Update uart example to use latest library version

Update submodule
Adapt to new interrupt handling interface and change example back to atmega1284p
2020-10-18 12:19:19 +02:00 · 2020-04-13 17:17:38 +02:00 · 2020-04-13 16:43:48 +02:00 · 2020-04-13 13:06:31 +02:00 · 2020-04-12 23:59:18 +02:00 · 2020-04-07 03:54:40 +02:00
15 changed files with 579 additions and 1192 deletions
--- a/.gitmodules
+++ b/.gitmodules
@ -0,0 +1,12 @@
 [submodule "uart/io"]
 	path = uart/io
 	url = git@git.blackmark.me:avr/io.git
 [submodule "uart/uart"]
 	path = uart/uart
 	url = git@git.blackmark.me:avr/uart.git
 [submodule "uart/flash"]
 	path = uart/flash
 	url = git@git.blackmark.me:avr/flash.git
 [submodule "uart/util"]
 	path = uart/util
 	url = git@git.blackmark.me:avr/util.git
--- a/config.hpp
+++ b/config.hpp
@ -1,50 +0,0 @@
 #pragma once
 #include <cstdint>
 namespace uart {
 enum class DataBits {
 	FIVE,
 	SIX,
 	SEVEN,
 	EIGHT,
 	NINE,
 };
 enum class StopBits {
 	ONE,
 	TWO,
 };
 enum class Parity {
 	NONE,
 	ODD,
 	EVEN,
 };
 namespace detail {
 template <DataBits dataBits>
 struct choose_data_type {
 	using type = std::uint8_t;
 };
 template <>
 struct choose_data_type<DataBits::NINE> {
 	using type = std::uint16_t;
 };
 } // namespace detail
 template <std::uint32_t baudRate = 9600, DataBits dataBits = DataBits::EIGHT, Parity parity = Parity::NONE,
          StopBits stopBits = StopBits::ONE>
 struct Config {
 	static constexpr auto BAUD_RATE = baudRate;
 	static constexpr auto DATA_BITS = dataBits;
 	static constexpr auto PARITY = parity;
 	static constexpr auto STOP_BITS = stopBits;
 	using data_t = typename detail::choose_data_type<DATA_BITS>::type;
 };
 } // namespace uart
--- a/hardware.hpp
+++ b/hardware.hpp
@ -1,423 +0,0 @@
 #pragma once
 #include "../clock.hpp"
 #include <cmath>
 #include <cstdint>
 namespace uart {
 enum class Mode {
 	ASYNCHRONOUS,
 	SYNCHRONOUS_MASTER,
 	SYNCHRONOUS_SLAVE,
 	SPI,
 };
 enum class Driven {
 	INTERRUPT,
 	BLOCKING,
 };
 namespace detail {
 using reg_ptr_t = volatile std::uint8_t *;
 template <std::uintptr_t Address>
 static inline reg_ptr_t getRegPtr()
 {
 	return reinterpret_cast<reg_ptr_t>(Address);
 }
 template <typename data_t, std::uint8_t Size>
 struct RingBuffer {
 	std::uint8_t head;
 	std::uint8_t tail;
 	data_t buf[Size];
 };
 template <class Registers, typename CtrlFlagsA, typename CtrlFlagsB, typename CtrlFlagsC, class cfg, Driven driven,
          Mode mode>
 class Hardware {
  public:
 	[[gnu::always_inline]] static void init()
 	{
 		constexpr auto AbsDoubleError = std::fabs(calcBaudError<true>());
 		constexpr auto AbsNormalError = std::fabs(calcBaudError<false>());
 		static_assert(AbsDoubleError <= 3.0 || AbsNormalError <= 3.0, "Baud rate error over 3%, probably unusable");
 		constexpr auto UseDoubleSpeed = (AbsDoubleError < AbsNormalError);
 		constexpr auto BaudVal = calcBaudVal<UseDoubleSpeed>();
 		*getRegPtr<Registers::BAUD_REG_H_ADDR>() = static_cast<std::uint8_t>(BaudVal >> 8);
 		*getRegPtr<Registers::BAUD_REG_L_ADDR>() = static_cast<std::uint8_t>(BaudVal);
 		constexpr auto DataBitsValues = calcDataBits();
 		constexpr auto ParityVal = calcParity();
 		constexpr auto StopBitsVal = calcStopBits();
 		constexpr auto ModeVal = calcMode();
 		constexpr auto EnableRx = calcRxState<true>();
 		constexpr auto EnableTx = calcTxState<true>();
 		constexpr auto InterruptVal = calcInterrupt();
 		constexpr std::uint8_t ControlRegB = DataBitsValues.regBVal | EnableRx | EnableTx | InterruptVal;
 		constexpr std::uint8_t ControlRegC = DataBitsValues.regCVal | ParityVal | StopBitsVal | ModeVal;
 		auto ctrlStatRegA = getRegPtr<Registers::CTRL_STAT_REG_A_ADDR>();
 		if constexpr (UseDoubleSpeed)
 			*ctrlStatRegA = *ctrlStatRegA | (1 << CtrlFlagsA::SPEED_2X);
 		else
 			*ctrlStatRegA = *ctrlStatRegA & ~(1 << CtrlFlagsA::SPEED_2X);
 		*getRegPtr<Registers::CTRL_STAT_REG_B_ADDR>() = ControlRegB;
 		*getRegPtr<Registers::CTRL_STAT_REG_C_ADDR>() = ControlRegC;
 	}
 	[[gnu::always_inline]] static bool rxByteBlocking(typename cfg::data_t &byte)
 	{
 		if (*getRegPtr<Registers::CTRL_STAT_REG_A_ADDR>() & (1 << CtrlFlagsA::RECEIVE_COMPLETE)) {
 			byte = *getRegPtr<Registers::IO_REG_ADDR>();
 			return true;
 		}
 		return false;
 	}
 	[[gnu::always_inline]] static typename cfg::data_t rxByteInterrupt()
 	{
 		return *getRegPtr<Registers::IO_REG_ADDR>();
 	}
 	[[gnu::always_inline]] static bool txEmpty()
 	{
 		return *getRegPtr<Registers::CTRL_STAT_REG_A_ADDR>() & (1 << CtrlFlagsA::DATA_REG_EMPTY);
 	}
 	[[gnu::always_inline]] static bool txComplete()
 	{
 		return *getRegPtr<Registers::CTRL_STAT_REG_A_ADDR>() & (1 << CtrlFlagsA::TRANSMIT_COMPLETE);
 	}
