193 lines
6.8 KiB
C
193 lines
6.8 KiB
C
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//////////////////////////////////////////////////////
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// First things first, all the includes we need //
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//////////////////////////////////////////////////////
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#include <cpu/irq.h> // Interrupt functionality from BertOS
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#include <drv/ser.h> // Serial driver from BertOS
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#include <drv/timer.h> // Timer driver from BertOS
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#include <stdio.h> // Standard input/output
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#include <string.h> // String operations
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#include "afsk.h" // Header for AFSK modem
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#include "protocol/mp1.h" // Header for MP.1 protocol
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#if SERIAL_DEBUG
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#include "cfg/debug.h" // Debug configuration from BertOS
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#endif
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//////////////////////////////////////////////////////
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// A few definitions //
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//////////////////////////////////////////////////////
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static Afsk afsk; // Declare a AFSK modem struct
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static MP1 mp1; // Declare a protocol struct
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static Serial ser; // Declare a serial interface struct
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#define ADC_CH 0 // Define which channel (pin) we want
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// for the ADC (this is A0 on arduino)
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static uint8_t serialBuffer[MP1_MAX_DATA_SIZE]; // This is a buffer for incoming serial data
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static int sbyte; // For holding byte read from serial port
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static size_t serialLen = 0; // Counter for counting length of data from serial
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static bool sertx = false; // Flag signifying whether it's time to send data
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// received on the serial port.
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#define SER_BUFFER_FULL (serialLen < MP1_MAX_DATA_SIZE-1)
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//////////////////////////////////////////////////////
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// And here comes the actual program :) //
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//////////////////////////////////////////////////////
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// This is a callback we register with the protocol,
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// so we can process each packet as they are decoded.
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// Right now it just prints the packet to the serial port.
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static void mp1Callback(struct MP1Packet *packet) {
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if (SERIAL_DEBUG) {
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kfile_printf(&ser.fd, "%.*s\n", packet->dataLength, packet->data);
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} else {
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for (unsigned long i = 0; i < packet->dataLength; i++) {
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kfile_putc(packet->data[i], &ser.fd);
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}
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}
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}
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// Simple initialization function.
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static void init(void)
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{
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// Enable interrupts
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IRQ_ENABLE;
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// Initialize hardware timers
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timer_init();
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// Initialize serial comms on UART0,
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// which is the hardware serial on arduino
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ser_init(&ser, SER_UART0);
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ser_setbaudrate(&ser, 9600);
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// For some reason BertOS sets the serial
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// to 7 bit characters by default. We set
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// it to 8 instead.
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UCSR0C = _BV(UCSZ01) | _BV(UCSZ00);
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// Create a modem context
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afsk_init(&afsk, ADC_CH);
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// ... and a protocol context with the modem
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mp1Init(&mp1, &afsk.fd, mp1Callback);
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// That's all!
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}
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int main(void)
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{
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// Start by running the main initialization
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init();
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// Record the current tick count for time-keeping
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ticks_t start = timer_clock();
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#if MP1_USE_TX_QUEUE
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ticks_t frameQueued = 0;
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#endif
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// Go into ye good ol' infinite loop
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while (1)
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{
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// First we instruct the protocol to check for
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// incoming data
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mp1Poll(&mp1);
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// If there was actually some data waiting for us
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// there, let's se what it tastes like :)
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if (!sertx && ser_available(&ser)) {
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// We then read a byte from the serial port.
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// Notice that we use "_nowait" since we can't
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// have this blocking execution until a byte
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// comes in.
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sbyte = ser_getchar_nowait(&ser);
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// If SERIAL_DEBUG is specified we'll handle
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// serial data as direct human input and only
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// transmit when we get a LF character
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#if SERIAL_DEBUG
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// If we have not yet surpassed the maximum frame length
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// and the byte is not a "transmit" (newline) character,
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// we should store it for transmission.
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if ((serialLen < MP1_MAX_DATA_SIZE) && (sbyte != 10)) {
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// Put the read byte into the buffer;
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serialBuffer[serialLen] = sbyte;
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// Increment the read length counter
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serialLen++;
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} else {
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// If one of the above conditions were actually the
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// case, it means we have to transmit, se we set
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// transmission flag to true.
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sertx = true;
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}
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#else
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// Otherwise we assume the modem is running
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// in automated mode, and we push out data
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// as it becomes available. We either transmit
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// immediately when the max frame length has
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// been reached, or when we get no input for
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// a certain amount of time.
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if (serialLen < MP1_MAX_DATA_SIZE-1) {
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// Put the read byte into the buffer;
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serialBuffer[serialLen] = sbyte;
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// Increment the read length counter
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serialLen++;
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} else {
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// If max frame length has been reached
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// we need to transmit.
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serialBuffer[serialLen] = sbyte;
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serialLen++;
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sertx = true;
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}
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start = timer_clock();
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#endif
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} else {
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if (!SERIAL_DEBUG && serialLen > 0 && timer_clock() - start > ms_to_ticks(TX_MAXWAIT)) {
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sertx = true;
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}
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}
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// Check whether we should send data in our serial buffer
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if (sertx) {
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#if MP1_USE_TX_QUEUE
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mp1QueueFrame(&mp1, serialBuffer, serialLen);
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frameQueued = timer_clock();
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sertx = false;
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serialLen = 0;
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#else
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// Wait until incoming packets are done
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if (!mp1CarrierSense(&mp1)) {
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// And then send the data
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mp1Send(&mp1, serialBuffer, serialLen);
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// Reset the transmission flag and length counter
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sertx = false;
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serialLen = 0;
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}
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#endif
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}
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#if MP1_USE_TX_QUEUE
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// We first wait a little to see if more
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// frames are coming in.
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if (timer_clock() - frameQueued > ms_to_ticks(MP1_QUEUE_TX_WAIT)) {
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if (!ser_available(&ser) && !mp1CarrierSense(&mp1)) {
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// And if not, we send process the frame
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// queue if possible.
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mp1ProcessQueue(&mp1);
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}
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}
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#endif
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}
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return 0;
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} |