ardupilot/libraries/AP_HAL_AVR/UARTDriver.h

219 lines
8.3 KiB
C++

#ifndef __AP_HAL_AVR_UART_DRIVER_H__
#define __AP_HAL_AVR_UART_DRIVER_H__
#if (CONFIG_HAL_BOARD == HAL_BOARD_APM1 || CONFIG_HAL_BOARD == HAL_BOARD_APM2)
#include <stdint.h>
#include <stdarg.h>
#include <avr/interrupt.h>
#include <AP_HAL.h>
#include "AP_HAL_AVR_Namespace.h"
/**
* AVRUARTDriver is an implementation of UARTDriver for the AVR.
* It will be a thin wrapper on FastSerial.
*/
class AP_HAL_AVR::AVRUARTDriver : public AP_HAL::UARTDriver {
public:
AVRUARTDriver(
const uint8_t portNumber, volatile uint8_t *ubrrh,
volatile uint8_t *ubrrl, volatile uint8_t *ucsra,
volatile uint8_t *ucsrb, const uint8_t u2x,
const uint8_t portEnableBits, const uint8_t portTxBits);
/* Implementations of UARTDriver virtual methods */
void begin(uint32_t b) { begin(b, 0, 0); }
void begin(uint32_t b, uint16_t rxS, uint16_t txS);
void end();
void flush();
bool is_initialized() { return _initialized; }
void set_blocking_writes(bool blocking) {
_nonblocking_writes = !blocking;
}
bool tx_pending() {
return (_txBuffer->head != _txBuffer->tail);
}
/* Implementations of BetterStream virtual methods */
void print_P(const prog_char_t *s);
void println_P(const prog_char_t *s);
void printf(const char *s, ...)
__attribute__ ((format(__printf__, 2, 3)));
void _printf_P(const prog_char *s, ...)
__attribute__ ((format(__printf__, 2, 3)));
/* Implementations of Stream virtual methods */
int16_t available();
int16_t txspace();
int16_t read();
int16_t peek();
/* Implementations of Print virtual methods */
size_t write(uint8_t c);
/// Transmit/receive buffer descriptor.
///
/// Public so the interrupt handlers can see it
struct Buffer {
volatile uint16_t head, tail; ///< head and tail pointers
uint16_t mask; ///< buffer size mask for pointer wrap
uint8_t *bytes; ///< pointer to allocated buffer
};
private:
/* Instance Variables */
bool _initialized;
// register accessors
volatile uint8_t * const _ubrrh;
volatile uint8_t * const _ubrrl;
volatile uint8_t * const _ucsra;
volatile uint8_t * const _ucsrb;
// register magic numbers
const uint8_t _u2x;
const uint8_t _portEnableBits; ///< rx, tx and rx interrupt enables
const uint8_t _portTxBits; ///< tx data and completion interrupt enables
// ring buffers
Buffer * const _rxBuffer;
Buffer * const _txBuffer;
bool _open;
// whether writes to the port should block waiting
// for enough space to appear
bool _nonblocking_writes;
/* Class Variables */
/// Allocates a buffer of the given size
///
/// @param buffer The buffer descriptor for which the buffer will
/// will be allocated.
/// @param size The desired buffer size.
/// @returns True if the buffer was allocated successfully.
///
static bool _allocBuffer(Buffer *buffer, uint16_t size);
/// Frees the allocated buffer in a descriptor
///
/// @param buffer The descriptor whose buffer should be freed.
///
static void _freeBuffer(Buffer *buffer);
/// default receive buffer size
static const uint16_t _default_rx_buffer_size = 128;
/// default transmit buffer size
static const uint16_t _default_tx_buffer_size = 16;
/// maxium tx/rx buffer size
/// @note if we could bring the max size down to 256, the mask and head/tail
/// pointers in the buffer could become uint8_t.