 	[[gnu::always_inline]] static void clearTxComplete()
 	{
 		*getRegPtr<Registers::CTRL_STAT_REG_A_ADDR>() |= (1 << CtrlFlagsA::TRANSMIT_COMPLETE);
 	}
 	[[gnu::always_inline]] static void txByteBlocking(const typename cfg::data_t &byte)
 	{
 		while (!txEmpty())
 			;
 		*getRegPtr<Registers::IO_REG_ADDR>() = byte;
 	}
 	[[gnu::always_inline]] static void txByteInterrupt(volatile const typename cfg::data_t &byte)
 	{
 		*getRegPtr<Registers::IO_REG_ADDR>() = byte;
 	}
 	[[gnu::always_inline]] static bool peekBlocking()
 	{
 		if (*getRegPtr<Registers::CTRL_STAT_REG_A_ADDR>() & (1 << CtrlFlagsA::RECEIVE_COMPLETE)) {
 			return true;
 		}
 		return false;
 	}
 	[[gnu::always_inline]] static void enableDataRegEmptyInt()
 	{
 		auto ctrlStatRegB = getRegPtr<Registers::CTRL_STAT_REG_B_ADDR>();
 		*ctrlStatRegB = *ctrlStatRegB | (1 << CtrlFlagsB::DATA_REG_EMPTY_INT_ENABLE);
 	}
 	[[gnu::always_inline]] static void disableDataRegEmptyInt()
 	{
 		auto ctrlStatRegB = getRegPtr<Registers::CTRL_STAT_REG_B_ADDR>();
 		*ctrlStatRegB = *ctrlStatRegB & ~(1 << CtrlFlagsB::DATA_REG_EMPTY_INT_ENABLE);
 	}
  private:
 	struct DataBitsVal {
 		std::uint8_t regCVal = 0;
 		std::uint8_t regBVal = 0;
 	};
 	template <bool DoubleSpeed = true>
 	static constexpr auto calcBaudVal()
 	{
 		if constexpr (DoubleSpeed) {
 			constexpr auto BaudVal = static_cast<std::uint16_t>(round(F_CPU / (8.0 * cfg::BAUD_RATE) - 1));
 			return BaudVal;
 		}
 		constexpr auto BaudVal = static_cast<std::uint16_t>(round(F_CPU / (16.0 * cfg::BAUD_RATE) - 1));
 		return BaudVal;
 	}
 	template <std::uint16_t BaudVal, bool DoubleSpeed = true>
 	static constexpr auto calcBaudRate()
 	{
 		if constexpr (DoubleSpeed) {
 			constexpr auto BaudRate = static_cast<std::uint32_t>(round(F_CPU / (8.0 * (BaudVal + 1))));
 			return BaudRate;
 		}
 		constexpr auto BaudRate = static_cast<std::uint32_t>(round(F_CPU / (16.0 * (BaudVal + 1))));
 		return BaudRate;
 	}
 	template <bool DoubleSpeed = true>
 	static constexpr auto calcBaudError()
 	{
 		constexpr auto BaudVal = calcBaudVal<DoubleSpeed>();
 		constexpr auto ClosestBaudRate = calcBaudRate<BaudVal, DoubleSpeed>();
 		constexpr auto BaudError = (static_cast<double>(ClosestBaudRate) / cfg::BAUD_RATE - 1) * 100;
 		return BaudError;
 	}
 	static constexpr auto calcDataBits()
 	{
 		DataBitsVal dataBitsVal;
 		switch (cfg::DATA_BITS) {
 		case DataBits::FIVE:
 			dataBitsVal.regCVal = 0;
 			break;
 		case DataBits::SIX:
 			dataBitsVal.regCVal = (1 << CtrlFlagsC::CHAR_SIZE_0);
 			break;
 		case DataBits::SEVEN:
 			dataBitsVal.regCVal = (1 << CtrlFlagsC::CHAR_SIZE_1);
 			break;
 		case DataBits::EIGHT:
 			dataBitsVal.regCVal = (1 << CtrlFlagsC::CHAR_SIZE_1) | (1 << CtrlFlagsC::CHAR_SIZE_0);
 			break;
 		case DataBits::NINE:
 			dataBitsVal.regCVal = (1 << CtrlFlagsC::CHAR_SIZE_1) | (1 << CtrlFlagsC::CHAR_SIZE_0);
 			dataBitsVal.regBVal = (1 << CtrlFlagsB::CHAR_SIZE_2);
 			break;
 		}
 		return dataBitsVal;
 	}
 	static constexpr auto calcParity()
 	{
 		std::uint8_t parityVal = 0;
 		if (cfg::PARITY == Parity::EVEN)
 			parityVal = (1 << CtrlFlagsC::PARITY_MODE_1);
 		else if (cfg::PARITY == Parity::ODD)
 			parityVal = (1 << CtrlFlagsC::PARITY_MODE_1) | (1 << CtrlFlagsC::PARITY_MODE_0);
 		return parityVal;
 	}
 	static constexpr auto calcStopBits()
 	{
 		std::uint8_t stopBitsVal = 0;
 		if (cfg::STOP_BITS == StopBits::TWO)
 			stopBitsVal = (1 << CtrlFlagsC::STOP_BIT_SEL);
 		return stopBitsVal;
 	}
 	static constexpr auto calcMode()
 	{
 		static_assert(mode != Mode::SPI, "SPI mode can not be used with uart");
 		std::uint8_t modeVal = 0;
 		if (mode == Mode::SYNCHRONOUS_MASTER || mode == Mode::SYNCHRONOUS_SLAVE) {
 			modeVal = (1 << CtrlFlagsC::MODE_SEL_0);
 		}
 		return modeVal;
 	}
 	template <bool Enable>
 	static constexpr auto calcRxState()
 	{
 		std::uint8_t enableVal = 0;
 		if (Enable)
 			enableVal = (1 << CtrlFlagsB::RX_ENABLE);
 		return enableVal;
 	}
 	template <bool Enable>
 	static constexpr auto calcTxState()
 	{
 		std::uint8_t enableVal = 0;
 		if (Enable)
 			enableVal = (1 << CtrlFlagsB::TX_ENABLE);
 		return enableVal;
 	}
 	static constexpr auto calcInterrupt()
 	{
 		std::uint8_t interruptVal = 0;
 		if (driven == Driven::INTERRUPT)
 			interruptVal = (1 << CtrlFlagsB::RX_INT_ENABLE);
 		return interruptVal;
 	}
 };
 template <class Registers, typename CtrlFlagsA, typename CtrlFlagsB, typename CtrlFlagsC, class cfg, Mode mode>
 class BlockingHardware {
  public:
 	using data_t = typename cfg::data_t;
 	static constexpr auto DATA_BITS = cfg::DATA_BITS;
 	[[gnu::always_inline]] static void init()
 	{
 		HardwareImpl::init();
 	}
 	[[gnu::always_inline]] static void txByte(const data_t &byte)
