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-rw-r--r--docs/ChangeLog/20210529/PR12172.md13
-rw-r--r--docs/adc_driver.md154
-rw-r--r--docs/compatible_microcontrollers.md3
-rw-r--r--docs/feature_auto_shift.md27
-rw-r--r--docs/feature_leader_key.md13
-rw-r--r--docs/feature_led_matrix.md2
-rw-r--r--docs/feature_rgb_matrix.md4
-rw-r--r--docs/feature_rgblight.md1
-rw-r--r--docs/feature_wpm.md67
-rw-r--r--docs/flashing.md26
-rw-r--r--docs/ja/compatible_microcontrollers.md3
-rw-r--r--docs/ja/feature_led_matrix.md2
-rw-r--r--docs/keycodes.md3
-rw-r--r--docs/one_shot_keys.md3
-rw-r--r--docs/ws2812_driver.md22
15 files changed, 251 insertions, 92 deletions
diff --git a/docs/ChangeLog/20210529/PR12172.md b/docs/ChangeLog/20210529/PR12172.md
new file mode 100644
index 0000000000..0c355c151e
--- /dev/null
+++ b/docs/ChangeLog/20210529/PR12172.md
@@ -0,0 +1,13 @@
+## Bootmagic Deprecation and Refactor ([#12172](https://github.com/qmk/qmk_firmware/pull/12172))
+
+QMK has decided to deprecate the full Bootmagic feature and leave Bootmagic Lite as the only remaining option.
+
+This pull request changes the behavior of `BOOTMAGIC_ENABLE` such that specifying `BOOTMAGIC_ENABLE = yes` enables Bootmagic Lite instead of full Bootmagic.
+
+### Tentative Deprecation Schedule
+
+This is the current planned roadmap for the behavior of `BOOTMAGIC_ENABLE`:
+
+- From 2021-05-29, setting `BOOTMAGIC_ENABLE = yes` will enable Bootmagic Lite instead of full Bootmagic.
+- From 2021-08-28, `BOOTMAGIC_ENABLE` must be either `yes`, `lite`, or `no` – setting `BOOTMAGIC_ENABLE = full` will cause compilation to fail.
+- From 2021-11-27, `BOOTMAGIC_ENABLE` must be either `yes` or `no` – setting `BOOTMAGIC_ENABLE = lite` will cause compilation to fail.
diff --git a/docs/adc_driver.md b/docs/adc_driver.md
index 6e3d513863..69fff4b3c2 100644
--- a/docs/adc_driver.md
+++ b/docs/adc_driver.md
@@ -47,73 +47,79 @@ Note that some of these pins are doubled-up on ADCs with the same channel. This
Also note that the F0 and F3 use different numbering schemes. The F0 has a single ADC and the channels are 0-indexed, whereas the F3 has 4 ADCs and the channels are 1-indexed. This is because the F0 uses the `ADCv1` implementation of the ADC, whereas the F3 uses the `ADCv3` implementation.
