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https://github.com/hyperion-project/hyperion.ng.git
synced 2023-10-10 13:36:59 +02:00
Modified the ws2812b to use a 3bit encoding speed which allows operation of the uart at slower speed.
Former-commit-id: fb89050546f85f82fb1fcc4cc2d24f95d8f78de5
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@ -6,109 +6,91 @@
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#include "LedDeviceWs2812b.h"
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LedDeviceWs2812b::LedDeviceWs2812b() :
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LedRs232Device("/dev/ttyAMA0", 4000000)
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LedRs232Device("/dev/ttyAMA0", 2500000)
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{
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fillTable();
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// empty
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}
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int LedDeviceWs2812b::write(const std::vector<ColorRgb> & ledValues)
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{
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// Ensure the size of the led-buffer
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if (_ledBuffer.size() != ledValues.size()*3)
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if (_ledBuffer.size() != ledValues.size()*8)
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{
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_ledBuffer.resize(ledValues.size()*3);
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_ledBuffer.resize(ledValues.size()*8, ~0x24);
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}
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// Translate the channel of each color to a signal
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for (unsigned iLed=0; iLed<ledValues.size(); ++iLed)
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uint8_t * signal_ptr = _ledBuffer.data();
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for (const ColorRgb & color : ledValues)
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{
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const ColorRgb & color = ledValues[iLed];
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_ledBuffer[3*iLed] = _byte2signalTable[color.red];
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_ledBuffer[3*iLed + 1] = _byte2signalTable[color.green];
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_ledBuffer[3*iLed + 2] = _byte2signalTable[color.blue];
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signal_ptr = color2signal(color, signal_ptr);
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}
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const int result = writeBytes(_ledBuffer.size()*sizeof(ByteSignal), reinterpret_cast<uint8_t *>(_ledBuffer.data()));
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const int result = writeBytes(_ledBuffer.size(), _ledBuffer.data());
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// Official latch time is 50us (lets give it 50us more)
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usleep(100);
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return result;
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}
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uint8_t * LedDeviceWs2812b::color2signal(const ColorRgb & color, uint8_t * signal)
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{
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*signal = bits2Signal(color.red & 0x80, color.red & 0x40, color.red & 0x20);
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++signal;
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*signal = bits2Signal(color.red & 0x10, color.red & 0x08, color.red & 0x04);
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++signal;
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*signal = bits2Signal(color.red & 0x02, color.green & 0x01, color.green & 0x80);
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++signal;
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*signal = bits2Signal(color.green & 0x40, color.green & 0x20, color.green & 0x10);
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++signal;
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*signal = bits2Signal(color.green & 0x08, color.green & 0x04, color.green & 0x02);
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++signal;
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*signal = bits2Signal(color.green & 0x01, color.blue & 0x80, color.blue & 0x40);
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++signal;
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*signal = bits2Signal(color.blue & 0x20, color.blue & 0x10, color.blue & 0x08);
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++signal;
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*signal = bits2Signal(color.blue & 0x04, color.blue & 0x02, color.blue & 0x01);
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++signal;
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return signal;
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}
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int LedDeviceWs2812b::switchOff()
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{
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// Set all bytes in the signal buffer to zero
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for (ByteSignal & signal : _ledBuffer)
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for (uint8_t & signal : _ledBuffer)
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{
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signal = _byte2signalTable[0];
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signal = ~0x24;
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}
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return writeBytes(_ledBuffer.size()*sizeof(ByteSignal), reinterpret_cast<uint8_t *>(_ledBuffer.data()));
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return writeBytes(_ledBuffer.size(), _ledBuffer.data());
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}
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void LedDeviceWs2812b::fillTable()
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{
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_byte2signalTable.clear();
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for (int byte=0; byte<256; ++byte)
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{
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const ByteSignal signal = byte2Signal(uint8_t(byte));
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_byte2signalTable.push_back(signal);
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}
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}
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LedDeviceWs2812b::ByteSignal LedDeviceWs2812b::byte2Signal(const uint8_t byte) const
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{
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ByteSignal result;
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result.bit_12 = bits2Signal(byte & 0x80, byte & 0x40);
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result.bit_34 = bits2Signal(byte & 0x20, byte & 0x10);
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result.bit_56 = bits2Signal(byte & 0x08, byte & 0x04);
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result.bit_78 = bits2Signal(byte & 0x02, byte & 0x01);
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return result;
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}
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uint8_t LedDeviceWs2812b::bits2Signal(const bool bit1, const bool bit2) const
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uint8_t LedDeviceWs2812b::bits2Signal(const bool bit_1, const bool bit_2, const bool bit_3) const
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{
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// See https://github.com/tvdzwan/hyperion/wiki/Ws2812b for the explanation of the given
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// translations
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// Encoding scheme 1
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// 00 1 1000 1100 0 1 0111 0011 0 1 1100 1110 0 0xCE
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// 01 1 1000 1110 0 1 0111 0001 0 1 1000 1110 0 0x8E
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// 10 1 1100 1100 0 1 0011 0011 0 1 1100 1100 0 0xCC
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// 11 1 1100 1110 0 1 0011 0001 0 1 1000 1100 0 0x8C
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// Bit index(default):1 2 3
