#include "uart_communication.h" LFR_UART::LFR_UART() : fileDescriptor(-1) { this->openSerialPort(); this->configureSerialPort(); } LFR_UART::~LFR_UART() { this->closeSerialPort(); } void LFR_UART::openFile(const char *fileName) { this->fileDescriptor = open(fileName, O_RDWR | O_NONBLOCK); } int LFR_UART::writeDataToFile(uint8_t *buff, uint32_t bufferLength) { //std::cout << "Sending uart telegram" << std::endl; return write(this->fileDescriptor, buff, bufferLength); } int LFR_UART::readFromFile(uint8_t *buff, uint32_t bufferLength) { return read(this->fileDescriptor, buff, bufferLength); } int LFR_UART::closeFile() { return close(this->fileDescriptor); } uint8_t LFR_UART::doubleToByte(double in){ /* * Map the range of -1.0 to 1.0 as double to the range of a byte. * * -1 -> 0 * 0.0 -> 127 * 1.0 -> 254 * Not using the full range upto 254 to hit the 0.0 */ double minDouble = -1.0; double maxDouble = 1.0; double rangeDouble = maxDouble - minDouble; double minByte = 0.0; double maxByte = 255.0; double rangeByte = maxByte - minByte; double progress = in - minDouble; double progressPercent = progress/rangeDouble; double inputInByteRange = minByte + progressPercent*rangeByte; return uint8_t(inputInByteRange); } double LFR_UART::byteToDouble(uint8_t in){ double minDouble = -1.0; double maxDouble = 1.0; double rangeDouble = maxDouble - minDouble; double minByte = 0.0; double maxByte = 255.0; double rangeByte = maxByte - minByte; double progress = double(in) - minByte; double progressPercent = progress/rangeByte; double inputInDoubleRange = minDouble + progressPercent*rangeDouble; return inputInDoubleRange; } void LFR_UART::sendTelegram(double wheel1, double wheel2, double wheel3, double wheel4){ if(wheel1 > 1.0 || wheel2 > 1.0 || wheel3 > 1.0 || wheel4 > 1.0){ throw CommunicatorException("Wheel value must not be greater than 1.0"); } if(wheel1 < -1.0 || wheel2 < -1.0 || wheel3 < -1.0 || wheel4 < -1.0){ throw CommunicatorException("Wheel value must not be smaller than -1.0"); } uint8_t wheel1B = this->doubleToByte(wheel1); uint8_t wheel2B = this->doubleToByte(wheel2); uint8_t wheel3B = this->doubleToByte(wheel3); uint8_t wheel4B = this->doubleToByte(wheel4); uint8_t checksum = wheel1B^wheel2B^wheel3B^wheel4B; uint8_t telegram_buffer[5] = {wheel1B, wheel2B, wheel3B, wheel4B, checksum}; uint32_t telegram_length = 5; this->writeDataToFile(telegram_buffer, telegram_length); } bool LFR_UART::readTelegram(double* buffer){ uint8_t tmp_buffer[5] = {0, 0, 0, 0, 0}; uint32_t telegram_length = 5; this->readFromFile(tmp_buffer, telegram_length); //std::cout << "Read from file: " << std::bitset<8>(tmp_buffer[0]) << ", " << std::bitset<8>(tmp_buffer[1]) << ", " << std::bitset<8>(tmp_buffer[2]) << ", " << std::bitset<8>(tmp_buffer[3]) << ", " << std::bitset<8>(tmp_buffer[4]) << std::endl; if (std::bitset<8>(tmp_buffer[0]^tmp_buffer[1]^tmp_buffer[2]^tmp_buffer[3]) != std::bitset<8>(tmp_buffer[4])){ return false; } else { buffer[0] = this->byteToDouble(tmp_buffer[0]); buffer[1] = this->byteToDouble(tmp_buffer[1]); buffer[2] = this->byteToDouble(tmp_buffer[2]); buffer[3] = this->byteToDouble(tmp_buffer[3]); } return true; } void LFR_UART::openSerialPort() { openFile(this->serialPortPath); if(this->fileDescriptor < 0) { throw CommunicatorException("LFR_UART couldn't open the serial port."); exit(EXIT_FAILURE); } } void LFR_UART::configureSerialPort() { if(tcgetattr(this->fileDescriptor, &this->tty)) { throw CommunicatorException("LFR_UART couldn't get the port attributes."); exit(EXIT_FAILURE); } cfsetispeed(&this->tty,B115200); cfsetospeed(&this->tty,B115200); cfmakeraw(&this->tty); if(tcsetattr(this->fileDescriptor,TCSANOW,&this->tty)) { throw CommunicatorException("LFR_UART couldn't set the port attributes."); exit(EXIT_FAILURE); } } void LFR_UART::closeSerialPort() { this->closeFile(); }