This is a simple menu system written in micropython. It uses a switch, a rotary encoder and an OLED display.
It was developed on a Raspberry Pi Pico but also runs on an ESP32 and ESP8266.
The prototype used a little 128 * 64 pixel SSD1306 based OLED.
It could an be adapted to other displays using micropython's framebuffer or even to a very basic like a one-line display like a liquid crystal display.
The rotary encoder I used has a switch on the shaft, which is used as the click button.
The Rotaryirq library for an ESP32 worked perfectly on Raspi Pico and the display used the library SSD1306I2c.py
When the Pico is started the root menu is shown and menuitems are actioned when the switch is clicked.
Any number of subitems can be shown.
Possible menu actions include running a Python funciton, entering an integer by twiddling the encoder and entering a string.
Since some functions can be slow or can block, the menu runs within an asyncio loop.
For rotary encoder. https://github.com/miketeachman/micropython-rotary
For OLED display: https://github.com/micropython/micropython/blob/master/drivers/display/ssd1306.py
Any display driver that depends on the module framebuf should work out of the box. It would be simple to adapt the display function for a single or two line dislay like an LCD.
I have written my library with a minimal "hardware abstration layer" in case you want to use other libraries.
WARNING - STILL BEING DEVELOPED. Some of the information below may not immediately match the actual library code.
Menus are defined as a list of menu-items. Submenus are really the same as menus. Each menu item is defined as a pair of values:
- A Caption (string)
- An action function (a python function with NO parameters)
Example of a main menu and two submenus called trees and patterns.
trees = wrap_menu( [('gum',wizard),('ti-tree',info),('red-gum count',get_integer),('willow',treesize),('Back!',back)])
patterns = wrap_menu( [('Chaser',yellow),('Red',red),('Blue',blue),('Rainbow',rainbow),('Back!',back)])
main_menu = wrap_menu( [('Patterns',patterns),('trees',trees),('Brightness',brightness)])
Here we have defined three menus, 'trees', 'patterns' and 'main_menu'.
Note that the menu caption needs quotes (because it is a string), but the function does not because it is just the name of a function.
To transform our list into a function we pass it to another function called 'wrap_menu'.
Note that our wrapped menu becomes a function, so it can be the function that is called from a menuitem. In this way we get sub-menus.
Menu functions must be defined before they are used. The root menu should be the last to be defined. (Later versions may address this by allowing an action function to be defined as a string which is turned into a function on a second pass).
There are three predefined functions to get information:
- get_integer
- get_selection
- wizard
This allows us to set a number by twiddling the shaft of the encoder. The number is entered by clicking the switch.
The result is stored in a global dictionary called data. The key is set by a field parameter.
sethours = get_integer(field = 'hour', low_v=1,high_v=24,increment=1,caption='Hours',field='hour')
Later the value can be retrieved from the global dictionary data as shown in the example below:
if data['hour'] = 10:
pass
#Then do something
The value from the encoder ranges from low to high. It goes up or down by one each time we turn the encoder by one click.
Sometimes the desired value is a relatively high number, say 0-100 for percentages.
Doing 100 clicks can be tedious if we do not really need that degree of precision so there is an option for the encoder value to be multiplied by Increment when it is displayed.
In this way, the display will have increment of 10 for instance, we can go from 0 to 100 with 10 clicks.
Note that the stored value is still the raw value.
For instance, with an increment of 10 the display may show 50 but the stored value will be 5.
The selection function lets us get a string value from a list of values. The list is similar to a menu's list but also has a field parameter so it can be retrieved from the global menu_data dictionary.
colour1 = selection('colour1',['RED',('Green','GREEN'),('Blue','BLUE'),('Yellow','YELLOW'),('WHITE','white')])
The name displayed is the first value in the tuple and the value returned is the second element of the tuple.
There is an option to just provide a string (say "RED"). In this case the string value is exanded to a tuple ('RED','RED') behind the scenes.
As we turn the shaft the name of the various colours are scrolled, in the same way as a menu.
When we click the shaft value string is stored in the global dictionary and we return to the parent menu.
Default values for selection and get_integer
A selection or get_integer is initialised to the value already in the dictionary,
if a value exists for that field, otherwise the initial value is zero or an empty .
This way we can get a default value by storing values in the dictionary before starting the program and we can revisit the selection to change values.
In small microprocessor systems we often want to enter a series of numbers.
For instance we may want to set hours, minutes and seconds for a clock or day, month year to set the date.
The wizard calls a series of functions in sequence, usually get_integer. A wizard is defined similarly to a menu.
timewizard = wizard([("Hours",sethours),("Minutes",setminutes),("Seconds",setseconds)])
In this example, the wizard will gather hours, minutes and seconds in that order, then return. The wizard list looks like the menu list but in fact the caption part is ignored ( because a caption has to be provided to get_integer.)
The info function just displays a screen of text which will be shown when you click its menuitem.
Any click or scroll with clear the display (back to the parent menu).
You can provide the text as a simple string but you can also provide a function that returns a string. This would allow you, for instance, to display the current time.
Examples of these alternatives are show below:
showtime = info('I dont have a clock')
showtime = info(my_gettime_function)
# don't use brackets on the function name
An integer or a string is returned by the functions get_integer and selection. Both of these functions have a parameter called field.
The fields is used as the key to store the value in a global dictionary menu_data.
