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BlockNot Arduino Library

This library enables you to create non-blocking timers using simple, common sense terms which simplifies the reading and writing of your code. It offers, among several things, convenient timer functionality, but most of all ... it gets you away from blocking methods - like delay() - as a means of managing events in your code.

Non-Blocking is the proper way to implement timing events in Arduino code and BlockNot makes it easy!

*** If you are noticing unwanted rapid succession triggering on high speed microcontrollers, READ THIS

Table of Contents

Quick Start

Here is an example of BlockNot's easiest and most common usage:

First, you crate the timer:

#include <BlockNot.h>   
BlockNot helloTimer(1300); //In Milliseconds    

OR optionally

#include <BlockNot.h>   
BlockNot helloTimer(15, SECONDS); //Whole Seconds timer    
BlockNot helloTimer(120000, MICROSECONDS); //Microseconds timer    

Then, you just test it to see if it triggered.

   if (helloTimer.TRIGGERED) {  
      Serial.println("Hello World!"); 
   } 

Every time the TRIGGERED call returns true, the timer is reset and it wont trigger again until the duration time has elapsed (all behaviors can be changed based on your needs).

That is all you need to start using BlockNot. Keep reading to learn about other features of the library.

Theory behind BlockNot

This is a traditional non-blockling timer:

long someDuration = 1300;  
long startTime = millis();  
if (millis() - startTime >= someDuration) {  
        //Code to run after someDuration has passed.
 }  

This does the same thing, only with much simpler code!

if (myTimer.TRIGGERED) {  
        //Code to run after timer has triggered.
 }  

The idea behind BlockNot is very simple. You create the timer, setting its duration when you declare it, then check on the timer in your looping code to see if it TRIGGERED. Or, you can check for other information such as how long until it will trigger, or how much time has passed since it last triggered or you can ask it what the current duration is, which might be useful in scenarios where you change the duration based on dynamic criteria.

For example, if you wanted to see if the timers duration has come to pass, but you don't want to reset the timer, you can use this method:

if (myTimer.triggered(NO_RESET)) {}  

OR, you can do it like this:

if (myTimer.HAS_TRIGGERED) {}  

They both do the same thing, but in terms of readability, the second example is the obvious choice. BlockNot has several easy to understand commands that make it very 'user-friendly' and make your code much more readable.

Here is a simple graph showing you how BlockNot timers work. What's important here is to realize that your code never stops executing while the timer is passing time.

How To Use BlockNot

The Trigger

BlockNot is all about the trigger event. When runners line up to start a race, it is a traditional practice for someone to stand next to the line and hold a gun in the air and pull the trigger when the race starts. That is the idea behind the TRIGGERED event in BlockNot. If your timer is set, for example, to 1300 milliseconds, it will return true when you call the TRIGGERED event on or after 1300 milliseconds have passed ... there are exceptions, however, as you will see which can be useful.

if (voltageReadTimer.TRIGGERED) {  
    readVoltage();
}  

One Time Trigger

I have personally found it quite handy in some scenarios, to be able to get a boolean true response after the timer has triggered, but only once, so that the code which executes after getting a true response only executes once and when the test comes up again in the loop, a response of false will be given until the timer has been manually reset. The false response can be changed to true if you desire, by running this method:

myTimer.setFirstTriggerResponse(true);

This kind of trigger is called FIRST_TRIGGER and you use it like this:

if (myTimer.FIRST_TRIGGER) { my code }  

That method will return true ONLY ONE TIME after the timer's duration has passed, but subsequent calls to that method will return false until you manually reset the timer like this:

myTimer.RESET;  

Why would you need to do that? There are countless scenarios where that would be immediately useful. I have used it with stepper motor projects where I want an idle stepper motor to be completely cut off from any voltage when it has been idle for a certain length of time ... lets say 25 seconds.

So first, we define the timer

BlockNot stepperSleepTimer (25, SECONDS);  

Then, we reset the timer every time we use the motor:

stepperSleepTimer.RESET;  

Then, in your loop, you would put something like this:

if (stepperSleepTimer.FIRST_TRIGGER) {  
     sleepStepper();
 }  

So that if the stepper hasn't moved in the last 25 seconds, it will be put to sleep and that sleep routine won't execute over and over again each time the loop encounters the check. Yet when the stepper is engaged again, the sleep timer is reset and when it becomes idle again for 25 seconds, it is put to sleep. This helps efficiency in your program, and it conserves valuable CPU time.

Last Trigger Duration

There can be times when you are collecting information about events using an interrupt pin and it becomes necessary to know how much time passed in the last data gathering interval.

myTimer.LAST_TRIGGER_DURATION

will give you the amount of time that passed when the last trigger was checked. Because it is possible to have checked for the trigger after the timers duration has passed and so you might need to know how much time actually did elapse and the lastTiggerDuration() method is how you get that information.

Triggered OnDuration

This topic is a little tricky to comprehend (myself included as I wrote this method), but I have done my best to explain it as simply as possible.

