eink/eink.hpp

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#pragma once
#include <tuple>
#include <type_traits>
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#include <utility>
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#include <cstddef>
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#include <cstdint>
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#include <cstring>
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#include "eink_spi.hpp"
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#include "font.hpp"
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#include "otp.hpp"
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#include "../clock.hpp"
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#include "../flash/flash.hpp"
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#include "../io/io.hpp"
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#include "../util/util.hpp"
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namespace eink {
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template <std::uint16_t Width, std::uint16_t Height, typename Spi, io::P RstPin, io::P BusyPin>
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class Eink {
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using word_t = typename Spi::word_t;
struct original_lut_tag {
};
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static io::Pin<RstPin> m_rst;
static io::Pin<BusyPin> m_busy;
public:
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enum class Cmd : std::uint8_t {
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DRIVER_OUTPUT_CONTROL = 0x01,
DEEP_SLEEP_MODE = 0x10,
DATA_ENTRY_MODE = 0x11,
SW_RESET = 0x12,
READ_TEMPERATURE_SENSOR = 0x18,
UPDATE_DISPLAY = 0x20,
DISPLAY_UPDATE_CONTROL_2 = 0x22,
WRITE_RAM_BLACK = 0x24,
WRITE_RAM_RED = 0x26,
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READ_RAM = 0x27,
LOAD_OTP_TO_RAM = 0x31,
WRITE_LUT = 0x32,
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BORDER_WAVEFORM_CONTROL = 0x3C,
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READ_RAM_CHANNEL = 0x41,
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SET_RAM_X_ADDR_POSITIONS = 0x44,
SET_RAM_Y_ADDR_POSITIONS = 0x45,
SET_RAM_X_ADDR = 0x4E,
SET_RAM_Y_ADDR = 0x4F,
};
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enum class Color : std::uint8_t {
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BLACK = 0x00,
RED = 0x01,
WHITE = 0x02,
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};
enum class RamDirection : std::uint8_t {
DECREMENT = 0,
INCREMENT = 1,
};
enum class FastestMovingIndex : std::uint8_t {
X = 0,
Y = 1,
};
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static void init()
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{
m_rst.dir(io::Dir::OUT);
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m_busy.pullup(false);
m_busy.dir(io::Dir::IN);
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Spi::init();
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reset();
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softReset();
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sendCommand(Cmd::DRIVER_OUTPUT_CONTROL);
sendData(0xC7);
sendData(0x00);
sendData(0x01);
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setDataEntryMode(RamDirection::DECREMENT, RamDirection::INCREMENT, FastestMovingIndex::X);
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setRamRange();
setRamXPos();
setRamYPos();
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sendCommand(Cmd::BORDER_WAVEFORM_CONTROL);
sendData(0x05);
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sendCommand(Cmd::READ_TEMPERATURE_SENSOR);
sendData(0x80);
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waitUntilIdle();
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}
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static void sendCommand(const Cmd command)
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{
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Spi::select(true);
Spi::write(static_cast<word_t>(command), true);
Spi::select(false);
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}
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static void sendData(word_t data)
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{
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Spi::select(true);
Spi::write(data, false);
Spi::select(false);
}
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static word_t readData()
{
Spi::select(true);
const auto res = Spi::read();
Spi::select(false);
return res;
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}
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static void waitUntilIdle()
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{
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while (m_busy) {
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_delay_ms(100);
}
}
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static void reset()
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{
m_rst = true;
_delay_ms(200);
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m_rst = false;
