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Mechy

This is a mechanical keyboard library, in the same spirit as QMK but it doesn't share any code with that project. Only supports the Atmega32u4 for now, but support for other microcontrollers was in mind. As other boards become supported I'll make sure to list them here and include examples for them.

Mechy is designed around C++ Plugin classes, and included in the main bundle are a bunch of plugins. I tried to make Mechy focused on being well designed, but it's also compact and, I think, more intuitive for new programmers than TMK/QMK.

Btw I'll make lots of comparisons to QMK here and I'll try not to disparage it. It's a fantastic tool, and is responsible for the rise in interest in mechanical keyboards. I have to make the comparisons because it's the only other keyboard firmware tool that I'm familiar with. I found it a bit clunky and I couldn't get the split code to work on my BFO-9000, so I started this project.

Mechy is built using Arduino but this might change. Arduino does unfortunate things in their USB/HID code (the TX/RXLED on/off "feature") that prevents it from working with some boards, like the XD75. So I'd like to transition away from Arduino and rely instead on a Makefile/CLI. I could use some help on that! I've already ported all the pinMode/digitalRead/digitalWrite code (see Wiring.h/cpp) so that ALL the I/O ports/pins can be utilized, and I have a work-in-progress folder where I copied all the relevant Arduino libaries, I just need to get them to compile and linked. I don't really know how to use avr-gcc/avr-g++.

See the examples first to see if this library appeals to you:

  • Basic.ino - A basic Planck (rev1-5, using the Atmega32u4) with just one layer. Doesn't use the Hardware class, to keep things simple.
  • Numpad.ino - simple 4x5 layout, uses a bunch of plugins
  • Layers.ino - I copied and modified my XD75 layout, uses layers and all my favorite plugins
  • Planck.ino - A port of the Planck default layout, with layers and Hardware object.
  • DZ60.ino - A port of the DZ60 default layout, but with unsupported features and macros removed - a good starting point for a new layout.
  • LeftSplit.ino - left side of a BFO9000 keyboard, uses split feature
  • RightSplit.ino - right side of a BFO9000 keyboard.
  • My Layout - my own personal Mechy layout.

Supported Keyboards

Right now only keyboards that use the Atmega32u4 are supported, but I think it will be easy to add support for other boards that have USB HID support.

I wrote this firmware to support three keyboards that I enjoy: XD75, BFO9000, and the Iris, which all use the 32u4. These boards were not created with Arduino in mind, in particular they use pins B0 (aka RXLED) and D5 (aka TXLED) as digital I/O pins, whereas most Arduino boards wire these to LEDs to show off serial and USB communication.

To solve this, and make these pins available as digital I/O pins, I created a custom board variant that turns RXLED and TXLED into no-ops. You should install this board definition and use it instead of the usual "Leonardo" board. Open preferences and add this URL to "Additional Board Manager URLs". If you have URLs there already, make sure to separate this one with a comma.

https://raw.githubusercontent.com/colinta/grayduino/json/package_colinta_grayduino_index.json

Next you need to install the board, so open the "Board Manager" (Tools → Board: "..." → Boards Manager…) and search for gray, and click the Install button:

board manager screenshot showing grayduino search

Then you'll have a new board "Grayduino Atmega32u4".

Migrating from QMK

If you've been using QMK and want to start using Mechy you'll need to install the Arduino bootloader onto your keyboard. It sounds daunting, but it's not too bad. You'll need either an FTDI progammer or a spare Arduino. Here are instructions on the Arduino ISP method: https://www.arduino.cc/en/Tutorial/ArduinoISP

The XD75 and other keyboards (e.g. GH60) has the SPI programming headers, but they're vertical instead of in the 2x3 grid. If you have one of these boards look for the headers in the middle or edge of the board, find the one that is a square instead of a circle, that's "Pin 1". Solder some headers in, and wire it up like the instructions say (Keyboard Pin 1 goes to Arduino Pin 12, Pin 2 to 5V, Pin 3 to Pin 13, Pin 4 to Pin 11, Pin 5 to Pin 10, Pin 6 to GND).

Usage

Include the main library (Mechy.h), include your plugins (Mechy/KeyPress.h, Mechy/MediaKey.h), define the pins for your keyboard (better yet use a Hardware header to do this). Then define your layout, create a few plugin objects, and add mechy.begin() and mechy.tick() to setup() and loop(). Easy! (I think.)