-|ADC|Channel|STM32F0xx|STM32F3xx|
-|---|-------|---------|---------|
-|1 |0 |`A0` | |
-|1 |1 |`A1` |`A0` |
-|1 |2 |`A2` |`A1` |
-|1 |3 |`A3` |`A2` |
-|1 |4 |`A4` |`A3` |
-|1 |5 |`A5` |`F4` |
-|1 |6 |`A6` |`C0` |
-|1 |7 |`A7` |`C1` |
-|1 |8 |`B0` |`C2` |
-|1 |9 |`B1` |`C3` |
-|1 |10 |`C0` |`F2` |
-|1 |11 |`C1` | |
-|1 |12 |`C2` | |
-|1 |13 |`C3` | |
-|1 |14 |`C4` | |
-|1 |15 |`C5` | |
-|1 |16 | | |
-|2 |1 | |`A4` |
-|2 |2 | |`A5` |
-|2 |3 | |`A6` |
-|2 |4 | |`A7` |
-|2 |5 | |`C4` |
-|2 |6 | |`C0` |
-|2 |7 | |`C1` |
-|2 |8 | |`C2` |
-|2 |9 | |`C3` |
-|2 |10 | |`F2` |
-|2 |11 | |`C5` |
-|2 |12 | |`B2` |
-|2 |13 | | |
-|2 |14 | | |
-|2 |15 | | |
-|2 |16 | | |
-|3 |1 | |`B1` |
-|3 |2 | |`E9` |
-|3 |3 | |`E13` |
-|3 |4 | | |
-|3 |5 | | |
-|3 |6 | |`E8` |
-|3 |7 | |`D10` |
-|3 |8 | |`D11` |
-|3 |9 | |`D12` |
-|3 |10 | |`D13` |
-|3 |11 | |`D14` |
-|3 |12 | |`B0` |
-|3 |13 | |`E7` |
-|3 |14 | |`E10` |
-|3 |15 | |`E11` |
-|3 |16 | |`E12` |
-|4 |1 | |`E14` |
-|4 |2 | |`B12` |
-|4 |3 | |`B13` |
-|4 |4 | |`B14` |
-|4 |5 | |`B15` |
-|4 |6 | |`E8` |
-|4 |7 | |`D10` |
-|4 |8 | |`D11` |
-|4 |9 | |`D12` |
-|4 |10 | |`D13` |
-|4 |11 | |`D14` |
-|4 |12 | |`D8` |
-|4 |13 | |`D9` |
-|4 |14 | | |
-|4 |15 | | |
-|4 |16 | | |
+|ADC|Channel|STM32F0xx|STM32F1xx|STM32F3xx|STM32F4xx|
+|---|-------|---------|---------|---------|---------|
+|1 |0 |`A0` |`A0` | |`A0` |
+|1 |1 |`A1` |`A1` |`A0` |`A1` |
+|1 |2 |`A2` |`A2` |`A1` |`A2` |
+|1 |3 |`A3` |`A3` |`A2` |`A3` |
+|1 |4 |`A4` |`A4` |`A3` |`A4` |
+|1 |5 |`A5` |`A5` |`F4` |`A5` |
+|1 |6 |`A6` |`A6` |`C0` |`A6` |
+|1 |7 |`A7` |`A7` |`C1` |`A7` |
+|1 |8 |`B0` |`B0` |`C2` |`B0` |
+|1 |9 |`B1` |`B1` |`C3` |`B1` |
+|1 |10 |`C0` |`C0` |`F2` |`C0` |
+|1 |11 |`C1` |`C1` | |`C1` |
+|1 |12 |`C2` |`C2` | |`C2` |
+|1 |13 |`C3` |`C3` | |`C3` |
+|1 |14 |`C4` |`C4` | |`C4` |
+|1 |15 |`C5` |`C5` | |`C5` |
+|1 |16 | | | | |
+|2 |0 | |`A0`¹ | |`A0`² |
+|2 |1 | |`A1`¹ |`A4` |`A1`² |
+|2 |2 | |`A2`¹ |`A5` |`A2`² |
+|2 |3 | |`A3`¹ |`A6` |`A3`² |
+|2 |4 | |`A4`¹ |`A7` |`A4`² |
+|2 |5 | |`A5`¹ |`C4` |`A5`² |
+|2 |6 | |`A6`¹ |`C0` |`A6`² |
+|2 |7 | |`A7`¹ |`C1` |`A7`² |
+|2 |8 | |`B0`¹ |`C2` |`B0`² |
+|2 |9 | |`B1`¹ |`C3` |`B1`² |
+|2 |10 | |`C0`¹ |`F2` |`C0`² |
+|2 |11 | |`C1`¹ |`C5` |`C1`² |
+|2 |12 | |`C2`¹ |`B2` |`C2`² |
+|2 |13 | |`C3`¹ | |`C3`² |
+|2 |14 | |`C4`¹ | |`C4`² |
+|2 |15 | |`C5`¹ | |`C5`² |
+|2 |16 | | | | |
+|3 |0 | |`A0`¹ | |`A0`² |
+|3 |1 | |`A1`¹ |`B1` |`A1`² |
+|3 |2 | |`A2`¹ |`E9` |`A2`² |
+|3 |3 | |`A3`¹ |`E13` |`A3`² |
+|3 |4 | |`F6`¹ | |`F6`² |
+|3 |5 | |`F7`¹ |`B13` |`F7`² |
+|3 |6 | |`F8`¹ |`E8` |`F8`² |
+|3 |7 | |`F9`¹ |`D10` |`F9`² |
+|3 |8 | |`F10`¹ |`D11` |`F10`² |
+|3 |9 | | |`D12` |`F3`² |
+|3 |10 | |`C0`¹ |`D13` |`C0`² |
+|3 |11 | |`C1`¹ |`D14` |`C1`² |
+|3 |12 | |`C2`¹ |`B0` |`C2`² |
+|3 |13 | |`C3`¹ |`E7` |`C3`² |
+|3 |14 | | |`E10` |`F4`² |
+|3 |15 | | |`E11` |`F5`² |
+|3 |16 | | |`E12` | |
+|4 |1 | | |`E14` | |
+|4 |2 | | |`E15` | |
+|4 |3 | | |`B12` | |
+|4 |4 | | |`B14` | |
+|4 |5 | | |`B15` | |
+|4 |6 | | |`E8` | |
+|4 |7 | | |`D10` | |
+|4 |8 | | |`D11` | |
+|4 |9 | | |`D12` | |
+|4 |10 | | |`D13` | |
+|4 |11 | | |`D14` | |
+|4 |12 | | |`D8` | |
+|4 |13 | | |`D9` | |
