded4To2Buttons
- demo of
Encoded4To2ButtonConfig
class to decodeM=3
buttons withN=2
pins
- demo of
- Encoded8To3Buttons
- demo of
Encoded8To3ButtonConfig
class to decodeM=7
buttons withN=3
pins
- demo of
- Encoded16To4Buttons
- demo of general M-to-N
EncodedButtonConfig
class to handleM=15
buttons withN=4
pins
- demo of general M-to-N
- Encoded4To2Buttons
- Resistor Ladder Buttons
- LadderButtonCalibrator
- print out the value returned by
analogRead()
for various buttons - useful to compare the expected values of the resistor ladder versus the actual values returned by the function
- print out the value returned by
- LadderButtons
- demo of 4 buttons on a single analog pin using
analogRead()
- demo of 4 buttons on a single analog pin using
- LadderButtonsTiny
- 2 buttons on the
RESET/A0
pin of an ATtiny85 microcontroller - avoids wasting the RESET pin, saving the other pins for other purposes
- 2 buttons on the
- LadderButtonCalibrator
- digitalWriteFast
- SingleButtonFast
- Same as
SingleButton
but usingButtonConfigFast1<PIN>
which uses thedigitalWriteFast
library
- Same as
- TwoButtonsUsingOneButtonConfigFast
- Same as
TwoButtonsUsingOneButtonConfig
but usingButtonConfigFast2<PIN0,PIN1>
which uses thedigitalWriteFast
library
- Same as
- ThreeButtonsUsingOneButtonConfigFast
- Same as
ThreeButtonsUsingOneButtonConfig
but usingButtonConfigFast3<PIN0,PIN1,PIN2>
which uses thedigitalWriteFast
library
- Same as
- SingleButtonFast
- Benchmarks
- These are internal benchmark programs. They were not written as examples of how to use the library.
- AutoBenchmark
- generates the timing stats (min/average/max) for the
AceButton::check()
method for various types of events (idle, press/release, click, double-click, and long-press)
- generates the timing stats (min/average/max) for the
- MemoryBenchmark
- determines the amount of flash memory consumed by various objects and features of the library
There are 2 classes and one typedef that a user will normally interact with:
AceButton
(class)ButtonConfig
(class)EventHandler
(typedef)
Advanced usage is supported by:
EncodedButtonConfig
- binary encoded buttons supporting2^N-1
buttons onN
digital pinsLadderButtonConfig
- resistor ladder buttons using analog pinsIEventHandler
- use a callback object instead of a callback function
We explain how to use these below.
Only a single header file AceButton.h
is required to use this library.
To prevent name clashes with other libraries that the calling code may use, all
classes are defined in the ace_button
namespace. To use the code without
prepending the ace_button::
prefix, use the using
directive:
#include <AceButton.h>
using namespace ace_button;
If you are dependent on just AceButton
, the following might be sufficient:
#include <AceButton.h>
using ace_button::AceButton;
The ButtonConfig
class supports the simplest wiring. Each button is connected
to a single digital input pin, as shown below. In the example below, 3 buttons
labeled S0
, S1
and S2
are connected to digital input pins D2
, D3
, and
D4
:
An Arduino microcontroller pin can be in an OUTPUT
mode, an INPUT
mode, or
an INPUT_PULLUP
mode. This mode is controlled by the pinMode()
method.
By default upon boot, the pin is set to the INPUT
mode. However, this INPUT
mode puts the pin into a high impedance state, which means that if there is no
wire connected to the pin, the voltage on the pin is indeterminate. When the
input pin is read (using digitalRead()
), the boolean value will be a random
value. If you are using the pin in INPUT
mode, you must connect an external
pull-up resistor (connected to Vcc) or pull-down resistor (connected to ground)
so that the voltage level of the pin is defined when there is nothing connected
to the pin (i.e. when the button is not pressed).
The INPUT_PULLUP
mode is a special INPUT
mode which tells the
microcontroller to connect an internal pull-up resistor to the pin. It is
activated by calling pinMode(pin, INPUT_PULLUP)
on the given pin
. This mode
is very convenient because it eliminates the external resistor, making the
wiring simpler.
The 3 resistors Rc1
, Rc2
and Rc3
are optional current limiting resistors.
They help protect the microcontroller in the case of misconfiguration. If the
pins are accidentally set to OUTPUT
mode, then pressing one of the buttons
would connect the output pin directly to ground, causing a large amount of
current to flow that could permanently damage the microcontroller. The
resistance value of 220 ohms (or maybe 330 ohms) is high enough to keep the
current within safety limits, but low enough compared to the internal pullup
resistor that it is able to pull the digital pin to a logical 0 level. These
current limiting resistors are good safety measures, but I admit that I often
get lazy and don't use them when doing quick experiments.
The AceButton library itself does not call the pinMode()
function. The
calling application is responsible for calling pinMode()
. Normally, this
happens in the global setup()
method but the call can happen somewhere else if
the application requires it. The reason for decoupling the hardware
configuration from the AceButton library is mostly because the library does not
actually care about the specific hardware wiring of the button. It does not care
whether an external resistor is used, or the internal resistor is used. It only
cares about whether the resistor is a pull-up or a pull-down.
See https://www.arduino.cc/en/Tutorial/DigitalPins for additional information about the I/O pins on an Arduino.
The AceButton
class looks like this (not all public methods are shown):
namespace ace_button {
class AceButton {
public:
static const uint8_t kEventPressed = 0;
static const uint8_t kEventReleased = 1;
static const uint8_t kEventClicked = 2;
static const uint8_t kEventDoubleClicked = 3;
static const uint8_t kEventLongPressed = 4;
static const uint8_t kEventRepeatPressed = 5;
static const uint8_t kEventLongReleased = 6;
static const uint8_t kButtonStateUnknown = 127;
explicit AceButton(uint8_t pin = 0, uint8_t defaultReleasedState = HIGH,
uint8_t id = 0);
explicit AceButton(ButtonConfig* buttonConfig, uint8_t pin = 0,
uint8_t defaultReleasedState = HIGH, uint8_t id = 0);
void init(uint8_t pin = 0, uint8_t defaultReleasedState = HIGH,
uint8_t id = 0);
void init(ButtonConfig* buttonConfig, uint8_t pin = 0,
uint8_t defaultReleasedState = HIGH, uint8_t id = 0);
ButtonConfig* getButtonConfig();
void setButtonConfig(ButtonConfig* buttonConfig);
void setEventHandler(ButtonConfig::EventHandler eventHandler);
uint8_t getPin();
uint8_t getDefaultReleasedState();
uint8_t getId();
void check();
};
}
Each physical button will be handled by an instance of AceButton
. At a
minimum, the instance needs to be told the pin number of the button. This can
be done through the constructor:
const uint8_t BUTTON_PIN = 2;
AceButton button(BUTTON_PIN);
void setup() {
pinMode(BUTTON_PIN, INPUT_PULLUP);
...