If a keyboard is available (in Keyboards.h) the process is even slightly easier: the pins will be defined for you, and you can create a Hardware instance. This will make it easy to use keyboard features like LEDs and sound. The Hardware author needs to write this class to support what that keyboard is capable of, or you can use it as a starting point and do your own thing!

The keyboard header will also define handy LAYOUT macros and a keyboard template that you can use. The macro is nice because it can take into account staggering and keys that span multiple rows & columns.

API

Mechy

The heart of it all! Create a Mechy instance, add() your plugins, attach() your responders, and that should do it!

Mechy mechy = Mechy();

// Layout and Mechy expect your keys to be in PROGMEM, use this macro to have
// your keys array defined correctly.
KEYS(keys) = LAYOUT(KC_A, KC_B, ..., KC_RSFT);

// Create a scanner with your keys array (or Layout).  This class will generate events and send them to Mechy.
Scanner scanner = Scanner(keys, pinRows, pinCols, ROWS, COLS);
// scanner.setDiodeDirection(COL_TO_ROW); // default setting
// scanner.setDiodeDirection(ROW_TO_COL); // alternative diode wiring

void setup() {
    // add all your plugins
    mechy.add(new KeyPress());

    mechy.attach(scanner);  // and attach(receiver) if you have a split keyboard

    mechy.begin();
    mechy.setUpdateFunc(update);  // optional
}

void loop() {
    mechy.tick();
}

void update(Event* event) {
    // listen for all events here - press, hold, and release
}

Plugins

In QMK you might be used to activating features in your rules.mk and config.h files. In Mechy a lot of these same features are accomplished instead by using the appropriate plugin. For instance, "AutoShift" is a plugin, not a feature you activate. Once you include it you need to use its key commands, e.g. AS_A instead of KC_A.

KeyPress

The most basic plugin, sends any printable key press and modifiers, also supports HYPER (⌘⌥⌃⇧), MEH (⌥⌃⇧), and CAG (⌘⌥⌃) keys, and keyboard chords.

#include <Mechy/KeyPress.h>

// define a custom "cmd+tab" key:
#define CMD_TAB KC(LGUI(KEY_TAB))
KEYS(mainKeys) = { KC_ESC, KC_A, CMD_TAB };

See KeyPress.h for defined keys.

MediaKey

Send play, pause, volume, track change keys. I've only tested on macOS.

Btw this plugin uses the "ArduinoMedia" Library at https://github.com/colinta/ArduinoMedia. I maintain this library but it's just a copy of code I found in https://github.com/Nicohood/HID

#include <Mechy/MediaKey.h>

KEYS(mainKeys) = { MD_PLAY, MD_VOLU, MD_FFD };

See MediaKey.h for defined keys.

MouseKey

A simple implementation of mouse keys. Hold shift to move the mouse faster.

#include <Mechy/MouseKey.h>

KEYS(mainKeys) = { MK_LEFT, MK_LCLK, MK_RGHT };

See MouseKey.h for defined keys.

AutoShift

A port of QMK's auto shift feature. Tap a letter for lower case, hold it for the shifted key. Also works for numbers and symbol keys.

This is an interesting plugin because it is very careful about when it reports that it is a keypress. The mechanism for this is the function bool Plugin::is(event_type, Event*). This plugin function returns true when it is considered a match for the event_type (EVENT_KEYPRESS, EVENT_MOUSE, EVENT_MODIFIER, EVENT_LOCK, EVENT_LAYER are possible values).

The AutoShift key only matches at two times: after being held for 1/4 second, or at release when it is below that time. At all other times this key is not doing anything; it doesn't send key repeat events.

See AutoShift.h for defined keys.

TapHold

Tap a key for one key, press and hold for another. Much like AutoShift but works with any key commands. Getting it setup is just a little more work, but it's great for limited-size keyboards to have keys like PageUp double as the Home key!

The default behavior is to send a "key tap", i.e. a down event followed immediately by an up event. If you want to use the "hold" feature to activate modifiers or switch layers, you'll probably want to use the TH_HOLD behavior (though not necessarily - the GotoLayer PUSH and LSET behaviors work just fine with the "tap" behavior).