There might be times when it becomes necessary to respect a timers trigger in the context of its duration, so that when a timers trigger is checked, it then resets its startTime to a time that is relative to its duration rather than simply resetting to the current value of micros() or millis().

triggeredOnDuration() Does this with two optional results.

Default Behavior

Let's use a timer that is set to a duration of 500ms as our example.

You test it for TRIGGER by using either the macros or the method

myTimer.TRIGGERED_ON_DURATION
myTimer.TRIGGERED_ON_MARK
myTimer.triggeredOnDuration()

BlockNot views the timer as having rigid trigger marks that happen exactly 500ms apart. So if you check the timer - say 700ms after you start it, you will get a TRUE response and it will trigger again in 300ms instead of 500ms because BlockNot will set the startTime back to 500ms and not the current time of 700.

So lets say we are well into the passage of time, and you test for trigger at time index 2830 ... BlockNot will return TRUE and then set the startTime back to 2500 so it will trigger again at 3000.

The idea is that you can have a timer that will provide the ability to run code on a consistent pulse where each pulse happens exactly at every interval of time based on the timers duration, and you can have your code execute as close to those 'pulse marks' as possible.

OnDuration(ALL)

triggeredOnDuration(ALL) works exactly as triggeredOnDuration() EXCEPT that BlockNot will continue to return a TRUE result until every missed mark is accounted for.

You can test for TRIGGERED using these macros or the method

myTimer.TRIGGERED_ON_DURATION_ALL
myTimer.TRIGGERED_ALL
myTimer.triggeredOnDuration(ALL)

Continuing with our 500ms duration timer, if you test it at time index 1250 then again at time index 1300, you will get a TRUE response for both tests, since you missed the first mark at 500, but then tested after the second mark at 1000. If you tested again before 1500, you would get a FALSE response.

These graphs show you what will happen as time advances and you test for TRIGGERED using this method.

A green Test means you tested and got TRUE while red means you got FALSE.

This is how the standard TRIGGERED event responds:

This visualises how TRIGGERED_ON_DURATION / TRIGGERED_ON_MARK works.

Notice how you can get a TRUE response immediately before and immediately after a trigger event. BlockNot is giving you a TRUE response for the trigger that happened at time index 2500, then it gives a TRUE response for the trigger that happened at time index 3000. But when you test again before 3500, you will get a FALSE response.

Here is how TRIGGERED_ON_DURATION_ALL / TRIGGERED_ALL works.

Notice you got FOUR consecutive TRUE results in a row. This is because you missed three triggers , then you tested twice, then at a trigger point, then once again, and the 5th time you tested, your test happened before the next trigger and all of the missed trigger events had been accounted for, so you get a FALSE response.

A possible use case for the ALL trigger test would be when using a timer as a sync counter of sorts. And to explain that, I am going to use an extreme example that should illustrate the point... Lets say that you have a project that must automatically water plants at least six times every hour. It doesn't matter if the plants are watered every 10 minutes, or if they are watered once, then 15 minutes later, then again 5 minutes later etc., as long as they are watered six times every hour.

We would define this timer as follows:

BlockNot waterTimer = BlockNot(600, SECONDS); //10 minute duration

Let's also assume that your code is so busy doing other things, that it might not be able to check the trigger on that timer - possibly even after two full durations have passed. When you check the trigger using TRIGGERED_ALL, that will cause BlockNot to continue giving you a TRUE response until each missed trigger has been provided to you.

See the example sketch called DurationTrigger to see this method in action.

The Reset

Resetting a timer is critical to performing repeated events at the right intervals. However, there may be times when you don't want this behavior.

Resetting of a timer once it has triggered is the default behavior of BlockNot.

if (myTimer.TRIGGERED) { my code }  

Using TRIGGERED, the timer automatically resets, whereas if you do this:

if (myTimer.HAS_TRIGGERED) { my code }   

The startTime does not reset and that test will always come back true every time it is executed in your code, as long as the timer's duration has passed. The exception of course would be using the FIRST_TRIGGER method.

Global Reset

Sometimes, having the ability to reset all of your timers at the exact same time is handy. There are situations, for example, when you need things to happen in a specific timed order and to do so repeatedly. This is possible by creating your timers then simply calling one method that resets them all simultaneously.

You can reset all of your timers simultaneously by simply calling either the method or the macro:

resetAllTimers();
RESET_TIMERS;

When you call this method, it first captures the value of micros() or millis() then it assigns that value to the startTime of every instantiated timer so that they all reset at precisely the exact same time. And don't worry, if you have a peppered mix of timers each with different base units ( milliseconds, microseconds etc.) BlockNot will use either millis() or micros() based on each timers individual - currently assigned base unit.

It should be noted that even if you have your project divided into multiple code files, the resetAll method will reset all timers across all of your code ... It is global to your entire project.

Time Unit Options

Default

When you declare your timers without specifying the units, they will default to millisecond timers, because milliseconds are the most commonly used time units in Arduino programming.

