diff --git a/README.md b/README.md index 0a0e28c..fa351c3 100644 --- a/README.md +++ b/README.md @@ -1,5 +1,9 @@ # HamShield +WARNING: The dev branch is not guaranteed to work. Please use caution if you choose to use that branch. + +All of the AFSK, DDS, etc. files have been moved to the in Progress directory. These files collectively use twice as much memory as the essential HamShield functions. The current plan is to make sure these are only included if they're going to be used. We'll also be adapting them to make them more friendly to non-Uno Arduinos. Stay tuned for those changes. + The master branch is intended for use with HamShield hardware -09 and above. HamShield Arduino Library and Example Sketches diff --git a/examples/AFSK_PacketTester/AFSK_PacketTester.ino b/examples/AFSK_PacketTester/AFSK_PacketTester.ino index 110a2ca..af09f9a 100644 --- a/examples/AFSK_PacketTester/AFSK_PacketTester.ino +++ b/examples/AFSK_PacketTester/AFSK_PacketTester.ino @@ -8,11 +8,15 @@ * this program to your adruino, open the Serial Monitor to * monitor the process of the HamShield. Check for output on * AFSK receiver. -*/ + + * Note: add message receive code + */ #define DDS_REFCLK_DEFAULT 9600 #include +#include +#include #include #define PWM_PIN 3 @@ -21,6 +25,7 @@ HamShield radio; DDS dds; +AFSK afsk; String messagebuff = ""; String origin_call = ""; String destination_call = ""; @@ -46,7 +51,7 @@ void setup() { radio.frequency(144390); radio.setRfPower(0); dds.start(); - radio.afsk.start(&dds); + afsk.start(&dds); delay(100); Serial.println("HELLO"); } @@ -76,13 +81,13 @@ void prepMessage() { packet->print(textmessage); packet->finish(); - bool ret = radio.afsk.putTXPacket(packet); + bool ret = afsk.putTXPacket(packet); - if(radio.afsk.txReady()) { + if(afsk.txReady()) { Serial.println(F("txReady")); radio.setModeTransmit(); //delay(100); - if(radio.afsk.txStart()) { + if(afsk.txStart()) { Serial.println(F("txStart")); } else { radio.setModeReceive(); @@ -93,7 +98,7 @@ void prepMessage() { // Wait up to 2.5 seconds to finish sending, and stop transmitter. // TODO: This is hackery. for(int i = 0; i < 500; i++) { - if(radio.afsk.encoder.isDone()) + if(afsk.encoder.isDone()) break; delay(50); } @@ -115,8 +120,8 @@ ISR(ADC_vect) { TIFR1 = _BV(ICF1); // Clear the timer flag dds.clockTick(); if(++tcnt == 1) { - if(radio.afsk.encoder.isSending()) { - radio.afsk.timer(); + if(afsk.encoder.isSending()) { + afsk.timer(); } tcnt = 0; } diff --git a/examples/AFSK_SerialMessenger/AFSK_SerialMessenger.ino b/examples/AFSK_SerialMessenger/AFSK_SerialMessenger.ino index 96434bc..701009f 100644 --- a/examples/AFSK_SerialMessenger/AFSK_SerialMessenger.ino +++ b/examples/AFSK_SerialMessenger/AFSK_SerialMessenger.ino @@ -16,6 +16,8 @@ #define DDS_REFCLK_DEFAULT 9600 #include +#include +#include #include #define PWM_PIN 3 @@ -24,6 +26,7 @@ HamShield radio; DDS dds; +AFSK afsk; String messagebuff = ""; String origin_call = ""; String destination_call = ""; @@ -49,7 +52,7 @@ void setup() { radio.frequency(145570); radio.setRfPower(0); dds.start(); - radio.afsk.start(&dds); + afsk.start(&dds); delay(100); Serial.println("HELLO"); } @@ -91,13 +94,13 @@ void prepMessage() { textmessage = ""; - bool ret = radio.afsk.putTXPacket(packet); + bool ret = afsk.putTXPacket(packet); - if(radio.afsk.txReady()) { + if(afsk.txReady()) { Serial.println(F("txReady")); //radio.setModeTransmit(); //delay(100); - if(radio.afsk.txStart()) { + if(afsk.txStart()) { Serial.println(F("txStart")); } else { radio.setModeReceive(); @@ -108,7 +111,7 @@ void prepMessage() { // Wait up to 2.5 seconds to finish sending, and stop transmitter. // TODO: This is hackery. for(int i = 0; i < 500; i++) { - if(radio.afsk.encoder.isDone()) + if(afsk.encoder.isDone()) break; delay(50); } @@ -136,8 +139,8 @@ ISR(ADC_vect) { //PORTD |= _BV(2); // Diagnostic pin (D2) dds.clockTick(); if(++tcnt == 1) { - if(radio.afsk.encoder.isSending()) { - radio.afsk.timer(); + if(afsk.encoder.isSending()) { + afsk.timer(); } tcnt = 0; } diff --git a/examples/AX25Receive/AX25Receive.ino b/examples/AX25Receive/AX25Receive.ino index f06332d..d1fcfb1 100644 --- a/examples/AX25Receive/AX25Receive.ino +++ b/examples/AX25Receive/AX25Receive.ino @@ -13,6 +13,8 @@ */ #include +#include +#include #define PWM_PIN 3 #define RESET_PIN A3 @@ -20,6 +22,7 @@ HamShield radio; DDS dds; +AFSK afsk; void setup() { // NOTE: if not using PWM out, it should be held low to avoid tx noise @@ -55,7 +58,7 @@ void setup() { dds.start(); Serial.println(F("AFSK start")); delay(100); - radio.afsk.start(&dds); + afsk.start(&dds); Serial.println(F("Starting...")); delay(100); dds.setAmplitude(255); @@ -63,11 +66,11 @@ void setup() { uint32_t last = 0; void loop() { - if(radio.afsk.decoder.read() || radio.afsk.rxPacketCount()) { + if(afsk.decoder.read() || afsk.rxPacketCount()) { // A true return means something was put onto the packet FIFO // If we actually have data packets in the buffer, process them all now - while(radio.afsk.rxPacketCount()) { - AFSK::Packet *packet = radio.afsk.getRXPacket(); + while(afsk.rxPacketCount()) { + AFSK::Packet *packet = afsk.getRXPacket(); Serial.print(F("Packet: ")); if(packet) { packet->printPacket(&Serial); @@ -83,6 +86,6 @@ ISR(ADC_vect) { TIFR1 = _BV(ICF1); // Clear the timer flag //PORTD |= _BV(2); // Diagnostic pin (D2) //dds.clockTick(); - radio.afsk.timer(); + afsk.timer(); //PORTD &= ~(_BV(2)); // Pin D2 off again } diff --git a/examples/CrystalCalibration/CrystalCalibration.ino b/examples/CrystalCalibration/CrystalCalibration.ino index 4a2d4c6..0f09655 100644 --- a/examples/CrystalCalibration/CrystalCalibration.ino +++ b/examples/CrystalCalibration/CrystalCalibration.ino @@ -15,6 +15,7 @@ #define DDS_DEBUG_SERIAL #include +#include #define PWM_PIN 3 #define RESET_PIN A3 @@ -117,7 +118,7 @@ void loop() { } while(Serial.available()) { char c = Serial.read(); - Serial.print(c); + Serial.println(c); switch(c) { case 'h': Serial.println(F("Commands:")); diff --git a/examples/DDS/DDS.ino b/examples/DDS/DDS.ino index 9352a4d..9f30ca1 100644 --- a/examples/DDS/DDS.ino +++ b/examples/DDS/DDS.ino @@ -12,6 +12,7 @@ #define DDS_REFCLK_DEFAULT 9600 #include +#include #define PWM_PIN 3 #define RESET_PIN A3 diff --git a/examples/FunctionalTest/FunctionalTest.ino b/examples/FunctionalTest/FunctionalTest.ino index e3cd51b..b270a03 100644 --- a/examples/FunctionalTest/FunctionalTest.ino +++ b/examples/FunctionalTest/FunctionalTest.ino @@ -44,7 +44,7 @@ void setup() { void loop() { radio.setModeReceive(); radio.setSQLoThresh(0); - radio.setSQOn(); + radio.setSQOff(); radio.setVolume1(0xF); radio.setVolume2(0xF); delay(1000); diff --git a/examples/Gauges/Gauges.ino b/examples/Gauges/Gauges.ino index 4020571..f2ecc8f 100755 --- a/examples/Gauges/Gauges.ino +++ b/examples/Gauges/Gauges.ino @@ -24,13 +24,6 @@ HamShield radio; -void clr() { -/* Serial.write(27); - Serial.print("[2J"); // cursor to home command */ - Serial.write(27); - Serial.print("[H"); // cursor to home command -} - void setup() { // NOTE: if not using PWM out, it should be held low to avoid tx noise pinMode(PWM_PIN, OUTPUT); @@ -68,7 +61,6 @@ int txc = 0; int mode = 0; void loop() { - clr(); int16_t rssi = radio.readRSSI(); gauge = map(rssi,-123,-50,0,8); Serial.print("["); diff --git a/examples/HAMBot/HAMBot.ino b/examples/HAMBot/HAMBot.ino index 40b0c81..d66048a 100755 --- a/examples/HAMBot/HAMBot.ino +++ b/examples/HAMBot/HAMBot.ino @@ -12,7 +12,7 @@ * '6' => turn robot right * '2' => move robot forward * '5' => tell robot to send morse code identity -/* +*/ #include // include the robot library #include diff --git a/examples/JustTransmit/JustTransmit.ino b/examples/JustTransmit/JustTransmit.ino index 757a748..4a488df 100644 --- a/examples/JustTransmit/JustTransmit.ino +++ b/examples/JustTransmit/JustTransmit.ino @@ -39,7 +39,6 @@ void setup() { Serial.println("Setting radio to its defaults.."); radio.initialize(); radio.setRfPower(0); - //radio.setChanMode(3); } void loop() { diff --git a/examples/KISS/KISS.ino b/examples/KISS/KISS.ino index 16d7d64..37449b6 100644 --- a/examples/KISS/KISS.ino +++ b/examples/KISS/KISS.ino @@ -11,10 +11,12 @@ #include #include +#include HamShield radio; DDS dds; KISS kiss(&Serial, &radio, &dds); +AFSK afsk; //TODO: move these into library #define PWM_PIN 3 @@ -46,7 +48,7 @@ void setup() { //I2Cdev::writeWord(A1846S_DEV_ADDR_SENLOW, 0x44, 0x05FF); dds.start(); - radio.afsk.start(&dds); + afsk.start(&dds); } void loop() { diff --git a/examples/PSK31Transmit/PSK31Transmit.ino b/examples/PSK31Transmit/PSK31Transmit.ino index a4bb331..bcc26b0 100644 --- a/examples/PSK31Transmit/PSK31Transmit.ino +++ b/examples/PSK31Transmit/PSK31Transmit.ino @@ -11,6 +11,7 @@ */ #include +#include #include "varicode.h" #define PWM_PIN 3 diff --git a/examples/Parrot/Parrot.ino b/examples/Parrot/Parrot.ino index e0a273d..364f8d4 100755 --- a/examples/Parrot/Parrot.ino +++ b/examples/Parrot/Parrot.ino @@ -8,7 +8,11 @@ * into the HamShield RF jack. Plug a pair of headphones into * the HamShield. Connect the Arduino to wall power and then to * your computer via USB. To test the output, tune you HT to +<<<<<<< HEAD * 446MHz. The HamShield should make a recording of the next +======= + * 446MHz. The HamShield should make a recording ofthe next +>>>>>>> 8b8fd7a9a141e015aceecf604357ecf277df0c1f * broadcast on that frequncy. The recording should then be * repeated ten times by the HamShield. */ @@ -56,16 +60,16 @@ void loop() { if(x == -1) { for(x = 0; x < SIZE; x++) { if(mode == 4) { - sample1 = analogRead(0); + sample1 = analogRead(2); sound[x] = sample1 >> 4; delayMicroseconds(RATE); x++; - sample1 = analogRead(0); + sample1 = analogRead(2); sound[x] = (sample1 & 0xF0) | sound[x]; delayMicroseconds(RATE); } else { - sound[x] = analogRead(0); + sound[x] = analogRead(2); delayMicroseconds(RATE); x++; - sound[x] = analogRead(0); + sound[x] = analogRead(2); delayMicroseconds(RATE); } } diff --git a/examples/QPSK63Transmit/QPSK63Transmit.ino b/examples/QPSK63Transmit/QPSK63Transmit.ino index d97e146..e68ae76 100644 --- a/examples/QPSK63Transmit/QPSK63Transmit.ino +++ b/examples/QPSK63Transmit/QPSK63Transmit.ino @@ -9,7 +9,9 @@ * wait to receive the message "Why hello there, friend. * Nice to meet you. Welcome to QPSK63. 