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_delay_ms(10);
m_rst = true;
_delay_ms(200);
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waitUntilIdle();
}
static void softReset()
{
sendCommand(Cmd::SW_RESET);
waitUntilIdle();
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}
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static void update()
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{
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update(original_lut_tag{});
}
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template <typename Lut = original_lut_tag>
static void update(const Lut &lut)
{
constexpr auto USE_ORIGINAL_LUT = std::is_same_v<Lut, original_lut_tag>;
if constexpr (!USE_ORIGINAL_LUT) {
writeLut(lut);
}
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sendCommand(Cmd::DISPLAY_UPDATE_CONTROL_2);
sendData(USE_ORIGINAL_LUT ? 0xF7 : 0xC7);
sendCommand(Cmd::UPDATE_DISPLAY);
waitUntilIdle();
}
template <typename RleImage>
static void draw(const RleImage &rleImage)
{
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constexpr auto sendImageChannel = [](const auto command, const auto &image) {
using image_t = std::remove_cvref_t<decltype(image)>;
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sendCommand(command);
for (auto j = std::size_t{0}; j < std::tuple_size_v<image_t>; ++j) {
const auto [count, data] = flash::loadLike<RleImage>(image[j]);
for (auto i = std::uint16_t{0}; i < count; ++i) {
if (command == Cmd::WRITE_RAM_BLACK) {
sendData(data);
} else {
sendData(~data);
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}
}
}
};
sendImageChannel(Cmd::WRITE_RAM_BLACK, std::get<0>(rleImage.value));
sendImageChannel(Cmd::WRITE_RAM_RED, std::get<1>(rleImage.value));
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}
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static void clear(const Color color = Color::WHITE)
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{
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constexpr auto getFillData = [](const auto &color) -> std::pair<std::uint8_t, std::uint8_t> {
switch (color) {
case Color::BLACK:
return {0x00, 0x00};
case Color::RED:
return {0xFF, 0xFF};
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case Color::WHITE:
return {0xFF, 0x00};
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}
return {0xFF, 0x00};
};
const auto fillData = getFillData(color);
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sendCommand(Cmd::WRITE_RAM_BLACK);
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for (auto i = std::uint16_t{0}; i < Width * Height / 8; i++) {
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sendData(fillData.first);
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}
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sendCommand(Cmd::WRITE_RAM_RED);
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for (auto i = std::uint16_t{0}; i < Width * Height / 8; i++) {
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sendData(fillData.second);
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}
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}
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static void drawText(const std::pair<std::uint8_t, std::uint8_t> &pos, const char *text,
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const Color textColor = Color::BLACK, const Color backgroundColor = Color::WHITE,
const std::uint8_t scaling = 1)
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{
const auto textLength = std::strlen(text);
constexpr auto getXScreenCoordinates = [](const std::uint8_t pos) { return (Width - pos - 1) / 8; };
constexpr auto flipEndianness = [](const std::uint8_t value) {
auto flippedVal = std::uint8_t{0};
for (auto i = 0; i < 8; ++i) {
const auto oldBit = (value >> i) & 1;
flippedVal |= oldBit << (8 - i - 1);
}
return flippedVal;
};
const auto adjustColor = [&](const auto &data, const auto command) {
auto backgroundData = data;
auto outData = data & 0x00;
if (command == Cmd::WRITE_RAM_BLACK) {
if (backgroundColor == Color::BLACK) {
backgroundData = 0x00;
} else if (backgroundColor == Color::RED || backgroundColor == Color::WHITE) {
backgroundData = 0xFF;
}
if (textColor == Color::BLACK) {
outData = backgroundData & ~data;
} else if (textColor == Color::RED || textColor == Color::WHITE) {
outData = backgroundData | data;
}
} else {
if (backgroundColor == Color::BLACK || backgroundColor == Color::WHITE) {
backgroundData = 0x00;
} else if (backgroundColor == Color::RED) {
backgroundData = 0xFF;
}
if (textColor == Color::BLACK || textColor == Color::WHITE) {
outData = backgroundData & ~data;
} else if (textColor == Color::RED) {
outData = backgroundData | data;
}
}
return outData;
};
const auto sendChannel = [&](const auto command) {
for (auto i = std::size_t{0}; i < textLength; ++i) {
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const auto posX = pos.first + i * 8 * scaling;
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const auto screenPosX = getXScreenCoordinates(posX);
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setRamRange({screenPosX, screenPosX - (scaling - 1)}, {pos.second, pos.second + 8 * scaling - 1});
