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Diffstat (limited to 'docs')
38 files changed, 1493 insertions, 652 deletions
diff --git a/docs/_summary.md b/docs/_summary.md index b7fcddc237..66f2d60af0 100644 --- a/docs/_summary.md +++ b/docs/_summary.md @@ -85,11 +85,11 @@ * [Pointing Device](feature_pointing_device.md) * [Raw HID](feature_rawhid.md) * [Secure](feature_secure.md) + * [Send String](feature_send_string.md) * [Sequencer](feature_sequencer.md) * [Swap Hands](feature_swap_hands.md) * [Tap Dance](feature_tap_dance.md) * [Tap-Hold Configuration](tap_hold.md) - * [Terminal](feature_terminal.md) * [Unicode](feature_unicode.md) * [Userspace](feature_userspace.md) * [WPM Calculation](feature_wpm.md) @@ -108,6 +108,7 @@ * [Audio](feature_audio.md) * [Bluetooth](feature_bluetooth.md) * [Bootmagic Lite](feature_bootmagic.md) + * [Converters](feature_converters.md) * [Custom Matrix](custom_matrix.md) * [Digitizer](feature_digitizer.md) * [DIP Switch](feature_dip_switch.md) @@ -116,7 +117,6 @@ * [Joystick](feature_joystick.md) * [LED Indicators](feature_led_indicators.md) * [MIDI](feature_midi.md) - * [Proton C Conversion](proton_c_conversion.md) * [PS/2 Mouse](feature_ps2_mouse.md) * [Split Keyboard](feature_split_keyboard.md) * [Stenography](feature_stenography.md) @@ -148,6 +148,7 @@ * [SPI Driver](spi_driver.md) * [WS2812 Driver](ws2812_driver.md) * [EEPROM Driver](eeprom_driver.md) + * [Flash Driver](flash_driver.md) * ['serial' Driver](serial_driver.md) * [UART Driver](uart_driver.md) * [GPIO Controls](gpio_control.md) @@ -166,6 +167,8 @@ * Arm/ChibiOS * [Selecting an MCU](platformdev_selecting_arm_mcu.md) * [Early initialization](platformdev_chibios_earlyinit.md) + * [Raspberry Pi RP2040](platformdev_rp2040.md) + * [Proton C](platformdev_proton_c.md) * QMK Reference * [Contributing to QMK](contributing.md) diff --git a/docs/cli_commands.md b/docs/cli_commands.md index a380d3eb2f..56767d962b 100644 --- a/docs/cli_commands.md +++ b/docs/cli_commands.md @@ -352,6 +352,73 @@ $ qmk via2json -kb ai03/polaris -o polaris_keymap.json polaris_via_backup.json Ψ Wrote keymap to /home/you/qmk_firmware/polaris_keymap.json ``` +## `qmk import-keyboard` + +This command imports a data-driven `info.json` keyboard into the repo. + +**Usage**: + +``` +usage: qmk import-keyboard [-h] filename +``` + +**Example:** + +``` +$ qmk import-keyboard ~/Downloads/forever60.json +Ψ Importing forever60.json. + +Ψ Imported a new keyboard named forever60. +Ψ To start working on things, `cd` into keyboards/forever60, +Ψ or open the directory in your preferred text editor. +Ψ And build with qmk compile -kb forever60 -km default. +``` + +## `qmk import-keymap` + +This command imports a data-driven `keymap.json` keymap into the repo. + +**Usage**: + +``` +usage: qmk import-keymap [-h] filename +``` + +**Example:** + +``` +qmk import-keymap ~/Downloads/asdf2.json +Ψ Importing asdf2.json. + +Ψ Imported a new keymap named asdf2. +Ψ To start working on things, `cd` into keyboards/takashicompany/dogtag/keymaps/asdf2, +Ψ or open the directory in your preferred text editor. +Ψ And build with qmk compile -kb takashicompany/dogtag -km asdf2. +``` + +## `qmk import-kbfirmware` + +This command creates a new keyboard based on a [Keyboard Firmware Builder](https://kbfirmware.com/) export. + +**Usage**: + +``` +usage: qmk import-kbfirmware [-h] filename +``` + +**Example:** + +``` +$ qmk import-kbfirmware ~/Downloads/gh62.json +Ψ Importing gh62.json. + +⚠ Support here is basic - Consider using 'qmk new-keyboard' instead +Ψ Imported a new keyboard named gh62. +Ψ To start working on things, `cd` into keyboards/gh62, +Ψ or open the directory in your preferred text editor. +Ψ And build with qmk compile -kb gh62 -km default. +``` + --- # Developer Commands @@ -527,3 +594,4 @@ This command converts a TTF font to an intermediate format for editing, before c ## `qmk