73, VE6SLP sk" */ + #include +#include #include "varicode.h" #define PWM_PIN 3 diff --git a/examples/SSTV_M1_Static/SSTV_M1_Static.ino b/examples/SSTV_M1_Static/SSTV_M1_Static.ino index 4082aa8..5ac9858 100644 --- a/examples/SSTV_M1_Static/SSTV_M1_Static.ino +++ b/examples/SSTV_M1_Static/SSTV_M1_Static.ino @@ -14,6 +14,7 @@ #define DDS_REFCLK_DEFAULT (34965/2) #include +#include #define PWM_PIN 3 #define RESET_PIN A3 diff --git a/examples/SerialTransceiver/SerialTransceiver.ino b/examples/SerialTransceiver/SerialTransceiver.ino index 0f0a0a0..66cce13 100644 --- a/examples/SerialTransceiver/SerialTransceiver.ino +++ b/examples/SerialTransceiver/SerialTransceiver.ino @@ -8,6 +8,12 @@ * to your computer via USB. After uploading this program to * your adruino, open the Serial Monitor. Use the bar at the * top of the serial monitor to enter commands as seen below. + * + * EXAMPLE: To change the repeater offset to 144.425MHz, + * enable offset, then key in, use the following commands: + * T144425; + * R1; + * [Just a space] Commands: @@ -90,14 +96,14 @@ void setup() { digitalWrite(RESET_PIN, HIGH); Serial.begin(9600); - Serial.print(";;;;;;;;;;;;;;;;;;;;;;;;;;"); + Serial.println(";;;;;;;;;;;;;;;;;;;;;;;;;;"); int result = radio.testConnection(); Serial.print("*"); Serial.print(result,DEC); - Serial.print(";"); + Serial.println(";"); radio.initialize(); // initializes automatically for UHF 12.5kHz channel - Serial.print("*START;"); + Serial.println("*START;"); radio.frequency(freq); radio.setVolume1(0xF); radio.setVolume2(0xF); @@ -127,14 +133,14 @@ void loop() { if(repeater == 1) { radio.frequency(tx); } radio.setModeTransmit(); state = 10; - Serial.print("#TX,ON;"); + Serial.println("#TX,ON;"); timer = millis(); break; case 63: // ? - RSSI Serial.print(":"); Serial.print(radio.readRSSI(),DEC); - Serial.print(";"); + Serial.println(";"); break; case 65: // A - CTCSS In @@ -155,7 +161,7 @@ void loop() { case 70: // F - frequency getValue(); freq = atol(cmdbuff); - if(radio.frequency(freq) == true) { Serial.print("@"); Serial.print(freq,DEC); Serial.print(";!;"); } else { Serial.print("X1;"); } + if(radio.frequency(freq) == true) { Serial.print("@"); Serial.print(freq,DEC); Serial.println(";!;"); } else { Serial.println("X1;"); } break; case 'M': @@ -194,14 +200,14 @@ void loop() { case 94: // ^ - VSSI (voice) level Serial.print(":"); Serial.print(radio.readVSSI(),DEC); - Serial.print(";"); + Serial.println(";"); } break; } } if(state == 10) { - if(millis() > (timer + 500)) { Serial.print("#TX,OFF;");radio.setModeReceive(); if(repeater == 1) { radio.frequency(freq); } state = 0; txcount = 0; } + if(millis() > (timer + 500)) { Serial.println("#TX,OFF;");radio.setModeReceive(); if(repeater == 1) { radio.frequency(freq); } state = 0; txcount = 0; } } } @@ -212,7 +218,8 @@ void getValue() { if(Serial.available()) { temp = Serial.read(); if(temp == 59) { cmdbuff[p] = 0; Serial.print("@"); - for(int x = 0; x < 32; x++) { Serial.print(cmdbuff[x]); } + for(int x = 0; x < 32; x++) { Serial.print(cmdbuff[x]);} + Serial.println(); return; } cmdbuff[p] = temp; @@ -220,12 +227,12 @@ void getValue() { if(p == 32) { Serial.print("@"); for(int x = 0; x < 32; x++) { - Serial.print(cmdbuff[x]); + Serial.println(cmdbuff[x]); } cmdbuff[0] = 0; - Serial.print("X0;"); return; } // some sort of alignment issue? lets not feed junk