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Merge remote-tracking branch 'origin/master' into develop

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QMK Bot 2022-03-05 04:59:18 +00:00
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@ -188,7 +188,7 @@ cli.log.info('Reading from %s and writing to %s', cli.args.filename, cli.args.ou
# Testing, and Linting, and Formatting (oh my!)
We use nose2, flake8, and yapf to test, lint, and format code. You can use the `pytest` and `format-py` subcommands to run these tests:
We use nose2, flake8, and yapf to test, lint, and format code. You can use the `pytest` and `format-python` subcommands to run these tests:
### Testing and Linting
@ -196,7 +196,7 @@ We use nose2, flake8, and yapf to test, lint, and format code. You can use the `
### Formatting
qmk format-py
qmk format-python
## Formatting Details

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@ -275,14 +275,14 @@ $ qmk kle2json -f kle.txt -f
Ψ Wrote out to info.json
```
## `qmk format-py`
## `qmk format-python`
このコマンドは `qmk_firmware` 内の python コードを整形します。
**使用法**:
```
qmk format-py
qmk format-python
```
## `qmk pytest`

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@ -192,7 +192,7 @@ cli.log.info('Reading from %s and writing to %s', cli.args.filename, cli.args.ou
# テスト、リントおよびフォーマット
nose2、flake8 および yapf を使ってコードをテスト、リントおよびフォーマットします。これらのテストを実行するために `pytest``format-py` サブコマンドを使うことができます。
nose2、flake8 および yapf を使ってコードをテスト、リントおよびフォーマットします。これらのテストを実行するために `pytest``format-python` サブコマンドを使うことができます。
### テストとリント
@ -200,7 +200,7 @@ nose2、flake8 および yapf を使ってコードをテスト、リントお
### フォーマット
qmk format-py
qmk format-python
## フォーマットの詳細

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@ -132,7 +132,7 @@ The main part of this file is the `keymaps[]` definition. This is where you list
const uint16_t PROGMEM keymaps[][MATRIX_ROWS][MATRIX_COLS] = {
After this you'll find a list of LAYOUT() macros. A LAYOUT() is simply a list of keys to define a single layer. Typically you'll have one or more "base layers" (such as QWERTY, Dvorak, or Colemak) and then you'll layer on top of that one or more "function" layers. Due to the way layers are processed you can't overlay a "lower" layer on top of a "higher" layer.
After this you'll find the layer definitions. Typically you'll have one or more "base layers" (such as QWERTY, Dvorak, or Colemak) and then you'll layer on top of that one or more "function" layers. Due to the way layers are processed you can't overlay a "lower" layer on top of a "higher" layer.
`keymaps[][MATRIX_ROWS][MATRIX_COLS]` in QMK holds the 16 bit action code (sometimes referred as the quantum keycode) in it. For the keycode representing typical keys, its high byte is 0 and its low byte is the USB HID usage ID for keyboard.
@ -153,7 +153,9 @@ Here is an example of the Clueboard's base layer:
Some interesting things to note about this:
* From a C source point of view it's only a single array, but we have embedded whitespace to more easily visualize where each key is on the physical device.
* The layer is defined using the LAYOUT macro, traditionally defined in the keyboard's `.h` file.
* The LAYOUT macro takes a single list of keycodes, but we have written it in the C source using embedded whitespace and newlines to visualize where each key is on the physical device.
* The LAYOUT macro hides and handles the mapping to the hardware's key scan matrix.
* Plain keyboard scancodes are prefixed with KC_, while "special" keys are not.
* The upper left key activates custom function 0 (`F(0)`)
* The "Fn" key is defined with `MO(_FL)`, which moves to the `_FL` layer while that key is being held down.

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@ -8,27 +8,22 @@ This document attempts to explain how the QMK firmware works from a very high le
## Startup
You can think of QMK as no different from any other computer program. It is started, performs its tasks, and then ends. The entry point for the program is the `main()` function, just like it is on any other C program. However, for a newcomer to QMK it can be confusing because the `main()` function appears in multiple places, and it can be hard to tell which one to look at.