+|4 |14 | | | | |
+|4 |15 | | | | |
+|4 |16 | | | | |
+
+<sup>¹ As of ChibiOS 20.3.4, the ADC driver for STM32F1xx devices supports only ADC1, therefore any configurations involving ADC2 or ADC3 cannot actually be used. In particular, pins `F6`…`F10`, which are present at least on some STM32F103x[C-G] devices, cannot be used as ADC inputs because of this driver limitation.</sup>
+
+<sup>² Not all STM32F4xx devices have ADC2 and/or ADC3, therefore some configurations shown in this table may be unavailable; in particular, pins `F4`…`F10` cannot be used as ADC inputs on devices which do not have ADC3. Check the device datasheet to confirm which pin functions are supported.</sup>
## Functions
@@ -141,10 +147,10 @@ Also note that the F0 and F3 use different numbering schemes. The F0 has a singl
The ARM implementation of the ADC has a few additional options that you can override in your own keyboards and keymaps to change how it operates. Please consult the corresponding `hal_adc_lld.h` in ChibiOS for your specific microcontroller for further documentation on your available options.
-|`#define` |Type |Default |Description |
-|---------------------|------|---------------------|------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------|
-|`ADC_CIRCULAR_BUFFER`|`bool`|`false` |If `true`, then the implementation will use a circular buffer. |
-|`ADC_NUM_CHANNELS` |`int` |`1` |Sets the number of channels that will be scanned as part of an ADC operation. The current implementation only supports `1`. |
-|`ADC_BUFFER_DEPTH` |`int` |`2` |Sets the depth of each result. Since we are only getting a 12-bit result by default, we set this to 2 bytes so we can contain our one value. This could be set to 1 if you opt for an 8-bit or lower result.|
-|`ADC_SAMPLING_RATE` |`int` |`ADC_SMPR_SMP_1P5` |Sets the sampling rate of the ADC. By default, it is set to the fastest setting. |
-|`ADC_RESOLUTION` |`int` |`ADC_CFGR1_RES_12BIT`|The resolution of your result. We choose 12 bit by default, but you can opt for 12, 10, 8, or 6 bit. |
+|`#define` |Type |Default |Description |
+|---------------------|------|----------------------------------------------|------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------|
+|`ADC_CIRCULAR_BUFFER`|`bool`|`false` |If `true`, then the implementation will use a circular buffer. |
+|`ADC_NUM_CHANNELS` |`int` |`1` |Sets the number of channels that will be scanned as part of an ADC operation. The current implementation only supports `1`. |
+|`ADC_BUFFER_DEPTH` |`int` |`2` |Sets the depth of each result. Since we are only getting a 10-bit result by default, we set this to 2 bytes so we can contain our one value. This could be set to 1 if you opt for an 8-bit or lower result.|
+|`ADC_SAMPLING_RATE` |`int` |`ADC_SMPR_SMP_1P5` |Sets the sampling rate of the ADC. By default, it is set to the fastest setting. |
+|`ADC_RESOLUTION` |`int` |`ADC_CFGR1_RES_10BIT` or `ADC_CFGR_RES_10BITS`|The resolution of your result. We choose 10 bit by default, but you can opt for 12, 10, 8, or 6 bit. Different MCUs use slightly different names for the resolution constants. |