into whatever takes this string in + Serial.println("X0;"); return; } // some sort of alignment issue? lets not feed junk into whatever takes this string in } } } diff --git a/examples/SignalTest/SignalTest.ino b/examples/SignalTest/SignalTest.ino index 2f849ca..d07456a 100755 --- a/examples/SignalTest/SignalTest.ino +++ b/examples/SignalTest/SignalTest.ino @@ -2,7 +2,9 @@ * Example: Signal Test * Plays back the current signal strength level and morses out * it's call sign at the end. You will need a HandyTalkie (HT) - * to test the output of this example. + * to test the output of this example. You will also need to + * download the PCM library from + * https://github.com/damellis/PCM * Connect the HamShield to your Arduino. Screw the antenna * into the HamShield RF jack. Plug a pair of headphones into * the HamShield. Connect the Arduino to wall power and then @@ -16,7 +18,7 @@ */ #define DOT 100 -#define CALLSIGN "1ZZ9ZZ/B" +char CALLSIGN[] = "1ZZ9ZZ/B"; /* Standard libraries and variable init */ diff --git a/src/AFSK.cpp b/src/AFSK.cpp deleted file mode 100644 index 1fcfab6..0000000 --- a/src/AFSK.cpp +++ /dev/null @@ -1,738 +0,0 @@ -#include -#include "HamShield.h" -#include "SimpleFIFO.h" -#include - -#define PHASE_BIT 8 -#define PHASE_INC 1 - -#define PHASE_MAX (SAMPLEPERBIT * PHASE_BIT) -#define PHASE_THRES (PHASE_MAX / 2) - -#define BIT_DIFFER(bitline1, bitline2) (((bitline1) ^ (bitline2)) & 0x01) -#define EDGE_FOUND(bitline) BIT_DIFFER((bitline), (bitline) >> 1) - -#define PPOOL_SIZE 2 - -#define AFSK_SPACE 2200 -#define AFSK_MARK 1200 - -// Timers -volatile unsigned long lastTx = 0; -volatile unsigned long lastTxEnd = 0; -volatile unsigned long lastRx = 0; - -#define T_BIT ((unsigned int)(SAMPLERATE/BITRATE)) - -#ifdef PACKET_PREALLOCATE -SimpleFIFO preallocPool; -AFSK::Packet preallocPackets[PPOOL_SIZE]; -#endif - -void AFSK::Encoder::process() { - // We're on the start of a byte position, so fetch one - if(bitPosition == 0) { - if(preamble) { // Still in preamble - currentByte = HDLC_PREAMBLE; - --preamble; // Decrement by one - } else { - if(!packet) { // We aren't on a packet, grab one - // Unless we already sent enough - if(maxTx-- == 0) { - stop(); - lastTxEnd = millis(); - return; - } - packet = pBuf.getPacket(); - if(!packet) { // There actually weren't any - stop(); // Stop transmitting and return - lastTxEnd = millis(); - return; - } - lastTx = millis(); - currentBytePos = 0; - nextByte = HDLC_FRAME; // Our next output should be a frame boundary - hdlc = true; - } - - // We ran out of actual data, provide an HDLC frame (idle) - if(currentBytePos == packet->len && nextByte == 0) { - // We also get here if nextByte isn't set, to handle empty frames - pBuf.freePacket(packet); - packet = pBuf.getPacket(); // Get the next, if any - //packet = NULL; - currentBytePos = 0; - nextByte = 0; - currentByte = HDLC_FRAME; - hdlc = true; - } else { - if(nextByte) { - // We queued up something other than the actual stream to be sent next - currentByte = nextByte; - nextByte = 0; - } else { - // Get the next byte to send, but if it's an HDLC frame, escape it - // and queue the real byte for the next cycle. - currentByte = packet->getByte(); - if(currentByte == HDLC_FRAME) { - nextByte = currentByte; - currentByte = HDLC_ESCAPE; - } else { - currentBytePos++; - } - hdlc = false; // If we get here, it will be NRZI bit stuffed - } - } - } - } - - // Pickup