You can think of QMK as no different from any other computer program. It is started and performs its tasks, but this program never finishes. Like other C programs, the entry point is the `main()` function. For QMK, the `main()` function is found in [`quantum/main.c`](https://github.com/qmk/qmk_firmware/blob/0.15.13/quantum/main.c#L55).
The reason for this is the different platforms that QMK supports. The most common platform is `lufa`, which runs on AVR processors such at the atmega32u4. We also support `chibios` and `vusb`.
If you browse through the `main()` function you'll find that it starts by initializing any hardware that has been configured (including USB to the host). The most common platform for QMK is `lufa`, which runs on AVR processors such as the atmega32u4. When compiled for that platform, it will invoke for example `platform_setup()` in [`platforms/avr/platform.c`](https://github.com/qmk/qmk_firmware/blob/0.15.13/platforms/avr/platform.c#L19) and `protocol_setup()` in [`tmk_core/protocol/lufa/lufa.c`](https://github.com/qmk/qmk_firmware/blob/0.15.13/tmk_core/protocol/lufa/lufa.c#L1066). It will use other implementations when compiled for other platforms like `chibios` and `vusb`. At first glance, it can look like a lot of functionality but most of the time the code will be disabled by `#define`s.
We'll focus on AVR processors for the moment, which use the `lufa` platform. You can find the `main()` function in [tmk_core/protocol/lufa/lufa.c](https://github.com/qmk/qmk_firmware/blob/e1203a222bb12ab9733916164a000ef3ac48da93/tmk_core/protocol/lufa/lufa.c#L1028). If you browse through that function you'll find that it initializes any hardware that has been configured (including USB to the host) and then it starts the core part of the program with a [`while(1)`](https://github.com/qmk/qmk_firmware/blob/e1203a222bb12ab9733916164a000ef3ac48da93/tmk_core/protocol/lufa/lufa.c#L1069). This is [The Main Loop](#the-main-loop).
The `main()` function will then start the core part of the program with a [`while (true)`](https://github.com/qmk/qmk_firmware/blob/0.15.13/quantum/main.c#L63). This is [The Main Loop](#the-main-loop).
## The Main Loop
This section of code is called "The Main Loop" because it's responsible for looping over the same set of instructions forever. This is where QMK dispatches out to the functions responsible for making the keyboard do everything it is supposed to do. At first glance it can look like a lot of functionality but most of the time the code will be disabled by `#define`'s.
This section of code is called "The Main Loop" because it's responsible for looping over the same set of instructions forever, without ever reaching the end. This is where QMK dispatches out to the functions responsible for making the keyboard do everything it is supposed to do.
```
keyboard_task();
```
This is where all the keyboard specific functionality is dispatched. The source code for `keyboard_task()` can be found in [tmk_core/common/keyboard.c](https://github.com/qmk/qmk_firmware/blob/e1203a222bb12ab9733916164a000ef3ac48da93/tmk_core/common/keyboard.c#L216), and it is responsible for detecting changes in the matrix and turning status LEDs on and off.
The main loop will call [`protocol_task()`](https://github.com/qmk/qmk_firmware/blob/0.15.13/quantum/main.c#L38), which in turn will call `keyboard_task()` in [`quantum/keyboard.c`](https://github.com/qmk/qmk_firmware/blob/0.15.13/quantum/keyboard.c#L377). This is where all the keyboard specific functionality is dispatched, and it is responsible for detecting changes in the matrix and turning status LEDs on and off.
Within `keyboard_task()` you'll find code to handle:
* [Matrix Scanning](#matrix-scanning)
* Mouse Handling
* Serial Link(s)
* Keyboard status LEDs (Caps Lock, Num Lock, Scroll Lock)
#### Matrix Scanning