?> LED indicators on split keyboards will require state information synced to the slave half (e.g. `#define SPLIT_LED_STATE_ENABLE`). See [data sync options](feature_split_keyboard.md#data-sync-options) for more details.
|`LED_NUM_LOCK_PIN` |*Not defined*|The pin that controls the `Num Lock` LED |
|`LED_CAPS_LOCK_PIN` |*Not defined*|The pin that controls the `Caps Lock` LED |
|`LED_SCROLL_LOCK_PIN`|*Not defined*|The pin that controls the `Scroll Lock` LED|
|`LED_COMPOSE_PIN` |*Not defined*|The pin that controls the `Compose` LED |
|`LED_KANA_PIN` |*Not defined*|The pin that controls the `Kana` LED |
|`LED_PIN_ON_STATE` |`1` |The state of the indicator pins when the LED is "on" - `1` for high, `0` for low|
Unless you are designing your own keyboard, you generally should not need to change the above config options.
## `led_update_*()`
When the configuration options do not provide enough flexibility, the API hooks provided allow custom control of the LED behavior. These functions will be called when the state of one of those 5 LEDs changes. It receives the LED state as a struct parameter.
By convention, return `true` from `led_update_user()` to get the `led_update_kb()` hook to run its code, and
return `false` when you would prefer not to run the code in `led_update_kb()`.
Some examples include:
- overriding the LEDs to use them for something else like layer indication
- return `false` because you do not want the `_kb()` function to run, as it would override your layer behavior.
- play a sound when an LED turns on or off.
- return `true` because you want the `_kb` function to run, and this is in addition to the default LED behavior.
?> Because the `led_set_*` functions return `void` instead of `bool`, they do not allow for overriding the keyboard LED control, and thus it's recommended to use `led_update_*` instead.
### Example `led_update_kb()` Implementation
```c
bool led_update_kb(led_t led_state) {
bool res = led_update_user(led_state);
if(res) {
// writePin sets the pin high for 1 and low for 0.
// In this example the pins are inverted, setting
// it low/0 turns it on, and high/1 turns the LED off.
// This behavior depends on whether the LED is between the pin
// and VCC or the pin and GND.
writePin(B0, !led_state.num_lock);
writePin(B1, !led_state.caps_lock);
writePin(B2, !led_state.scroll_lock);
writePin(B3, !led_state.compose);
writePin(B4, !led_state.kana);
}
return res;
}
```
### Example `led_update_user()` Implementation
This incomplete example would play a sound if Caps Lock is turned on or off. It returns `true`, because you also want the LEDs to maintain their state.
Call this function to get the last received LED state as a `led_t`. This is useful for reading the LED state outside `led_update_*`, e.g. in [`matrix_scan_user()`](#matrix-scanning-code).
## Setting Physical LED State
Some keyboard implementations provide convenience methods for setting the state of the physical LEDs.
### Ergodox Boards
The Ergodox implementations provide `ergodox_right_led_1`/`2`/`3_on`/`off()` to turn individual LEDs on or off, as well as `ergodox_right_led_on`/`off(uint8_t led)` to turn them on or off by their index.
In addition, it is possible to specify the brightness level of all LEDs with `ergodox_led_all_set(uint8_t n)`; of individual LEDs with `ergodox_right_led_1`/`2`/`3_set(uint8_t n)`; or by index with `ergodox_right_led_set(uint8_t led, uint8_t n)`.
Ergodox boards also define `LED_BRIGHTNESS_LO` for the lowest brightness and `LED_BRIGHTNESS_HI` for the highest brightness (which is the default).