the last bit - currentBit = currentByte & 0x1; - - if(lastZero == 5) { - currentBit = 0; // Force a 0 bit output - } else { - currentByte >>= 1; // Bit shift it right, for the next round - ++bitPosition; // Note our increase in position - } - - // To handle NRZI 5 bit stuffing, count the bits - if(!currentBit || hdlc) - lastZero = 0; - else - ++lastZero; - - // NRZI and AFSK uses toggling 0s, "no change" on 1 - // So, if not a 1, toggle to the opposite tone - if(!currentBit) - currentTone = !currentTone; - - if(currentTone == 0) { - PORTD |= _BV(7); - dds->setFrequency(AFSK_SPACE); - } else { - PORTD &= ~_BV(7); - dds->setFrequency(AFSK_MARK); - } -} - -bool AFSK::Encoder::start() { - if(!done || sending) { - return false; - } - - if(randomWait > millis()) { - return false; - } - - // First real byte is a frame - currentBit = 0; - lastZero = 0; - bitPosition = 0; - //bitClock = 0; - preamble = 0b110000; // 6.7ms each, 23 = 153ms - done = false; - hdlc = true; - packet = 0x0; // No initial packet, find in the ISR - currentBytePos = 0; - maxTx = 3; - sending = true; - nextByte = 0; - dds->setFrequency(0); - dds->on(); - return true; -} - -void AFSK::Encoder::stop() { - randomWait = 0; - sending = false; - done = true; - dds->setFrequency(0); - dds->off(); -} - -AFSK::Decoder::Decoder() { - // Initialize the sampler delay line (phase shift) - //for(unsigned char i = 0; i < SAMPLEPERBIT/2; i++) - // delay_fifo.enqueue(0); -} - -bool AFSK::HDLCDecode::hdlcParse(bool bit, SimpleFIFO *fifo) { - bool ret = true; - - demod_bits <<= 1; - demod_bits |= bit ? 1 : 0; - - // Flag - if(demod_bits == HDLC_FRAME) { - fifo->enqueue(HDLC_FRAME); - rxstart = true; - currchar = 0; - bit_idx = 0; - return ret; - } - - // Reset - if((demod_bits & HDLC_RESET) == HDLC_RESET) { - rxstart = false; - lastRx = millis(); - return ret; - } - if(!rxstart) { - return ret; - } - - // Stuffed? - if((demod_bits & 0x3f) == 0x3e) - return ret; - - if(demod_bits & 0x01) - currchar |= 0x80; - - if(++bit_idx >= 8) { - if(currchar == HDLC_FRAME || - currchar == HDLC_RESET || - currchar == HDLC_ESCAPE) { - fifo->enqueue(HDLC_ESCAPE); - } - fifo->enqueue(currchar & 0xff); - currchar = 0; - bit_idx = 0; - } else { - currchar >>= 1; - } - - return ret; -} - -template -class FastRing { -private: - T ring[size]; - uint8_t position; -public: - FastRing(): position(0) {} - inline void write(T value) { - ring[(position++) & (size-1)] = value; - } - inline T read() const { - return ring[position & (size-1)]; - } - inline T readn(uint8_t n) const { - return ring[(position + (~n+1)) & (size-1)]; - } -}; -// Create a delay line that's half the length of the bit cycle (-90 degrees) -FastRing delayLine; - -// Handle the A/D converter interrupt (hopefully quickly :) -void AFSK::Decoder::process(int8_t curr_sample) { - // Run the same through the phase multiplier and butterworth filter - iir_x[0] = iir_x[1]; - iir_x[1] = ((int8_t)delayLine.read() * curr_sample) >> 2; - iir_y[0] = iir_y[1]; - iir_y[1] = iir_x[0] + iir_x[1] + (iir_y[0] >> 1) + (iir_y[0]>>3) + (iir_y[0]>>5); - - // Place this ADC sample into the delay line - delayLine.write(curr_sample); - - // Shift the bit into place based on the output of the discriminator - sampled_bits <<= 1; - sampled_bits |= (iir_y[1] > 0) ? 