painter-convert-font-image` This command converts an intermediate font image to the QFF File Format. See the [Quantum Painter](quantum_painter.md?id=quantum-painter-cli) documentation for more information on this command. + diff --git a/docs/compatible_microcontrollers.md b/docs/compatible_microcontrollers.md index cee8986829..cc9c0b7f92 100644 --- a/docs/compatible_microcontrollers.md +++ b/docs/compatible_microcontrollers.md @@ -62,9 +62,17 @@ You can also use any ARM chip with USB that [ChibiOS](https://www.chibios.org) s * [MK20DX128](https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/general-purpose-mcus/k-series-cortex-m4/k2x-usb/kinetis-k20-50-mhz-full-speed-usb-mixed-signal-integration-microcontrollers-based-on-arm-cortex-m4-core:K20_50) * [MK20DX256](https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/general-purpose-mcus/k-series-cortex-m4/k2x-usb/kinetis-k20-72-mhz-full-speed-usb-mixed-signal-integration-microcontrollers-mcus-based-on-arm-cortex-m4-core:K20_72) * PJRC Teensy 3.2 + * [MK64FX512](https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/general-purpose-mcus/k-series-cortex-m4/k6x-ethernet/kinetis-k64-120-mhz-256-kb-sram-microcontrollers-mcus-based-on-arm-cortex-m4-core:K64_120) + * PJRC Teensy 3.5 * [MK66FX1M0](https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/general-purpose-mcus/k-series-cortex-m4/k6x-ethernet/kinetis-k66-180-mhz-dual-high-speed-full-speed-usbs-2mb-flash-microcontrollers-mcus-based-on-arm-cortex-m4-core:K66_180) * PJRC Teensy 3.6 +### Raspberry Pi + +* [RP2040](https://www.raspberrypi.com/documentation/microcontrollers/rp2040.html) + +For a detailed overview about the RP2040 support by QMK see the [dedicated RP2040 page](platformdev_rp2040.md). + ## Atmel ATSAM There is limited support for one of Atmel's ATSAM microcontrollers, that being the [ATSAMD51J18A](https://www.microchip.com/wwwproducts/en/ATSAMD51J18A) used by the [Massdrop keyboards](https://github.com/qmk/qmk_firmware/tree/master/keyboards/massdrop). However, it is not recommended to design a board with this microcontroller as the support is quite specialized to Massdrop hardware. diff --git a/docs/config_options.md b/docs/config_options.md index 8227a0e074..34034f7c8d 100644 --- a/docs/config_options.md +++ b/docs/config_options.md @@ -107,8 +107,10 @@ This is a C header file that is one of the first things included, and will persi * sets the maximum power (in mA) over USB for the device (default: 500) * `#define USB_POLLING_INTERVAL_MS 10` * sets the USB polling rate in milliseconds for the keyboard, mouse, and shared (NKRO/media keys) interfaces -* `#define USB_SUSPEND_WAKEUP_DELAY 200` - * set the number of milliseconde to pause after sending a wakeup packet +* `#define USB_SUSPEND_WAKEUP_DELAY 0` + * sets the number of milliseconds to pause after sending a wakeup packet. + Disabled by default, you might want to set this to 200 (or higher) if the + keyboard does not wake up properly after suspending. * `#define F_SCL 100000L` * sets the I2C clock rate speed for keyboards using I2C. The default is `400000L`, except for keyboards using `split_common`, where the default is `100000L`. @@ -141,7 +143,7 @@ If you define these options you will enable the associated feature, which may in ## Behaviors That Can Be Configured * `#define TAPPING_TERM 200` - * how long before a tap becomes a hold, if set above 500, a key tapped during the tapping term will turn it into a hold too + * how long before a key press becomes a hold * `#define TAPPING_TERM_PER_KEY` * enables handling for per key `TAPPING_TERM` settings * `#define RETRO_TAPPING` @@ -174,6 +176,8 @@ If you define these options you will enable the associated feature, which may in * sets the timer for leader key chords to run on each key press rather than overall * `#define LEADER_KEY_STRICT_KEY_PROCESSING` * Disables keycode filtering for Mod-Tap and