diff --git a/docs/compatible_microcontrollers.md b/docs/compatible_microcontrollers.md
index 47a4844e7f..0f5b140de0 100644
--- a/docs/compatible_microcontrollers.md
+++ b/docs/compatible_microcontrollers.md
@@ -28,8 +28,11 @@ You can also use any ARM chip with USB that [ChibiOS](https://www.chibios.org) s
* [STM32F303](https://www.st.com/en/microcontrollers-microprocessors/stm32f303.html)
* [STM32F401](https://www.st.com/en/microcontrollers-microprocessors/stm32f401.html)
* [STM32F411](https://www.st.com/en/microcontrollers-microprocessors/stm32f411.html)
+ * [STM32F446](https://www.st.com/en/microcontrollers-microprocessors/stm32f446.html)
* [STM32G431](https://www.st.com/en/microcontrollers-microprocessors/stm32g4x1.html)
* [STM32G474](https://www.st.com/en/microcontrollers-microprocessors/stm32g4x4.html)
+ * [STM32L433](https://www.st.com/en/microcontrollers-microprocessors/stm32l4x3.html)
+ * [STM32L443](https://www.st.com/en/microcontrollers-microprocessors/stm32l4x3.html)
### NXP (Kinetis)
diff --git a/docs/feature_auto_shift.md b/docs/feature_auto_shift.md
index 8e04d9dd38..ec7eeaaa0c 100644
--- a/docs/feature_auto_shift.md
+++ b/docs/feature_auto_shift.md
@@ -109,6 +109,33 @@ Do not Auto Shift numeric keys, zero through nine.
Do not Auto Shift alpha characters, which include A through Z.
+### Auto Shift Per Key
+
+This is a function that allows you to determine which keys shold be autoshifted, much like the tap-hold keys.
+
+The default function looks like this:
+
+```c
+bool get_auto_shifted_key(uint16_t keycode, keyrecord_t *record) {
+ switch (keycode) {
+# ifndef NO_AUTO_SHIFT_ALPHA
+ case KC_A ... KC_Z:
+# endif
+# ifndef NO_AUTO_SHIFT_NUMERIC
+ case KC_1 ... KC_0:
+# endif
+# ifndef NO_AUTO_SHIFT_SPECIAL
+ case KC_TAB:
+ case KC_MINUS ... KC_SLASH:
+ case KC_NONUS_BSLASH:
+# endif
+ return true;
+ }
+ return false;
+}
+```
+This functionality is enabled by default, and does not need a define.
+
### AUTO_SHIFT_REPEAT (simple define)
Enables keyrepeat.
diff --git a/docs/feature_leader_key.md b/docs/feature_leader_key.md
index 41ff8f1a4e..f10bca7589 100644
--- a/docs/feature_leader_key.md
+++ b/docs/feature_leader_key.md
@@ -72,6 +72,19 @@ SEQ_THREE_KEYS(KC_C, KC_C, KC_C) {
}
```
+## Infinite Leader key timeout
+
+Sometimes your leader key is not on a comfortable places as the rest of keys on your sequence. Imagine that your leader key is one of your outer top right keys, you may need to reposition your hand just to reach your leader key.
+This can make typing the entire sequence on time hard even if you are able to type most of the sequence fast. For example, if your sequence is `Leader + asd` typing `asd` fast is very easy once you have your hands in your home row. However starting the sequence in time after moving your hand out of the home row to reach the leader key and back is not.
+To remove the stress this situation produces to your hands you can enable an infinite timeout just for the leader key. This mean that, after you hit the leader key you will have an infinite amount of time to start the rest of the sequence, allowing you to proper position your hands on the best position to type the rest of the sequence comfortably.
