uart/hardware1.hpp

#pragma once

#include <stdint.h>

#include <avr/interrupt.h>
#include <avr/io.h>
#include <avr/sfr_defs.h>

#include "config.hpp"
#include "hardware.hpp"

#define FORCE_INLINE __attribute__((always_inline))

namespace uart {

namespace detail {

#if defined(__AVR_ATmega1284P__)

/*
The following works in avr-gcc 5.4.0, but is not legal C++, because ptr's are not legal constexpr's
  constexpr auto *foo = ptr;

Workaround is to store the the address of the ptr in a uintptr_t and reinterpret_cast it at call site
For this the sfr_defs.h provides a macro which returns the address of a register
*/

struct Registers1 {
	static constexpr uintptr_t IO_REG_ADDR = _SFR_ADDR(UDR1);
	static constexpr uintptr_t CTRL_STAT_REG_A_ADDR = _SFR_ADDR(UCSR1A);
	static constexpr uintptr_t CTRL_STAT_REG_B_ADDR = _SFR_ADDR(UCSR1B);
	static constexpr uintptr_t CTRL_STAT_REG_C_ADDR = _SFR_ADDR(UCSR1C);
	static constexpr uintptr_t BAUD_REG_L_ADDR = _SFR_ADDR(UBRR1L);
	static constexpr uintptr_t BAUD_REG_H_ADDR = _SFR_ADDR(UBRR1H);
};

enum class ControlFlagsA1 {
	MULTI_PROC_COMM_MODE = MPCM1,
	SPEED_2X = U2X1,
	PARITY_ERROR = UPE1,
	DATA_OVER_RUN = DOR1,
	FRAME_ERROR = FE1,
	DATA_REG_EMPTY = UDRE1,
	TRANSMIT_COMPLETE = TXC1,
	RECEIVE_COMPLETE = RXC1,
};

enum class ControlFlagsB1 {
	TX_DATA_BIT_8 = TXB81,
	RX_DATA_BIT_8 = RXB81,
	CHAR_SIZE_2 = UCSZ12,
	TX_ENABLE = TXEN1,
	RX_ENABLE = RXEN1,
	DATA_REG_EMPTY_INT_ENABLE = UDRIE1,
	TX_INT_ENABLE = TXCIE1,
	RX_INT_ENABLE = RXCIE1,
};

enum class ControlFlagsC1 {
	CLK_POLARITY = UCPOL1,
	CHAR_SIZE_0 = UCSZ10,
	CHAR_SIZE_1 = UCSZ11,
	STOP_BIT_SEL = USBS1,
	PARITY_MODE_0 = UPM10,
	PARITY_MODE_1 = UPM11,
	MODE_SEL_0 = UMSEL10,
	MODE_SEL_1 = UMSEL11,
};

// clang-format off
constexpr int operator<<(const int &lhs, const ControlFlagsA1 &rhs) { return lhs << static_cast<int>(rhs); }
constexpr int operator<<(const int &lhs, const ControlFlagsB1 &rhs) { return lhs << static_cast<int>(rhs); }
constexpr int operator<<(const int &lhs, const ControlFlagsC1 &rhs) { return lhs << static_cast<int>(rhs); }
// clang-format on

extern void (*fnRx1IntHandler)();
extern void (*fnDataReg1EmptyIntHandler)();

#define HAS_UART1

#endif

} // namespace detail

#ifdef HAS_UART1

template <class cfg = Config<>, Driven driven = Driven::INTERRUPT, Mode mode = Mode::ASYNCHRONOUS>
class Hardware1 : public detail::BlockingHardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,
                                                  detail::ControlFlagsC1, cfg, mode> {
};

template <class cfg, Mode mode>
class Hardware1<cfg, Driven::INTERRUPT, mode>
    : public detail::InterruptHardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,
                                       detail::ControlFlagsC1, cfg, mode> {
	using detail::InterruptHardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,
	                                detail::ControlFlagsC1, cfg, mode>::rxIntHandler;

	using detail::InterruptHardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,
	                                detail::ControlFlagsC1, cfg, mode>::dataRegEmptyIntHandler;

	using HardwareImpl = detail::Hardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,
	                                      detail::ControlFlagsC1, cfg, Driven::INTERRUPT, mode>;

  public:
	static void init() FORCE_INLINE
	{
		detail::fnRx1IntHandler = rxIntHandler;
		detail::fnDataReg1EmptyIntHandler = dataRegEmptyIntHandler;