Layer-Tap keycodes. Eg, if you enable this, you would need to specify `MT(MOD_CTL, KC_A)` if you want to use `KC_A`. +* `#define MOUSE_EXTENDED_REPORT` + * Enables support for extended reports (-32767 to 32767, instead of -127 to 127), which may allow for smoother reporting, and prevent maxing out of the reports. Applies to both Pointing Device and Mousekeys. * `#define ONESHOT_TIMEOUT 300` * how long before oneshot times out * `#define ONESHOT_TAP_TOGGLE 2` diff --git a/docs/custom_matrix.md b/docs/custom_matrix.md index 8f6878f94a..6d6ae5e972 100644 --- a/docs/custom_matrix.md +++ b/docs/custom_matrix.md @@ -81,17 +81,17 @@ void matrix_init(void) { } uint8_t matrix_scan(void) { - bool matrix_has_changed = false; + bool changed = false; // TODO: add matrix scanning routine here // Unless hardware debouncing - use the configured debounce routine - debounce(raw_matrix, matrix, MATRIX_ROWS, changed); + changed = debounce(raw_matrix, matrix, MATRIX_ROWS, changed); // This *must* be called for correct keyboard behavior matrix_scan_quantum(); - return matrix_has_changed; + return changed; } ``` diff --git a/docs/eeprom_driver.md b/docs/eeprom_driver.md index 6dcf10c04d..50d8bcb7b3 100644 --- a/docs/eeprom_driver.md +++ b/docs/eeprom_driver.md @@ -2,12 +2,15 @@ The EEPROM driver can be swapped out depending on the needs of the keyboard, or whether extra hardware is present. +Selecting the EEPROM driver is done in your keyboard's `rules.mk`: + Driver | Description -----------------------------------|--------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- `EEPROM_DRIVER = vendor` (default) | Uses the on-chip driver provided by the chip manufacturer. For AVR, this is provided by avr-libc. This is supported on ARM for a subset of chips -- STM32F3xx, STM32F1xx, and STM32F072xB will be emulated by writing to flash. STM32L0xx and STM32L1xx will use the onboard dedicated true EEPROM. Other chips will generally act as "transient" below. `EEPROM_DRIVER = i2c` | Supports writing to I2C-based 24xx EEPROM chips. See the driver section below. `EEPROM_DRIVER = spi` | Supports writing to SPI-based 25xx EEPROM chips. See the driver section below. `EEPROM_DRIVER = transient` | Fake EEPROM driver -- supports reading/writing to RAM, and will be discarded when power is lost. +`EEPROM_DRIVER = wear_leveling` | Frontend driver for the wear_leveling system, allowing for EEPROM emulation on top of flash -- both in-MCU and external SPI NOR flash. ## Vendor Driver Configuration :id=vendor-eeprom-driver-configuration @@ -43,8 +46,9 @@ Module | Equivalent `#define` | Source -----------------|---------------------------------|------------------------------------------ CAT24C512 EEPROM | `#define EEPROM_I2C_CAT24C512` | <https://www.sparkfun.com/products/14764> RM24C512C EEPROM | `#define EEPROM_I2C_RM24C512C` | <https://www.sparkfun.com/products/14764> -24LC64 EEPROM | `#define EEPROM_I2C_24LC64` | <https://www.microchip.com/wwwproducts/en/24LC64> -24LC128 EEPROM | `#define EEPROM_I2C_24LC128` | <https://www.microchip.com/wwwproducts/en/24LC128> +24LC32A EEPROM | `#define EEPROM_I2C_24LC32A` | <https://www.microchip.com/en-us/product/24LC32A> +24LC64 EEPROM | `#define EEPROM_I2C_24LC64` | <https://www.microchip.com/en-us/product/24LC64> +24LC128 EEPROM | `#define EEPROM_I2C_24LC128` | <https://www.microchip.com/en-us/product/24LC128> 24LC256 EEPROM | `#define EEPROM_I2C_24LC256` | <https://www.sparkfun.com/products/525> MB85RC256V FRAM | `#define EEPROM_I2C_MB85RC256V` | <https://www.adafruit.com/product/1895> @@ -54,13 +58,13 @@ MB85RC256V FRAM | `#define EEPROM_I2C_MB85RC256V` | <https://www.adafruit.com/p Currently QMK supports 25xx-series chips over SPI. As such, requires a working spi_master driver configuration. You can override the driver configuration via your config.h: -`config.h` override | Description | Default Value ------------------------------------------------|--------------------------------------------------------------------------------------|-------------- -`#define EXTERNAL_EEPROM_SPI_SLAVE_SELECT_PIN` | SPI Slave select pin in order to inform that the EEPROM is currently being addressed | _none_ -`#define EXTERNAL_EEPROM_SPI_CLOCK_DIVISOR` | Clock divisor used to divide the peripheral clock to derive the SPI frequency | `64` -`#define EXTERNAL_EEPROM_BYTE_COUNT` | Total size of the EEPROM in bytes | 8192 -`#define EXTERNAL_EEPROM_PAGE_SIZE` | Page size of the EEPROM in bytes, as specified in the datasheet | 32 -`#define EXTERNAL_EEPROM_ADDRESS_SIZE` | The number of bytes to transmit for the memory location within the EEPROM | 2 +`config.h` override | Default Value | Description +-----------------------------------------------|---------------|------------------------------------------------------------------------------------- +`#define EXTERNAL_EEPROM_SPI_SLAVE_SELECT_PIN` | _none_ | SPI Slave select pin in order to inform that the EEPROM is currently being addressed +`#define EXTERNAL_EEPROM_SPI_CLOCK_DIVISOR` | `64` | Clock divisor used to divide the peripheral clock to derive the SPI frequency +`#define EXTERNAL_EEPROM_BYTE_COUNT` | `8192` | Total size of the EEPROM in bytes +`#define EXTERNAL_EEPROM_PAGE_SIZE` | `32` | Page size of the EEPROM in bytes, as specified in the datasheet +`#define EXTERNAL_EEPROM_ADDRESS_SIZE` | `2` | The number of bytes to transmit for the memory location within the EEPROM !> There's no way to determine if there is an SPI EEPROM actually responding. Generally, this will result in reads of nothing but zero. @@ -73,3 +77,84 @@ The only configurable item for the transient EEPROM driver is its size: `#define TRANSIENT_EEPROM_SIZE` | Total size of the EEPROM storage in bytes | 64 Default values and extended descriptions can be found in `drivers/eeprom/eeprom_transient.h`. + +## Wear-leveling Driver Configuration :id=wear_leveling-eeprom-driver-configuration + +The wear-leveling driver uses an algorithm to minimise the number of erase cycles on the underlying MCU flash memory. + +There is no specific configuration for this driver, but the wear-leveling system used by this driver may need configuration. See the [wear-leveling configuration](#wear_leveling-configuration) section for more information. + +# Wear-leveling Configuration :id=wear_leveling-configuration + +The wear-leveling driver has a few possible _backing stores_ that may be used by adding to your keyboard's `rules.mk` file: + +Driver | Description +----------------------------------------|------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ +`WEAR_LEVELING_DRIVER = embedded_flash` | This driver is used for emulating EEPROM by writing to embedded flash on the MCU. +`WEAR_LEVELING_DRIVER = spi_flash` | This driver is used to address external SPI NOR Flash peripherals. +`WEAR_LEVELING_DRIVER = rp2040_flash` | This driver is used to write to the same storage the RP2040 executes code from. +`WEAR_LEVELING_DRIVER = legacy` | This driver is the "legacy" emulated EEPROM provided in historical revisions of QMK. Currently used for STM32F0xx and STM32F4x1, but slated for deprecation and removal once `embedded_flash` support for those MCU families is complete. + +!> All wear-leveling drivers require an amount of RAM equivalent to the selected logical EEPROM size. Increasing the size to 32kB of EEPROM requires 32kB of RAM, which a significant number of MCUs simply do not have. + +## Wear-leveling Embedded Flash Driver Configuration :id=wear_leveling-efl-driver-configuration + +This driver performs writes to the embedded flash storage embedded in the MCU. In most circumstances, the last few of sectors of flash are used in order to minimise the likelihood of collision with program code. + +Configurable options in your keyboard's `config.h`: + +`config.h` override | Default | Description +-----------------------------------------|-------------|---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- +`#define WEAR_LEVELING_EFL_FIRST_SECTOR` | _unset_ | The first sector on the MCU to use. By default this is not defined and calculated at runtime based on the MCU. However, different flash sizes on MCUs may require custom configuration. +`#define WEAR_LEVELING_EFL_FLASH_SIZE` | _unset_ | Allows overriding the flash size available for use for wear-leveling. Under normal circumstances this is automatically calculated and should not need to be overridden. Specifying a size larger than the amount actually available in flash will usually prevent the MCU from booting. +`#define WEAR_LEVELING_LOGICAL_SIZE` | `1024` | Number of bytes "exposed" to the rest of QMK and denotes the size of the usable EEPROM. +`#define WEAR_LEVELING_BACKING_SIZE` | `2048` | Number of bytes used by the wear-leveling algorithm for its underlying storage, and needs to be a multiple of the logical size. +`#define BACKING_STORE_WRITE_SIZE` | _automatic_ | The byte width of the underlying write used on the MCU, and is usually automatically determined from the selected MCU family. If an error occurs in the auto-detection, you'll need to consult the MCU's datasheet and determine this value, specifying it directly. + +!> If your MCU does not boot after swapping to the EFL wear-leveling driver, it's likely that the flash size is incorrectly detected, usually as an MCU with larger flash and may require overriding. + +## Wear-leveling SPI Flash Driver Configuration :id=wear_leveling-flash_spi-driver-configuration + +This driver performs writes to an external SPI NOR Flash peripheral. It also requires a working configuration for the SPI NOR Flash peripheral -- see the [flash driver](flash_driver.md) documentation for more information. + +Configurable options in your keyboard's `config.h`: + +`config.h` override | Default | Description +----------------------------------------------------|--------------------------------|-------------------------------------------------------------------------------------------------------------------------------- +`#define WEAR_LEVELING_EXTERNAL_FLASH_BLOCK_COUNT` | `1` | Number of blocks in the external flash used by the wear-leveling algorithm. +`#define WEAR_LEVELING_EXTERNAL_FLASH_BLOCK_OFFSET` | `0` | The index first block in the external flash used by the wear-leveling algorithm. +`#define WEAR_LEVELING_LOGICAL_SIZE` | `((block_count*block_size)/2)` | Number of bytes "exposed" to the rest of QMK and denotes the size of the usable EEPROM. Result must be <= 64kB. +`#define WEAR_LEVELING_BACKING_SIZE` | `(block_count*block_size)` | Number of bytes used by the wear-leveling algorithm for its underlying storage, and needs to be a multiple of the logical size. +`#define BACKING_STORE_WRITE_SIZE` | `8` | The write width used whenever a write is performed on the external flash peripheral. + +!> There is currently a limit of 64kB for the EEPROM subsystem within QMK, so using a larger flash is not going to be beneficial as the logical size cannot be increased beyond 65536. The backing size may be increased to a larger value, but erase timing may suffer as a result. + +## Wear-leveling RP2040 Driver Configuration :id=wear_leveling-rp2040-driver-configuration + +This driver performs writes to the same underlying storage that the RP2040 executes its code. + +Configurable options in your keyboard's `config.h`: + +`config.h` override | Default | Description +------------------------------------------|----------------------------|-------------------------------------------------------------------------------------------------------------------------------- +`#define WEAR_LEVELING_RP2040_FLASH_SIZE` | `PICO_FLASH_SIZE_BYTES` | Number of bytes of flash on the board. +`#define WEAR_LEVELING_RP2040_FLASH_BASE` | `(flash_size-sector_size)` | The