int main(int argc, char** argv) { /*The mySerialino must be setup to use the same baud rate*/ cout << "opening port" << endl; mySerial.Open(PORT); mySerial.SetBaudRate(SerialStreamBuf::BAUD_9600); mySerial.SetCharSize(SerialStreamBuf::CHAR_SIZE_8); cout << "port open" << endl; do { cout << "Press a command key, use q to quit: "; char val = cin.get(); cout << "Key pressed was " << val << endl; cin.ignore(); if (val == 'q') break; stringstream ss; string cmd; ss << val; ss >> cmd; cmd.append("#"); sendSerial(cmd); if (val == 'b') { cout << "value received = " << getSerial() << endl; } } while(1); }
void serialport_open(const char* sp) { /*The arduino must be setup to use the same baud rate*/ fprintf(stdout, "Setting Params:\n"); ardu.SetBaudRate( SerialStreamBuf::BAUD_115200 ) ; ardu.SetCharSize( SerialStreamBuf::CHAR_SIZE_8 ) ; ardu.SetNumOfStopBits(1) ; ardu.SetParity( SerialStreamBuf::PARITY_ODD ) ; ardu.SetFlowControl( SerialStreamBuf::FLOW_CONTROL_HARD ) ; ardu.SetVTime(1); fprintf(stdout, "Opening:\n"); ardu.Open( sp ) ; fprintf(stdout, "Opened:\n"); }
void Serial_Open_Port(string comPort) { serial_port.Open( comPort ) ; if(! serial_port.good()) { std::cerr<<"Error: could not open serial port"<<std::endl; exit(1); } serial_port.SetBaudRate( SerialStreamBuf::BAUD_9600) ; serial_port.SetCharSize( SerialStreamBuf::CHAR_SIZE_8 ) ; serial_port.SetNumOfStopBits(1) ; serial_port.SetParity( SerialStreamBuf::PARITY_EVEN ) ; serial_port.SetFlowControl( SerialStreamBuf::FLOW_CONTROL_NONE ) ; }
int main(int argc, char** argv) { cout << "opening port" << endl; mySerial.Open(PORT); mySerial.SetBaudRate(SerialStreamBuf::BAUD_9600); mySerial.SetCharSize(SerialStreamBuf::CHAR_SIZE_8); cout << "port open" << endl; ros::init(argc, argv, "serialCommands"); ros::NodeHandle nh_; ros::Subscriber arduino_sub = nh_.subscribe("arduino_commands", 60, arduinoCallback); arduino_pub = nh_.advertise<std_msgs::String>("arduino_sensors", 5); ros::spin(); mySerial.Close(); }
int main(int argc,char** argv) { char response[3]; serial_stream.Open( argv[1] ) ; serial_stream.SetBaudRate( SerialStreamBuf::BAUD_115200 ) ; serial_stream.SetCharSize( SerialStreamBuf::CHAR_SIZE_8 ) ; serial_stream.SetFlowControl( SerialStreamBuf::FLOW_CONTROL_NONE ) ; serial_stream.SetParity( SerialStreamBuf::PARITY_NONE ) ; serial_stream.SetNumOfStopBits(0) ; while (1) { serial_stream<<"ABCD"; cout<<"waiting response"<<endl; serial_stream.read(response,3); cout<<response<<endl; } return 0; }
void init_connection(SerialStream& stream) { stream.Open("/dev/ttyUSB0"); if (stream.IsOpen()){ cout << "\tStream open" << endl; } else { cout << "\tCould not open stream" << endl; exit(1); } //Connection Characteristics stream.SetBaudRate(SerialStreamBuf::BAUD_9600); stream.SetCharSize(SerialStreamBuf::CHAR_SIZE_8); stream.SetNumOfStopBits(1); stream.SetParity(SerialStreamBuf::PARITY_NONE); stream.SetFlowControl(SerialStreamBuf::FLOW_CONTROL_HARD); //?? stream.SetVMin(1000); }
int main(int argc, char **argv) { // initialize global variables prevtime = std::chrono::system_clock::now(); std::cerr << "koko1" << std::endl; for(int k=0;k<7;++k) data.push_back(0); ardu.Open(PORT); std::cerr << "koko2" << std::endl; ardu.SetBaudRate(SerialStreamBuf::BAUD_38400); ardu.SetCharSize(SerialStreamBuf::CHAR_SIZE_8); std::cerr << "koko3" << std::endl; glutInit(&argc, argv); std::cerr << "koko4" << std::endl; InitGL(); std::cerr << "koko5" << std::endl; glutMainLoop(); return 0; }
void open() { ardu.Open("/dev/ttyACM0"); ardu.SetBaudRate(SerialStreamBuf::BAUD_9600); ardu.SetCharSize(SerialStreamBuf::CHAR_SIZE_8); }