1 : 0; - - // If we found a 0/1 transition, adjust phases to track - if(EDGE_FOUND(sampled_bits)) { - if(curr_phase < PHASE_THRES) - curr_phase += PHASE_INC; - else - curr_phase -= PHASE_INC; - } - - // Move ahead in phase - curr_phase += PHASE_BIT; - - // If we've gone over the phase maximum, we should now have some data - if(curr_phase >= PHASE_MAX) { - curr_phase %= PHASE_MAX; - found_bits <<= 1; - - // If we have 3 bits or more set, it's a positive bit - register uint8_t bits = sampled_bits & 0x07; - if(bits == 0x07 || bits == 0x06 || bits == 0x05 || bits == 0x03) { - found_bits |= 1; - } - - hdlc.hdlcParse(!EDGE_FOUND(found_bits), &rx_fifo); // Process it - } -} - -// This routine uses a pre-allocated Packet structure -// to save on the memory requirements of the stream data -bool AFSK::Decoder::read() { - bool retVal = false; - if(!currentPacket) { // We failed a prior memory allocation - currentPacket = pBuf.makePacket(PACKET_MAX_LEN); - if(!currentPacket) // Still nothing - return false; - } - // While we have AFSK receive FIFO bytes... - while(rx_fifo.count()) { - // Grab the character - char c = rx_fifo.dequeue(); - bool escaped = false; - if(c == HDLC_ESCAPE) { // We received an escaped byte, mark it - escaped = true; - // Do we want to keep HDLC_ESCAPEs in the packet? - //currentPacket->append(HDLC_ESCAPE); // Append without FCS - c = rx_fifo.dequeue(); // Reset to the next character - } - - // Append all the bytes - // This will include unescaped HDLC_FRAME bytes - if(c != HDLC_FRAME || escaped) // Append frame if it is escaped - currentPacket->appendFCS(c); // Escaped characters and all else go into FCS - - if(currentPacket->len > PACKET_MAX_LEN) { - // We've now gone too far and picked up far too many bytes - // Cancel this frame, start back at the beginning - currentPacket->clear(); - continue; - } - - // We have a frame boundary, if it isn't escaped - // If it's escaped, it was part of the data stream - if(c == HDLC_FRAME && !escaped) { - if(!currentPacket->len) { - currentPacket->clear(); // There wasn't any data, restart stream - continue; - } else { - // We have some bytes in stream, check it meets minimum payload length - // Min payload is 1 (flag) + 14 (addressing) + 2 (control/PID) + 1 (flag) - if(currentPacket->len >= 16) { - // We should end up here with a valid FCS due to the appendFCS - if(currentPacket->crcOK()) { // Magic number for the CRC check passing - // Valid frame, so, let's filter for control + PID - // Maximum search distance is 71 bytes to end of the address fields - // Skip the HDLC frame start - bool filtered = false; - for(unsigned char i = 0; i < (currentPacket->len<70?currentPacket->len:71); ++i) { - if((currentPacket->getByte() & 0x1) == 0x1) { // Found a byte with LSB set - // which marks the final address payload - // next two bytes should be the control/PID - //if(currentPacket->getByte() == 0x03 && currentPacket->getByte() == 0xf0) { - filtered = true; - break; // Found it - //} - } - } - - if(!filtered) { - // Frame wasn't one we care about, discard - currentPacket->clear(); - continue; - } - - // It's all done and formatted, ready to go - currentPacket->ready = 1; - if(!pBuf.putPacket(currentPacket)) // Put it in the receive FIFO - pBuf.freePacket(currentPacket); // Out of FIFO space, so toss it - - // Allocate a new one of maximum length - currentPacket = pBuf.makePacket(PACKET_MAX_LEN); - retVal = true; - } - } - } - // Restart the stream - currentPacket->clear(); - } - } - return retVal; // This is true if we parsed a