}
Or we can use the init()
method in the setup()
:
AceButton button;
void setup() {
pinMode(BUTTON_PIN, INPUT_PULLUP);
button.init(BUTTON_PIN);
...
}
Both the constructor and the init()
function take 3 optional parameters as
shown above:
pin
: the I/O pin number assigned to the buttondefaultReleasedState
: the logical value of the button when it is in its default "released" state (HIGH
using a pull-up resistor,LOW
for a pull-down resistor)id
: an optional, user-defined identifier for the button, for example, an index into an array with additional information
The pin
must be defined either through the constructor or the init()
method.
But the other two parameters may be optional in many cases.
To read the state of the button, the AceButton::check()
method should be
called from the loop()
method periodically. Roughly speaking, this should be
about 4 times faster than the value of getDebounceDelay()
so that the various
event detection logic can work properly. For example, for the default debounce
delay is 20 ms, AceButton::check()
should be called every 5 ms. I have
successfully experimented with using a sampling delay as large as 10 ms, but I
recommend about 5 ms in most cases.
You could call the AceButton::check()
method directly in the global loop()
function like this:
void loop() {
...
button.check();
...
}
This would sample the button as fast as possible on your particular
microprocessor, perhaps as fast as 10,000 or 100,000 times a second, depending
on the other code that is in the loop()
function.
Most of the time, a high sampling rate is not a problem except for 2 things:
- Calling the
AceButton::check()
has a small overhead and your processor could be doing other things during that time. - If you use Resistor Ladder Buttons described below,
on an ESP8266, you will trigger a bug that causes the WiFi to disconnect if
you sample the
analogRead()
function more than a 1000 times/second.
If you want to limit the sampling rate, see the example code in Rate
Limit CheckButtons. The
code relies on using a static
variable to implement a non-blocking delay, like
this:
AceButton button;
...
void checkButtons() {
static uint16_t prev = millis();
// DO NOT USE delay(5) to do this.
// The (uint16_t) cast is required on 32-bit processors, harmless on 8-bit.
uint16_t now = millis();
if ((uint16_t) (now - prev) >= 5) {
button.check();
prev = now;
}
}
void loop() {
checkButtons();
...
}
If you attempt to use Pin 0 in the AceButton()
constructor:
AceButton button(0);
you may encounter a compile-time error such as this:
error: call of overloaded 'AceButton(int)' is ambiguous
The solution is to explicitly cast the 0
to a uint8_t
type, or to
assign it explicitly to a uint8_t
const, like this:
// Explicit cast
AceButton button((uint8_t) 0);
// Or assign to a const first.
static const uint8_t PIN = 0;
AceButton button(PIN);
See Issue #40 for details.
The core concept of the AceButton library is the separation of the
button (AceButton
) from its configuration (ButtonConfig
).
- The
AceButton
class has the logic for debouncing and detecting the various events (Pressed, Released, etc), and the various bookkeeping variables needed to implement the logic. These variables are associated with the specific instance of thatAceButton
. - The
ButtonConfig
class has the various timing parameters which control how much time is needed to detect certain events. This class also has the ability to override the default methods for reading the pin (readButton()
) and the clock (getClock()
). This ability allows unit tests to be written.
The class looks like this (not all public methods are shown):
namespace ace_button {
class ButtonConfig {
public:
static const uint16_t kDebounceDelay = 20;
static const uint16_t kClickDelay = 200;
static const uint16_t kDoubleClickDelay = 400;
static const uint16_t kLongPressDelay = 1000;
static const uint16_t kRepeatPressDelay = 1000;
static const uint16_t kRepeatPressInterval = 200;
typedef uint16_t FeatureFlagType;
static const FeatureFlagType kFeatureClick = 0x01;
static const FeatureFlagType kFeatureDoubleClick = 0x02;
static const FeatureFlagType kFeatureLongPress = 0x04;
static const FeatureFlagType kFeatureRepeatPress = 0x08;
static const FeatureFlagType kFeatureSuppressAfterClick = 0x10;
static const FeatureFlagType kFeatureSuppressAfterDoubleClick = 0x20;
static const FeatureFlagType kFeatureSuppressAfterLongPress = 0x40;
static const FeatureFlagType kFeatureSuppressAfterRepeatPress = 0x80;
static const FeatureFlagType kFeatureSuppressClickBeforeDoubleClick = 0x100;
static const FeatureFlagType kFeatureSuppressAll = (
kFeatureSuppressAfterClick
| kFeatureSuppressAfterDoubleClick
| kFeatureSuppressAfterLongPress
| kFeatureSuppressAfterRepeatPress
| kFeatureSuppressClickBeforeDoubleClick);
typedef void (*EventHandler)(AceButton* button, uint8_t eventType,
uint8_t buttonState);
ButtonConfig() = default;
uint16_t getDebounceDelay();
uint16_t getClickDelay();
uint16_t getDoubleClickDelay();
uint16_t getLongPressDelay();
uint16_t getRepeatPressDelay();
uint16_t getRepeatPressInterval();
void setDebounceDelay(uint16_t debounceDelay);
void setClickDelay(uint16_t clickDelay);
void setDoubleClickDelay(uint16_t doubleClickDelay);
void setLongPressDelay(uint16_t longPressDelay);
void setRepeatPressDelay(uint16_t repeatPressDelay);
void setRepeatPressInterval(uint16_t repeatPressInterval);
virtual unsigned long getClock();
virtual int readButton(uint8_t pin);
bool isFeature(FeatureFlagType features);
void setFeature(FeatureFlagType features);
void clearFeature(FeatureFlagType features);
void resetFeatures();
void setEventHandler(EventHandler eventHandler);
void setIEventHandler(IEventHandler* eventHandler);
static ButtonConfig* getSystemButtonConfig();
};
}
The ButtonConfig
(or a customized subclass) can be created and assigned to one
or more AceButton
instances using dependency injection through the
AceButton(ButtonConfig*)
constructor. This constructor also accepts the same
(pin, defaultReleasedState, id)
parameters as init(pin, defaultReleasedState, id)
method. Sometimes it's easier to set all the parameters in one place using
the constructor. Other times, the parameters are not known until the
AceButton::init()
method can be called from the global setup()
method.
const uint8_t PIN1 = 2;
const uint8_t PIN2 = 4;
ButtonConfig buttonConfig;
AceButton button1(&buttonConfig, PIN1);
AceButton button2(&buttonConfig, PIN2);
void setup() {
pinMode(PIN1, INPUT_PULLUP);
pinMode(PIN2, INPUT_PULLUP);
...
}
Another way to inject the ButtonConfig
dependency is to use the
AceButton::setButtonConfig()
method but it is recommended that you use the
constructor instead because the dependency is easier to follow.
A single instance of ButtonConfig
called the "System ButtonConfig" is
automatically created by the library at startup. By default, all instances of
AceButton
are automatically assigned to this singleton instance. We explain in
the Single Button Simplifications section below how this simplifies the code
needed to handle a single button.