Other Units

You can declare a timer to operate within any time unit you desire, as long as the time unit you desire is either SECONDS, MILLISECONDS or MICROSECONDS.

For example, when you only need second precision, you can declare your timer as a SECONDS timer. It can be much easier in terms of writing and reading your code, if you don't need milli or micro second precision. It's much simpler to use 23 than 23000 when you only need to know about 23 seconds.

You instantiate your timers with other units like this:

BlockNot myTimer(5, SECONDS);
BlockNot myTimer(14000, MICROSECONDS);

Under the hood, BlockNot calculates SECONDS and MILLISECONDS using the millis() method, where MICROSECOND timers use the micros() method.

BlockNot Assumptions

When a timer is declared as a SECONDS, MILLISECONDS, or MICROSECONDS timer, the unit you choose is referred to as the timers base units.

You MUST interact with your timer, in the base units you declared it as or in the base units you switch it to (discussed below).

When you read values from your timer, by default, you will always get back a value that is in the base units of the timer.

For example, these

BloclNot myTimer(50000, MICROSECONDS);

myTimer.GET_START_TIME;
myTimer.getStartTime();

will always return a value in MICROSECONDS.

And

BloclNot myTimer(50000, SECONDS);

myTimer.GET_START_TIME;
myTimer.getStartTime();

will always return a value in SECONDS.

It needs to be noted that in a SECONDS timer, the numbers that are returned when seeking a value, will ALWAYS be rounded DOWN. So if, for example, you have a SECONDS timer, and you request the value for the number of seconds remaining until the next trigger, and BlockNot calculates that value to be 8700 milliseconds. You will get 8 SECONDS back in response.

This shouldn't be a problem, because if you need fractional second accuracy, then use a millisecond timer.

Microseconds

MICROSECONDS are almost always used in situations when you need to reference time durations that are faster than a millisecond. Therefore, NEVER use a MICROSECONDS timer when you need to evaluate time in durations longer than an hour, because the Arduino rolls the micros() counter after roughly one hour (read discussion on rollover below) and BlockNot has no way of knowing how often that counter rolls over. It can and will calculate durations accurately when a rollover happens in between TRIGGERED events, but when more than one of these events happens in between TRIGGERED events, BlockNot will not be able to know about those rollovers and your results will be inaccurate.

Realistically, you should never use a MICROSECONDS timer if your event durations are always longer than one million microseconds, and certainly you should never use a MICROSECONDS timer for durations longer than an hour. If you need to track intervals of time that are longer than an hour, USE SECONDS OR MICROSECONDS!

Converting Units

Because program storage space is extremely valuable with microcontrollers, I decided to offer the convert method as opposed to writing methods and macros for every option available where values of interest might be needed. The convert method will convert from the units that your timer is declared in, to whichever DESIRED units are passed into the method.

The convert method uses this structure

unsigned long desiredValue = myTimer.convert(valueOfInterest, UNIT_DESIRED);
  • The number returned will always be an unsigned long.

  • valueOfInterest MUST be an unsigned long, or a long that is not negative

  • UNIT_DESIRED MUST be either SECONDS, MILLISECONDS or MICROSECONDS

For example, lets say that we have declared a timer as a MILLISECONDS timer, but we are interested in knowing how many SECONDS or MICROSECONDS remain until the timer triggers again. We can get those values in different units like this:

value = myTimer.convert(myTimer.TIME_TILL_TRIGGER, SECONDS);
value = myTimer.convert(myTimer.TIME_TILL_TRIGGER, MICROSECONDS);

The convert() method can be used to convert ANY value into whichever units you need, but realize that the value you pass into the method will be assumed to be in the timers base units.

Any of these methods can be passed into the convert() method to obtain their values in whichever unit you desire (desired units in this example were chosen randomly).

myTimer.convert(myTimer.getTimeUntilTrigger(), SECONDS)
myTimer.convert(myTimer.getNextTriggerTime(), MILLISECONDS)
myTimer.convert(myTimer.getStartTime(), SECONDS)
myTimer.convert(myTimer.getDuration(), MICROSECONDS)
myTimer.convert(myTimer.getTimeSinceLastReset(), MILLISECONDS)

Here is what each of these methods provides:

  • getTimeUntilTrigger() returns a value that is relative to the timer's duration. So if the duration is set to 1350ms, and it has been 500ms since it last triggered, the returned value will be 850ms
  • getNextTriggerTime() will return a value that is relative to the microcontrollers internal micros() or millis() value, which will be the timers current startTime PLUS the timer's duration
  • getStartTime() returns the value of the CPUs micros() or millis() method that was recorded as the timers current startTime
  • getDuration() Simply returns the duration that is currently set in the timer (the duration you assign when you create the timer, or the one that you changed it to after the fact)
  • getTimeSinceLastReset() returns a value that represents how much time has elapsed since the timer was last reset. It does not consider trigger events, but only the current startTime.

