#pragma once #include #include #include "../clock.hpp" #include "../io/io.hpp" #include "../util/util.hpp" namespace eink { template class Eink { struct Cmd { static constexpr auto SW_RESET = uint8_t{0x12}; static constexpr auto DRIVER_OUTPUT_CONTROL = uint8_t{0x01}; static constexpr auto DATA_ENTRY_MODE = uint8_t{0x11}; static constexpr auto SET_RAM_X_ADDR_POSITIONS = uint8_t{0x44}; static constexpr auto SET_RAM_Y_ADDR_POSITIONS = uint8_t{0x45}; static constexpr auto BORDER_WAVEFORM_CONTROL = uint8_t{0x3C}; static constexpr auto READ_TEMPERATURE_SENSOR = uint8_t{0x18}; static constexpr auto SET_RAM_X_ADDR = uint8_t{0x4E}; static constexpr auto SET_RAM_Y_ADDR = uint8_t{0x4F}; static constexpr auto WRITE_RAM_BLACK = uint8_t{0x24}; static constexpr auto WRITE_RAM_RED = uint8_t{0x26}; static constexpr auto DISPLAY_UPDATE_CONTROL_2 = uint8_t{0x22}; static constexpr auto UPDATE_DISPLAY = uint8_t{0x20}; static constexpr auto DEEP_SLEEP_MODE = uint8_t{0x10}; }; static io::Pin m_rst; static io::Pin m_dc; static io::Pin m_bsy; public: static void init() { m_rst.dir(io::Dir::OUT); m_dc.dir(io::Dir::OUT); m_bsy.dir(io::Dir::IN); Spi::init(); reset(); waitUntilIdle(); sendCommand(Cmd::SW_RESET); waitUntilIdle(); sendCommand(Cmd::DRIVER_OUTPUT_CONTROL); sendData(0xC7); sendData(0x00); sendData(0x01); sendCommand(Cmd::DATA_ENTRY_MODE); sendData(0x02); sendCommand(Cmd::SET_RAM_X_ADDR_POSITIONS); sendData(Width / 8 - 1); sendData(0x00); sendCommand(Cmd::SET_RAM_Y_ADDR_POSITIONS); sendData(0x00); sendData(0x00); sendData(Height - 1); sendData(0x00); sendCommand(Cmd::BORDER_WAVEFORM_CONTROL); sendData(0x05); sendCommand(Cmd::READ_TEMPERATURE_SENSOR); sendData(0x80); sendCommand(Cmd::SET_RAM_X_ADDR); sendData(Width / 8 - 1); sendCommand(Cmd::SET_RAM_Y_ADDR); sendData(0x00); sendData(0x00); waitUntilIdle(); } static void sendCommand(const uint8_t command) { m_dc = false; spiTransfer(command); } static void sendData(const uint8_t data) { m_dc = true; spiTransfer(data); } static void waitUntilIdle() { while (m_bsy) { _delay_ms(100); } } static void reset() { m_rst = true; _delay_ms(200); m_rst = false; _delay_ms(10); m_rst = true; _delay_ms(200); } static void draw(const uint8_t *image) { constexpr auto BLOCK_SIZE = 5; enum class Color : uint8_t { BLACK = 0b00, WHITE = 0b01, RED = 0b10, ERROR = 0b11, }; class Block { public: inline Color &operator[](const size_t idx) { return data[idx]; } inline const Color &operator[](const size_t idx) const { return data[idx]; } private: Color data[BLOCK_SIZE]; }; constexpr auto lookup = [](uint8_t bits) { auto block = Block{}; for_constexpr( [&](const auto idx) { block[idx.value] = static_cast(bits % 3); bits /= 3; }, util::make_index_sequence{}); return block; }; constexpr auto sendImageChannel = [lookup](const auto command, const auto image) { sendCommand(command); auto buffer = uint8_t{0}; auto bufferPos = uint8_t{0}; for (auto i = uint16_t{0}; i < Width * Height / BLOCK_SIZE; i++) { const auto block = lookup(pgm_read_byte(&image[i])); for (auto p = uint8_t{0}; p < BLOCK_SIZE; ++p) { const auto pixel = uint8_t{(command == Cmd::WRITE_RAM_BLACK) ? (block[p] != Color::BLACK) : (block[p] == Color::RED)}; buffer |= pixel << (7 - bufferPos++); if (bufferPos == 8) { sendData(buffer); buffer = 0; bufferPos = 0; } } } }; sendImageChannel(Cmd::WRITE_RAM_BLACK, image); sendImageChannel(Cmd::WRITE_RAM_RED, image); sendCommand(Cmd::DISPLAY_UPDATE_CONTROL_2); sendData(0xF7); sendCommand(Cmd::UPDATE_DISPLAY); waitUntilIdle(); } static void clear() { sendCommand(Cmd::WRITE_RAM_BLACK); for (auto i = uint16_t{0}; i < Width * Height / 8; i++) { sendData(0xff); } sendCommand(Cmd::WRITE_RAM_RED); for (auto i = uint16_t{0}; i < Width * Height / 8; i++) { sendData(0x00); } sendCommand(Cmd::DISPLAY_UPDATE_CONTROL_2); sendData(0xF7); sendCommand(Cmd::UPDATE_DISPLAY); waitUntilIdle(); } static void sleep() { sendCommand(Cmd::DEEP_SLEEP_MODE); sendData(0x01); _delay_ms(100); } static void spiTransfer(const uint8_t data) { Spi::select(true); Spi::transfer(data); Spi::select(false); } }; } // namespace eink