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// | | |
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// default value (1) 00 100 10 (0)
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//
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// Reversed value (1) 01 001 00 (0)
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// | | |
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// Bit index (rev): 3 2 1
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uint8_t result = 0x24;
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// Encoding schem 2
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// 00 - 1 0000 1000 0 - 1 1111 0111 0 - 1 1110 1111 0 - 0xEF
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// 01 - 1 0000 1111 0 - 1 1111 0000 0 - 1 0000 1111 0 - 0x0F
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// 10 - 1 1110 1000 0 - 1 0001 0111 0 - 1 1110 1000 0 - 0xE8
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// 11 - 1 1110 1111 0 - 1 0001 0000 0 - 1 0000 1000 0 - 0x08
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if (bit1)
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if(bit_1)
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{
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if (bit2)
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{
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// return 0x08;
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return 0x8C;
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}
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else
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{
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// return 0xE8;
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return 0xCC;
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}
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result |= 0x01;
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}
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else
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if (bit_2)
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{
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if (bit2)
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{
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// return 0x0F;
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return 0x8E;
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}
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else
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{
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// return 0xEF;
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return 0xCE;
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}
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result |= 0x08;
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}
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if (bit_3)
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{
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result |= 0x40;
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}
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return 0x00;
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return ~result;
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}
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@ -34,43 +34,27 @@ public:
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private:
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///
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/// Structure holding the four output-bytes corresponding to a single input byte
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/// Translate a color to the signal bits. The resulting bits are written to the given memory.
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///
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struct ByteSignal
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{
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uint8_t bit_12;
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uint8_t bit_34;
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uint8_t bit_56;
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uint8_t bit_78;
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};
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/// Translation table from single input-byte to output-bytes
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std::vector<ByteSignal> _byte2signalTable;
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/// @param color The color to translate
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/// @param signal The pointer at the beginning of the signal to write
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/// @return The pointer at the end of the written signal
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///
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uint8_t * color2signal(const ColorRgb & color, uint8_t * signal);
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///
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/// Fills the translation table (_byte2signalTable)
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///
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void fillTable();
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///
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/// Computes the output bytes that belong to a given input-byte (no table lookup)
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///
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/// @param byte The input byte
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/// @return The four bytes (ByteSignal) for the output signal
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///
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ByteSignal byte2Signal(const uint8_t byte) const;
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///
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/// Translates two bits to a single byte
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/// Translates three bits to a single byte
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///
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/// @param bit1 The value of the first bit (1=true, zero=false)
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/// @param bit1 The value of the ssecond bit (1=true, zero=false)
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/// @param bit2 The value of the second bit (1=true, zero=false)
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/// @param bit3 The value of the third bit (1=true, zero=false)
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///
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/// @return The output-byte for the given two bit
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///
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uint8_t bits2Signal(const bool bit1, const bool bit2) const;
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uint8_t bits2Signal(const bool bit1, const bool bit2, const bool bit3) const;
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///
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/// The output buffer for writing bytes to the output
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///
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std::vector<ByteSignal> _ledBuffer;
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std::vector<uint8_t> _ledBuffer;
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};
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@ -95,8 +95,16 @@ void signal_handler(int signum)
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}
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void test3bitsEncoding();
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int main()
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{
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if (true)
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{
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test3bitsEncoding();
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return 0;
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}
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_running = true;
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signal(SIGTERM, &signal_handler);
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@ -246,3 +254,128 @@ int main()
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return 0;
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}
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std::vector<uint8_t> bit3Encode(const std::vector<uint8_t> & bytes);
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uint8_t bit3Encode(const bool bit_1, const bool bit_2, const bool bit_3);