The ButtonConfig
class provides a number of methods which are mostly
used internally by the AceButton
class. The one method which is expected
to be used by the calling client code is setEventHandler()
which
assigns the user-defined EventHandler
callback function to the ButtonConfig
instance. This is explained in more detail below in the
EventHandler section below.
Here are the methods to retrieve the timing parameters:
uint16_t getDebounceDelay();
(default: 20 ms)uint16_t getClickDelay();
(default: 200 ms)uint16_t getDoubleClickDelay();
(default: 400 ms)uint16_t getLongPressDelay();
(default: 1000 ms)uint16_t getRepeatPressDelay();
(default: 1000 ms)uint16_t getRepeatPressInterval();
(default: 200 ms)
The default values of each timing parameter can be changed at run-time using the following methods:
void setDebounceDelay(uint16_t debounceDelay);
void setClickDelay(uint16_t clickDelay);
void setDoubleClickDelay(uint16_t doubleClickDelay);
void setLongPressDelay(uint16_t longPressDelay);
void setRepeatPressDelay(uint16_t repeatPressDelay);
void setRepeatPressInterval(uint16_t repeatPressInterval);
The ButtonConfig
class has 2 methods which provide hooks to its external
hardware dependencies:
virtual unsigned long getClock();
virtual int readButton(uint8_t pin);
By default these are mapped to the underlying Arduino system functions respectively:
millis()
digitalRead()
Unit tests are possible because these methods are virtual
and the hardware
dependencies can be swapped out with fake ones.
We have assumed that there is a 1-to-many relationship between a ButtonConfig
and the AceButton
. In other words, multiple buttons will normally be
associated with a single configuration. Each AceButton
has a pointer to an
instance of ButtonConfig
. So the cost of separating the ButtonConfig
from
AceButton
is 2 bytes in each instance of AceButton
. Note that this is
equivalent to adding virtual methods to AceButton
(which would add 2 bytes),
so in terms of static RAM size, this is a wash.
The library is designed to handle multiple buttons, and it assumes that the buttons are normally grouped together into a handful of types. For example, consider the buttons of a car radio. It has several types of buttons:
- the tuner buttons (2, up and down)
- the preset buttons (6)
- the AM/FM band button (1)
In this example, there are 9 buttons, but only 3 instances of ButtonConfig
would be needed.
The event handler is a callback function that gets called when the AceButton
class determines that an interesting event happened on the button. The
advantage of this mechanism is that all the complicated logic of determining
the various events happens inside the AceButton
class, and the user will
normally not need to worry about the details.
The event handler is defined in the ButtonConfig
class and has the following
signature:
class ButtonConfig {
public:
typedef void (*EventHandler)(AceButton* button, uint8_t eventType,
uint8_t buttonState);
...
};
The event handler is registered with the ButtonConfig
object, not with the
AceButton
object, although the convenience method
AceButton::setEventHandler()
is provided as a pass-through to the underlying
ButtonConfig
(see the Single Button Simplifications section below):
ButtonConfig buttonConfig;
void handleEvent(AceButton* button, uint8_t eventType, uint8_t buttonState) {
...
}
void setup() {
...
buttonConfig.setEventHandler(handleEvent);
...
}
The motivation for this design is to save static memory. If multiple buttons
are associated with a single ButtonConfig
, then it is not necessary for every
button of that type to hold the same pointer to the EventHandler
function. It
is only necessary to save that information once, in the ButtonConfig
object.
Pro Tip 1: Comment out the unused parameter(s) in the handleEvent()
method
to avoid the unused parameter
compiler warning:
void handleEvent(AceButton* /*button*/, uint8_t eventType,
uint8_t /*buttonState*/) {
...
}
The Arduino sketch compiler can get confused with the parameters commented out,
so you may need to add a forward declaration for the handleEvent()
method
before the setup()
method:
void handleEvent(AceButton*, uint8_t, uint8_t);
Pro Tips 2: The event handler can be an object instead of just a function pointer. An object-based event handler can be useful in more complex applications with numerous buttons. See the section on Object-based Event Handler in the Advanced Topics below.
The EventHandler
function receives 3 parameters from the AceButton
:
button
- pointer to the
AceButton
instance that generated this event - can be used to retrieve the
getPin()
or thegetId()
- pointer to the
eventType
- the type of this event given by the various
AceButton::kEventXxx
constants
- the type of this event given by the various
buttonState
- the
HIGH
orLOW
button state that generated this event
- the
The button
pointer should be used only to extract information about the
button that triggered the event. It should not be used to modify the
button's internal variables in any way within the eventHandler. The logic in
AceButton::check()
assumes that those internal variable are held constant,
and if they are changed by the eventHandler, unpredictable results may occur.
(I should have made the button
be a const AceButton*
but by the time I
realized this, there were too many users of the library already, and I did not
want to make a breaking change to the API.)
If you are using only a single button, then you should need to check
only the eventType
.
It is not expected that buttonState
will be needed very often. It should be
sufficient to examine just the eventType
to determine the action that needs to
be performed. Part of the difficulty with this parameter is that it has the
value of LOW
or HIGH
, but the physical interpretation of those values
depends on whether the button was wired with a pull-up or pull-down resistor.
Use the helper function button->isReleased(buttonState)
to translate the raw
buttonState
into a more meaningful determination if you need it.
Only a single EventHandler
per ButtonConfig
is supported. An alternative
would have been to register a separate event handler for each of the 6
kEventXxx
events. But each callback function requires 2 bytes of memory, and
it was assumed that in most cases, the calling client code would be interested
in only a few of these event types, so it seemed wasteful to allocate 12 bytes
when most of these would be unused. If the client code really wanted separate
event handlers, it can be easily emulated by invoking them through the main
event handler:
void handleEvent(AceButton* button, uint8_t eventType, uint8_t buttonState) {
switch (eventType) {
case AceButton::kEventPressed:
handleEventPressed(button, eventType, buttonState);
break;
case AceButton::kEventReleased:
handleEventReleased(button, eventType, buttonState);
break;
...
}
}
The Arduino runtime environment is single-threaded, so the EventHandler
is
called in the middle of the AceButton::check()
method, in the same thread as
the check()
method. It is therefore important to write the EventHandler
code to run somewhat quickly, so that the delay doesn't negatively impact the
logic of the AceButton::check()
algorithm. Since AceButton::check()
should
run approximately every 5 ms, the user-provided EventHandler
should run
somewhat faster than 5 ms. Given a choice, it is probably better to use the
EventHandler
to set some flags or variables and return quickly, then do
additional processing from the loop()
method.
Sometimes it is too convenient or unavoidable to perform a long-running operation inside the event handler (e.g. making an HTTP). This is fine, I have done this occasionally. Just be aware that the button scanning operation will not work during that long-running operation.
Speaking of threads, the API of the AceButton Library was designed to work in a multi-threaded environment, if that situation were to occur in the Arduino world.