Changing Duration

When you need to change a timers' duration, use the setDuration(time) method. BlockNot assumes that the number you pass into the argument will be in the same units as the current baseUnit of the timer. However, if you wish to change the duration by passing in a value that is in different units, you can use setDuration(time, Unit) and BlockNot will convert that number into whatever its current baseUnit is.

For example, if you have a timer that is declared as a MILLISECONDS timer

BlockNot myTimer(2500);

And you want to change the duration to three seconds, you could do it in two ways:

myTimer.setDuration(3, SECONDS);
//OR
myTimer.switchTo(SECONDS);
myTimer.setDuration(3);

Using the first option will not change the baseUnit of the timer, so a MILLISECOND timer will remain as a MILLISECOND timer even though you changed the duration to 3 SECONDS.

Switching Base Units

If you need to switch the timers base units, you can do so like this:

myTimer.switchTo(MICROSECONDS);
myTimer.switchTo(MILLISECONDS);
myTimer.switchTo(SECONDS);

Once you have changed the base units, then obviously, values returned from methods will be returned in the new base unit, and values given to the timer will be assumed to be in the new base unit that you switched it to.

Using switchTo() is no different from originally declaring the timer in the base unit that you switch it to.

Start / Stop

You can stop a timer, then start it again as needed.

By default, the start() method DOES NOT reset a timer. Calling the method like this is like starting a stop watch, after it has been stopped. The stop watch does not reset the start time to 00:00, but rather it merely pauses the timer until you start it again. In like manner, calling stop() then start() merely pauses the timer, so that any time that passes between a stop() and a start() gets subtracted out ... and the timers startTime is changed so that the time that passed is added to the startTime so that you can pick up right where you left off.

You can override this behavior and have the timer RESET when you start it, by using either of these options:

myTimer.START_RESET;
myTimer.start(WITH_RESET);

When a timer is in a stopped state, any call to the timer that would return a boolean value will ALWAYS return false. And when you query the timer where a numeric value is supposed to be returned, it will return a ZERO by default, although you can change what number it returns for those methods, as long as the number you set is a positive number (BlockNot does not ever deal with negative numbers, since time in our universe always moves forward).

I've used STOP and START when stepping motors, where the delay between steps is defined in a MICROSECONDS timer (where the duration is constantly changing based on the value of RPMs) but when the RPMs are set to 0, then I simply STOP the timer and stepping will not occur. When RPMs are above 0, then I START the timer and stepping resumes.

These methods will ALWAYS return false when a timer is stopped (for macro calls see the Macro section of this document):

  • triggered()
  • notTriggered()
  • firstTrigger()

These methods will return a ZERO by default when a timer is stopped (or whichever value you set as the return).

  • getDuration()
  • getTimeUntilTrigger()
  • timeSinceLastReset()

Return Values on Stopped Timers

You can declare the return value when you create the timer (see the constructors in the .h file), OR, once you create your timer, you simply set the value using this method:

setStoppedReturnValue(8675309);

What matters in this situation is that the default return value for any stopped timer is always ZERO unless you change it, and the number you assign, once again, CANNOT BE NEGATIVE

You can start and stop a timer using these methods / macros.

myTimer.START;  
myTimer.STOP;  

And you can find out if the timer is running or not using either of these calls:

if (myTimer.ISRUNNING) { my code; }  
if (myTimer.ISSTARTED) { my code; }  
if (myTimer.ISSTOPPED) { my code; }  

You can also flip the state of the timer (if stopped, it will start; if started, it will stop):

myTimer.TOGGLE;  

Why would you want to just change the state with one line of code? Perhaps you have a toggle button that will toggle a timer to be started or stopped ... you can assign the one command to the button and everything is handled.

#define BUTTON_PRESSED digitalRead(BUTTON) == LOW

pinMode(BUTTON, INPUT_PULLUP);

if (BUTTON_PRESSED) {  
   myTimer.TOGGLE;
 }  

Summary

Well, that's BlockNot in a nutshell.

Simple, right?

BlockNot is a library intended to make the employment of non-blocking timers easy, intuitive, natural and obvious. It can be engaged with simple single word macros or by calling the methods directly.

There are more methods that allow you to affect change on your timers after instantiation and also methods to get info about your timers. You can change the duration of an existing timer in three different ways, you can reset the timer, or you can even find out how much time is left before the trigger event occurs, or find out how much time has passed since the timer last triggered.

Examples

There are currently nine examples in the library.

Advanced Auto Flashers

This sketch was one I wrote recently that was for a friend who wanted to put large LEDs on the back of his 5th wheel so that people behind him received much better feedback depending on whether he hits his brakes, uses his turn signals or uses the hazard lights. It's a fairly good example of using BlockNot timers to achieve compartmentalized functions in code that runs continuously and never stops. The code was written for a Raspberry Pi Pico.

BlockNot Blink

This sketch does the same thing as the famous blink sketch, only it does it with BlockNot elegance and style.