+This infinite timeout only affects the leader key, so in our previous example of `Leader + asd` you will have an infinite amount of time between `Leader` and `a`, but once you start the sequence the timeout you have configured (global or per key) will work normally.
+This way you can configure a very short `LEADER_TIMEOUT` but still have plenty of time to position your hands.
+
+In order to enable this, place this in your `config.h`:
+```c
+#define LEADER_NO_TIMEOUT
+```
+
## Strict Key Processing
By default, the Leader Key feature will filter the keycode out of [`Mod-Tap`](mod_tap.md) and [`Layer Tap`](feature_layers.md#switching-and-toggling-layers) functions when checking for the Leader sequences. That means if you're using `LT(3, KC_A)`, it will pick this up as `KC_A` for the sequence, rather than `LT(3, KC_A)`, giving a more expected behavior for newer users.
diff --git a/docs/feature_led_matrix.md b/docs/feature_led_matrix.md
index f4a6616340..ac2be2e775 100644
--- a/docs/feature_led_matrix.md
+++ b/docs/feature_led_matrix.md
@@ -79,7 +79,7 @@ Custom layer effects can be done by defining this in your `<keyboard>.c`:
```c
void led_matrix_indicators_kb(void) {
- led_matrix_set_index_value(index, value);
+ led_matrix_set_value(index, value);
}
```
diff --git a/docs/feature_rgb_matrix.md b/docs/feature_rgb_matrix.md
index e996cadddd..63ff7d6ad6 100644
--- a/docs/feature_rgb_matrix.md
+++ b/docs/feature_rgb_matrix.md
@@ -437,7 +437,7 @@ These are defined in [`rgblight_list.h`](https://github.com/qmk/qmk_firmware/blo
#define RGB_MATRIX_KEYRELEASES // reacts to keyreleases (instead of keypresses)
#define RGB_DISABLE_TIMEOUT 0 // number of milliseconds to wait until rgb automatically turns off
#define RGB_DISABLE_AFTER_TIMEOUT 0 // OBSOLETE: number of ticks to wait until disabling effects
-#define RGB_DISABLE_WHEN_USB_SUSPENDED false // turn off effects when suspended
+#define RGB_DISABLE_WHEN_USB_SUSPENDED // turn off effects when suspended
#define RGB_MATRIX_LED_PROCESS_LIMIT (DRIVER_LED_TOTAL + 4) / 5 // limits the number of LEDs to process in an animation per task run (increases keyboard responsiveness)
#define RGB_MATRIX_LED_FLUSH_LIMIT 16 // limits in milliseconds how frequently an animation will update the LEDs. 16 (16ms) is equivalent to limiting to 60fps (increases keyboard responsiveness)
#define RGB_MATRIX_MAXIMUM_BRIGHTNESS 200 // limits maximum brightness of LEDs to 200 out of 255. If not defined maximum brightness is set to 255
@@ -447,6 +447,8 @@ These are defined in [`rgblight_list.h`](https://github.com/qmk/qmk_firmware/blo
#define RGB_MATRIX_STARTUP_VAL RGB_MATRIX_MAXIMUM_BRIGHTNESS // Sets the default brightness value, if none has been set
#define RGB_MATRIX_STARTUP_SPD 127 // Sets the default animation speed, if none has been set
#define RGB_MATRIX_DISABLE_KEYCODES // disables control of rgb matrix by keycodes (must use code functions to control the feature)
+#define RGB_MATRIX_SPLIT { X, Y } // (Optional) For split keyboards, the number of LEDs connected on each half. X = left, Y = Right.
+ // If RGB_MATRIX_KEYPRESSES or RGB_MATRIX_KEYRELEASES is enabled, you also will want to enable SPLIT_TRANSPORT_MIRROR
```
## EEPROM storage :id=eeprom-storage
diff --git a/docs/feature_rgblight.md b/docs/feature_rgblight.md
index d2612a6d1b..8e8d6b81c3 100644
--- a/docs/feature_rgblight.md
+++ b/docs/feature_rgblight.md
@@ -74,6 +74,7 @@ Changing the **Value** sets the overall brightness.<br>
|`RGB_MODE_XMAS` |`RGB_M_X` |Christmas animation mode |
|`RGB_MODE_GRADIENT`|`RGB_M_G` |Static gradient animation mode |
|`RGB_MODE_RGBTEST` |`RGB_M_T` |Red, Green, Blue test animation mode |
+|`RGB_MODE_TWINKLE` |`RGB_M_TW`|Twinkle animation mode |
!> By default, if you have both the RGB Light and the [RGB Matrix](feature_rgb_matrix.md) feature enabled, these keycodes will work for both features, at the same time. You can disable the keycode functionality by defining the `*_DISABLE_KEYCODES` option for the specific feature.