 	{
 		HardwareImpl::txByteBlocking(byte);
 	}
 	[[gnu::always_inline]] static bool rxByte(data_t &byte)
 	{
 		return HardwareImpl::rxByteBlocking(byte);
 	}
 	[[gnu::always_inline]] static bool peek(data_t &)
 	{
 		static_assert(util::always_false_v<data_t>, "Peek with data is not supported in blocking mode");
 		return false;
 	}
 	[[gnu::always_inline]] static bool peek()
 	{
 		return HardwareImpl::peekBlocking();
 	}
 	[[gnu::always_inline]] static void flushTx()
 	{
 		while (!HardwareImpl::txEmpty())
 			;
 		while (!HardwareImpl::txComplete())
 			;
 		HardwareImpl::clearTxComplete();
 	}
  private:
 	using HardwareImpl = Hardware<Registers, CtrlFlagsA, CtrlFlagsB, CtrlFlagsC, cfg, Driven::BLOCKING, mode>;
 };
 template <class Registers, typename CtrlFlagsA, typename CtrlFlagsB, typename CtrlFlagsC, class cfg, Mode mode>
 class InterruptHardware {
  public:
 	using data_t = typename cfg::data_t;
 	static constexpr auto DATA_BITS = cfg::DATA_BITS;
 	[[gnu::always_inline]] static void txByte(const data_t &byte)
 	{
 		std::uint8_t tmpHead = (sm_txBuf.head + 1) % TX_BUFFER_SIZE;
 		while (tmpHead == sm_txBuf.tail)
 			;
 		sm_txBuf.buf[tmpHead] = byte;
 		sm_txBuf.head = tmpHead;
 		HardwareImpl::enableDataRegEmptyInt();
 	}
 	[[gnu::always_inline]] static bool rxByte(data_t &byte)
 	{
 		if (sm_rxBuf.head == sm_rxBuf.tail)
 			return false;
 		std::uint8_t tmpTail = (sm_rxBuf.tail + 1) % RX_BUFFER_SIZE;
 		byte = sm_rxBuf.buf[tmpTail];
 		sm_rxBuf.tail = tmpTail;
 		return true;
 	}
 	[[gnu::always_inline]] static bool peek(data_t &byte)
 	{
 		if (sm_rxBuf.head == sm_rxBuf.tail)
 			return false;
 		std::uint8_t tmpTail = (sm_rxBuf.tail + 1) % RX_BUFFER_SIZE;
 		byte = sm_rxBuf.buf[tmpTail];
 		return true;
 	}
 	[[gnu::always_inline]] static bool peek()
 	{
 		return (sm_rxBuf.head != sm_rxBuf.tail);
 	}
 	[[gnu::always_inline]] static void flushTx()
 	{
 		while (sm_txBuf.head != sm_txBuf.tail)
 			;
 		while (!HardwareImpl::txEmpty())
 			;
 		while (!HardwareImpl::txComplete())
 			;
 		HardwareImpl::clearTxComplete();
 	}
  protected:
 	[[gnu::always_inline]] static void rxIntHandler()
 	{
 		const auto data = HardwareImpl::rxByteInterrupt();
 		const std::uint8_t tmpHead = (sm_rxBuf.head + 1) % RX_BUFFER_SIZE;
 		if (tmpHead != sm_rxBuf.tail) {
 			sm_rxBuf.head = tmpHead;
 			sm_rxBuf.buf[tmpHead] = data;
 		} else {
 			// TODO: Handle overflow
 		}
 	}
 	[[gnu::always_inline]] static void dataRegEmptyIntHandler()
 	{
 		if (sm_txBuf.head != sm_txBuf.tail) {
 			const std::uint8_t tmpTail = (sm_txBuf.tail + 1) % TX_BUFFER_SIZE;
 			sm_txBuf.tail = tmpTail;
 			HardwareImpl::txByteInterrupt(sm_txBuf.buf[tmpTail]);
 		} else
 			HardwareImpl::disableDataRegEmptyInt();
 	}
  private:
 	using HardwareImpl = Hardware<Registers, CtrlFlagsA, CtrlFlagsB, CtrlFlagsC, cfg, Driven::INTERRUPT, mode>;
 	static constexpr auto TX_BUFFER_SIZE = 16;
 	static constexpr auto RX_BUFFER_SIZE = 16;
 	static volatile RingBuffer<data_t, TX_BUFFER_SIZE> sm_txBuf;
 	static volatile RingBuffer<data_t, RX_BUFFER_SIZE> sm_rxBuf;
 };
 template <class Registers, typename CtrlFlagsA, typename CtrlFlagsB, typename CtrlFlagsC, class cfg, Mode mode>
 volatile RingBuffer<typename InterruptHardware<Registers, CtrlFlagsA, CtrlFlagsB, CtrlFlagsC, cfg, mode>::data_t,
                    InterruptHardware<Registers, CtrlFlagsA, CtrlFlagsB, CtrlFlagsC, cfg, mode>::TX_BUFFER_SIZE>
    InterruptHardware<Registers, CtrlFlagsA, CtrlFlagsB, CtrlFlagsC, cfg, mode>::sm_txBuf = {0, 0, {0}};
 template <class Registers, typename CtrlFlagsA, typename CtrlFlagsB, typename CtrlFlagsC, class cfg, Mode mode>
 volatile RingBuffer<typename InterruptHardware<Registers, CtrlFlagsA, CtrlFlagsB, CtrlFlagsC, cfg, mode>::data_t,
                    InterruptHardware<Registers, CtrlFlagsA, CtrlFlagsB, CtrlFlagsC, cfg, mode>::RX_BUFFER_SIZE>
    InterruptHardware<Registers, CtrlFlagsA, CtrlFlagsB, CtrlFlagsC, cfg, mode>::sm_rxBuf = {0, 0, {0}};
 } // namespace detail
 } // namespace uart
--- a/hardware0.hpp
+++ b/hardware0.hpp
@ -1,152 +0,0 @@
 #pragma once
 #include <cstdint>
 #include <avr/interrupt.h>
 #include <avr/io.h>
 #include <avr/sfr_defs.h>
 #include "config.hpp"
 #include "hardware.hpp"
 namespace uart {
 namespace detail {
 #if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega328P__)
 /*
 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.
 The _SFR_ADDR macro in sfr_defs.h would give the address, but it does that by taking the address of the dereferenced
 pointer and casts it to uint16_t, which is still not a legal constexpr.
 The workaround therefore is to disable the pointer cast and dereference macro _MMIO_BYTE temporarily.
