////////////////////////////////////////////////////// // First things first, all the includes we need // ////////////////////////////////////////////////////// #include // Interrupt functionality from BertOS #include // Serial driver from BertOS #include // Timer driver from BertOS #include // Standard input/output #include // String operations #include #include "afsk.h" // Header for AFSK modem #include "protocol/SimpleSerial.h" // Simple serial control protocol #include "protocol/KISS.h" // KISS TNC protocol #if SERIAL_DEBUG #include "cfg/debug.h" // Debug configuration from BertOS #endif #define SERIAL_PROTOCOL PROTOCOL_SIMPLE_SERIAL ////////////////////////////////////////////////////// // A few definitions // ////////////////////////////////////////////////////// static Afsk afsk; // Declare a AFSK modem struct static AX25Ctx ax25; // Declare a protocol struct static Serial ser; // Declare a serial interface struct #define ADC_CH 0 // Define which channel (pin) we want // for the ADC (this is A0 on arduino) /* Removed for now, use serial to send packets instead static AX25Call path[] = AX25_PATH(AX25_CALL(TO_CALL, 0), AX25_CALL(YOUR_CALLSIGN, 0), AX25_CALL("wide1", 1), AX25_CALL("wide2", 2)); #define SEND_TEST_PACKETS false #define TEST_INTERVAL 15000L #define APRS_MSG "Test APRS packet" */ static uint8_t serialBuffer[CONFIG_AX25_FRAME_BUF_LEN+1]; // Buffer for holding incoming serial data static int sbyte; // For holding byte read from serial port static size_t serialLen = 0; // Counter for counting length of data from serial static bool sertx = false; // Flag signifying whether it's time to send data // received on the serial port. #define SER_BUFFER_FULL (serialLen < MP1_MAX_DATA_SIZE-1) ////////////////////////////////////////////////////// // And here comes the actual program :) // ////////////////////////////////////////////////////// // This is a callback we register with the protocol, // so we can process each packet as they are decoded. // Right now it just prints the packet to the serial port. static void message_callback(struct AX25Msg *msg) { if (SERIAL_PROTOCOL == PROTOCOL_SIMPLE_SERIAL) { ss_messageCallback(msg, &ser); } if (SERIAL_PROTOCOL == PROTOCOL_KISS) { // Not implemented yet } } // Simple initialization function. static void init(void) { // Enable interrupts IRQ_ENABLE; // Initialize hardware timers timer_init(); // Initialize serial comms on UART0, // which is the hardware serial on arduino ser_init(&ser, SER_UART0); ser_setbaudrate(&ser, 9600); // For some reason BertOS sets the serial // to 7 bit characters by default. We set // it to 8 instead. UCSR0C = _BV(UCSZ01) | _BV(UCSZ00); // Create a modem context afsk_init(&afsk, ADC_CH); // ... and a protocol context with the modem ax25_init(&ax25, &afsk.fd, message_callback); // Init SimpleSerial ss_init(); // That's all! } int main(void) { // Start by running the main initialization init(); // Record the current tick count for time-keeping ticks_t start = timer_clock(); // Go into ye good ol' infinite loop while (1) { // First we instruct the protocol to check for // incoming data ax25_poll(&ax25); // Poll for incoming serial data if (!sertx && ser_available(&ser)) { // We then read a byte from the serial port. // Notice that we use "_nowait" since we can't // have this blocking execution until a byte // comes in. sbyte = ser_getchar_nowait(&ser); // If SERIAL_DEBUG is specified we'll handle // serial data as direct human input and only // transmit when we get a LF character #if SERIAL_DEBUG // If we have not yet surpassed the maximum frame length // and the byte is not a "transmit" (newline) character, // we should store it for transmission. if ((serialLen < MP1_MAX_DATA_SIZE) && (sbyte != 10)) { // Put the read byte into the buffer; serialBuffer[serialLen] = sbyte; // Increment the read length counter serialLen++; } else { // If one of the above conditions were actually the // case, it means we have to transmit, se we set // transmission flag to true. sertx = true; } #else // Otherwise we assume the modem is running // in automated mode, and we push out data // as it becomes available. We either transmit // immediately when the max frame length has // been reached, or when we get no input for // a certain amount of time. if (serialLen < CONFIG_AX25_FRAME_BUF_LEN-1) { // Put the read byte into the buffer; serialBuffer[serialLen] = sbyte; // Increment the read length counter serialLen++; } else { // If max frame length has been reached // we need to transmit. serialBuffer[serialLen] = sbyte; serialLen++; sertx = true; } start = timer_clock(); #endif } else { if (!SERIAL_DEBUG && serialLen > 0 && timer_clock() - start > ms_to_ticks(TX_MAXWAIT)) { sertx = true; } } if (sertx) { ss_serialCallback(serialBuffer, serialLen, &ser, &ax25); sertx = false; serialLen = 0; } // Removing this for now /* // Use AX.25 to send test data if (SEND_TEST_PACKETS && timer_clock() - start > ms_to_ticks(TEST_INTERVAL)) { start = timer_clock(); ax25_sendVia(&ax25, path, countof(path), APRS_MSG, sizeof(APRS_MSG)); } */ } return 0; }