The supported events are defined by a list of constants in AceButton.h
:
AceButton::kEventPressed
(always enabled, cannot be suppressed)AceButton::kEventReleased
(default: enabled)AceButton::kEventClicked
(default: disabled)AceButton::kEventDoubleClicked
(default: disabled)AceButton::kEventLongPressed
(default: disabled)AceButton::kEventRepeatPressed
(default: disabled)AceButton::kEventLongReleased
(default: disabled, autoenabled bykFeatureSuppressAfterLongPress
, new for v1.8)
These values are sent to the EventHandler
in the eventType
parameter.
Two of the events are enabled by default, four are disabled by default but can be enabled by using a Feature flag described below.
There are 9 flags defined in ButtonConfig
which can
control the behavior of AceButton
event handling:
ButtonConfig::kFeatureClick
ButtonConfig::kFeatureDoubleClick
ButtonConfig::kFeatureLongPress
ButtonConfig::kFeatureRepeatPress
ButtonConfig::kFeatureSuppressAfterClick
ButtonConfig::kFeatureSuppressAfterDoubleClick
ButtonConfig::kFeatureSuppressAfterLongPress
ButtonConfig::kFeatureSuppressAfterRepeatPress
ButtonConfig::kFeatureSuppressClickBeforeDoubleClick
ButtonConfig::kFeatureSuppressAll
These constants are used to set or clear the given flag:
// Get the current config.
ButtonConfig* config = button.getButtonConfig();
// Set a specific feature
config->setFeature(ButtonConfig::kFeatureLongPress);
// Clear a specific feature
config->clearFeature(ButtonConfig::kFeatureLongPress);
// Test for a specific feature
if (config->isFeature(ButtonConfig::kFeatureLongPress)) {
...
}
// Clear all features
config->resetFeatures()
The meaning of these flags are described below.
Of the 7 event types, 5 are disabled by default:
AceButton::kEventClicked
AceButton::kEventDoubleClicked
AceButton::kEventLongPressed
AceButton::kEventRepeatPressed
AceButton::kEventLongReleased
To receive these events, call ButtonConfig::setFeature()
with the following
corresponding flags:
ButtonConfig::kFeatureClick
ButtonConfig::kFeatureDoubleClick
ButtonConfig::kFeatureLongPress
ButtonConfig::kFeatureRepeatPress
ButtonConfig::kFeatureSuppressAfterLongPress
(suppresseskEventReleased
after a LongPress, but turns onkEventLongReleased
as a side effect)
To disable these events, call ButtonConfig::clearFeature()
with one of these
flags.
Enabling kFeatureDoubleClick
automatically enables kFeatureClick
, because we
need to have a Clicked event before a DoubleClicked event can be detected.
It seems unlikely that both LongPress
and RepeatPress
events would be
useful at the same time, but both event types can be activated if you need it.
Event types can be considered to be built up in layers, starting with the lowest level primitive events: Pressed and Released. Higher level events are built on top of the lower level events through various timing delays. When a higher level event is detected, it is sometimes useful to suppress the lower level event that was used to detect the higher level event.
For example, a Clicked event requires a Pressed event followed by a Released
event within a ButtonConfig::getClickDelay()
milliseconds (200 ms by
default). The Pressed event is always generated. If a Clicked event is
detected, we could choose to generate both a Released event and a Clicked
event, and this is the default behavior.
However, many times, it is useful to suppress the Released event if the Clicked
event is detected. The ButtonConfig
can be configured to suppress these lower
level events. Call the setFeature(feature)
method passing the various
kFeatureSuppressXxx
constants:
ButtonConfig::kFeatureSuppressAfterClick
- suppresses the
kEventReleased
event after a Clicked event is detected - also suppresses the Released event from the first Clicked of a
DoubleClicked, since
kFeatureDoubleClick
automatically enableskFeatureClick
- suppresses the
ButtonConfig::kFeatureSuppressAfterDoubleClick
- suppresses the
kEventReleased
event and the second Clicked event if a DoubleClicked event is detected
- suppresses the
ButtonConfig::kFeatureSuppressAfterLongPress
- suppresses the
kEventReleased
event if a LongPressed event is detected - (v1.8) automatically enables
kEventLongReleased
event as a substitute for the suppressedkEventReleased
, see Distinguishing Pressed and Long Pressed subsection below for more details.
- suppresses the
ButtonConfig::kFeatureSuppressAfterRepeatPress
- suppresses the
kEventReleased
event after the last RepeatPressed event
- suppresses the
ButtonConfig::kFeatureSuppressClickBeforeDoubleClick
- The first
kEventClicked
event is postponed bygetDoubleClickDelay()
millis until the code can determine if a DoubleClick has occurred. If so, then the postponedkEventClicked
message to theEventHandler
is suppressed. - See Distinguishing Clicked and DoubleClicked subsection below for more info.
- The first
ButtonConfig::kFeatureSuppressAll
- a convenience parameter that is the equivalent of suppressing all of the previous events
By default, no suppression is performed.
As an example, to suppress the kEventReleased
after a kEventLongPressed
(this is actually often the case), you would do this:
ButtonConfig* config = button.getButtonConfig();
config->setFeature(ButtonConfig::kFeatureSuppressAfterLongPress);
The special convenient constant kFeatureSuppressAll
is equivalent of using all
suppression constants:
ButtonConfig* config = button.getButtonConfig();
config->setFeature(ButtonConfig::kFeatureSuppressAll);
All suppressions can be cleared by using:
ButtonConfig* config = button.getButtonConfig();
config->clearFeature(ButtonConfig::kFeatureSuppressAll);
Note, however, that the isFeature(ButtonConfig::kFeatureSuppressAll)
currently
means "isAnyFeature() implemented?" not "areAllFeatures() implemented?" We don't
expect isFeature()
to be used often (or at all) for kFeatureSuppressAll
.
You can clear all feature at once using:
ButtonConfig* config = button.getButtonConfig();
config->resetFeatures();
This is useful if you want to reuse a ButtonConfig
instance and you want to
reset its feature flags to its initial state.
Although the AceButton library is designed to shine for multiple buttons, you may want to use it to handle just one button. The library provides some features to make this simple case easy.
- The library automatically creates one instance of
ButtonConfig
called a "System ButtonConfig". This System ButtonConfig can be retrieved using the class static methodButtonConfig::getSystemButtonConfig()
. - Every instance of
AceButton
is assigned an instance of the System ButtonConfig by default (which can be overridden manually). - A convenience method allows the
EventHandler
for the System ButtonConfig to be set easily throughAceButton
itself, instead of having to get the System ButtonConfig first, then set the event handler. In other words,button.setEventHandler(handleEvent)
is a synonym forbutton.getButtonConfig()->setEventHandler(handleEvent)
.
These simplifying features allow a single button to be configured and used like this:
AceButton button(BUTTON_PIN);
void setup() {
pinMode(BUTTON_PIN, INPUT_PULLUP);
button.setEventHandler(handleEvent);
...