int main() { // Open the serial port for reading: ardu.Open(PORT); ardu.SetBaudRate(SerialStreamBuf::BAUD_115200); ardu.SetCharSize(SerialStreamBuf::CHAR_SIZE_8); char str[8]; // ardu << out; ardu >> str; std::cout << str; //sscanf(str,"%d",&res); //sleep(1); //serial_send(fd, 'A'); sleep(1); //while(result != 'A') return 1; while(true) { ardu >> str; std::cout << str; //int test = read(fd, &byte, 1); //serial_send(fd, 'A'); //printf("%i %i %c\n", test, byte, byte); //sleep(1); } // Set the last signalled state of the system as sent by the opto signal over USB. // "t" is top-dead-center, and "b" is bottom-dead-center. char system_state = 'B'; int image_counter = image_counter_min; // Create the main rendering window sf::RenderWindow App(sf::VideoMode(800, 600, 32), "SFML Graphics"); // Use v-sync (make it so that we sync with the monitor, and don't draw more than 60fps. App.UseVerticalSync(false); // App.SetFramerateLimit(60); // Limit to 60 frames per second // App.SetFramerateLimit(0); // No limit // Start game loop while (App.IsOpened()) { // Process events sf::Event Event; while (App.GetEvent(Event)) { // Close window : exit if (Event.Type == sf::Event::Closed) App.Close(); // A key has been pressed if (Event.Type == sf::Event::KeyPressed) { // Escape key : exit if (Event.Key.Code == sf::Key::Escape) App.Close(); } } // Read from the USB port. uint8_t input_state; //= serial_recv(fd); printf("%i ", input_state); if (input_state != system_state && (input_state == 'B' || input_state == 'T')) { // Start the appropriate image sequence. // Change the system state. system_state = input_state; //printf("%c\n", system_state); // Reset the image counter. image_counter = 0; } // Get the elapsed time. float elapsed = Clock.GetElapsedTime(); if (elapsed > refresh_rate) { // Update the image. printf("%i %f\n", image_counter, elapsed); Clock.Reset(); // Increment or decrement the image counter. if (system_state == 'B') image_counter++; else if (system_state == 'T') image_counter++; // Make sure the counter doesn't go out of bounds. if (image_counter > image_counter_max) image_counter = image_counter_max; if (image_counter < image_counter_min) image_counter = image_counter_min; // Draw the appropriate colour: switch( image_counter ) { case 0: App.Clear(sf::Color(0, 0, 0)); break; case 1: App.Clear(sf::Color(85, 85, 85)); break; case 2: App.Clear(sf::Color(170, 170, 170)); break; case 3: App.Clear(sf::Color(255, 255, 255)); break; } } // Clear the screen with red color // App.Clear(sf::Color(200, 0, 0)); // Display window contents on screen App.Display(); } return EXIT_SUCCESS; }
Server::Server(DomParser* _parser): QObject(0) { parser = _parser; connect(&server, SIGNAL(newConnection()), this, SLOT(acceptConnection())); serial_port.Open(ARDUINO) ; if ( ! serial_port.good() ) { std::cerr << "[" << __FILE__ << ":" << __LINE__ << "] " << "Error: Could not open serial port." << std::endl ; exit(1) ; } // // Set the baud rate of the serial port. // serial_port.SetBaudRate( SerialStreamBuf::BAUD_9600 ) ; if ( ! serial_port.good() ) { std::cerr << "Error: Could not set the baud rate." << std::endl ; exit(1) ; } // // Set the number of data bits. // serial_port.SetCharSize( SerialStreamBuf::CHAR_SIZE_8 ) ; if ( ! serial_port.good() ) { std::cerr << "Error: Could not set the character size." << std::endl ; exit(1) ; } // // Disable parity. // serial_port.SetParity( SerialStreamBuf::PARITY_NONE ) ; if ( ! serial_port.good() ) { std::cerr << "Error: Could not disable the parity." << std::endl ; exit(1) ; } // // Set the number of stop bits. // serial_port.SetNumOfStopBits( 1 ) ; if ( ! serial_port.good() ) { std::cerr << "Error: Could not set the number of stop bits." << std::endl ; exit(1) ; } // // Turn off hardware flow control. // serial_port.SetFlowControl( SerialStreamBuf::FLOW_CONTROL_NONE ) ; if ( ! serial_port.good() ) { std::cerr << "Error: Could not use hardware flow control." << std::endl ; exit(1) ; } server.listen(QHostAddress::Any, 8888); }
void serial_setup( void ) { ardu.Open(PORT); ardu.SetBaudRate(BAUDRATE); ardu.SetCharSize(SerialStreamBuf::CHAR_SIZE_8); }
SerialComm() { node.SetBaudRate(SerialStreamBuf::BAUD_9600); node.SetCharSize(SerialStreamBuf::CHAR_SIZE_8); node.Open(PORT); }