 */
 #pragma push_macro("_MMIO_BYTE")
 #undef _MMIO_BYTE
 #define _MMIO_BYTE
 struct Registers0 {
 	static constexpr std::uintptr_t IO_REG_ADDR = UDR0;
 	static constexpr std::uintptr_t CTRL_STAT_REG_A_ADDR = UCSR0A;
 	static constexpr std::uintptr_t CTRL_STAT_REG_B_ADDR = UCSR0B;
 	static constexpr std::uintptr_t CTRL_STAT_REG_C_ADDR = UCSR0C;
 	static constexpr std::uintptr_t BAUD_REG_L_ADDR = UBRR0L;
 	static constexpr std::uintptr_t BAUD_REG_H_ADDR = UBRR0H;
 };
 #pragma pop_macro("_MMIO_BYTE")
 enum class ControlFlagsA0 {
 	MULTI_PROC_COMM_MODE = MPCM0,
 	SPEED_2X = U2X0,
 	PARITY_ERROR = UPE0,
 	DATA_OVER_RUN = DOR0,
 	FRAME_ERROR = FE0,
 	DATA_REG_EMPTY = UDRE0,
 	TRANSMIT_COMPLETE = TXC0,
 	RECEIVE_COMPLETE = RXC0,
 };
 enum class ControlFlagsB0 {
 	TX_DATA_BIT_8 = TXB80,
 	RX_DATA_BIT_8 = RXB80,
 	CHAR_SIZE_2 = UCSZ02,
 	TX_ENABLE = TXEN0,
 	RX_ENABLE = RXEN0,
 	DATA_REG_EMPTY_INT_ENABLE = UDRIE0,
 	TX_INT_ENABLE = TXCIE0,
 	RX_INT_ENABLE = RXCIE0,
 };
 enum class ControlFlagsC0 {
 	CLK_POLARITY = UCPOL0,
 	CHAR_SIZE_0 = UCSZ00,
 	CHAR_SIZE_1 = UCSZ01,
 	STOP_BIT_SEL = USBS0,
 	PARITY_MODE_0 = UPM00,
 	PARITY_MODE_1 = UPM01,
 	MODE_SEL_0 = UMSEL00,
 	MODE_SEL_1 = UMSEL01,
 };
 // clang-format off
 constexpr int operator<<(const int &lhs, const ControlFlagsA0 &rhs) { return lhs << static_cast<int>(rhs); }
 constexpr int operator<<(const int &lhs, const ControlFlagsB0 &rhs) { return lhs << static_cast<int>(rhs); }
 constexpr int operator<<(const int &lhs, const ControlFlagsC0 &rhs) { return lhs << static_cast<int>(rhs); }
 // clang-format on
 #if defined(__AVR_ATmega328P__)
 #define USART0_RX_vect USART_RX_vect
 #define USART0_UDRE_vect USART_UDRE_vect
 #endif
 #else
 #error "This chip is not supported"
 #endif
 } // namespace detail
 template <class cfg = Config<>, Driven driven = Driven::INTERRUPT, Mode mode = Mode::ASYNCHRONOUS>
 class Hardware0 : public detail::BlockingHardware<detail::Registers0, detail::ControlFlagsA0, detail::ControlFlagsB0,
                                                  detail::ControlFlagsC0, cfg, mode> {
 };
 template <class cfg, Mode mode>
 class Hardware0<cfg, Driven::INTERRUPT, mode>
    : public detail::InterruptHardware<detail::Registers0, detail::ControlFlagsA0, detail::ControlFlagsB0,
                                       detail::ControlFlagsC0, cfg, mode> {
  public:
 	[[gnu::always_inline]] static void init()
 	{
 		HardwareImpl::init();
 		sei();
 	}
  private:
 	using HardwareImpl = detail::Hardware<detail::Registers0, detail::ControlFlagsA0, detail::ControlFlagsB0,
 	                                      detail::ControlFlagsC0, cfg, Driven::INTERRUPT, mode>;
 	using InterruptHardwareImpl = detail::InterruptHardware<detail::Registers0, detail::ControlFlagsA0,
 	                                                        detail::ControlFlagsB0, detail::ControlFlagsC0, cfg, mode>;
 	// Must be friends with Uart interface to call these private handlers
 	template <class Driver>
 	friend class Uart;
 	[[gnu::always_inline]] static void rxIntHandler()
 	{
 		InterruptHardwareImpl::rxIntHandler();
 	}
 	[[gnu::always_inline]] static void dataRegEmptyIntHandler()
 	{
 		InterruptHardwareImpl::dataRegEmptyIntHandler();
 	}
 };
 } // namespace uart
 //////////////////////////////////////////////////////////////////////////
 // Forward declare interrupt functions to allow adding them as friends
 extern "C" {
 void USART0_RX_vect() __attribute__((signal));
 void USART0_UDRE_vect() __attribute__((signal));
 }
 // clang-format off
 #define REGISTER_UART0_INT_VECTORS(uart_type) \
 	ISR(USART0_RX_vect)                       \
 	{                                         \
 		uart_type::rxIntHandler();            \
 	}                                         \
 	ISR(USART0_UDRE_vect)                     \
 	{                                         \
 		uart_type::dataRegEmptyIntHandler();  \
 	}                                         \
 	struct _##uart_type {}
 // clang-format on
--- a/hardware1.hpp
+++ b/hardware1.hpp
@ -1,157 +0,0 @@
 #pragma once
 #include <cstdint>
 #include <avr/interrupt.h>
 #include <avr/io.h>
 #include <avr/sfr_defs.h>
 #include "config.hpp"
 #include "hardware.hpp"
 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.
 The _SFR_ADDR macro in sfr_defs.h would give the address, but it does that by taking the address of the dereferenced
 pointer and casts it to uint16_t, which is still not a legal constexpr.
 The workaround therefore is to disable the pointer cast and dereference macro _MMIO_BYTE temporarily.