}
void loop() {
button.check();
}
void handleEvent(AceButton* button, uint8_t eventType, uint8_t buttonState) {
...
}
To configure the System ButtonConfig, you may need to add something like
this to the setup()
section:
button.getButtonConfig()->setFeature(ButtonConfig::kFeatureLongPress);
When transitioning from a single button to multiple buttons, it's important to
remember what's happening underneath the convenience methods. The single
AceButton
button is assigned to the System ButtonConfig that was created
automatically. When an EventHandler
is assigned to the button, it is actually
assigned to the System ButtonConfig. All subsequent instances of AceButton
will also be associated with this event handler, unless another ButtonConfig
is explicitly assigned.
There are at least 2 ways you can configure multiple buttons.
Option 1: Multiple ButtonConfigs
#include <AceButton.h>
using namespace ace_button;
ButtonConfig config1;
AceButton button1(&config1);
ButtonConfig config2;
AceButton button2(&config2);
void button1Handler(AceButton* button, uint8_t eventType, uint8_t buttonState) {
Serial.println("button1");
}
void button2Handler(AceButton* button, uint8_t eventType, uint8_t buttonState) {
Serial.println("button2");
}
void setup() {
Serial.begin(115200);
pinMode(6, INPUT_PULLUP);
pinMode(7, INPUT_PULLUP);
config1.setEventHandler(button1Handler);
config2.setEventHandler(button2Handler);
button1.init(6);
button2.init(7);
}
void loop() {
button1.check();
button2.check();
}
See the example sketch
TwoButtonsUsingTwoButtonConfigs
which uses 2 ButtonConfig
instances to configure 2 AceButton
instances.
Option 2: Multiple Button Discriminators
Another technique keeps the single system ButtonConfig
and the single
EventHandler
, but use the AceButton::getPin()
to discriminate between the
multiple buttons:
#include <AceButton.h>
using namespace ace_button;
AceButton button1(6);
AceButton button2(7);
void button1Handler(AceButton* button, uint8_t eventType, uint8_t buttonState) {
Serial.println("button1");
}
void button2Handler(AceButton* button, uint8_t eventType, uint8_t buttonState) {
Serial.println("button2");
}
void buttonHandler(AceButton* button, uint8_t eventType, uint8_t buttonState) {
switch (button->getPin()) {
case 6:
button1Handler(button, eventType, buttonState);
break;
case 7:
button2Handler(button, eventType, buttonState);
break;
}
}
void setup() {
Serial.begin(115200);
pinMode(6, INPUT_PULLUP);
pinMode(7, INPUT_PULLUP);
ButtonConfig* config = ButtonConfig::getSystemButtonConfig();
config->setEventHandler(buttonHandler);
}
void loop() {
button1.check();
button2.check();
}
See the example code
TwoButtonsUsingOneButtonConfig.
which uses a single ButtonConfig
instance to handle 2 AceButton
instances.
Sometimes, it is more convenient to use the AceButton::getId()
method
to identify the button instead of the AceButton::getPin()
.
See ArrayButtons for an example.
The EventHandler
is a typedef that is defined to be a function pointer. This
is a simple, low-overhead design that produces the smallest memory footprint,
and allows the event handler to be written with the smallest amount of
boilerplate code. The user does not have to override a class.
In more complex applications involving larger number of AceButton
and
ButtonConfig
objects, it is often useful for the EventHandler
to be an
object instead of a simple function pointer. This is especially true if the
application uses Object Oriented Programming (OOP) techniques for modularity and
encapsulation. Using an object as the event handler allows additional context
information to be injected into the event handler.
To support OOP techniques, AceButton v1.6 adds:
IEventHandler
interface class- contains a single pure virtual function
handleEvent()
- contains a single pure virtual function
ButtonConfig::setIEventHandler()
method- accepts a pointer to an instance of the
IEventHandler
interface.
- accepts a pointer to an instance of the
The IEventHandler
interface is simply this:
class IEventHandler {
public:
virtual void handleEvent(AceButton* button, uint8_t eventType,
uint8_t buttonState) = 0;
};
At least one of ButtonConfig::setEventHandler()
or
ButtonConfig::setIEventHandler()
must be called before events are actually
dispatched. If both are called, the last one takes precedence.
See examples/SingleButtonUsingIEventHandler for an example.
On a project using only a small number of buttons (due to physical limits or the limited availability of pins), it may be desirable to distinguish between a single Clicked event and a DoubleClicked event from a single button. This is a challenging problem to solve because fundamentally, a DoubleClicked event must always generate a Clicked event, because a Clicked event must happen before it can become a DoubleClicked event.
Notice that on a desktop computer (running Windows, MacOS or Linux), a double-click on a mouse always generates both a Clicked and a DoubleClicked. The first Click selects the given desktop object (e.g. an icon or a window), and the DoubleClick performs some action on the selected object (e.g. open the icon, or resize the window).
The AceButton Library provides 3 solutions which may work for some projects:
Method 1: The kFeatureSuppressClickBeforeDoubleClick
flag causes the first
Clicked event to be detected, but the posting of the event message (i.e. the
call to the EventHandler
) is postponed until the state of the DoubleClicked
can be determined. If the DoubleClicked happens, then the first Clicked event
message is suppressed. If DoubleClicked does not occur, the long delayed
Clicked message is sent via the EventHandler
.
There are two noticeable disadvantages of this method. First, the response time
of all Clicked events is delayed by about 600 ms (kClickDelay + kDoubleClickDelay
) whether or not the DoubleClicked event happens. Second, the
user may not be able to accurately produce a Clicked event (due to the physical
characteristics of the button, or the user's dexterity).
It may also be worth noting that only the Clicked event is postponed. The accompanying Released event of the Clicked event is not postponed. So a single click action (without a DoubleClick) produces the following sequence of events to the EventHandler:
kEventPressed
- at time 0mskEventReleased
- at time 200mskEventClicked
- at time 600ms (200ms + 400ms)
The ButtonConfig
configuration looks like this:
ButtonConfig* buttonConfig = button.getButtonConfig();
buttonConfig->setFeature(ButtonConfig::kFeatureDoubleClick);
buttonConfig->setFeature(
ButtonConfig::kFeatureSuppressClickBeforeDoubleClick);
See the example code at
examples/ClickVersusDoubleClickUsingSuppression/
.
Method 2: A viable alternative is to use the Released event instead of the Clicked event to distinguish it from the DoubleClicked. For this method to work, we need to suppress the Released event after both Clicked and DoubleClicked.
The advantage of using this method is that there is no response time lag in the handling of the Released event. To the user, there is almost no difference between triggering on the Released event, versus triggering on the Clicked event.
The disadvantage of this method is that the Clicked event must be be ignored (because of the spurious Clicked event generated by the DoubleClicked). If the user accidentally presses and releases the button too quickly, it generates a Clicked event, which will cause the program to do nothing.
