| .. | ||
| .github/workflows | ||
| examples | ||
| test | ||
| .arduino-ci.yml | ||
| CountDown.cpp | ||
| CountDown.h | ||
| keywords.txt | ||
| library.json | ||
| library.properties | ||
| LICENSE | ||
| README.md | ||
CountDown
Arduino Library to implement a CountDown clock (in SW polling, no HW timer).
Description
The countdown library is a clock that counts down from a given time to zero. It does not call a function or so as the user is responsible to check the time remaining. Typically one checks the remaining time in every loop.
UNder the hood the function uses micros() or millis() which results in a maximum time of 4294 seconds in micros (1h10m) or about 49+ days when using millis.
For longer periods one could cascade countDown, so when one is finished the next one starts.
Interface
The main functions of the CountDown clock are:
- bool start(uint32_t ticks)
- bool start(uint8_t days, uint16_t hours, uint32_t minutes, uint32_t seconds)
- bool start(uint8_t days, uint16_t hours, uint32_t minutes)
- void stop()
- void cont() (continue is a C-Keyword)
- uint32_t remaining()
- bool isRunning()
These functions work straightforward.
Operation
The function start(days, hours, minutes, seconds) has changed its parameters type to minimize them, given that the total time may not exceed 2^32 milliseconds. This allows the user to call start() with e.g. four hundred minutes start(0, 0, 400, 0) or a million seconds start(0, 0, 0, 1000000) as parameter. The resolution is implicitly set to CountDown::SECONDS.
Since 0.2.4 the function start() will check if the parameters cause an overflow in the underlying math. If there is no overflow call to start() returns true. If there is an overflow it returns false
Total amount of time to countdown for CountDown::MICROS may not exceed 2^32 micros ~ 1 hour 10 minutes. Total amount of time to countdown for CountDown::MILLIS, CountDown::SECONDS and CountDown::MINUTES may not exceed 2^32 milliseconds ~49 days
The function start(days, hours, minutes) is new since 0.2.2. It also uses millis() under the hood. The resolution is implicitly set to CountDown::MINUTES.
| Call to start() | resolution | max time | comments |
|---|---|---|---|
| start(days, hours, minutes, seconds) | SECONDS = millis | 49+ days | |
| start(days, hours, minutes) | MINUTES = millis | 49+ days | |
| start(ticks) | MILLIS = millis | 49+ days | default |
| start(ticks) | MICROS = micros | ~70 min | use setResolution(CountDown::MICROS) |
| start(ticks) | SECONDS = millis | 49+ days | use setResolution(CountDown::SECONDS) |
| start(ticks) | MINUTES = millis | 49+ days | use setResolution(CountDown::MINUTES) |
The Countdown clock uses by default millis() to do the time keeping, although this can be changed runtime by setResolution(res). The parameter res can be:
- CountDown::MICROS // based upon micros()
- CountDown::MILLIS // default
- CountDown::SECONDS // based upon millis()
- CountDown::MINUTES // based upon millis()
Although possible one should not change the resolution of the CountDown clock while it is running as you mix up different timescales.
One can call start(...) at any time to reset the running clock to a new value. This allows to implement a sort of watchdog clock in which e.g. the user must press a button at least once per minute to show he is still awake.
Future
- incorporate a real time clock? or EEPROM to be reboot proof?
- examples with visualisations (e.g. hexadecimal countdown)
- Countdown based upon external pulses
- uint64_t version ==> CountDown64 class?