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setRamXPos(screenPosX);
setRamYPos(pos.second);
sendCommand(command);
for (auto j = std::uint8_t{0}; j < 8; ++j) {
const auto fontByte = flash::loadLike<decltype(FONT_8X8)>(FONT_8X8.value[text[i]][j]);
static_assert(std::is_same_v<std::remove_cvref_t<decltype(fontByte)>, std::uint8_t>);
const auto dataByte = adjustColor(flipEndianness(fontByte), command);
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auto scaledByte = std::uint8_t{0};
auto bitCounter = 0;
for (auto sy = std::uint8_t{0}; sy < scaling; ++sy) {
for (auto b = std::uint8_t{0}; b < 8; ++b) {
const auto currentBit = dataByte >> (8 - b - 1) & 1;
for (auto sx = std::uint8_t{0}; sx < scaling; ++sx) {
scaledByte |= currentBit << (8 - bitCounter - 1);
if (++bitCounter == 8) {
sendData(scaledByte);
scaledByte = 0;
bitCounter = 0;
}
}
}
}
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}
}
};
sendChannel(Cmd::WRITE_RAM_BLACK);
sendChannel(Cmd::WRITE_RAM_RED);
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setRamRange();
setRamXPos();
setRamYPos();
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}
template <typename Lut>
static void writeLut(const Lut &lut)
{
static_assert(sizeof(lut) == sizeof(Waveform), "Invalid LUT size");
sendCommand(Cmd::WRITE_LUT);
for (auto i = std::size_t{0}; i < sizeof(lut); ++i) {
const auto lutByte = lut[i];
static_assert(std::is_same_v<std::byte, std::remove_cvref_t<decltype(lutByte)>>, "Invalid LUT value type");
sendData(static_cast<word_t>(lutByte));
}
}
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static void autoPatternFill()
{
constexpr auto RED_PATTERN_FILL_CMD = static_cast<Cmd>(0x46);
constexpr auto BLACK_PATTERN_FILL_CMD = static_cast<Cmd>(0x47);
constexpr auto RED_PATTERN = 0b0'001'0'001;
constexpr auto BLACK_PATTERN = 0b1'000'0'000;
sendCommand(RED_PATTERN_FILL_CMD);
sendData(RED_PATTERN);
waitUntilIdle();
sendCommand(BLACK_PATTERN_FILL_CMD);
sendData(BLACK_PATTERN);
waitUntilIdle();
}
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static void setDataEntryMode(const RamDirection &xDir = RamDirection::INCREMENT,
const RamDirection &yDir = RamDirection::INCREMENT,
const FastestMovingIndex &fastestMovingIndex = FastestMovingIndex::X)
{
auto setting = static_cast<std::uint8_t>(xDir) << 0;
setting |= static_cast<std::uint8_t>(yDir) << 1;
setting |= static_cast<std::uint8_t>(fastestMovingIndex) << 2;
sendCommand(Cmd::DATA_ENTRY_MODE);
sendData(setting);
}
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static void setRamRange(const std::pair<std::uint8_t, std::uint8_t> &xrange = {Width / 8 - 1, 0},
const std::pair<std::uint16_t, std::uint16_t> &yrange = {0, Height - 1})
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{
sendCommand(Cmd::SET_RAM_X_ADDR_POSITIONS);
sendData(xrange.first & 0b00111111);
sendData(xrange.second & 0b00111111);
sendCommand(Cmd::SET_RAM_Y_ADDR_POSITIONS);
sendData(yrange.first & 0xFF);
sendData((yrange.first >> 8) & 0b1);
sendData(yrange.second & 0xFF);
sendData((yrange.second >> 8) & 0b1);
}
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static void setRamXPos(const std::uint8_t pos = Width / 8 - 1)
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{
sendCommand(Cmd::SET_RAM_X_ADDR);
sendData(pos & 0b00111111);
}
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static void setRamYPos(const std::uint16_t pos = 0)
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{
sendCommand(Cmd::SET_RAM_Y_ADDR);
sendData(pos & 0xFF);
sendData((pos >> 8) & 0b1);
}
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template <typename PrintFn>
static void dumpOTP(PrintFn &&printFn)
{
constexpr auto byteWidth = Width / 8;
constexpr auto ramHeight = Height + 46;
constexpr auto xRamRange = std::pair<std::uint8_t, std::uint8_t>{0, byteWidth - 1};
constexpr auto yRamRange = std::pair<std::uint16_t, std::uint16_t>{0, ramHeight - 1};
setDataEntryMode(RamDirection::INCREMENT, RamDirection::INCREMENT, FastestMovingIndex::X);
setRamRange(xRamRange, yRamRange);
setRamXPos(0);
setRamYPos(0);
sendCommand(Cmd::WRITE_RAM_BLACK);
for (auto i = std::uint16_t{0}; i < byteWidth * ramHeight; i++) {
sendData(0xFF);
}
sendCommand(Cmd::WRITE_RAM_RED);
for (auto i = std::uint16_t{0}; i < byteWidth * ramHeight; i++) {
sendData(0x00);
}
//////////////////////////////////////////////////////////////////////////
sendCommand(Cmd::DISPLAY_UPDATE_CONTROL_2);
sendData(0x80);
sendCommand(Cmd::UPDATE_DISPLAY);
waitUntilIdle();
sendCommand(Cmd::LOAD_OTP_TO_RAM);
waitUntilIdle();
setRamXPos(0);
setRamYPos(0);
sendCommand(Cmd::READ_RAM_CHANNEL);
sendData(static_cast<word_t>(Color::BLACK));
sendCommand(Cmd::READ_RAM);
readData(); // First byte must be discarded
for (auto i = std::size_t{0}; i < sizeof(OTP); ++i) {
printFn(readData());
}
init();
}
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static void sleep()
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{
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sendCommand(Cmd::DEEP_SLEEP_MODE);
sendData(0x01);
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_delay_ms(100);
}
};
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} // namespace eink