		HardwareImpl::init();
		sei();
	}
};

#endif

} // namespace uart

#undef FORCE_INLINE
Added basic layout for new library implementation 2019-07-27 18:55:17 +02:00			`#pragma once`
Implemented hardware abstraction that both hardware0 and hardware1 can use 2019-07-30 21:43:52 +02:00
Fixed missing headers 2019-08-02 20:23:54 +02:00			`#include <stdint.h>`

Added enabling of interrupts for interrupt driven uart 2019-08-05 17:59:33 +02:00			`#include <avr/interrupt.h>`
Fixed missing headers 2019-08-02 20:23:54 +02:00			`#include <avr/io.h>`
Fixed non-compliant use of constexpr for pointers 2019-08-10 14:12:10 +02:00			`#include <avr/sfr_defs.h>`
Fixed missing headers 2019-08-02 20:23:54 +02:00
Fixed header includes 2019-08-02 09:31:02 +02:00			`#include "config.hpp"`
Moved hardware abstraction to separate header 2019-08-02 09:21:47 +02:00			`#include "hardware.hpp"`
Implemented hardware abstraction that both hardware0 and hardware1 can use 2019-07-30 21:43:52 +02:00
			`#define FORCE_INLINE __attribute__((always_inline))`

			`namespace uart {`

			`namespace detail {`

			`#if defined(__AVR_ATmega1284P__)`

Fixed non-compliant use of constexpr for pointers 2019-08-10 14:12:10 +02:00			`/*`
			`The following works in avr-gcc 5.4.0, but is not legal C++, because ptr's are not legal constexpr's`
			`constexpr auto *foo = ptr;`

			`Workaround is to store the the address of the ptr in a uintptr_t and reinterpret_cast it at call site`
Replaced workaround with provided macro 2019-08-15 17:48:41 +02:00			`For this the sfr_defs.h provides a macro which returns the address of a register`
Fixed non-compliant use of constexpr for pointers 2019-08-10 14:12:10 +02:00			`*/`

Implemented hardware abstraction that both hardware0 and hardware1 can use 2019-07-30 21:43:52 +02:00			`struct Registers1 {`
Replaced workaround with provided macro 2019-08-15 17:48:41 +02:00			`static constexpr uintptr_t IO_REG_ADDR = _SFR_ADDR(UDR1);`
			`static constexpr uintptr_t CTRL_STAT_REG_A_ADDR = _SFR_ADDR(UCSR1A);`
			`static constexpr uintptr_t CTRL_STAT_REG_B_ADDR = _SFR_ADDR(UCSR1B);`
			`static constexpr uintptr_t CTRL_STAT_REG_C_ADDR = _SFR_ADDR(UCSR1C);`
			`static constexpr uintptr_t BAUD_REG_L_ADDR = _SFR_ADDR(UBRR1L);`
			`static constexpr uintptr_t BAUD_REG_H_ADDR = _SFR_ADDR(UBRR1H);`
Implemented hardware abstraction that both hardware0 and hardware1 can use 2019-07-30 21:43:52 +02:00			`};`

			`enum class ControlFlagsA1 {`
			`MULTI_PROC_COMM_MODE = MPCM1,`
			`SPEED_2X = U2X1,`
			`PARITY_ERROR = UPE1,`
			`DATA_OVER_RUN = DOR1,`
			`FRAME_ERROR = FE1,`
			`DATA_REG_EMPTY = UDRE1,`
			`TRANSMIT_COMPLETE = TXC1,`
			`RECEIVE_COMPLETE = RXC1,`
			`};`

			`enum class ControlFlagsB1 {`
			`TX_DATA_BIT_8 = TXB81,`
			`RX_DATA_BIT_8 = RXB81,`
			`CHAR_SIZE_2 = UCSZ12,`
			`TX_ENABLE = TXEN1,`
			`RX_ENABLE = RXEN1,`
			`DATA_REG_EMPTY_INT_ENABLE = UDRIE1,`
			`TX_INT_ENABLE = TXCIE1,`
			`RX_INT_ENABLE = RXCIE1,`
			`};`