diff --git a/docs/feature_wpm.md b/docs/feature_wpm.md
index 12dd080579..c8ec3a7f32 100644
--- a/docs/feature_wpm.md
+++ b/docs/feature_wpm.md
@@ -1,25 +1,62 @@
# Word Per Minute (WPM) Calculcation
-The WPM feature uses time between keystrokes to compute a rolling average words
-per minute rate and makes this available for various uses.
+The WPM feature uses time between keystrokes to compute a rolling average words per minute rate and makes this available for various uses.
Enable the WPM system by adding this to your `rules.mk`:
WPM_ENABLE = yes
-For split keyboards using soft serial, the computed WPM
-score will be available on the master AND slave half.
+For split keyboards using soft serial, the computed WPM score will be available on the master AND slave half.
-## Public Functions
-
-`uint8_t get_current_wpm(void);`
-This function returns the current WPM as an unsigned integer.
+## Configuration
+|Define |Default | Description |
+|-----------------------------|--------------|------------------------------------------------------------------------------------------|
+|`WPM_SMOOTHING` |`0.0487` | Sets the smoothing to about 40 keystrokes |
+|`WPM_ESTIMATED_WORD_SIZE` |`5` | This is the value used when estimating average word size (for regression and normal use) |
+|`WPM_ALLOW_COUNT_REGRESSOIN` |_Not defined_ | If defined allows the WPM to be decreased when hitting Delete or Backspace |
+## Public Functions
-## Customized keys for WPM calc
-
-By default, the WPM score only includes letters, numbers, space and some
-punctuation. If you want to change the set of characters considered as part of
-the WPM calculation, you can implement `wpm_keycode_user(uint16_t keycode)`
-and return true for any characters you would like included in the calculation,
-or false to not count that particular keycode.
+|Function |Description |
+|--------------------------|--------------------------------------------------|
+|`get_current_wpm(void)` | Returns the current WPM as a value between 0-255 |
+|`set_current_wpm(x)` | Sets the current WPM to `x` (between 0-255) |
+
+## Callbacks
+
+By default, the WPM score only includes letters, numbers, space and some punctuation. If you want to change the set of characters considered as part of the WPM calculation, you can implement your own `bool wpm_keycode_user(uint16_t keycode)` and return true for any characters you would like included in the calculation, or false to not count that particular keycode.
+
+For instance, the default is:
+
+```c
+bool wpm_keycode_user(uint16_t keycode) {
+ if ((keycode >= QK_MOD_TAP && keycode <= QK_MOD_TAP_MAX) || (keycode >= QK_LAYER_TAP && keycode <= QK_LAYER_TAP_MAX) || (keycode >= QK_MODS && keycode <= QK_MODS_MAX)) {
+ keycode = keycode & 0xFF;
+ } else if (keycode > 0xFF) {
+ keycode = 0;
+ }
+ if ((keycode >= KC_A && keycode <= KC_0) || (keycode >= KC_TAB && keycode <= KC_SLASH)) {
+ return true;
+ }
+
+ return false;
+}
+```
+
+Additionally, if `WPM_ALLOW_COUNT_REGRESSION` is defined, there is the `uint8_t wpm_regress_count(uint16_t keycode)` function that allows you to decrease the WPM. This is useful if you want to be able to penalize certain keycodes (or even combinations).