byte-wise location that the backing storage should be located. +`#define WEAR_LEVELING_LOGICAL_SIZE` | `4096` | Number of bytes "exposed" to the rest of QMK and denotes the size of the usable EEPROM. +`#define WEAR_LEVELING_BACKING_SIZE` | `8192` | Number of bytes used by the wear-leveling algorithm for its underlying storage, and needs to be a multiple of the logical size as well as the sector size. +`#define BACKING_STORE_WRITE_SIZE` | `2` | The write width used whenever a write is performed on the external flash peripheral. + +## Wear-leveling Legacy EEPROM Emulation Driver Configuration :id=wear_leveling-legacy-driver-configuration + +This driver performs writes to the embedded flash storage embedded in the MCU much like the normal Embedded Flash Driver, and is only for use with STM32F0xx and STM32F4x1 devices. This flash implementation is still currently provided as the EFL driver is currently non-functional for the previously mentioned families. + +By default, `1024` bytes of emulated EEPROM is provided: + +MCU | EEPROM Provided | Flash Used +----------|-----------------|-------------- +STM32F042 | `1024` bytes | `2048` bytes +STM32F070 | `1024` bytes | `2048` bytes +STM32F072 | `1024` bytes | `2048` bytes +STM32F401 | `1024` bytes | `16384` bytes +STM32F411 | `1024` bytes | `16384` bytes + +Under normal circumstances configuration of this driver requires intimate knowledge of the MCU's flash structure -- reconfiguration is at your own risk and will require referring to the code. diff --git a/docs/feature_converters.md b/docs/feature_converters.md new file mode 100644 index 0000000000..11dcc62b2a --- /dev/null +++ b/docs/feature_converters.md @@ -0,0 +1,98 @@ +# Converters + +Since many drop-in replacement controllers now exist, we've done our best to make them easy to use in existing designs. + +This page documents the handy automated process for converting keyboards. + +### Supported Converters + +Currently the following converters are available: + +| From | To | +|------------|-------------------| +| `promicro` | `proton_c` | +| `promicro` | `kb2040` | +| `promicro` | `promicro_rp2040` | +| `promicro` | `blok` | + +See below for more in depth information on each converter. + +## Overview + +Each converter category is broken down by its declared `pin compatibility`. +This ensures that only valid combinations are attempted. + +You can generate the firmware by appending `-e CONVERT_TO=<target>` to your compile/flash command. For example: + +```sh +qmk flash -c -kb keebio/bdn9/rev1 -km default -e CONVERT_TO=proton_c +``` + +You can also add the same `CONVERT_TO=<target>` to your keymap's `rules.mk`, which will accomplish the same thing. + +?> If you get errors about `PORTB/DDRB`, etc not being defined, you'll need to convert the keyboard's code to use the [GPIO Controls](gpio_control.md) that will work for both ARM and AVR. This shouldn't affect the AVR builds at all. + +### Conditional Configuration + +Once a converter is enabled, it exposes the `CONVERT_TO_<target_uppercase>` flag that you can use in your code with `#ifdef`s, For example: + +```c +#ifdef CONVERT_TO_PROTON_C + // Proton C code +#else + // Pro Micro code +#endif +``` + +## Pro Micro + +If a board currently supported in QMK uses a [Pro Micro](https://www.sparkfun.com/products/12640) (or compatible board), the supported alternative controllers are: + +| Device | Target | +|------------------------------------------------------------------------|-------------------| +| [Proton C](https://qmk.fm/proton-c/) | `proton_c` | +| [Adafruit KB2040](https://learn.adafruit.com/adafruit-kb2040) | `kb2040` | +| [SparkFun Pro Micro - RP2040](https://www.sparkfun.com/products/18288) | `promicro_rp2040` | +| [Blok](https://boardsource.xyz/store/628b95b494dfa308a6581622) | `blok` | + +Converter summary: + +| Target | Argument | `rules.mk` | Condition | +|-------------------|---------------------------------|------------------------------|-------------------------------------| +| `proton_c` | `-e CONVERT_TO=proton_c` | `CONVERT_TO=proton_c` | `#ifdef CONVERT_TO_PROTON_C` | +| `kb2040` | `-e CONVERT_TO=kb2040` | `CONVERT_TO=kb2040` | `#ifdef CONVERT_TO_KB2040` | +| `promicro_rp2040` | `-e CONVERT_TO=promicro_rp2040` | `CONVERT_TO=promicro_rp2040` | `#ifdef CONVERT_TO_PROMICRO_RP2040` | +| `blok` | `-e CONVERT_TO=blok` | `CONVERT_TO=blok` | `#ifdef CONVERT_TO_BLOK` | + +### Proton C :id=proton_c + +The Proton C only has one on-board LED (C13), and by default, the TXLED (D5) is mapped to it. If you want the RXLED (B0) mapped to it instead, add this line to your `config.h`: + +```c +#define CONVERT_TO_PROTON_C_RXLED +``` + +The following defaults are based on what has been implemented for STM32 boards. + +| Feature | Notes | +|----------------------------------------------|------------------------------------------------------------------------------------------------------------------| +| [Audio](feature_audio.md) | Enabled | +| [RGB Lighting](feature_rgblight.md) | Disabled | +| [Backlight](feature_backlight.md) | Forces [task driven PWM](feature_backlight.md#software-pwm-driver) until ARM can provide automatic configuration | +| USB Host (e.g. USB-USB converter) | Not supported (USB host code is AVR specific and is not currently supported on ARM) | +| [Split keyboards](feature_split_keyboard.md) | Partial - heavily dependent on enabled features | + +### Adafruit KB2040 :id=kb2040 + +The following defaults are based on what has been implemented for [RP2040](platformdev_rp2040.md) boards. + +| Feature | Notes | +|----------------------------------------------|------------------------------------------------------------------------------------------------------------------| +| [RGB Lighting](feature_rgblight.md) | Enabled via `PIO` vendor driver | +| [Backlight](feature_backlight.md) | Forces [task driven PWM](feature_backlight.md#software-pwm-driver) until ARM can provide automatic configuration | +| USB Host (e.g. USB-USB converter) | Not supported (USB host code is AVR specific and is not currently supported on ARM) | +| [Split keyboards](feature_split_keyboard.md) | Partial via `PIO` vendor driver - heavily dependent on enabled features | + +### SparkFun Pro Micro - RP2040 and Blok :id=promicro_rp2040 + +Currently identical to [Adafruit KB2040](#kb2040). diff --git a/docs/feature_dynamic_macros.md b/docs/feature_dynamic_macros.md index 01f2a0ca40..0660e0c065 100644 --- a/docs/feature_dynamic_macros.md +++ b/docs/feature_dynamic_macros.md @@ -35,6 +35,7 @@ There are a number of options added that should allow some additional degree of |`DYNAMIC_MACRO_SIZE` |128 |Sets the amount of memory that Dynamic Macros can use. This is a limited resource, dependent on the controller. | |`DYNAMIC_MACRO_USER_CALL` |*Not defined* |Defining this falls back to using the user `keymap.c` file to trigger the macro behavior. | |`DYNAMIC_MACRO_NO_NESTING` |*Not Defined* |Defining this disables the ability to call a macro from another macro (nested macros). | +|`DYNAMIC_MACRO_DELAY` |*Not Defined* |Sets the waiting time (ms unit) when sending each key. | If the LEDs start blinking during the recording with each keypress, it means there is no more space for the macro in the macro buffer. To fit the macro in, either make the other macro shorter (they share the same buffer) or increase the buffer size by adding the `DYNAMIC_MACRO_SIZE` define in your `config.h` (default value: 128; please read the comments for it in the header). diff --git a/docs/feature_macros.md b/docs/feature_macros.md index 78bc4ba0a5..f5b163d5df 100644 --- a/docs/feature_macros.md +++ b/docs/feature_macros.md @@ -106,6 +106,8 @@ Only basic keycodes (prefixed by `KC_`) are supported. Do not include the `KC_` ### `SEND_STRING()` & |