BlockNot Blink Party

If you have a nano or an uno or equivalent laying around and four LEDs and some resistors, connect them to pins 9 - 12 and run this sketch. You will immediately see the benefit of non-blocking timers. You could never write a sketch that could do the same thing using the delay() command. It would be impossible.

Non-Blocking MATTERS!

Millis Rollover Test

This sketch was added to demonstrate that BlockNot can and does properly calculate timer durations even when millis() rolls over. The sketch has comments at the top that fully explain what it does, and how you can adjust the time until millis() rolls using the terminal. See the discussion further down on millis() and micros() rollover.

Button Debounce

Learn how to debounce a button without using delay()

Duration Trigger

Read the section above to get an idea of what TRIGGERED_ON_DURATION does, then load this example up and play around with it. You can pause the loop from Terminal monitor by typing in p and hitting enter. Then if you wait for several durations to pass, then un-pause the loop, you will see hoe BlockNot handles that feature.

On With Off Timers

This example shows you how to use on and off timers to control anything that you need to have on for a certain length of time and also off for a certain length of time.

The example specifically blinks two LEDs such that they will always be in sync every 6 seconds ... by this pattern:

Reset All

This sketch shows how all BlockNot timers defined in your sketch can be reset with a single line of code, rather than having to call reset() for each and every one separately. This comes in handy when all timers need to be reset at once, e.g. after the system clock has been adjusted from an external source (NTP or RTC, for example).

Timers Rules

This sketch has SIX timers created and running at the same time. There are various things happening at the trigger event of each timer. The expected behavior is explained in the out Strings to Serial. Read them, then let it run for a minute or so then stop your Serial monitor and look at the output. You should be able to look at the number of milliseconds that is given in each output, and compare the differences with the expected behavior and see that everything runs as it is expected to run.

For example, when LiteTimer triggers, you should soon after that see the output from stopAfterThreeTimer. When you look at the number of milliseconds in each of their outputs, you can see that indeed it does trigger three seconds after being reset, but then it does not re-trigger until after it is reset again.

  • Thanks to @SteveRMann for kick-starting this example and working with me on fine-tuning it.

These examples barely scratch the surface of what you can accomplish with BlockNot.

Library

Methods

Below you will find the name of each method in the library and any arguments that it accepts. Below that list, you will find the names of the macros that are connected to each method along with the arguments that a given macro may or may not pass to the method. The macros are key to making your code simple.

** For any method call that resets a timer by default, the resetting behavior can be overridden by passing NO_RESET into the methods argument, the exception to this is the triggeredOnDuration() method, which exists because of the way it resets your timer, so overriding reset would make the method useless.

  • setDuration() - Override the current timer duration and set it to a new value. This also resets the timer. If you need the timer to NOT reset, then pass arguments like this (newDuration, NO_RESET);
  • addTime() - Adds the time you pass into the argument to the current duration value. This does NOT reset the timer. To also reset the timer, call the method like this addTime(newTime, WITH_RESET);
  • takeTime() - The opposite effect of addTime(), same deal if you want to also reset the timer.
  • triggered() - Returns true if the duration time has passed. Also resets the timer to the current micros() or millis() (override by passing NO_RESET as an argument).
  • triggeredOnDuration() - See section above entitled Triggered On Duration for complete discussion.
  • notTriggered() - Returns true if the trigger event has not happened yet.
  • firstTrigger() - Returns true only once and only after the timer has triggered - can be modified with setFirstTriggerResponse(bool).
  • getNextTriggerTime() - Returns an unsigned long of the next time that the timer will trigger. If it has triggered, it will return 0.
  • getTimeUntilTrigger() - Returns an unsigned long with the number of microseconds remaining until the trigger event happens, converted to the timers base units.
  • getStartTime() - Returns an unsigned long, The value of micros() or millis() that was recorded at the last reset of the timer, converted to the timers currently assigned base unit.
  • getDuration() - Returns an unsigned long, the duration that is currently set in the timer.
  • getUnits() - Returns a String of the assigned base units of the timer; Seconds, Milliseconds or Microseconds.
  • getTimeSinceLastReset() - Returns an unsigned long indicating how much time has passed since the timer was last reset or instantiated. Response will be in the base units of the timer.
  • setStoppedReturnValue() - Lets you set the value returned for those methods that return numbers, when the timer is stopped.
  • start() - starts the timer (timers are started by default when you create them).
  • stop() - stops the timer.
  • isRunning() - returns true if the timer is not stopped.
  • isStopped() - returns true if the timer is stopped.
  • toggle() - Toggles the start and stopped state so that you only need to call this one method - like in a push button toggle situation.
  • switchTo() - Change the timer from whichever base unit it currently is, over to SECONDS, MILLISECONDS or MICROSECONDS.
  • reset() - Sets the start time of the timer to the current micros() or millis depending on its currently assigned base unit.
  • resetAllTimers() - loops through all timers that you created and resets startTime to micros() or millis() depending on the timers currently assigned base unit, which is recorded once and applied to all timers, so they will all have the exact same startTime. See Memory section for further discussion.