#include <Mechy/TapHold.h>

// define human readable shortcuts for the layout
#define TH_PGUP TH_0
#define TH_PGDN TH_1
#define TH_SPC  TH(2)  // TH_0...TH_9 are defined, if you need more use TH(n)
KEYS(mainKeys) = { TH_PGUP, TH_PGDN, TH_SPC };

void setup() {
    TapHold* tapHold = new TapHold();
    // we need to tell TapHold what keys should be associated with these events.
    // Order matters here - the first call to `add` will be associated with
    // TH_0, and so on.
    tapHold->add(KC_PGUP, KC_HOME);
    tapHold->add(KC_PGDN, KC_END);
    // check this out, you can use this command to switch layers. tap for space,
    // or hold to activate layer 1.  Uses the `TH_HOLD` behavior to keep the
    // layer active as long as the key is held
    tapHold->add(KC_SPC, GOTO_1, TH_HOLD);
    // these must be called before mechy.begin()!  They get copied over as an
    // array in TapHold::begin()

    mechy.add(tapHold);
    mechy.begin();
}
GotoLayer

Obviously it changes layers! This is only the key listener part, to define multiple layers you'll need to study the Layout class.

There are a few layer changing "modes". The simplest is GOTO, which momentarily activates another layer while the key is held. When you release the key you'll bounce back to the previous layer.

Another option is LSET or layer set. This is used to activate another layer and keep it active. A good use case for this is to activate Colemak or Dvorak or Qwerty layouts. The "set layout" key could be on your function layer, and using LSET there you would in effect swap out the layer below the function layer. See below for this trick. Btw this does not exactly "push" the layer on, it activates the layer while the key is held and assigns it as the default, when no other layers are active.

My favorite, though, is PUSH, which takes the best of both these behaviors. It activates another layer while the key is held, and then you have an option: release the PUSH key and that layer will remain the active layer (which makes it similar to LSET). Or if you keep it held and press some keys, when you release the PUSH key you'll return to the previous layer (which makes it similar to GOTO). This is called "one shot layer" in QMK speak, though I don't know whether QMK's OSL() macro works the same way or not. If you use this macro be sure to include the BACK key (or other layer changing keys) because otherwise you won't be able to return to the base layer.

LOWER uses the PUSH behaviour but activates layer 1, RAISE uses `PUSH behaviour and activates layer 2.

Lastly there is the BACK behavior, this just pops the top-most layer off the stack of activated layers. Don't expect miracles if you have a dozen layers defined and want this feature to "just work".

There is limited support for "transparent" keys. This is deliberate, it keeps the "what keys are active?" logic simple. If you use the vvvv macro you can cascade up to the zero'th layer, but that's all. If you use LSET to activate another layer, it will still cascade up to the zero'th layer, not the "previous" layer. In the future this might change to support cascading to multiple layers, but that will probably be an option and not the default behavior.

#include <Mechy/GotoLayer.h>

KEYS(mainKeys) = { GOTO_1, PUSH_2, LSET_3 };
KEYS(fnKeys) = { LOWER , RAISE , BACK };  // LOWER and RAISE use the PUSH behavior, btw.

// here's an example of supporting colemak/qwerty/dvorak layers
#define LSET_QW LSET_0
#define LSET_CM LSET_1
#define LSET_DK LSET_2
#define GOTO_FN GOTO_3
// remember that this first layer is always used for cascading, regardless of which layer is active.
KEYS(mainKeys)    = { KC_LCTL,  KC_Q  ,  KC_W  ,  KC_E  ,  KC_R  ,  KC_T  ,  KC_Y  , GOTO_FN };
KEYS(colemakKeys) = {  vvvv  ,  KC_Q  ,  KC_W  ,  KC_F  ,  KC_P  ,  KC_G  ,  KC_J  ,  vvvv   };
KEYS(dvorakKeys)  = {  vvvv  , KC_QUOT, KC_COMM, KC_DOT ,  KC_P  ,  KC_Y  ,  KC_F  ,  vvvv   };
KEYS(fnKeys)      = { KC_LCTL, LSET_QW, LSET_CM, LSET_DK,  ____  ,  ____  ,  ____  , GOTO_FN };
Layout(ROWS, COLS, mainKeys, colemakKeys, dvorakKeys, fnKeys);

See GotoLayer.h for defined keys.

Password

This is only for passwords, and for that reason it requires two presses of the key to activate, so a password isn't sent by accidental activation. For macros that don't require this security you can use SendString, or submit a PR adding an option to disable this.

