2019-07-27 18:55:17 +02:00
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#pragma once
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2019-07-28 12:15:19 +02:00
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#include "config.hpp"
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2019-07-27 18:55:17 +02:00
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2019-07-28 17:32:51 +02:00
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#define FORCE_INLINE __attribute__((always_inline))
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2019-07-27 18:55:17 +02:00
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namespace uart {
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2019-07-28 12:15:19 +02:00
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enum class Mode {
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ASYNCHRONOUS,
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ASYNCHRONOUS_2X,
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SYNCHRONOUS_MASTER,
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SYNCHRONOUS_SLAVE,
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SPI,
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};
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2019-07-28 14:09:09 +02:00
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enum class Driven {
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INTERRUPT,
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BLOCKING,
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};
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2019-07-28 17:32:51 +02:00
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namespace detail {
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struct Registers0 {
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};
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enum class SupportedHardware {
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ATmega1284P,
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};
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template <SupportedHardware>
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struct HardwareAbstraction {
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};
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template <>
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struct HardwareAbstraction<SupportedHardware::ATmega1284P> {
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struct Reg0 {
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static constexpr volatile auto *ioReg = &UDR0;
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static constexpr volatile auto *controlStatusRegA = &UCSR0A;
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static constexpr volatile auto *controlStatusRegB = &UCSR0B;
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static constexpr volatile auto *controlStatusRegC = &UCSR0C;
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static constexpr volatile auto *baudRateRegL = &UBRR0L;
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static constexpr volatile auto *baudRateRegH = &UBRR0H;
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};
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struct Reg1 {
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static constexpr volatile auto *ioReg = &UDR1;
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static constexpr volatile auto *controlStatusRegA = &UCSR1A;
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static constexpr volatile auto *controlStatusRegB = &UCSR1B;
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static constexpr volatile auto *controlStatusRegC = &UCSR1C;
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static constexpr volatile auto *baudRateRegL = &UBRR1L;
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static constexpr volatile auto *baudRateRegH = &UBRR1H;
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};
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template <uint32_t baudRate>
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static constexpr auto calcBaud()
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{
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2019-07-28 19:20:03 +02:00
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// The actual formula is (F_CPU / (16 * baudRate)) - 1, but this one has the advantage of rounding correctly
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constexpr auto baudVal = (F_CPU + 8 * baudRate) / (16 * baudRate) - 1;
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return baudVal;
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2019-07-28 17:32:51 +02:00
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}
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struct DataBitsVal {
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uint8_t ucsrcVal = 0;
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uint8_t ucsrbVal = 0;
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};
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template <DataBits dataBits>
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static constexpr auto calcDataBits()
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{
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DataBitsVal dataBitsVal;
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switch (dataBits) {
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case DataBits::FIVE:
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dataBitsVal.ucsrcVal = 0;
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break;
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case DataBits::SIX:
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dataBitsVal.ucsrcVal = (1 << UCSZ00);
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break;
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case DataBits::SEVEN:
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dataBitsVal.ucsrcVal = (1 << UCSZ01);
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break;
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case DataBits::EIGHT:
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dataBitsVal.ucsrcVal = (1 << UCSZ01) | (1 << UCSZ00);
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break;
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case DataBits::NINE:
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dataBitsVal.ucsrcVal = (1 << UCSZ01) | (1 << UCSZ00);
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dataBitsVal.ucsrbVal = (1 << UCSZ02);
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break;
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}
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return dataBitsVal;
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}
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template <Parity parity>
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static constexpr auto calcParity()
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{
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uint8_t parityVal = 0;
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if (parity == Parity::EVEN)
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parityVal = (1 << UPM01);
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else if (parity == Parity::ODD)
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parityVal = (1 << UPM01) | (1 << UPM00);
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return parityVal;
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}
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template <StopBits stopBits>
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static constexpr auto calcStopBits()
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{
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uint8_t stopBitsVal = 0;
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if (stopBits == StopBits::TWO)