Macros

Here are the macro terms and the methods that they call along with any arguments they pass into the method:

Macro Method
TIME_PASSED getTimeSinceLastReset()
TIME_SINCE_RESET getTimeSinceLastReset()
ELAPSED getTimeSinceLastReset()
TIME_TILL_TRIGGER getTimeUntilTrigger()
TIME_REMAINING getTimeUntilTrigger()
REMAINING getTimeUntilTrigger()
DURATION getDuration()
GET_UNITS getUnits()
GET_START_TIME getStartTime()
DONE triggered()
TRIGGERED triggered()
LAST_TRIGGER_DURATION lastTriggerDuration()
HAS_TRIGGERED triggered(NO_RESET)
TRIGGERED_ON_DURATION triggeredOnDuration()
TRIGGERED_ON_MARK triggeredOnDuration()
TRIGGERED_ON_DURATION_ALL triggeredOnDuration(ALL)
TRIGGERED_ALL triggeredOnDuration(ALL)
NOT_DONE notTriggered()
NOT_TRIGGERED notTriggered()
FIRST_TRIGGER firstTrigger()
RESET reset()
RESET_TIMERS resetAllTimers()
START start()
START_RESET start(WITH_RESET)
STOP stop()
ISSTARTED isRunning()
ISRUNNING isRunning()
ISSTOPPED isStopped()
TOGGLE toggle()

Constants

  • WITH_RESET - boolean true
  • NO_RESET - boolean false
  • ALL - boolean true
  • SECONDS
  • MILLISECONDS
  • MICROSECONDS
  • NO_GLOBAL_RESET
  • GLOBAL_RESET
  • RUNNING
  • STOPPED (Pass this into a constructor to create a timer in a STOPPED state)

If you can think of MACRO names that would make the reading and writing of you code more natural and you think it would be a benefit to BlockNot, PLEASE either submit a pull request or shoot me an email so that we can all work together to make this library the best that it can possibly be.

Also, you can, of course create your own macros within your code. So, for example, let's say that you wanted a macro that overrides the default reset behavior in the setDuration() method, which by default, will change the duration of the timer to your new value and will also reset the timer. But lets say you want to change the duration WITHOUT resting the timer and you wanted that to be done with a word that makes more sense to you.

#define QUICK_CHANGE(value) myTimer.setDuration(value, false)  
  
QUICK_CHANGE(3200);  

The only difference here, is that you cannot make a macro that applies universally to all of your timers. You would need to make one macro for each timer you have created. This is why it is better to submit a pull request or contact me with your ideas, so that all of us who use BlockNot can benefit through continual improvement of the library.

Discussion

Memory

I have compiled BlockNot in a variety of scenarios. The only difference between each specific scenario is that I would use traditional methods of implementing non-blocking timers, vs using BlockNot. In some scenarios, BlockNot would cause the sketch to compile using less memory and in some scenarios, it would use a little more memory. Obviously your situation will be different depending on the size of your project, other libraries used etc.

If you're really struggling for memory space, try creating your timers using the manual method just to see if it makes a difference or not using BlockNot.

In the interest of squeezing as much program space as possible, I have added the ability to disable BockNot's global reset option, because it, by default, maintains an array of all instantiations of BlockNot which consumes a little extra memory and if you don't need that feature and are hurting for memory space, then you can disable it by passing NO_GLOBAL_RESET as the last argument into your first timer (You only need to pass that argument ONCE and it will remain disabled for all timers created after that).

Examples of how to disable the feature:

BlockNot myTimer(3800, NO_GLOBAL_RESET);
BlockNot myTimer(15, SECONDS, NO_GLOBAL_RESET);

OR, you can optionally define some timers that are affected by the global reset method, then issue the NO_GLOBAL argument into the next timer you create and that timer, and every timer created after it will not be included in the global reset option.

BlockNot timer1(1350);
BlockNot timer2(5,SECONDS);
BlockNot timer3(2670,NO_GLOBAL_RESET)
BlockNot timer4(3460); //not included in global reset

Rollover

I've been contacted by a few people who have expressed concern with possible problems in timing when the Arduino millis() or micros() counter rolls over (millis() at approximately 50 days and micros() at around 70 minutes) after power up.

First and foremost, DON'T USE MICROSECOND TIMERS WHEN YOU CAN USE MILLISECONDS INSTEAD

The whole issue about rollover is not a concern at all, because of the way that BlockNot uses micros() and millis(), your timers will still calculate properly even if the micros() or millis() value rolls over in the duration of a timer. I've tested BlockNot using simulated values to artificially create a rollover scenario and I can tell you that it indeed works properly through a rollover.

The reason it works has to do with the way CPUs handle binary numbers where there is no possibilty of the number being negative, and this article can explain it in detail if you're interested.