The ButtonConfig
configuration looks like this:
ButtonConfig* buttonConfig = button.getButtonConfig();
buttonConfig->setEventHandler(handleEvent);
buttonConfig->setFeature(ButtonConfig::kFeatureDoubleClick);
buttonConfig->setFeature(ButtonConfig::kFeatureSuppressAfterClick);
buttonConfig->setFeature(ButtonConfig::kFeatureSuppressAfterDoubleClick);
See the example code at
examples/ClickVersusDoubleClickUsingReleased/
.
Method 3: We could actually combine both Methods 1 and 2 so that either Released or a delayed Click is considered to be a "Click". This may be the best of both worlds.
The ButtonConfig
configuration looks like this:
ButtonConfig* buttonConfig = button.getButtonConfig();
buttonConfig->setEventHandler(handleEvent);
buttonConfig->setFeature(ButtonConfig::kFeatureDoubleClick);
buttonConfig->setFeature(
ButtonConfig::kFeatureSuppressClickBeforeDoubleClick);
buttonConfig->setFeature(ButtonConfig::kFeatureSuppressAfterClick);
buttonConfig->setFeature(ButtonConfig::kFeatureSuppressAfterDoubleClick);
See the example code at
examples/ClickVersusDoubleClickUsingBoth/
.
Sometimes it is useful to capture both a Pressed event and a LongPressed event
from a single button. Since every button press always triggers a kEventPressed
event, the only reasonable way to distinguish between Pressed and LongPressed is
to use the kEventReleased
as a substitute for the simple Pressed event. When
we active kFeatureLongPress
, we then must activate the
kFeatureSuppressAfterLongPress
feature to suppress the kEventReleased
event
after the kEventLongPressed
to avoid yet another overlap of events.
ButtonConfig* config = button.getButtonConfig();
config->setFeature(ButtonConfig::kFeatureLongPress);
config->setFeature(ButtonConfig::kFeatureSuppressAfterLongPress);
This works most of the time, but I encountered an edge case. Occasionally we
want to capture the Released event after the LongPressed event, even if
kEventReleased
must be suppressed as described above. To solve this edge case,
in v1.8, I added a new event type kEventLongReleased
which is triggered as a
substitute for kEventReleased
, only if kFeatureSuppressAfterLongPress
is
used to suppress kEventReleased
.
See the example code at examples/PressVersusLongPress to see how all these come together.
A number of edge cases occur when the microcontroller is rebooted:
- if the button is held down, should the Pressed event be triggered?
- if the button is in its natural Released state, should the Released event happen?
- if the button is Pressed down, and
ButtonConfig
is configured to support RepeatPress events, should thekEventRepeatPressed
events be triggered initially?
I think most users would expect that in all these cases, the answer is no, the
microcontroller should not trigger an event until the button undergoes a
human-initiated change in state. The AceButton library implements this logic.
(It might be useful to make this configurable using a ButtonConfig
feature
flag but that is not implemented.)
On the other hand, it is sometimes useful to perform some special action if a
button is pressed while the device is rebooted. To support this use-case, call
the AceButton::isPressedRaw()
in the global setup()
method (after the
button is configured). It will directly call the digitalRead()
method
associated with the button pin and return true
if the button is in the
Pressed state.
When a Clicked event is generated, the AceButton
class looks for a
second Clicked event within a certain time delay (default 400 ms) to
determine if the second Clicked event is actually a DoubleClicked event.
All internal timestamps in AceButton
are stored as uint16_t
(i.e. an unsigned integer of 16 bits) in millisecond units. A 16-bit
unsigned counter rolls over after 65536 iterations. Therefore, if the second
Clicked event happens between (65.636 seconds, 66.036 seconds) after the first
Clicked event, a naive-logic would erroneously consider the (long-delayed)
second click as a double-click.
The AceButton
contains code that prevents this from happening.
Note that even if the AceButton
class uses an unsigned long
type (a 32-bit
integer on the Arduino), the overflow problem would still occur after 2^32
milliseconds (i.e. 49.7 days). To be strictly correct, the AceButton
class
would still need logic to take care of orphaned Clicked events.
Instead of allocating one pin for each button, we can use Binary Encoding to support large number of buttons with only a few pins. The circuit can be implemented using a 74LS148 chip, or simple diodes like this:
Three subclasses of ButtonConfig
are provided to handle binary encoded
buttons:
Encoded4To2ButtonConfig
: 3 buttons with 2 pinsEncoded8To3ButtonConfig
: 7 buttons with 3 pinsEncodedButtonConfig
:M=2^N-1
buttons withN
pins
See docs/binary_encoding/README.md for information on how to use these classes.
It is possible to attach 1-8 (maybe more) buttons on a single analog pin through
a resistor ladder, and use the analogRead()
to read the different voltages
generated by each button. An example circuit looks like this:
The LadderButtonConfig
class handles this configuration.
See docs/resistor_ladder/README.md for information on how to use this class.
All classes in this library were originally designed to be created statically at
startup time and never deleted during the lifetime of the application. Since
they were never meant to be deleted through the pointer, I did not include the
virtual destructor for polymorphic classes (i.e. ButtonConfig
and its
subclasses). The AceButton
class is not polymorphic and does not need a
virtual destructor.
Most 8-bit processors have limited flash and static memory (for example,
32 kB flash and 2 KB static for the Nano or UNO). Adding a virtual destructor
causes 600 additional bytes of flash memory to be consumed. I suspect this
is due to the virtual destructor pulling the malloc()
and free()
functions which are needed to implement the new
and delete
operators. For a
library that consumes only about 1200 bytes on an 8-bit processor, this increase
in flash memory size did not seem acceptable.
For 32-bit processors (e.g. ESP8266, ESP32) which have far more flash memory
(e.g. 1 MB) and static memory (e.g. 80 kB), it seems reasonable to allow
AceButton
and ButtonConfig
to be created and deleted from the heap.
(See Issue #46 for the
motivation.) Testing shows that the virtual destructor adds only about 60-120
bytes of flash memory for these microcontrollers, probably because the
malloc()
and free()
functions are already pulled in by something else. The
60-120 bytes of additional consumption seems trivial compared to the range of
~256 kB to ~4 MB flash memory available on these 32-bit processors.
Therefore, I added a virtual destructor for the ButtonConfig
class (v1.5) and
enabled it for all architectures other than ARDUINO_ARCH_AVR
(v1.6.1). This
prevents 8-bit processors with limited memory from suffering the overhead of an
extra 600 bytes of flash memory usage.
Even for 32-bit processors, I still recommend avoiding the creation and deletion
of objects from the heap, to avoid the risk of heap fragmentation. If a variable
number of buttons is needed, it might be possible to design the application so
that all buttons which will ever be needed are predefined in a global pool. Even
if some of the AceButton
and ButtonConfig
instances are unused, the overhead
is probably smaller than the overhead of wasted space due to heap fragmentation.