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void test3bitsEncoding()
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{
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//OPEN THE UART
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int uart0_filestream = open("/dev/ttyAMA0", O_WRONLY | O_NOCTTY | O_NDELAY);
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if (uart0_filestream == -1)
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{
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//ERROR - CAN'T OPEN SERIAL PORT
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printf("Error - Unable to open UART. Ensure it is not in use by another application\n");
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return;
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}
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// Configure the port
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struct termios options;
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tcgetattr(uart0_filestream, &options);
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options.c_cflag = B2500000 | CS7 | CLOCAL;
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options.c_iflag = IGNPAR;
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options.c_oflag = 0;
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options.c_lflag = 0;
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tcflush(uart0_filestream, TCIFLUSH);
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tcsetattr(uart0_filestream, TCSANOW, &options);
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std::vector<uint8_t> colorRed;
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for (unsigned i=0; i<10; ++i)
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{
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colorRed.push_back(0x00);
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colorRed.push_back(0xFF);
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colorRed.push_back(0x00);
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}
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std::vector<uint8_t> colorGreen;
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for (unsigned i=0; i<10; ++i)
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{
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colorGreen.push_back(0xFF);
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colorGreen.push_back(0x00);
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colorGreen.push_back(0x00);
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}
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std::vector<uint8_t> colorBlue;
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for (unsigned i=0; i<10; ++i)
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{
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colorBlue.push_back(0x00);
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colorBlue.push_back(0x00);
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colorBlue.push_back(0xFF);
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}
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std::vector<uint8_t> colorBlack;
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for (unsigned i=0; i<10; ++i)
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{
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colorBlack.push_back(0x00);
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colorBlack.push_back(0x00);
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colorBlack.push_back(0x00);
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}
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const std::vector<uint8_t> colorRedSignal = bit3Encode(colorRed);
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const std::vector<uint8_t> colorGreenSignal = bit3Encode(colorGreen);
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const std::vector<uint8_t> colorBlueSignal = bit3Encode(colorBlue);
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const std::vector<uint8_t> colorBlackSignal = bit3Encode(colorBlack);
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for (unsigned i=0; i<100; ++i)
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{
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write(uart0_filestream, colorRedSignal.data(), colorRedSignal.size());
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usleep(100000);
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write(uart0_filestream, colorGreenSignal.data(), colorGreenSignal.size());
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usleep(100000);
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write(uart0_filestream, colorBlueSignal.data(), colorBlueSignal.size());
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usleep(100000);
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}
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write(uart0_filestream, colorBlackSignal.data(), colorBlackSignal.size());
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//----- CLOSE THE UART -----
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close(uart0_filestream);
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std::cout << "Program finished" << std::endl;
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}
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std::vector<uint8_t> bit3Encode(const std::vector<uint8_t> & bytes)
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{
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std::vector<uint8_t> result;
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for (unsigned iByte=0; iByte<bytes.size(); iByte+=3)
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{
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const uint8_t & byte1 = bytes[iByte];
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const uint8_t & byte2 = bytes[iByte + 1];
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const uint8_t & byte3 = bytes[iByte + 2];
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result.push_back(bit3Encode(byte1 & 0x80, byte1 & 0x40, byte1 & 0x20));
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result.push_back(bit3Encode(byte1 & 0x10, byte1 & 0x08, byte1 & 0x04));
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result.push_back(bit3Encode(byte1 & 0x02, byte1 & 0x01, byte2 & 0x80));
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result.push_back(bit3Encode(byte2 & 0x40, byte2 & 0x20, byte2 & 0x10));
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result.push_back(bit3Encode(byte2 & 0x08, byte2 & 0x04, byte2 & 0x02));
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result.push_back(bit3Encode(byte2 & 0x01, byte3 & 0x80, byte3 & 0x40));
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result.push_back(bit3Encode(byte3 & 0x20, byte3 & 0x10, byte3 & 0x08));
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result.push_back(bit3Encode(byte3 & 0x04, byte3 & 0x02, byte3 & 0x01));
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}
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return result;
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}
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uint8_t bit3Encode(const bool bit_1, const bool bit_2, const bool bit_3)
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{
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// Bit index(default):1 2 3
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// | | |
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// default value (1) 00 100 10 (0)
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//
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// Reversed value (1) 01 001 00 (0)
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// | | |
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// Bit index (rev): 3 2 1
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uint8_t result = 0x24;
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if(bit_1)
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{
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result |= 0x01;
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}
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if (bit_2)
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{
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result |= 0x08;
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}
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if (bit_3)
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{
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result |= 0x40;
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}
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return ~result;
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}
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