I have added an example sketch called MillisRolloverTest.ino that will demonstrate how well BlockNot calculates timer durations even through millis() rollovers, by artifically inflating the value of millis() and calculating the time difference between trigger events. There is more discussion in that sketch.

Thread Safety

With the introduction of cost effective multi-core microcontrollers, more and more people will be writing code where they take advantage of having more than one core in the CPU. And currently, the way that most microcontrollers implement the use of another core is by adding a separate code thread where the code for that core runs in a different thread.

One of the major problems with multi-threading applications is when the code from different threads tries to change the value of a global scoped variable simultaneously.

And where BlockNot is concerned, that could be an issue if you make references to a single timer from different threads, because, for example, when you check for TRIGGERED, and the return value is true, BlockNot updates a variable that resets the startTime of the timer so that TRIGGERED will only return true after the next duration time has passed.

I have changed the declaration of the relevant variables to be volatile variables, which can help situations where a change might be happening at the same instant in time. But the issue is more complex than that, so simply declaring variables as volatile by no means, makes BlockNot thread safe.

If you find yourself in a situation where you need to access or engage a timer from two different threads, what is most important is that only one thread make any calls to the timer that cause changes to the timers variables. This includes the TRIGGERED method. There is a way to accomplish the modification of a timer from two different threads, by utilizing a global variable where only one thread writes to it and the other thread reads from it.

Consider this example. Specifically look at the adjustTimer() method and the core1Entry method which is what is executing in the other core - or is what is running on the other thread - however you want to look at it (6 of one, half-dozen the other)

What is important to see here is that one thread is making changes to timerDelay while the other thread is taking that value and passing it into the timers setDuration method. That same thread is also making calls to TRIGGERED which leaves only that thread as the thread causing changes to the timers variables.

#include <BlockNot.h>

BlockNot stepperTimer(1, MICROSECONDS);
unsigned long timerDelay = 0;


void stepStepper() {
    digitalWrite(STEP, HIGH);
    delayMicroseconds(3);
    digitalWrite(STEP, LOW);
    delayMicroseconds(2);
}


[[noreturn]] void core1Entry() {
    static unsigned long lastTimerDelay = 0;
    while (true) {
        if(lastTimerDelay != timerDelay) {
            stepperTimer.setDuration(timerDelay, NO_RESET);
            lastTimerDelay = timerDelay;
        }
        if (stepperTimer.TRIGGERED)
            stepStepper();
    }
}

void adjustTimer() {
    long potValue = analogRead(POT_PIN);
    timerDelay = map(potValue, 0, 1024, 5000, 25);
}

void setup() {
    multicore_launch_core1(core1Entry);
}

void loop() {
    adjustTimer();
}

Even though BlockNot is not "thread-safe" you can still use it in multi-threaded environments if you simply make sure that only one thread will ever be causing changes to happen in the timer itself.

Triggering Too Fast With High Speed Microcontrollers

If you're noticing that some timers seem to trigger immediately after a trigger or a reset and you're running on a high speec microcontroller like a Pi Pico, you can enable a feature called speedComp() and pass in an amount of time for a delay during each reset. When I noticed the problem, I had in my loop, a switch statement that would run each time the timer triggered, and I had three cases in the switch. In this instance, each case that hit would set the next trigger to run the next case. Each case displayed something different on an OLED scree. However, I was noticing that the information was not being shown in the right order but instead I would see a quick flash of something then it would go to the next case after the one that was supposed to be next.

What fixed it for me was adding a 5ms delay after each triggering of the timer, so I added this feature, and you can use it like this:

myTimer.speedComp(5);

Put that in your setup() code as it only needs to be executed one time. That will automatically implement a delay (of 5 milliseconds in this example) every time the timer is reset. And the timer is automatically reset every time it triggers by default.

If you need to disable this feature:

myTimer.disableSpeedComp();

Version Update Notes

2.3.0

  • Added the speedComp() feature to compensate for unwanted rapid succession triggers when using a high speed microcontroller such as a Raspberry Pi Pico. READ THIS for more information.

2.2.0

  • Added the setFirstTriggerResponse(bool) method to provide an option for the response to firstTrigger()

2.1.5

  • Added the Advanced Auto Flashers example and updated the README.

2.1.4

  • Minor code changes per PR #19.

2.1.3

  • Changed firstTrigger() so that it does not run any calculations after it has triggered making subsequent calls more efficient.

2.1.2

  • Bug Fix

2.1.1

  • VERY MINOR change, I simply renamed the public enums to avoid conflicts with other libraries.

2.1.0

2.0.7

  • Changed declaration of some variables in order to assist in "thread-safety". Please See discussion in Thread Safety.

2.0.6

  • Added constructors that allow creating timers in a STOPPED state. Look at the constructors in BlockNot.h to see which arguments you can use when creating a new timer.
  • Added setDuration(unsigned long time, Unit inUnits) - this allows you to set a new duration using any units you want to use, WITHOUT changing the timers current base units. Read Changing Duration for more details.
  • Added the option of starting a timer while simultaneously resetting it. And also changed the stop and start methods so that the timer acts in similar fassion to a stop watch. Read the Start / Stop section for more details.