 */
 #pragma push_macro("_MMIO_BYTE")
 #undef _MMIO_BYTE
 #define _MMIO_BYTE
 struct Registers1 {
 	static constexpr std::uintptr_t IO_REG_ADDR = UDR1;
 	static constexpr std::uintptr_t CTRL_STAT_REG_A_ADDR = UCSR1A;
 	static constexpr std::uintptr_t CTRL_STAT_REG_B_ADDR = UCSR1B;
 	static constexpr std::uintptr_t CTRL_STAT_REG_C_ADDR = UCSR1C;
 	static constexpr std::uintptr_t BAUD_REG_L_ADDR = UBRR1L;
 	static constexpr std::uintptr_t BAUD_REG_H_ADDR = UBRR1H;
 };
 #pragma pop_macro("_MMIO_BYTE")
 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
 #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> {
  public:
 	[[gnu::always_inline]] static void init()
 	{
 		HardwareImpl::init();
 		sei();
 	}
  private:
 	using HardwareImpl = detail::Hardware<detail::Registers1, detail::ControlFlagsA1, detail::ControlFlagsB1,
 	                                      detail::ControlFlagsC1, cfg, Driven::INTERRUPT, mode>;
 	using InterruptHardwareImpl = detail::InterruptHardware<detail::Registers1, detail::ControlFlagsA1,
 	                                                        detail::ControlFlagsB1, detail::ControlFlagsC1, cfg, mode>;
 	// Must be friends with Uart interface to call these private handlers
 	template <class Driver>
 	friend class Uart;
 	[[gnu::always_inline]] static void rxIntHandler()
 	{
 		InterruptHardwareImpl::rxIntHandler();
 	}
 	[[gnu::always_inline]] static void dataRegEmptyIntHandler()
 	{
 		InterruptHardwareImpl::dataRegEmptyIntHandler();
 	}
 };
 #endif
 } // namespace uart
 //////////////////////////////////////////////////////////////////////////
 #ifdef HAS_UART1
 // Forward declare interrupt functions to allow adding them as friends
 extern "C" {
 void USART1_RX_vect() __attribute__((signal));
 void USART1_UDRE_vect() __attribute__((signal));
 }
 // clang-format off
 #define REGISTER_UART1_INT_VECTORS(uart_type) \
 	ISR(USART1_RX_vect)                       \
 	{                                         \
 		uart_type::rxIntHandler();            \
 	}                                         \
 	ISR(USART1_UDRE_vect)                     \
 	{                                         \
 		uart_type::dataRegEmptyIntHandler();  \
 	}                                         \
 	struct _##uart_type {                     \
 	}
 // clang-format off
 #endif
--- a/software.hpp
+++ b/software.hpp
@ -1,21 +0,0 @@
 #pragma once
 #include "config.hpp"
 #include "../io/io.hpp"
 #include "../util/util.hpp"
 namespace uart {
 template <io::P rxPin, io::P txPin, class cfg = Config<>>
 class Software {
 	static_assert(util::always_false_v<cfg>, "Not implemented");
  public:
 	using data_t = typename cfg::data_t;
 	static constexpr auto DATA_BITS = cfg::DATA_BITS;
 	static void init() {}
 };
 } // namespace uart
--- a/uart.atsln
+++ b/uart.atsln
@ -0,0 +1,22 @@
 Microsoft Visual Studio Solution File, Format Version 12.00
 # Atmel Studio Solution File, Format Version 11.00
 VisualStudioVersion = 14.0.23107.0
 MinimumVisualStudioVersion = 10.0.40219.1
 Project("{E66E83B9-2572-4076-B26E-6BE79FF3018A}") = "uart", "uart\uart.cppproj", "{DCE6C7E3-EE26-4D79-826B-08594B9AD897}"
 EndProject
 Global
 	GlobalSection(SolutionConfigurationPlatforms) = preSolution
 		Debug|AVR = Debug|AVR
 		Release|AVR = Release|AVR
 	EndGlobalSection
 	GlobalSection(ProjectConfigurationPlatforms) = postSolution
 		{DCE6C7E3-EE26-4D79-826B-08594B9AD897}.Debug|AVR.ActiveCfg = Debug|AVR
 		{DCE6C7E3-EE26-4D79-826B-08594B9AD897}.Debug|AVR.Build.0 = Debug|AVR
 		{DCE6C7E3-EE26-4D79-826B-08594B9AD897}.Release|AVR.ActiveCfg = Release|AVR
 		{DCE6C7E3-EE26-4D79-826B-08594B9AD897}.Release|AVR.Build.0 = Release|AVR
 	EndGlobalSection
 	GlobalSection(SolutionProperties) = preSolution
 		HideSolutionNode = FALSE
 	EndGlobalSection
 EndGlobal
--- a/uart.hpp
+++ b/uart.hpp
@ -1,389 +0,0 @@
 #pragma once
 #include <limits>
 #include <cstdint>
 #include "config.hpp"
 #include "software.hpp"
 #include "hardware0.hpp"
 #include "hardware1.hpp"
 #include "../flash/flash.hpp"
 #include "../util/util.hpp"
 namespace uart {
 namespace detail {
 template <typename T, T Limit, std::size_t Base>
 static constexpr std::size_t cntDigits()
 {
 	T num = Limit;
 	std::size_t cnt = 0;
 	do {
 		num /= Base;
 		++cnt;
 	} while (num > 0);
 	return cnt;
 }
 template <typename T, std::size_t Base>
 static constexpr std::size_t maxNumDigits()
 {
 	constexpr T MinVal = std::numeric_limits<T>::min();
 	constexpr T MaxVal = std::numeric_limits<T>::max();
 	constexpr T MinDigits = cntDigits<T, MinVal, Base>();
 	constexpr T MaxDigits = cntDigits<T, MaxVal, Base>();
 	return (MinDigits < MaxDigits) ? MaxDigits : MinDigits;
 }
 } // namespace detail
 template <class Driver>
 class Uart {
  public:
 	using data_t = typename Driver::data_t;
 	// Constructing a uart object does not initialize the driver to allow different specializations with the same
 	// back-end to exists at the same time
 	// Note that init must be called every time when switching specializations with the same back-end
 	Uart() = default;
 	// Moving and copying uart objects is not supported
 	Uart(const Uart &) = delete;
 	Uart(Uart &&) = delete;
 	Uart &operator=(const Uart &) = delete;
 	Uart &operator=(Uart &&) = delete;
 	// Before using the uart init must be called
 	static void init()
 	{
 		Driver::init();
 	}
 	static void txByte(const data_t &byte)
 	{
 		Driver::txByte(byte);
 	}
 	static bool rxByte(data_t &byte)
 	{
 		return Driver::rxByte(byte);
 	}
 	static bool peek(data_t &byte)
 	{
 		return Driver::peek(byte);
 	}
 	static bool peek()
 	{
 		return Driver::peek();
 	}
 	static void flushTx()
 	{
 		Driver::flushTx();
 	}
 	static void txString(const char *str)
 	{