The digitalWriteFast
libraries provide smaller and faster alternative versions
the digitalWrite()
, digitalRead()
, and pinMode()
functions. I have used 2
such libraries, but there probably others:
- https://github.com/NicksonYap/digitalWriteFast
- a simplified fork of the watterott library
- but it seems to be unmaintained, e.g. does not support ATtiny85
- https://github.com/watterott/Arduino-Libs/tree/master/digitalWriteFast
- seems to be better maintained, but is not an independent library
- you must manually
git clone
the repo and copy or symlink thedigitalWriteFast/
directory into your Arduino IDElibraries
directory
These libraries provide the following functions: digitalWriteFast()
,
digitalReadFast()
, and pinModeFast()
which are usually valid only AVR
processors. These alternative functions depend on the pin number and value to be
compile-time constants, bypassing the pin number lookup tables used by the
standard versions. These fast versions can be 20-50X faster. More importantly in
many situations, they can save 100-500 bytes of flash memory by not pulling in
the pin number lookup tables.
I created 3 alternative versions of ButtonConfig
which use the
digitalWriteFast
libraries:
- src/ace_button/fast/ButtonConfigFast1.h
- src/ace_button/fast/ButtonConfigFast2.h
- src/ace_button/fast/ButtonConfigFast3.h
(If ButtonConfigFast4.h
is needed, it is easy to copy ButtonConfigFast3.h
and create a 4-pin version.)
These classes use C++ templates on the pin numbers, so that they can be passed
to the digitalReadFast()
functions as compile-time constants. Because they
depend on an external digitalWriteFast
library, they are not included in
the <AceButton.h>
header file. They must be included explicitly, as shown
below:
#include <Arduino.h>
#include <AceButton.h>
#include <digitalWriteFast.h>
#include <ace_button/fast/ButtonConfigFast2.h>
using namespace ace_button;
// Physical pin numbers attached to the buttons.
const uint8_t BUTTON1_PHYSICAL_PIN = 2;
const uint8_t BUTTON2_PHYSICAL_PIN = 3;
// Virtual pin numbers attached to the buttons.
const uint8_t BUTTON1_PIN = 0;
const uint8_t BUTTON2_PIN = 1;
ButtonConfigFast2<BUTTON1_PHYSICAL_PIN, BUTTON2_PHYSICAL_PIN> buttonConfig;
AceButton button1(&buttonConfig, BUTTON1_PIN);
AceButton button2(&buttonConfig, BUTTON2_PIN);
void handleEvent(AceButton* button, uint8_t eventType, uint8_t buttonState) {
...
}
void setup() {
...
}
void loop() {
// Should be called every 4-5ms or faster, for the default debouncing time
// of ~20ms.
button1.check();
button2.check();
}
Each physical pin number given as template arguments to the
ButtonConfigFast2<>
class corresponds to a virtual pin number (starting with
0) assigned to the AceButton
object. Within the event handler, everything is
referenced by the virtual pin number, just like the EncodedButtonConfig
and
LadderButtonConfig
classes.
Here are the example programs for each ButtonConfigFast{N}
class:
- examples/SingleButtonFast (
ButtonConfigFast1
) - examples/TwoButtonsUsingOneButtonConfigFast (
ButtonConfigFast2
) - examples/ThreeButtonsUsingOneButtonConfigFast (
ButtonConfigFast3
)
The LadderButtonConfig
class uses analogRead()
which does not seem to
directly benefit from digitalWriteFast
libraries. However, if you use
pinModeFast()
instead of pinMode()
in your global setup()
function, you
can save about 50 bytes of flash (I think).
The Encoded4To2ButtonConfig
and Encoded8To3ButtonConfig
classes would
probably benefit from digitalWriteFast
libraries, but I have not created the
"fast" versions of these (i.e. Encoded4To2ButtonConfigFast
and
Encoded8To3ButtonConfigFast
) because I have not needed them personally.
The general EncodedButtonConfig
class is more difficult to convert into a
"fast" version, because its constructor takes a pointer argument to an array of
physical pins. These are not compile-time constants so we would not be able to
use the digitalWriteFast
libraries directly. I think the best we could do is
create special Encoded16To4ButtonConfigFast
and Encoded32To5ButtonConfigFast
classes.
Here are the sizes of the various classes on the 8-bit AVR microcontrollers (Arduino Uno, Nano, etc):
sizeof(AceButton): 14
sizeof(ButtonConfig): 18
sizeof(ButtonConfigFast1<>): 18
sizeof(ButtonConfigFast2<>): 18
sizeof(ButtonConfigFast3<>): 18
sizeof(Encoded4To2ButtonConfig): 21
sizeof(Encoded8To3ButtonConfig): 22
sizeof(EncodedButtonConfig): 25
sizeof(LadderButtonConfig): 26
For 32-bit microcontrollers:
sizeof(AceButton): 16
sizeof(ButtonConfig): 24
sizeof(Encoded4To2ButtonConfig): 28
sizeof(Encoded8To3ButtonConfig): 28
sizeof(EncodedButtonConfig): 36
sizeof(LadderButtonConfig): 36
(An early version of AceButton
, with only half of the functionality, consumed
40 bytes. It got down to 11 bytes before additional functionality increased it
to 14.)
MemoryBenchmark was used to determine the size of the library for various microcontrollers (Arduino Nano to ESP32). Here are 2 samples:
Arduino Nano
+--------------------------------------------------------------+
| functionality | flash/ ram | delta |
|---------------------------------+--------------+-------------|
| Baseline | 610/ 11 | 0/ 0 |
|---------------------------------+--------------+-------------|
| ButtonConfig | 1946/ 51 | 1336/ 40 |
| ButtonConfigFast1 | 1662/ 51 | 1052/ 40 |
| ButtonConfigFast2 | 1630/ 65 | 1020/ 54 |
| ButtonConfigFast3 | 1678/ 79 | 1068/ 68 |
| Encoded4To2ButtonConfig | 2160/ 82 | 1550/ 71 |
| Encoded8To3ButtonConfig | 2428/ 139 | 1818/ 128 |
| EncodedButtonConfig | 2474/ 162 | 1864/ 151 |
| LadderButtonConfig | 2476/ 175 | 1866/ 164 |
+--------------------------------------------------------------+
ESP8266:
+--------------------------------------------------------------+
| functionality | flash/ ram | delta |
|---------------------------------+--------------+-------------|
| Baseline | 256924/26800 | 0/ 0 |
|---------------------------------+--------------+-------------|
| ButtonConfig | 258424/26840 | 1500/ 40 |
| ButtonConfigFast1 | -1/ -1 | -1/ -1 |
| ButtonConfigFast2 | -1/ -1 | -1/ -1 |
| ButtonConfigFast3 | -1/ -1 | -1/ -1 |
| Encoded4To2ButtonConfig | 258732/26916 | 1808/ 116 |
| Encoded8To3ButtonConfig | 258876/26980 | 1952/ 180 |
| EncodedButtonConfig | 259004/27020 | 2080/ 220 |
| LadderButtonConfig | 259048/27024 | 2124/ 224 |
+--------------------------------------------------------------+
The profiling numbers for AceButton::check()
,
EncodedButtonConfig::checkButtons()
, and LadderButtonConfig::checkButtons()
can be found in examples/AutoBenchmark. Here are 2
samples, in units of microseconds.