2.0.5

  • Adjusted the way in which BlockNot handles the millis offset.
  • Added setMicrosOffset(unsigned long) for the testing of micros() rollovers.

2.0.3

  • Added undocumented methods to facilitate testing of millis() rollover.
  • Added sketch to demonstrate how BlockNot works through millis() rollover.

2.0.0

  • Upgraded the entire library so that it can accommodate all time units down to microseconds. You can now use BlockNot as a SECONDS, MILLISECONDS or MICROSECONDS timer. An upgrade worthy of being labeled - 2.0

1.8.5

  • Added TRIGGERED_ALL and TRIGGERED_ON_MARK macros.
  • Completely re-wrote the triggeredOnDuration section of this README to condense the verbiage and simplify the concept. Also changed the graphs used to explain it so that they are much easier to understand.
  • Added the Millis() Rollover section to this README

1.8.4

  • Changed STARTED, RUNNING and STOPPED to ISSTARTED, ISRUNNING and ISSTOPPED to avoid conflict with some libraries.

1.8.3

  • small bug fixes

1.8.2

  • This is HOPEFULLY the final re-working of the code for a while.
  • Moved the Global Reset option back to being the default behavior, with having the ability to disable it as might be needed in rare cases when you need to squeeze as much program memory as you can. See the section above entitled MEMORY
  • Most changes in this release were "under the hood" changes, with some public methods undergoing minor changes. This README has been properly updated to describe any changes accurately.

1.8.1

  • In order to squeeze as much memory as possible out of the microcontroller, the resetAllTimers method will no longer be default behavior. Read the section above concerning its use.
  • Added timeTillTrigger() method and TIME_TILL_TRIGGER macro ... they return a long that is the number of milliseconds that must transpire before the timer triggers again.
  • Removed code that was intended to check for a millis() rollover which had some extra math in there that turned out to be completely unnecessary. BlockNot always was compliant with millis() rollover since the binary math that goes on under the hood makes the use of special code completely unnecessary.
  • Cleaned out ambiguous and unnecessarily redundant macros... lean and mean is how we want to move forward.
  • Renamed some private methods to keep them consistent with their purpose.

1.8.0

  • MAJOR re-structuring of the library, breaking it up into a header and a code file as should have been done from the beginning. There was a violation of the One Definition Rule which has been solved with this update. Library should now compile in any standard C++ scenario. Thank you @dpetican for pointing this out.

1.7.4

  • Fixed a problem with the way that triggeredOnDuration was being calculated. It is now correct, and it also factors in any millis() rollover.

1.7.3

  • Minor update
    • Now compatible with millis() value rollover back to zero every 49 days.

1.7.2

  • Minor update
    • Added start() method.
    • Added stop() method.
    • Added START and STOP Macros.
    • Removed restrictions preventing changes to a timer when it is stopped (disabled). Changes made to a stopped timer will now work.

1.7.1

  • Minor code enhancements that improves efficiency thanks to @bizprof

1.7.0

  • Updated version to 1.7 - It just made sense to do a full step since the latest re-write, which includes cosmetic code changes as well as normalizing repetitive code, has been fairly substantial and it includes the new resetAllTimers() (RESET_TIMERS) method with its bug fixes.
  • Bug Fix - Fixed bug where invoking resetAllTimers() was causing an accumulated time drift fot all timers.
  • triggeredOnDuration() - method added so that when this method is called, the timer is reset by startTime + duration instead of using the current millis() value. This helps guarantee that the timer will only trigger exactly by the duration that you have set for the timer. That way, if you call a test for the timer being triggered and the time that you do the test is some time after the timer actually triggered, then it's new startTime will not include that extra time burned between the actual trigger time and the time when you called the test.

    This will help you implement timers that trigger more accurately as long as your delays between the timer triggering and the time you test for the trigger are not consistently lapsed or else you will eventually run into the problem where the trigger will happen twice in a row ... run through the logic and think it through before you use this method.

    The macro for calling this method is myTimer.TRIGGERED_ON_DURATION

1.6.7

  • Bug Fix - Fixed bug where declaring the timer with the time duration alone would not compile.

1.6.6

  • Reset ALL timers with a single command - resetAllTimers(); OR RESET_TIMERS;
    See the discussion above in the documentation for more details.
    Thank you @bizprof for contributing this feature to the project.

1.6.5

  • Added SECONDS Mode - Explained in this README (scroll up)

Suggestions

I welcome any and all suggestions for changes or improvements. You can either open an issue, or code the change yourself and create a pull request. This library is for all of us and making it the best it can be is important!

You can also email me
[email protected]

Thank you for your interest in BlockNot. I hope you find it as invaluable in your projects as I have in mine.

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BlockNot is a library that creates non-blocking timers with simplicity.

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