 		static_assert(Driver::DATA_BITS == DataBits::EIGHT, "Strings are only supported with 8 data bits");
 		while (char ch = *str++)
 			txByte(ch);
 	}
 	static void txString(const ::detail::FlashString *str)
 	{
 		static_assert(Driver::DATA_BITS == DataBits::EIGHT, "Strings are only supported with 8 data bits");
 		const char *strIt = reinterpret_cast<const char *>(str);
 		while (char ch = pgm_read_byte(strIt++))
 			txByte(ch);
 	}
 	template <typename T, std::size_t Base = 10, std::size_t Padding = 0, char PadChar = '0', bool LowerCase = true>
 	static void txNumber(const T &val)
 	{
 		static_assert(std::is_integral_v<T>, "Only supported on integral types");
 		static_assert(Base >= 2, "Numbers with base less than 2 make no sense");
 		static_assert(Base <= 16, "Numbers with base higher than 16 are not supported");
 		static_assert(Padding <= detail::maxNumDigits<T, Base>(), "Cannot pad more than maximum length of number");
 		constexpr char AlphaChar = (LowerCase) ? 'a' : 'A';
 		constexpr std::size_t NumDigits = detail::maxNumDigits<T, Base>();
 		T digits = val;
 		if (digits < 0) {
 			digits = -digits;
 			txByte('-');
 		}
 		data_t buffer[NumDigits];
 		data_t *bufEnd = buffer + NumDigits - 1;
 		do {
 			const data_t lastDigit = digits % Base;
 			*bufEnd-- = (lastDigit < 10) ? ('0' + lastDigit) : (AlphaChar + lastDigit - 10);
 			digits /= Base;
 		} while (digits > 0);
 		if (Padding > 0) {
 			std::size_t strLen = buffer + NumDigits - (bufEnd + 1);
 			if (Padding > strLen) {
 				for (std::size_t i = Padding; i > strLen && bufEnd >= buffer; --i) {
 					*bufEnd-- = PadChar;
 				}
 			}
 		}
 		for (data_t *buf = bufEnd + 1; buf < buffer + NumDigits; ++buf)
 			txByte(*buf);
 	}
 	//////////////////////////////////////////////////////////////////////////
 	// Output stream overloads
 	Uart &operator<<(const char *str)
 	{
 		txString(str);
 		return *this;
 	}
 	Uart &operator<<(const ::detail::FlashString *str)
 	{
 		txString(str);
 		return *this;
 	}
 	Uart &operator<<(const char &val)
 	{
 		txByte(val);
 		return *this;
 	}
 	Uart &operator<<(const signed char &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	Uart &operator<<(const unsigned char &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	Uart &operator<<(const short &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	Uart &operator<<(const unsigned short &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	Uart &operator<<(const int &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	Uart &operator<<(const unsigned int &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	Uart &operator<<(const long &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	Uart &operator<<(const unsigned long &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	Uart &operator<<(const long long &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	Uart &operator<<(const unsigned long long &val)
 	{
 		txNumber(val);
 		return *this;
 	}
 	template <typename... Ts>
 	Uart &operator<<(float) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not supported by hardware");
 	}
 	template <typename... Ts>
 	Uart &operator<<(double) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not supported by hardware");
 	}
 	template <typename... Ts>
 	Uart &operator<<(long double) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not supported by hardware");
 	}
 	Uart &operator<<(const bool &val)
 	{
 		txString(val ? F("true") : F("false"));
 		return *this;
 	}
 	Uart &operator<<(const void *val)
 	{
 		txString(F("0x"));
 		txNumber<std::uint16_t, 16, 4, '0', false>(reinterpret_cast<std::uint16_t>(val));
 		return *this;
 	}
 	//////////////////////////////////////////////////////////////////////////
 	// Input stream overloads
 	template <typename... Ts>
 	Uart &operator>>(char &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(unsigned char &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(short &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(unsigned short &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(int &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(unsigned int &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(long &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(unsigned long &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(long long &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(unsigned long long &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(float &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not supported by hardware");
 	}
 	template <typename... Ts>
 	Uart &operator>>(double &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not supported by hardware");
 	}
 	template <typename... Ts>
 	Uart &operator>>(long double &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not supported by hardware");
 	}
 	template <typename... Ts>
 	Uart &operator>>(bool &) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
 	template <typename... Ts>
 	Uart &operator>>(const void *&) const
 	{
 		static_assert(util::always_false_v<Ts...>, "Not implemented");
 	}
  private:
 	friend void ::USART0_RX_vect();
 	friend void ::USART0_UDRE_vect();
 #ifdef HAS_UART1
 	friend void ::USART1_RX_vect();
 	friend void ::USART1_UDRE_vect();
 #endif
 	[[gnu::always_inline]] static void rxIntHandler()
 	{
 		Driver::rxIntHandler();
 	}
 	[[gnu::always_inline]] static void dataRegEmptyIntHandler()
 	{
 		Driver::dataRegEmptyIntHandler();
 	}
 };
 template <typename cfg = Config<>>
 using Uart0 = Uart<Hardware0<cfg, Driven::INTERRUPT, Mode::ASYNCHRONOUS>>;
 #ifdef HAS_UART1
 template <typename cfg = Config<>>
 using Uart1 = Uart<Hardware1<cfg, Driven::INTERRUPT, Mode::ASYNCHRONOUS>>;
 #endif
 } // namespace uart
 #undef HAS_UART1