You should not include a newline in these macros/passwords, it will be added automatically unless the Shift key is held.

#include <Mechy/Password.h>

KEYS(mainKeys) = { PW_0, PW_1, PW_2 };

// If this is a "private" keyboard you can hardcode them, otherwise look at
// Layers.ino for how I put them in a secrets file.  They'll still be visible to
// someone who gets your keyboard and knows what to look for.
#define PASSWORDS 3
const char* passwords[PASSWORDS] = {"password 1", "password 2", "..."};

Mechy mechy = Mechy();
mechy.add(new Password(PASSWORDS, passwords));

See Password.h for defined keys.

SendString

This is similar to Password, but doesn't require two key presses to activate the macro, and has support for modifier keys, and fine-grained control over down and up key presses.

#include <Mechy/SendString.h>

KEYS(mainKeys) = { SS_0, SS_1 };

// kinda weird type here - a pointer to an array
// ie an array of arrays of uint16_t (uint16_t[][])
// the functions sendString, and sendKeys each return a uint16_t*
// so you can combine them into long macros:
uint16_t* macros[] = {
  // sends -> \ "
  // - Press \
  // - Press Left Shift + '  -> "
  sendKeys(downUp('\\'), downUp(LSFT('\''))),

  // sends -> ABc
  // - Left Shift Down,
  // - Press a -> A
  // - Press b -> B
  // - Left Shift Release,
  // - Press c -> c
  sendKeys(down(LSFT(0)), downUp('a'), downUp('b'), up(LSFT(0)), downUp('c'))
};

Mechy mechy = Mechy();

// SendString() needs the count of how many "entries". Each entry encodes the
// number of keys in the macro (based on the number of arguments).
mechy.add(new SendString(2, macros));

See SendString.h for defined keys.

Sticky

This is my own very opinionated version of how "sticky modifier keys" should work. The same spirit as "One shot" keys in QMK and "Sticky keys" on Windows and macOS. The difference is that my version of sticky keys deactivates the "sticky" key if you hold the modifier key.

  1. Press the modifier key once to activate it, then press any key to send "mod+key". The modifier will be deactivated afterwards.
  2. Press and hold the modifier (for 1/4 sec or more) and it will behave like a normal modifier. This makes it easy to Command+click or to decide "nevermind I don't want to activate the modifier".
  3. Double tap the modifier to lock it, press it again to unlock it.

Also supports HYPER (⌘⌥⌃⇧), MEH (⌥⌃⇧), and CAG (⌘⌥⌃) keys.

#include <Mechy/Sticky.h>

KEYS(mainKeys) = { ST_CTL, ST_ALT, ST_SFT, ST_GUI, ST_HYP, ST_MEH, ST_CAG };

The example above shows all the defined keys.

ComboKey

This plugin listens for multiple key down events and sends the 'combo' key when they are all pressed. Currently only supports one combination, in the future this could be refactored to support multiple combinations.

The key events that it listens to are still activated, so these can either perform double duty (like modifier keys), or just assign ____ to have them ignored.

#include <Mechy/ComboKey.h>

#define CK_LCTL CK(0)
#define CK_LALT CK(1)
#define CK_BSPC CK(2)

KEYS(mainKeys) = { CK_LALT, CK_LALT, CK_BSPC };

// map 'ctrl+alt+backspace' to 'goto layer 1'
KBD comboKeys[3] = { KC_LCTL, KC_LALT, KC_BSPC };
ComboKey comboKey = ComboKey(3, comboKeys, GOTO_1);
mechy.add(&comboKey);
Lock

A super simple Plugin, I wrote it as an early exercise. This plugin listens for two LK key presses (or more - the Lock() constructor accepts the number of keys needed), and after both are pressed it locks all keys except internal "meta" keys like GOTO_x and LK. You can prevent a small child from using your keyboard - which is the actual reason I wrote this, because I have a precosious daughter who loves to play with my keyboard. Actually now that I added the Notes I let her play with that feature.

#include <Mechy/Lock.h>

KEYS(mainKeys) = { LK, LK };
mechy.add(new Lock());
// to require 3 lock keys:
mechy.add(new Lock(3));

Only the LK key is defined.

Notes

For funsies! If you have a piezo speaker attached to a pin you can use this plugin to play music.