+
+__attribute__((weak)) uint8_t wpm_regress_count(uint16_t keycode) {
+ bool weak_modded = (keycode >= QK_LCTL && keycode < QK_LSFT) || (keycode >= QK_RCTL && keycode < QK_RSFT);
+
+ if ((keycode >= QK_MOD_TAP && keycode <= QK_MOD_TAP_MAX) || (keycode >= QK_LAYER_TAP && keycode <= QK_LAYER_TAP_MAX) || (keycode >= QK_MODS && keycode <= QK_MODS_MAX)) {
+ keycode = keycode & 0xFF;
+ } else if (keycode > 0xFF) {
+ keycode = 0;
+ }
+ if (((get_mods() | get_oneshot_mods()) & MOD_MASK_CTRL} || weak_modded) && (keycode == KC_DEL || keycode == KC_BSPC)) {
+ return WPM_ESTIMATED_WORD_SIZE;
+ }
+ if (keycode == KC_DEL || keycode == KC_BSPC) {
+ return 1;
+ }
+}
diff --git a/docs/flashing.md b/docs/flashing.md
index 7804a6bad8..83c97444e1 100644
--- a/docs/flashing.md
+++ b/docs/flashing.md
@@ -249,3 +249,29 @@ Flashing sequence:
2. Wait for the OS to detect the device
3. Flash a .bin file
4. Reset the device into application mode (may be done automatically)
+
+## tinyuf2
+
+Keyboards may opt into supporting the tinyuf2 bootloader. This is currently only supported on the F411 blackpill.
+
+The `rules.mk` setting for this bootloader is `tinyuf2`, and can be specified at the keymap or user level.
+
+To ensure compatibility with the tinyuf2 bootloader, make sure this block is present in your `rules.mk`:
+
+```make
+# Bootloader selection
+BOOTLOADER = tinyuf2
+```
+
+Compatible flashers:
+
+* Any application able to copy a file from one place to another, such as _macOS Finder_ or _Windows Explorer_.
+
+Flashing sequence:
+
+1. Enter the bootloader using any of the following methods:
+ * Tap the `RESET` keycode
+ * Double-tap the `nRST` button on the PCB.
+2. Wait for the OS to detect the device
+3. Copy the .uf2 file to the new USB disk
+4. Wait for the keyboard to become available
diff --git a/docs/ja/compatible_microcontrollers.md b/docs/ja/compatible_microcontrollers.md
index fdd11f14fa..b675b038d2 100644
--- a/docs/ja/compatible_microcontrollers.md
+++ b/docs/ja/compatible_microcontrollers.md
@@ -33,8 +33,11 @@ QMK は十分な容量のフラッシュメモリを備えた USB 対応 AVR ま
* [STM32F303](https://www.st.com/en/microcontrollers-microprocessors/stm32f303.html)
* [STM32F401](https://www.st.com/en/microcontrollers-microprocessors/stm32f401.html)
* [STM32F411](https://www.st.com/en/microcontrollers-microprocessors/stm32f411.html)
+* [STM32F446](https://www.st.com/en/microcontrollers-microprocessors/stm32f446.html)
* [STM32G431](https://www.st.com/en/microcontrollers-microprocessors/stm32g4x1.html)
* [STM32G474](https://www.st.com/en/microcontrollers-microprocessors/stm32g4x4.html)
+* [STM32L433](https://www.st.com/en/microcontrollers-microprocessors/stm32l4x3.html)
+* [STM32L443](https://www.st.com/en/microcontrollers-microprocessors/stm32l4x3.html)
### NXP (Kinetis)
diff --git a/docs/ja/feature_led_matrix.md b/docs/ja/feature_led_matrix.md
index b73487ca63..62e22859fb 100644
--- a/docs/ja/feature_led_matrix.md
+++ b/docs/ja/feature_led_matrix.md
@@ -76,7 +76,7 @@ I2C IS31FL3731 RGB コントローラを使ったアドレス指定可能な LED
カスタムレイヤー効果は `<keyboard>.c` 内で以下を定義することで行うことができます:
void led_matrix_indicators_kb(void) {
- led_matrix_set_index_value(index, value);
+ led_matrix_set_value(index, value);
}
同様の関数がキーマップ内で `led_matrix_indicators_user` として動作します。
diff --git a/docs/keycodes.md b/docs/keycodes.md
index 9acf8b6839..f3c519b130 100644
--- a/docs/keycodes.md
+++ b/docs/keycodes.md
@@ -516,6 +516,9 @@ See also: [One Shot Keys](one_shot_keys.md)
|------------|----------------------------------|
|`OSM(mod)` |Hold `mod` for one keypress |
|`OSL(layer)`|Switch to `layer` for one keypress|
+|`OS_ON` |Turns One Shot keys on |
+|`OS_OFF` |Turns One Shot keys off |
+|`OS_TOGG` |Toggles One Shot keys status |
## Space Cadet :id=space-cadet
diff --git a/docs/one_shot_keys.md b/docs/one_shot_keys.md
index 9a082d7d6d..9fc5486299 100644
--- a/docs/one_shot_keys.md
+++ b/docs/one_shot_keys.md
@@ -17,6 +17,9 @@ You can control the behavior of one shot keys by defining these in `config.h`:
* `OSM(mod)` - Momentarily hold down *mod*. You must use the `MOD_*` keycodes as shown in [Mod Tap](mod_tap.md), not the `KC_*` codes.