--- a/uart/clock.hpp
+++ b/uart/clock.hpp
@ -0,0 +1,4 @@
 #pragma once
 #define F_CPU 16'000'000
 #include <util/delay.h>
--- a/uart/flash
+++ b/uart/flash
@ -0,0 +1 @@
 Subproject commit 6edb2e5a21e0ce58ff2df936caee8b84e240a46b
--- a/uart/io
+++ b/uart/io
@ -0,0 +1 @@
 Subproject commit 80de36ee7ee3e6b0842d5eaee81d54062cb496b2
--- a/uart/main.cpp
+++ b/uart/main.cpp
@ -0,0 +1,283 @@
 #include "clock.hpp"
 #include <avr/interrupt.h>
 #include <stdint.h>
 #include "flash/flash.hpp"
 #include "io/io.hpp"
 #include "uart/uart.hpp"
 using uart0_interface_t =
    uart::Uart<uart::Hardware0<uart::Config<115200>, uart::Driven::INTERRUPT, uart::Mode::ASYNCHRONOUS>>;
 using uart1_interface_t = uart::Uart1<>;
 REGISTER_UART0_INT_VECTORS(uart0_interface_t);
 REGISTER_UART1_INT_VECTORS(uart1_interface_t);
 void doubleSpeedTest()
 {
 	uart0_interface_t serial;
 	serial.init();
 	uint8_t counter = 100;
 	uint8_t data;
 	while (counter) {
 		if (serial.rxByte(data)) {
 			serial.txByte(data);
 			--counter;
 		}
 	}
 	serial << F("\r\n");
 	serial.flushTx();
 }
 void newUartUsage()
 {
 	using namespace uart;
 	Uart<Hardware0<Config<115200>, Driven::BLOCKING, Mode::ASYNCHRONOUS>> serial;
 	serial.init();
 	serial << "New uart hi from RAM. " << F("New uart hi from flash\r\n");
 	while (false) {
 		uint8_t received = 0;
 		while (!serial.peek())
 			;
 		{
 			serial << F("Peeked: ");
 			serial.txByte(received);
 			serial << F("\r\n");
 		}
 		if (serial.rxByte(received)) {
 			serial << F("Received: ");
 			serial.txByte(received);
 			serial << F("\r\n");
 		}
 	}
 	serial.flushTx();
 }
 void newUartUsage2()
 {
 	uart1_interface_t serial1;
 	auto ramString = "Hello World from RAM. ";
 	auto flashString = F("Hello World from flash\r\n");
 	serial1.init();
 	serial1 << ramString;
 	serial1 << flashString;
 	serial1.flushTx();
 }
 void newUartStreamOverloads()
 {
 	using namespace uart;
 	Uart<Hardware0<Config<115200>, Driven::BLOCKING, Mode::ASYNCHRONOUS>> serial;
 	serial.init();
 	bool bVal = true;
 	char chVal = 'c';
 	signed char schVal = 's';
 	unsigned char uchVal = 'u';
 	short shVal = -12345;
 	unsigned short ushVal = 64123;
 	int iVal = -14321;
 	unsigned int uiVal = 32146;
 	long lVal = -571474496;
 	unsigned long ulVal = 2718958144;
 	long long llVal = -45197516864960;
 	unsigned long long ullVal = 4611685969606738496;
 	serial << F("Stream overload test:") << F("\r\n");
 	serial << F("bool               : ") << bVal << F("\r\n");
 	serial << F("char               : ") << chVal << F("\r\n");
 	serial << F("signed char        : ") << schVal << F("\r\n");
 	serial << F("unsigned char      : ") << uchVal << F("\r\n");
 	serial << F("short              : ") << shVal << F("\r\n");
 	serial << F("unsigned short     : ") << ushVal << F("\r\n");
 	serial << F("int                : ") << iVal << F("\r\n");
 	serial << F("unsigned int       : ") << uiVal << F("\r\n");
 	serial << F("long               : ") << lVal << F("\r\n");
 	serial << F("unsigned long      : ") << ulVal << F("\r\n");
 	serial << F("long long          : ") << llVal << F("\r\n");
 	serial << F("unsigned long long : ") << ullVal << F("\r\n");
 	serial << F("const void         : ") << &bVal << F("\r\n");
 	auto number = 0xBADF00D;
 	serial << F("Binary             : 0b");
 	serial.txNumber<decltype(number), 2>(number);
 	serial << F("\r\n");
 	serial << F("Octal              : 0");
 	serial.txNumber<decltype(number), 8>(number);
 	serial << F("\r\n");
 	serial << F("Decimal            : ");
 	serial.txNumber<decltype(number), 10>(number);
 	serial << F("\r\n");
 	serial << F("Hex                : 0x");
 	serial.txNumber<decltype(number), 16>(number);
 	serial << F("\r\n");
 	serial.flushTx();
 }
 namespace spi {
 enum class Cpol {
 	MODE_0,
 	MODE_1,
 };
 enum class Cpha {
 	MODE_0,
 	MODE_1,
 };
 enum class DataOrder {
 	MSB,
 	LSB,
 };
 template <Cpol cpol, Cpha cpha, DataOrder dataOrder>
 struct Config {
 	static constexpr auto CPOL_MODE = cpol;
 	static constexpr auto CPHA_MODE = cpha;
 	static constexpr auto DATA_ORDER = dataOrder;
 };
 template <class Driver>
 struct spi {
 	spi()
 	{
 		Driver::init();
 	}
 };
 } // namespace spi
 namespace uart {
 template <class Config>
 class Hardware0<Config, Driven::INTERRUPT, Mode::SPI> {
  public:
 	static void init()
 	{
 		UCSR0C |= (1 << UMSEL01) | (1 << UMSEL00);
 		if (DATA_ORDER == spi::DataOrder::MSB)
 			UCSR0C &= ~(1 << UCSZ01);
 		else
 			UCSR0C |= (1 << UCSZ01);
 		if (CPOL_MODE == spi::Cpol::MODE_0)
 			UCSR0C &= ~(1 << UCPOL0);
 		else
 			UCSR0C |= (1 << UCPOL0);
 		if (CPHA_MODE == spi::Cpha::MODE_0)
 			UCSR0C &= ~(1 << UCSZ00);
 		else
 			UCSR0C |= (1 << UCSZ00);
 	}
  private:
 	static constexpr auto CPOL_MODE = Config::CPOL_MODE;
 	static constexpr auto CPHA_MODE = Config::CPHA_MODE;
 	static constexpr auto DATA_ORDER = Config::DATA_ORDER;
 };
 } // namespace uart
 void spiTest()
 {
 	using config = spi::Config<spi::Cpol::MODE_0, spi::Cpha::MODE_0, spi::DataOrder::MSB>;
 	using uartspi = uart::Hardware0<config, uart::Driven::INTERRUPT, uart::Mode::SPI>;
 	spi::spi<uartspi> uartSpi;
 }
 static inline void initUart(const uint32_t baudRate)
 {
 	UBRR0 = static_cast<uint16_t>((F_CPU + 8 * baudRate) / (16 * baudRate) - 1);
 	UCSR0A = 0;
 	UCSR0C = (1 << UCSZ01) | (1 << UCSZ00);
 	UCSR0B = (1 << RXEN0) | (1 << TXEN0);
 }
 static inline void txUart(uint8_t byte)
 {
 	while (!(UCSR0A & (1 << UDRE0)))
 		;
 	UDR0 = byte;
 }
 static inline void txString(const char *str)
 {
 	while (char ch = *str++)
 		txUart(ch);
 }
 static inline void txString(const detail::FlashString *str)
 {
 	const char *strIt = reinterpret_cast<const char *>(str);
 	while (char ch = pgm_read_byte(strIt++))
 		txUart(ch);
 }