Arduino Nano:
+---------------------------+-------------+---------+
| Button Event | min/avg/max | samples |
|---------------------------+-------------+---------|
| idle | 8/ 15/ 24 | 1931 |
| press/release | 8/ 16/ 24 | 1924 |
| click | 12/ 15/ 24 | 1924 |
| double_click | 12/ 15/ 32 | 1921 |
| long_press/repeat_press | 12/ 16/ 28 | 1924 |
|---------------------------+-------------+---------|
| ButtonConfigFast1 | 8/ 14/ 24 | 1933 |
| ButtonConfigFast2 | 20/ 27/ 36 | 1910 |
| ButtonConfigFast3 | 28/ 40/ 48 | 1886 |
|---------------------------+-------------+---------|
| Encoded4To2ButtonConfig | 60/ 67/ 92 | 1839 |
| Encoded8To3ButtonConfig | 164/186/208 | 1659 |
| EncodedButtonConfig | 80/100/124 | 1785 |
| LadderButtonConfig | 176/199/272 | 1640 |
+---------------------------+-------------+---------+
ESP8266:
+---------------------------+-------------+---------+
| Button Event | min/avg/max | samples |
|---------------------------+-------------+---------|
| idle | 6/ 8/ 52 | 1917 |
| press/release | 6/ 8/ 62 | 1907 |
| click | 6/ 8/ 38 | 1902 |
| double_click | 6/ 8/ 32 | 1907 |
| long_press/repeat_press | 6/ 8/ 41 | 1903 |
|---------------------------+-------------+---------|
| Encoded4To2ButtonConfig | 22/ 27/ 55 | 1878 |
| Encoded8To3ButtonConfig | 54/ 66/ 90 | 1806 |
| EncodedButtonConfig | 42/ 54/ 81 | 1831 |
| LadderButtonConfig | 136/149/491 | 1682 |
+---------------------------+-------------+---------+
This library has Tier 1 support on the following boards:
- Arduino Nano (16 MHz ATmega328P)
- SparkFun Pro Micro (16 MHz ATmega32U4)
- SAMD21 M0 Mini (48 MHz ARM Cortex-M0+)
- STM32 Blue Pill (STM32F103C8, 72 MHz ARM Cortex-M3)
- NodeMCU 1.0 (ESP-12E module, 80MHz ESP8266)
- WeMos D1 Mini (ESP-12E module, 80 MHz ESP8266)
- ESP32 Dev Module (ESP-WROOM-32 module, 240MHz dual core Tensilica LX6)
- Teensy 3.2 (96 MHz ARM Cortex-M4)
Tier 2 support can be expected on the following boards, mostly because I don't test these as often:
- ATtiny85 (8 MHz ATtiny85)
- Arduino Pro Mini (16 MHz ATmega328P)
- Teensy LC (48 MHz ARM Cortex-M0+)
- Mini Mega 2560 (Arduino Mega 2560 compatible, 16 MHz ATmega2560)
The following boards are not officially supported, but AceButton may accidentally work on these:
- Any platform using the ArduinoCore-API
(https://github.com/arduino/ArduinoCore-api).
- For example, Nano Every, MKRZero, and Raspberry Pi Pico RP2040.
This library was developed and tested using:
- Arduino IDE 1.8.13
- Arduino CLI 0.14.0
- SpenceKonde ATTinyCore 1.5.2
- Arduino AVR Boards 1.8.3
- Arduino SAMD Boards 1.8.9
- SparkFun AVR Boards 1.1.13
- SparkFun SAMD Boards 1.8.3
- STM32duino 2.0.0
- ESP8266 Arduino Core 2.7.4
- ESP32 Arduino Core 1.0.6
- Teensyduino 1.53
It should work with PlatformIO but I have not tested it.
The library works on Linux or MacOS (using both g++ and clang++ compilers) using the EpoxyDuino emulation layer.
I use Ubuntu Linux 18.04 and 20.04 for most of my development.
There are numerous "button" libraries out there for the Arduino. Why write another one? I wanted to add a button to an addressable strip LED controller, which was being refreshed at 120 Hz. I had a number of requirements:
- the button needed to support a LongPress event, in addition to the simple Press and Release events
- the button code must not interfere with the LED refresh code which was updating the LEDs at 120 Hz
- well-tested, I didn't want to be hunting down random and obscure bugs
Since the LED refresh code needed to run while the button code was waiting for a "LongPress" delay, it seemed that the cleanest API for a button library would use an event handler callback mechanism. This reduced the number of candidate libraries to a handful. Of these, only a few of them supported a LongPress event. I did not find the remaining ones flexible enough for my button needs in the future. Finally, I knew that it was tricky to write correct code for debouncing and detecting various events (e.g. DoubleClick, LongPress, RepeatPress). I looked for a library that contained unit tests, and I found none.
I decided to write my own and use the opportunity to learn how to create and publish an Arduino library.
An Arduino UNO or Nano has 16 times more flash memory (32KB) than static memory (2KB), so the library is optimized to minimize the static memory usage. The AceButton library is not optimized to create a small program size (i.e. flash memory), or for small CPU cycles (i.e. high execution speed). I assumed that if you are seriously optimizing for program size or CPU cycles, you will probably want to write everything yourself from scratch.
That said, examples/MemoryBenchmark shows that the
library consumes between 970-2180 bytes of flash memory, and
AutoBenchmark shows that AceButton::check()
takes
between ~15 microseconds on a 16MHz ATmega328P chip and 2-3 microseconds on an
ESP32. Hopefully that is small enough and fast enough for the vast majority of
people.
With v1.9, I started using AceButton on an ATtiny85 which has only 8kB of flash
and 0.5 kB of static RAM. Flash memory consumption became more important and I
created the ButtonConfigFast1
, ButtonConfigFast2
, and ButtonConfigFast3
classes to decrease the flash memory consumption by using one of the
<digitalWriteFast.h>
3rd party libraries. See
Digital Write Fast for more info.
- Versions 1.0 to 1.0.6: Apache License 2.0
- Versions 1.1 and above: MIT License
I changed to the MIT License starting with version 1.1 because the MIT License is so simple to understand. I could not be sure that I understood what the Apache License 2.0 meant.
If you have any questions, comments, or feature requests for this library, please use the GitHub Discussions for this project. If you have a bug report, please file a ticket in GitHub Issues. Feature requests should go into Discussions first because they often have alternative solutions which are useful to remain visible, instead of disappearing from the default view of the Issue tracker after the ticket is closed.
Please refrain from emailing me directly unless the content is sensitive. The problem with email is that I cannot reference the email conversation when other people ask similar questions later.
Created by Brian T. Park ([email protected]).