* `OSL(layer)` - momentary switch to *layer*.
+* `OS_ON` - Turns on One Shot keys.
+* `OS_OFF` - Turns off One Shot keys. OSM act as regular mod keys, OSL act like `MO`.
+* `ON_TOGG` - Toggles the one shot key status.
Sometimes, you want to activate a one-shot key as part of a macro or tap dance routine.
diff --git a/docs/ws2812_driver.md b/docs/ws2812_driver.md
index cca6827ec8..e69400364c 100644
--- a/docs/ws2812_driver.md
+++ b/docs/ws2812_driver.md
@@ -77,6 +77,25 @@ Configure the hardware via your config.h:
You must also turn on the SPI feature in your halconf.h and mcuconf.h
+#### Circular Buffer Mode
+Some boards may flicker while in the normal buffer mode. To fix this issue, circular buffer mode may be used to rectify the issue.
+
+By default, the circular buffer mode is disabled.
+
+To enable this alternative buffer mode, place this into your `config.h` file:
+```c
+#define WS2812_SPI_USE_CIRCULAR_BUFFER
+```
+
+#### Setting baudrate with divisor
+To adjust the baudrate at which the SPI peripheral is configured, users will need to derive the target baudrate from the clock tree provided by STM32CubeMX.
+
+Only divisors of 2, 4, 8, 16, 32, 64, 128 and 256 are supported by hardware.
+
+|Define |Default|Description |
+|--------------------|-------|-------------------------------------|
+|`WS2812_SPI_DIVISOR`|`16` |SPI source clock peripheral divisor |
+
#### Testing Notes
While not an exhaustive list, the following table provides the scenarios that have been partially validated:
@@ -102,11 +121,14 @@ Configure the hardware via your config.h:
#define WS2812_PWM_DRIVER PWMD2 // default: PWMD2
#define WS2812_PWM_CHANNEL 2 // default: 2
#define WS2812_PWM_PAL_MODE 2 // Pin "alternate function", see the respective datasheet for the appropriate values for your MCU. default: 2
+//#define WS2812_PWM_COMPLEMENTARY_OUTPUT // Define for a complementary timer output (TIMx_CHyN); omit for a normal timer output (TIMx_CHy).
#define WS2812_DMA_STREAM STM32_DMA1_STREAM2 // DMA Stream for TIMx_UP, see the respective reference manual for the appropriate values for your MCU.
#define WS2812_DMA_CHANNEL 2 // DMA Channel for TIMx_UP, see the respective reference manual for the appropriate values for your MCU.
#define WS2812_DMAMUX_ID STM32_DMAMUX1_TIM2_UP // DMAMUX configuration for TIMx_UP -- only required if your MCU has a DMAMUX peripheral, see the respective reference manual for the appropriate values for your MCU.
```
+Note that using a complementary timer output (TIMx_CHyN) is possible only for advanced-control timers (TIM1, TIM8, TIM20 on STM32), and the `STM32_PWM_USE_ADVANCED` option in mcuconf.h must be set to `TRUE`. Complementary outputs of general-purpose timers are not supported due to ChibiOS limitations.
+
You must also turn on the PWM feature in your halconf.h and mcuconf.h
#### Testing Notes