4.5 KiB
UART Driver :id=uart-driver
The UART drivers used in QMK have a set of common functions to allow portability between MCUs.
Currently, this driver does not support enabling hardware flow control (the RTS and CTS pins) if available, but may do so in future.
Usage :id=usage
In most cases, the UART driver code is automatically included if you are using a feature or driver which requires it.
However, if you need to use the driver standalone, add the following to your rules.mk:
UART_DRIVER_REQUIRED = yes
You can then call the UART API by including uart.h in your code.
AVR Configuration :id=avr-configuration
No special setup is required - just connect the RX and TX pins of your UART device to the opposite pins on the MCU:
| MCU | TX |
RX |
CTS |
RTS |
|---|---|---|---|---|
| ATmega16/32U2 | D3 |
D2 |
D7 |
D6 |
| ATmega16/32U4 | D3 |
D2 |
D5 |
B7 |
| AT90USB64/128 | D3 |
D2 |
n/a | n/a |
| ATmega32A | D1 |
D0 |
n/a | n/a |
| ATmega328/P | D1 |
D0 |
n/a | n/a |
ChibiOS/ARM Configuration :id=arm-configuration
You'll need to determine which pins can be used for UART -- as an example, STM32 parts generally have multiple UART peripherals, labeled USART1, USART2, USART3 etc.
To enable UART, modify your board's halconf.h to enable the serial driver:
#define HAL_USE_SERIAL TRUE
Then, modify your board's mcuconf.h to enable the peripheral you've chosen, for example:
#undef STM32_SERIAL_USE_USART2
#define STM32_SERIAL_USE_USART2 TRUE
Configuration-wise, you'll need to set up the peripheral as per your MCU's datasheet -- the defaults match the pins for a Proton-C, i.e. STM32F303.
config.h override |
Description | Default Value |
|---|---|---|
#define SERIAL_DRIVER |
USART peripheral to use - USART1 -> SD1, USART2 -> SD2 etc. |
SD1 |
#define SD1_TX_PIN |
The pin to use for TX | A9 |
#define SD1_TX_PAL_MODE |
The alternate function mode for TX | 7 |
#define SD1_RX_PIN |
The pin to use for RX | A10 |
#define SD1_RX_PAL_MODE |
The alternate function mode for RX | 7 |
#define SD1_CTS_PIN |
The pin to use for CTS | A11 |
#define SD1_CTS_PAL_MODE |
The alternate function mode for CTS | 7 |
#define SD1_RTS_PIN |
The pin to use for RTS | A12 |
#define SD1_RTS_PAL_MODE |
The alternate function mode for RTS | 7 |
API :id=api
void uart_init(uint32_t baud) :id=api-uart-init
Initialize the UART driver. This function must be called only once, before any of the below functions can be called.
Arguments :id=api-uart-init-arguments
uint32_t baud
The baud rate to transmit and receive at. This may depend on the device you are communicating with. Common values are 1200, 2400, 4800, 9600, 19200, 38400, 57600, and 115200.
void uart_write(uint8_t data) :id=api-uart-write
Transmit a single byte.
Arguments :id=api-uart-write-arguments
uint8_t data
The byte to write.
uint8_t uart_read(void) :id=api-uart-read
Receive a single byte.
Return Value :id=api-uart-read-return
The byte read from the receive buffer. This function will block if the buffer is empty (ie. no data to read).
void uart_transmit(const uint8_t *data, uint16_t length) :id=api-uart-transmit
Transmit multiple bytes.
Arguments :id=api-uart-transmit-arguments
const uint8_t *data
A pointer to the data to write from.uint16_t length
The number of bytes to write. Take care not to overrun the length ofdata.
void uart_receive(char *data, uint16_t length) :id=api-uart-receive
Receive multiple bytes.
Arguments :id=api-uart-receive-arguments
uint8_t *data
A pointer to the buffer to read into.uint16_t length
The number of bytes to read. Take care not to overrun the length ofdata.
bool uart_available(void) :id=api-uart-available
Return whether the receive buffer contains data. Call this function to determine if uart_read() will return data immediately.
Return Value :id=api-uart-available-return
true if the receive buffer length is non-zero.