 static inline void flushTx()
 {
 	while (!(UCSR0A & (1 << UDRE0)))
 		;
 	while (!(UCSR0A & (1 << TXC0)))
 		;
 	UCSR0A |= (1 << TXC0);
 }
 void optimalUartTest()
 {
 	auto ramString = "Hello World from RAM. ";
 	auto flashString = F("Hello World from flash\r\n");
 	initUart(115200);
 	txString(ramString);
 	txString(flashString);
 	flushTx();
 }
 int main()
 {
 	sei();
 	doubleSpeedTest();
 	newUartUsage2();
 	optimalUartTest();
 	newUartStreamOverloads();
 	txString(F("\r\n"));
 	flushTx();
 	spiTest();
 	return 0;
 }
--- a/uart/uart
+++ b/uart/uart
@ -0,0 +1 @@
 Subproject commit 119de3244588b19b4afb06f33f66f22bb80a89b5
--- a/uart/uart.cppproj
+++ b/uart/uart.cppproj
@ -0,0 +1,254 @@
 <?xml version="1.0" encoding="utf-8"?>
 <Project DefaultTargets="Build" xmlns="http://schemas.microsoft.com/developer/msbuild/2003" ToolsVersion="14.0">
  <PropertyGroup>
    <SchemaVersion>2.0</SchemaVersion>
    <ProjectVersion>7.0</ProjectVersion>
    <ToolchainName>com.Atmel.AVRGCC8.CPP</ToolchainName>
    <ProjectGuid>dce6c7e3-ee26-4d79-826b-08594b9ad897</ProjectGuid>
    <avrdevice>ATmega1284P</avrdevice>
    <avrdeviceseries>none</avrdeviceseries>
    <OutputType>Executable</OutputType>
    <Language>CPP</Language>
    <OutputFileName>$(MSBuildProjectName)</OutputFileName>
    <OutputFileExtension>.elf</OutputFileExtension>
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    <Compile Include="io\io.hpp">
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 </Project>
--- a/uart/util
+++ b/uart/util
@ -0,0 +1 @@
 Subproject commit 81b3ae244c9773e7ea8ee08af43193275db48514
Author	SHA1	Message	Date
BlackMark	d1452b6dc0	Update uart example to use latest library version	2020-10-18 12:19:19 +02:00
BlackMark	e760cf541c	Update submodule	2020-04-13 17:17:38 +02:00
BlackMark	6b90c1779f	Adapt to new interrupt handling interface and change example back to atmega1284p	2020-04-13 16:43:48 +02:00
BlackMark	8bb1bd7397	Update uart submodule	2020-04-13 13:06:31 +02:00
BlackMark	24d17688c0	Add double speed test and change to atmega328p	2020-04-12 23:59:18 +02:00
BlackMark	414ebbebff	Refactor uart utils to separate submodule	2020-04-07 03:54:40 +02:00
BlackMark	717a69c231	Updated uart submodule	2020-04-05 03:37:41 +02:00
BlackMark	f0abf335e5	Updated flash submodule	2020-04-05 00:02:33 +02:00
BlackMark	991a67bd86	Updated submodule	2020-02-21 17:50:02 +01:00
BlackMark	4d31f20714	Updated submodules and added MIT license file	2020-02-01 15:43:38 +01:00
BlackMark	85e6510cd5	Adapted to library change	2019-08-15 19:01:56 +02:00
BlackMark	2eefa7fd7f	Changed toolchain to 9.1.0 and updated submodules	2019-08-15 18:49:53 +02:00
BlackMark	dd3e69daa3	Disabled unused interrupt vectors	2019-08-15 18:13:12 +02:00
BlackMark	cc5b375b44	Updated project settings	2019-08-15 17:43:11 +02:00
BlackMark	fcdce7cc1d	Adapted example slightly and updated submodules	2019-08-14 20:00:40 +02:00
BlackMark	0354bc3020	Adapted interface to move more often used template parameters to the front	2019-08-05 20:06:42 +02:00
BlackMark	c74f1afcac	Adapted to c++ clock header	2019-08-05 19:43:00 +02:00
BlackMark	823921dcd8	Added flushing test	2019-08-03 18:46:23 +02:00
BlackMark	2ba032c103	Added test for number conversion	2019-08-03 17:33:05 +02:00
BlackMark	dafb7ee059	Added test for stream operator overloading	2019-08-03 16:53:29 +02:00
BlackMark	9b4b0cac67	Adapted to new interface	2019-08-03 16:26:32 +02:00
BlackMark	2d54e4ea45	Updated submodule	2019-08-02 19:45:02 +02:00
BlackMark	d32e2a13e6	Fixed submodule url	2019-08-02 19:31:08 +02:00
BlackMark	5047b661af	Changed example to use peeking	2019-08-02 18:22:38 +02:00
BlackMark	408ab83afb	Changed example to use rx as well	2019-08-02 17:42:12 +02:00
BlackMark	e891e1019f	Switched to only Uart1 for testing	2019-08-02 09:22:27 +02:00
BlackMark	4a25398c1e	Added Uart1 example	2019-07-30 21:51:47 +02:00
BlackMark	48e312d076	Implemented test using Peter Fleury's c uart library	2019-07-30 18:32:32 +02:00
BlackMark	59a83a304b	Used defaultet constructor for uart	2019-07-28 19:20:36 +02:00
BlackMark	011776a709	Removed test implementation	2019-07-28 18:11:23 +02:00
BlackMark	d952794c55	Refactored code to use capital letters for classes and added using namespace inside functions	2019-07-28 18:00:15 +02:00
BlackMark	9809b34bca	Implemented optimal example to compare implementations	2019-07-28 17:33:42 +02:00
BlackMark	e71d103602	Added explicit selection of interrupt driven uart	2019-07-28 14:09:52 +02:00
BlackMark	d8aee7498d	Removed unnecessary const qualifiers in template	2019-07-28 14:01:05 +02:00
BlackMark	5cd2b963fa	Added proof of concept for using hardware0 in SPI mode	2019-07-28 12:16:09 +02:00
BlackMark	ab1d55ee6f	Updated submodule	2019-07-28 10:35:32 +02:00
BlackMark	b66c33506c	Implemented proof of concept for new library interface and added basic outline of new interface	2019-07-27 18:56:31 +02:00
BlackMark	2cb62d4fac	Added flash submodule for flash strings	2019-07-27 13:38:45 +02:00
BlackMark	98bd0e1238	Added clock and io/uart submodules	2019-07-27 11:01:56 +02:00
BlackMark	f1de6c3701	Renamed library from usart to uart and wiped example to implement new library	2019-07-27 10:53:23 +02:00
BlackMark	0ec71af448	Used submodule branch as library source	2018-08-11 13:37:15 +02:00
BlackMark	8fa18f8e88	Merged changes from submodule branch	2016-10-29 17:22:34 +02:00
BlackMark	5ba8cc4ec3	Fixed submodule	2016-10-29 17:12:11 +02:00
		`@ -0,0 +1 @@`
							`Subproject commit 6edb2e5a21e0ce58ff2df936caee8b84e240a46b`
		`@ -0,0 +1 @@`
							`Subproject commit 80de36ee7ee3e6b0842d5eaee81d54062cb496b2`
		`@ -0,0 +1 @@`
							`Subproject commit 119de3244588b19b4afb06f33f66f22bb80a89b5`
		`@ -0,0 +1 @@`
							`Subproject commit 81b3ae244c9773e7ea8ee08af43193275db48514`