Since the data dictionary is global it can accessed by other functions.
These functions are provided as a form of hardware abstraction in case you want to use different libraries from SSD1306_i2c and rotary-irq library (which I think is probably unlikely)
set_encoder(minimum_value, maximum_value,increment)
setencoder sets the rotary encoder so that value ranges between the maximum and minimum value inclusive. It increments on clockwise clicks and decrements on anti-clockwise clicks. It wraps over to minimum after click maximum and vice versa. This is the standard behaviour of the library rotary_irq.
Calls rotary_irq.setencoder()
Setencoder is provider as a function as a form of hardware abstraction in case you use a different rotary encoder library.
get_value()
Returns the encoder value as an integer.
Same as rotary_irq.encoder.value()
display(text)
Display lines of text on the display device. Up to 4 lines of text are allowed.
back()
Clicking goes forward in a menu and scrolling goes up and down but we need a way to go back.
This is achieved by calling the back function as a menu action. (see menu examples).
If we had a way to provide more events than simple clicking and scrolling we could use one of these events to go back.
Possible sources for such an event would be another button or using long push or double click on a single button.
While easy to implement, this has not been done since the current system seems quite intuitive.
make_task(coroutine)
This simple turns a co-routine into a task and stores the task in a global variable called task. Its main use is to hide the global.
Stop()
This cancels the global task above. This way we can make and stop tasks without worrying about global declarations. For instance if we have a rolling rainbow display on neopixels this should be run as a task, otherwise it will block the menu. We can make the task by passing our function or more precisely our co-routine to make_task(). If we want to run a different pattern we would stop the current pattern by calling stop().
There are several considerations in writing action functions.
Simplest
The simplest action function is just a normal python function with no parameters.
def showblueneopixels():
make_strip_blue()
This will work as a menu function. The menu will be unchanged, which is usually fine, especially if your function is small and quick.
An action function with parameters.
def showpixels(colour):
make_strip(color)
#There are two ways to convert this into a function with no parameters
def showpixels(color = 'blue'):
make_strip(color)
# calling showpixels() with no parameters will make the strip blue
def wrap_show_pixels():
color = 'blue'
def show_pixels(color):
make_strip(color)
return show_pixels
# calling wrap_show_pixels() with no parameters will make the strip blue
Writing a co-routine or multiasking.
A long running action on your microprocessor could block the menu system.
To avoid this the menu system supports co-operative multitasking using uasyncio.
There are several tutorials about multitasking with asyncio. Peter Hinchs tutorial is a particularly good one but gets moderately advanced. https://github.com/peterhinch/micropython-async/blob/master/v3/docs/TUTORIAL.md
**HOW TO TURN A FUNCTION INTO A CO-ROUTINE AND THEN A TASK ** I will assume that our program is long running because it has a loop. This is usually the case.
-
Import uasyncio as asyncio to make the async functions available.
-
put async before the def part of the function.
-
Put "await asyncio.sleep(0)" somewhere in the loop so it is called frequently. This makes our function play nicely with others, including the main menu.
-
Turn the co-routine into a task. This also starts it running, so we dont have to await it. Make_task(co-routine ) is provided as a utility.
-
cancel the task when we want our loop to stop. Stop() is provided as a utility.
Example:
import uasyncio as aysncio
from encodermenu import make_task, stop
# Define this function in the body of the program or (better) locally in an imported action module.
# This is the function that actually does the work.
async def worker_loopy_function(): #This makes it a co-routine
do_something()
await asyncio.sleep(0) #This makes it play nicely with others (including our menu)
#In our action function
def my_action_function():
stop() # stop any previously running tasks
make_task(worker_loopy_function) # this will make a task and run it
#note there are no brackets on our worker_loopy_function
- The system runs a bit like a normal event driven GUI.
- There is a event loop that polls the switch and the encoder.
- If the switch is pressed or the value of the encoder changes then an on_click or on_scroll event is called.
- Events are handled by an object, which can be a Menu, GetInteger, Selection, Info, Wizard and so on.
- The object currently handling events is a global variable called current.
- We change menus and entry screens etc by changing the current object.
- The convenience function back() pops the parent object off the stack and makes it current
- The main loop runs as an asyncio task so it does not block. Any function called within the menu system is also running within the asyncio loop so it can be a task or routine.
- A convenience function make_task stores the task in a global variable called task.
- A convenience function called stop can cancels the running task. (Note: This simple system will only handle one task. You can run more tasks, but you will have to manange them yourself).
You may have noticed that we can go down our menu tree but we cant go back. To get around this a back() function has been provided which is called like any other menu-item action. An alternative would be to provide a back button for a separate event. Another alternative would be to get some extra events off our single button (like long-press or double click)
The menu uses uasyncio which has a good primitives libary from Peter Hinch that allows us to easily program for long presses or double clicks. I may have a look at this later but I think the current system works pretty well.
We note that a menuitem is defined as tuple composed of a string menu item caption and an action that is performed if the menu is clicked, like so ('Caption1', action1). A menu is a list of menu-items. (Note - we could use either lists or tuples or some other iterative - it does not really matter-but lists and tuples look nice).
After we have provided a list of menu-items we have to wrap the list up into a function and we do this by using the wrap function. This means that both actions and submenus are handled the same way in our system. A submenu is simply an action that installs a new menu.