uart/hardware0.hpp

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#pragma once
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#include "config.hpp"
#include "hardware.hpp"
#define FORCE_INLINE __attribute__((always_inline))
namespace uart {
namespace detail {
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#if defined(__AVR_ATmega1284P__)
struct Registers0 {
static constexpr volatile auto *IO_REG = &UDR0;
static constexpr volatile auto *CTRL_STAT_REG_A = &UCSR0A;
static constexpr volatile auto *CTRL_STAT_REG_B = &UCSR0B;
static constexpr volatile auto *CTRL_STAT_REG_C = &UCSR0C;
static constexpr volatile auto *BAUD_REG_L = &UBRR0L;
static constexpr volatile auto *BAUD_REG_H = &UBRR0H;
};
enum class ControlFlagsA0 {
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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 {
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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 {
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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,
};
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// 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
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static void (*fnRx0IntHandler)() = nullptr;
static void (*fnDataReg0EmptyIntHandler)() = nullptr;
static void (*fnTx0IntHandler)() = nullptr;
ISR(USART0_RX_vect)
{
if (fnRx0IntHandler)
fnRx0IntHandler();
}
ISR(USART0_UDRE_vect)
{
if (fnDataReg0EmptyIntHandler)
fnDataReg0EmptyIntHandler();
}
ISR(USART0_TX_vect)
{
if (fnTx0IntHandler)
fnTx0IntHandler();
}
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#else
#error "This chip is not supported"
#endif
} // namespace detail
template <Mode mode = Mode::ASYNCHRONOUS, class cfg = Config<>, Driven driven = Driven::INTERRUPT>
class Hardware0 {
public:
using data_t = typename cfg::data_t;
static constexpr auto DATA_BITS = cfg::DATA_BITS;
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static void init() FORCE_INLINE
{
HardwareImpl::init();
}
static void txByte(data_t byte) FORCE_INLINE
{
HardwareImpl::txByteBlocking(byte);
}
static bool rxByte(data_t &byte) FORCE_INLINE
{
return false;
}
static data_t peek() FORCE_INLINE {}
private:
using HardwareImpl = detail::Hardware<detail::Registers0, detail::ControlFlagsA0, detail::ControlFlagsB0,
detail::ControlFlagsC0, cfg, mode, driven>;
};
template <Mode mode, class cfg>
class Hardware0<mode, cfg, Driven::INTERRUPT> {
public:
using data_t = typename cfg::data_t;
static constexpr auto DATA_BITS = cfg::DATA_BITS;
static void init() FORCE_INLINE
{
detail::fnRx0IntHandler = rxIntHandler;
detail::fnDataReg0EmptyIntHandler = dataRegEmptyIntHandler;
detail::fnTx0IntHandler = txIntHandler;
HardwareImpl::init();
}
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static void txByte(const data_t &byte) FORCE_INLINE
{
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uint8_t tmpHead = (sm_txBuf.head + 1) % TX_BUFFER_SIZE;
while (tmpHead == sm_txBuf.tail)
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;
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sm_txBuf.buf[tmpHead] = byte;
sm_txBuf.head = tmpHead;
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HardwareImpl::enableDataRegEmptyInt();
}
static bool rxByte(data_t &byte) FORCE_INLINE
{
if (sm_rxBuf.head == sm_rxBuf.tail)
return false;
uint8_t tmpTail = (sm_rxBuf.tail + 1) % RX_BUFFER_SIZE;
byte = sm_rxBuf.buf[tmpTail];
sm_rxBuf.tail = tmpTail;
return true;
}
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static data_t peek() FORCE_INLINE {}
private:
using HardwareImpl = detail::Hardware<detail::Registers0, detail::ControlFlagsA0, detail::ControlFlagsB0,
detail::ControlFlagsC0, cfg, mode, Driven::INTERRUPT>;
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static constexpr auto TX_BUFFER_SIZE = 16;
static constexpr auto RX_BUFFER_SIZE = 16;
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static volatile detail::RingBuffer<data_t, TX_BUFFER_SIZE> sm_txBuf;
static volatile detail::RingBuffer<data_t, RX_BUFFER_SIZE> sm_rxBuf;
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static void rxIntHandler()
{
uint8_t tmpHead = (sm_rxBuf.head + 1) % RX_BUFFER_SIZE;
if (tmpHead != sm_rxBuf.tail) {
sm_rxBuf.head = tmpHead;
sm_rxBuf.buf[tmpHead] = HardwareImpl::rxByteInterrupt();
}
}
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static void dataRegEmptyIntHandler() FORCE_INLINE
{
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if (sm_txBuf.head != sm_txBuf.tail) {
uint8_t tmpTail = (sm_txBuf.tail + 1) % TX_BUFFER_SIZE;
sm_txBuf.tail = tmpTail;
HardwareImpl::txByteInterrupt(sm_txBuf.buf[tmpTail]);
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} else
HardwareImpl::disableDataRegEmptyInt();
}
static void txIntHandler()
{
// TODO
}
};
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template <Mode mode, class cfg>
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volatile detail::RingBuffer<typename Hardware0<mode, cfg, Driven::INTERRUPT>::data_t,
Hardware0<mode, cfg, Driven::INTERRUPT>::TX_BUFFER_SIZE>
Hardware0<mode, cfg, Driven::INTERRUPT>::sm_txBuf = {0, 0, {0}};
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template <Mode mode, class cfg>
volatile detail::RingBuffer<typename Hardware0<mode, cfg, Driven::INTERRUPT>::data_t,
Hardware0<mode, cfg, Driven::INTERRUPT>::RX_BUFFER_SIZE>
Hardware0<mode, cfg, Driven::INTERRUPT>::sm_rxBuf = {0, 0, {0}};
} // namespace uart
#undef FORCE_INLINE