			`enum class ControlFlagsC1 {`
			`CLK_POLARITY = UCPOL1,`
			`CHAR_SIZE_0 = UCSZ10,`
			`CHAR_SIZE_1 = UCSZ11,`
			`STOP_BIT_SEL = USBS1,`
			`PARITY_MODE_0 = UPM10,`
			`PARITY_MODE_1 = UPM11,`
			`MODE_SEL_0 = UMSEL10,`
			`MODE_SEL_1 = UMSEL11,`
			`};`

Improved formatting 2019-07-30 21:51:13 +02:00			`// clang-format off`
			`constexpr int operator<<(const int &lhs, const ControlFlagsA1 &rhs) { return lhs << static_cast<int>(rhs); }`
			`constexpr int operator<<(const int &lhs, const ControlFlagsB1 &rhs) { return lhs << static_cast<int>(rhs); }`
			`constexpr int operator<<(const int &lhs, const ControlFlagsC1 &rhs) { return lhs << static_cast<int>(rhs); }`
			`// clang-format on`
Implemented hardware abstraction that both hardware0 and hardware1 can use 2019-07-30 21:43:52 +02:00
Moved interrupt vectors to their own translation unit to solve redefinition error 2019-08-02 20:29:04 +02:00			`extern void (*fnRx1IntHandler)();`
			`extern void (*fnDataReg1EmptyIntHandler)();`
Changed interrupt order to match vector numbers 2019-08-02 15:46:07 +02:00
Implemented hardware abstraction that both hardware0 and hardware1 can use 2019-07-30 21:43:52 +02:00			`#define HAS_UART1`

			`#endif`

			`} // namespace detail`

			`#ifdef HAS_UART1`

Changed template parameter order 2019-08-05 20:05:59 +02:00			`template <class cfg = Config<>, Driven driven = Driven::INTERRUPT, Mode mode = Mode::ASYNCHRONOUS>`
Refactored code to get rid of code duplication 2019-08-14 19:49:42 +02:00			`class Hardware1 : public detail::BlockingHardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,`
			`detail::ControlFlagsC1, cfg, mode> {`
			`};`
Implemented peeking with and without data for interrupt and blocking mode 2019-08-02 18:20:06 +02:00
Refactored code to get rid of code duplication 2019-08-14 19:49:42 +02:00			`template <class cfg, Mode mode>`
			`class Hardware1<cfg, Driven::INTERRUPT, mode>`
			`: public detail::InterruptHardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,`
			`detail::ControlFlagsC1, cfg, mode> {`
			`using detail::InterruptHardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,`
			`detail::ControlFlagsC1, cfg, mode>::rxIntHandler;`
Added basic structure to support interrupt driven operation 2019-08-02 12:08:16 +02:00
Refactored code to get rid of code duplication 2019-08-14 19:49:42 +02:00			`using detail::InterruptHardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,`
			`detail::ControlFlagsC1, cfg, mode>::dataRegEmptyIntHandler;`
Added flushing of transmit buffer 2019-08-03 17:52:28 +02:00
Added basic structure to support interrupt driven operation 2019-08-02 12:08:16 +02:00			`using HardwareImpl = detail::Hardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,`
Refactored code to get rid of code duplication 2019-08-14 19:49:42 +02:00			`detail::ControlFlagsC1, cfg, Driven::INTERRUPT, mode>;`
Added basic structure to support interrupt driven operation 2019-08-02 12:08:16 +02:00
			`public:`
			`static void init() FORCE_INLINE`
			`{`
			`detail::fnRx1IntHandler = rxIntHandler;`
Changed interrupt order to match vector numbers 2019-08-02 15:46:07 +02:00			`detail::fnDataReg1EmptyIntHandler = dataRegEmptyIntHandler;`
Added basic structure to support interrupt driven operation 2019-08-02 12:08:16 +02:00
			`HardwareImpl::init();`
Added enabling of interrupts for interrupt driven uart 2019-08-05 17:59:33 +02:00			`sei();`
Added basic structure to support interrupt driven operation 2019-08-02 12:08:16 +02:00			`}`
Implemented hardware abstraction that both hardware0 and hardware1 can use 2019-07-30 21:43:52 +02:00			`};`

			`#endif`

			`} // namespace uart`

			`#undef FORCE_INLINE`