#include <Mechy/Notes.h>

KEYS(mainKeys) = { NT_C3, NT_D3, NT_E3, NT_F3, NT_G3, NT_A3, NT_B3, NT_C4 }

The header file is big - it includes keys for every note and an easter egg song key. Notes.h

Support classes

Layout

This is the class you need to use if you want layers. It's easy:

KEYS(mainKeys) = { KC_A, GOTO_1 };
KEYS(fnKeys) = { KC_B , ____ };

Layout layout = Layout(ROWS, COLS, mainKeys, fnKeys);

The layout can then be assigned to a Scanner or Receiver (for split keyboards). A cool feature that QMK doesn't have - when you press a key in Mechy that key is stored until it is released, based on the layout, row, and column position. So the GOTO_1 key will send a key down AND key up even though it's not defined in fnKeys. Also, if you pressed KC_A before pressing GOTO_1, then released KC_A while GOTO_1 is still held, you won't have any bugs, and KC_B would become "available". I can't explain it well, but this feature avoids a lot of the "layer code hell" that QMK can run into sometimes.

Scanner

This class handles the hardware reading/writing, and sends updates to Mechy, which is responsible for debouncing and storing those key presses. You assign a Layout or a keyboard array directly (a Layout will be created for you, useful for one layer keyboards).

Implementation detail: Scanner is a Responder, which means it responds to key presses and emits KBD* events to Mechy, which stores the events and translates them to Event* objects, which are consumed by Plugin instances.

KEYS(keys) = { ... };
Scanner scanner = Scanner(keys, pinRows, pinCols, ROWS, COLS);
mechy.attach(scanner);

// multiple layers
KEYS(mainKeys) = { ... };
KEYS(fnKeys) = { ... };
Layout layout = Layout(ROWS, COLS, mainKeys, fnKeys);
Scanner scanner = Scanner(&layout, pinRows, pinCols, ROWS, COLS);

mechy.attach(scanner);
Receiver

Receiver is similar in usage to Scanner (it is also a "Responder" subclass, and so can emit key events). It accepts a Layout object and emits events that it receives from the "right half" of a split keyboard.

This class listens uses a custom-written 2-wire serial protocol (I tried to use I2C but it didn't work?), with support for up to 32 rows and 32 columns. The other half uses Transmitter and a very basic .ino program.

Fun history fact, this split keyboard code is the original reason I wrote Mechy. I couldn't get the split keyboard code to perform well using QMK, the resulting keyboard was buggy and unresponsive.

Transmitter

This is the "right half" of the split code. It implements the sending side of the 2-wire protocol.

Wiring

This is a re-implementation of Arduino's wiring.c code, but with support for all the pins on the Atmega32u4. It's used internally, and I recommend you use the pins as they are defined in Constants.h, but they are compatible with the "digital pin numbers" that Arduino uses. I.e. Arduino refers to PB0 as "11" in pinMode and digitalRead/Write, so the value for _B0 is also 11. The values don't have any other meaning, they just need to be unique.

#define _B0 11
#define _B1 15
#define _B2 16
#define _B3 14
#define _B4  8
#define _B5  9
#define _B6 10
#define _B7 12

#define _C6  5
#define _C7 13

#define _D0  3
#define _D1  2
#define _D2  0
#define _D3  1
#define _D4  4
#define _D5 17
#define _D6 22
#define _D7  6

#define _E2 23
#define _E6  7

#define _F0 24
#define _F1 25
#define _F4 21
#define _F5 20
#define _F6 19
#define _F7 18
Hardware

This class is defined per-keyboard, but in general it will have:

  • LAYOUT macro and maybe alternates like LAYOUT_standard and LAYOUT_60.
  • begin() to initialize LED or other pins
  • tick() to check Mechy for Caps lock status and update that LED automatically (if you assign to capsLockLedWrite() your setting will override the default).
  • Definitions for ROWS, COLS, pinRows and pinCols.
  • LED controlling methods like capsLockLedWrite() and capsLockLedRead() and defines like CAPS_LOCK_LED_PIN
  • RGB and backlight support, if available.

FAQ

Mechy is pronounced "Mech Key" (or I suppose it sounds like "Meh-key", too).

I would've called the Hardware class Keyboard, but that name was taken.

Technical documentation: yeah probably some day, but only if someone asks for it and wants to contribute.

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