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stopBitsVal = (1 << USBS0);
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return stopBitsVal;
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}
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template <Mode mode>
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static constexpr auto calcMode()
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{
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static_assert(mode != Mode::SPI, "SPI mode can not be used with uart");
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uint8_t modeVal = 0;
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if (mode == Mode::SYNCHRONOUS_MASTER || mode == Mode::SYNCHRONOUS_SLAVE) {
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modeVal = (1 << UMSEL00);
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}
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return modeVal;
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}
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template <bool enable>
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static constexpr auto calcRxState()
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{
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uint8_t enableVal = 0;
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if (enable)
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enableVal = (1 << RXEN0);
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return enableVal;
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}
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template <bool enable>
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static constexpr auto calcTxState()
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{
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uint8_t enableVal = 0;
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if (enable)
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enableVal = (1 << TXEN0);
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return enableVal;
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}
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static void setBaud(const uint16_t baudVal)
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{
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*Reg0::baudRateRegH = static_cast<uint8_t>(baudVal >> 8);
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*Reg0::baudRateRegL = static_cast<uint8_t>(baudVal);
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}
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template <uint8_t regVal>
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static void setControlRegA()
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{
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*Reg0::controlStatusRegA = regVal;
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}
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template <uint8_t regVal>
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static void setControlRegB()
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{
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*Reg0::controlStatusRegB = regVal;
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}
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template <uint8_t regVal>
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static void setControlRegC()
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{
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*Reg0::controlStatusRegC = regVal;
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}
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static void txByte(uint8_t byte) FORCE_INLINE
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{
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while (!(*Reg0::controlStatusRegA & (1 << UDRE0)))
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;
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*Reg0::ioReg = byte;
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}
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};
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static constexpr auto currentHardware = SupportedHardware::ATmega1284P;
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} // namespace detail
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2019-07-28 17:57:49 +02:00
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template <Mode mode = Mode::ASYNCHRONOUS, class cfg = Config<>, Driven driven = Driven::INTERRUPT>
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class Hardware0 {
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public:
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using data_t = typename cfg::data_t;
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static constexpr auto DATA_BITS = cfg::DATA_BITS;
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2019-07-28 17:32:51 +02:00
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static void init()
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{
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detail::HardwareAbstraction<detail::currentHardware> hal;
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hal.setBaud(hal.calcBaud<BAUD_RATE>());
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constexpr auto dataBitsVal = hal.calcDataBits<DATA_BITS>();
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constexpr auto parityVal = hal.calcParity<PARITY>();
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constexpr auto stopBitsVal = hal.calcStopBits<STOP_BITS>();
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constexpr auto modeVal = hal.calcMode<mode>();
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constexpr auto enableRx = hal.calcRxState<true>();
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constexpr auto enableTx = hal.calcTxState<true>();
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2019-07-27 18:55:17 +02:00
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2019-07-28 17:32:51 +02:00
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constexpr uint8_t ucsr0b = dataBitsVal.ucsrbVal | enableRx | enableTx;
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constexpr uint8_t ucsr0c = dataBitsVal.ucsrcVal | parityVal | stopBitsVal | modeVal;
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hal.setControlRegB<ucsr0b>();
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hal.setControlRegC<ucsr0c>();
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}
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static void txByte(data_t byte) FORCE_INLINE
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{
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2019-07-28 17:32:51 +02:00
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detail::HardwareAbstraction<detail::currentHardware> hal;
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hal.txByte(byte);
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}
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static data_t rxByte() {}
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static data_t peek() {}
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private:
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static constexpr auto BAUD_RATE = cfg::BAUD_RATE;
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static constexpr auto PARITY = cfg::PARITY;
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static constexpr auto STOP_BITS = cfg::STOP_BITS;
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2019-07-27 18:55:17 +02:00
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};
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} // namespace uart
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2019-07-28 17:32:51 +02:00
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#undef FORCE_INLINE
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