///
static const uint16_t _max_buffer_size = 512;
};
extern AP_HAL_AVR::AVRUARTDriver::Buffer __AVRUARTDriver__rxBuffer[];
extern AP_HAL_AVR::AVRUARTDriver::Buffer __AVRUARTDriver__txBuffer[];
/// Generic Rx/Tx vectors for a serial port - needs to know magic numbers
///
#define AVRUARTDriverHandler(_PORT, _RXVECTOR, _TXVECTOR, _UDR, _UCSRB, _TXBITS) \
ISR(_RXVECTOR, ISR_BLOCK) \
{ \
uint8_t c; \
uint16_t i; \
\
/* read the byte as quickly as possible */ \
c = _UDR; \
/* work out where the head will go next */ \
i = (__AVRUARTDriver__rxBuffer[_PORT].head + 1) & __AVRUARTDriver__rxBuffer[_PORT].mask; \
/* decide whether we have space for another byte */ \
if (i != __AVRUARTDriver__rxBuffer[_PORT].tail) { \
/* we do, move the head */ \
__AVRUARTDriver__rxBuffer[_PORT].bytes[__AVRUARTDriver__rxBuffer[_PORT].head] = c; \
__AVRUARTDriver__rxBuffer[_PORT].head = i; \
} \
} \
ISR(_TXVECTOR, ISR_BLOCK) \
{ \
/* if there is another character to send */ \
if (__AVRUARTDriver__txBuffer[_PORT].tail != __AVRUARTDriver__txBuffer[_PORT].head) { \
_UDR = __AVRUARTDriver__txBuffer[_PORT].bytes[__AVRUARTDriver__txBuffer[_PORT].tail]; \
/* increment the tail */ \
__AVRUARTDriver__txBuffer[_PORT].tail = \
(__AVRUARTDriver__txBuffer[_PORT].tail + 1) & __AVRUARTDriver__txBuffer[_PORT].mask; \
} else { \
/* there are no more bytes to send, disable the interrupt */ \
if (__AVRUARTDriver__txBuffer[_PORT].head == __AVRUARTDriver__txBuffer[_PORT].tail) \
_UCSRB &= ~_TXBITS; \
} \
} \
struct hack
//
// Portability; convert various older sets of defines for U(S)ART0 up
// to match the definitions for the 1280 and later devices.
//
#if !defined(USART0_RX_vect)
# if defined(USART_RX_vect)
# define USART0_RX_vect USART_RX_vect
# define USART0_UDRE_vect USART_UDRE_vect
# elif defined(UART0_RX_vect)
# define USART0_RX_vect UART0_RX_vect
# define USART0_UDRE_vect UART0_UDRE_vect
# endif
#endif
#if !defined(USART1_RX_vect)
# if defined(UART1_RX_vect)
# define USART1_RX_vect UART1_RX_vect
# define USART1_UDRE_vect UART1_UDRE_vect
# endif
#endif
#if !defined(UDR0)
# if defined(UDR)
# define UDR0 UDR
# define UBRR0H UBRRH
# define UBRR0L UBRRL
# define UCSR0A UCSRA
# define UCSR0B UCSRB
# define U2X0 U2X
# define RXEN0 RXEN
# define TXEN0 TXEN
# define RXCIE0 RXCIE
# define UDRIE0 UDRIE
# endif
#endif
///
/// Macro defining a AVRUARTDriver port instance.
///
#define AVRUARTDriverInstance(_name, _num) \
AVRUARTDriver _name(_num, \
&UBRR##_num##H, \
&UBRR##_num##L, \
&UCSR##_num##A, \
&UCSR##_num##B, \
U2X##_num, \
(_BV(RXEN##_num) | _BV(TXEN##_num) | _BV(RXCIE##_num)), \
(_BV(UDRIE##_num)));
#define AVRUARTDriverISRs(_num) \
AVRUARTDriverHandler(_num, \
USART##_num##_RX_vect, \
USART##_num##_UDRE_vect, \
UDR##_num, \
UCSR##_num##B, \
_BV(UDRIE##_num))
#endif
#endif // __AP_HAL_AVR_UART_DRIVER_H__