packet in this flow -} - -void AFSK::Decoder::start() { - // Do this in start to allocate our first packet - currentPacket = pBuf.makePacket(PACKET_MAX_LEN); -/* ASSR &= ~(_BV(EXCLK) | _BV(AS2)); - - // Do non-inverting PWM on pin OC2B (arduino pin 3) (p.159). - // OC2A (arduino pin 11) stays in normal port operation: - // COM2B1=1, COM2B0=0, COM2A1=0, COM2A0=0 - // Mode 1 - Phase correct PWM - TCCR2A = (TCCR2A | _BV(COM2B1)) & ~(_BV(COM2B0) | _BV(COM2A1) | _BV(COM2A0)) | - _BV(WGM21) | _BV(WGM20); - // No prescaler (p.162) - TCCR2B = (TCCR2B & ~(_BV(CS22) | _BV(CS21))) | _BV(CS20) | _BV(WGM22); - - OCR2A = pow(2,COMPARE_BITS)-1; - OCR2B = 0; - // Configure the ADC and Timer1 to trigger automatic interrupts - TCCR1A = 0; - TCCR1B = _BV(CS11) | _BV(WGM13) | _BV(WGM12); - ICR1 = ((F_CPU / 8) / REFCLK) - 1; - ADMUX = _BV(REFS0) | _BV(ADLAR) | 0; // Channel 0, shift result left (ADCH used) - DDRC &= ~_BV(0); - PORTC &= ~_BV(0); - DIDR0 |= _BV(0); - ADCSRB = _BV(ADTS2) | _BV(ADTS1) | _BV(ADTS0); - ADCSRA = _BV(ADEN) | _BV(ADSC) | _BV(ADATE) | _BV(ADIE) | _BV(ADPS2); // | _BV(ADPS0); */ -} - -AFSK::PacketBuffer::PacketBuffer() { - nextPacketIn = 0; - nextPacketOut = 0; - inBuffer = 0; - for(unsigned char i = 0; i < PACKET_BUFFER_SIZE; ++i) { - packets[i] = 0x0; - } -#ifdef PACKET_PREALLOCATE - for(unsigned char i = 0; i < PPOOL_SIZE; ++i) { - // Put some empty packets in the FIFO - preallocPool.enqueue(&preallocPackets[i]); - } -#endif -} - -unsigned char AFSK::PacketBuffer::readyCount() volatile { - unsigned char i; - unsigned int cnt = 0; - ATOMIC_BLOCK(ATOMIC_RESTORESTATE) { - for(i = 0; i < PACKET_BUFFER_SIZE; ++i) { - if(packets[i] && packets[i]->ready) - ++cnt; - } - } - return cnt; -} - -// Return NULL on empty packet buffers -AFSK::Packet *AFSK::PacketBuffer::getPacket() volatile { - unsigned char i = 0; - AFSK::Packet *p = NULL; - - ATOMIC_BLOCK(ATOMIC_RESTORESTATE) { - if(inBuffer == 0) { - return 0x0; - } - - do { - p = packets[nextPacketOut]; - if(p) { - packets[nextPacketOut] = 0x0; - --inBuffer; - } - nextPacketOut = ++nextPacketOut % PACKET_BUFFER_SIZE; - ++i; - } while(!p && iinit(dlen); - } - return p; // Passes through a null on failure. -} - -// Free a packet struct, mainly convenience -void AFSK::PacketBuffer::freePacket(Packet *p) { - if(!p) - return; - ATOMIC_BLOCK(ATOMIC_RESTORESTATE) { -#ifdef PACKET_PREALLOCATE - preallocPool.enqueue(p); -#else - p->free(); - /*unsigned char i; - for(i = 0; i < PPOOL_SIZE; ++i) - if(p == &(pPool[i])) - break; - if(i < PPOOL_SIZE) - pStatus &= ~(1<= PACKET_BUFFER_SIZE) { - return false; - } - packets[nextPacketIn] = p; - nextPacketIn = ++nextPacketIn % PACKET_BUFFER_SIZE; - ++inBuffer; - } - return true; -} - -// Print a single byte to the data array -size_t AFSK::Packet::write(uint8_t c) { - return (appendFCS(c)?1:0); -} - -size_t AFSK::Packet::write(const uint8_t *ptr, size_t len) { - size_t i; - for(i = 0; i < len; ++i) - if(!appendFCS(ptr[i])) - break; - return i; -} - -// Add a callsign, flagged as source, destination, or digi -// Also tell the routine the SSID to use and if this is the final callsign -size_t AFSK::Packet::appendCallsign(const char *callsign, uint8_t ssid, bool final) { - uint8_t i; - for(i = 0; i < strlen(callsign) && i < 6; i++) { - appendFCS(callsign[i]<<1); - } - if(i < 6) { - for(;i<6;i++) { - appendFCS(' '<<1); - } - } - uint8_t ssidField = (ssid&0xf) << 1; - // TODO: Handle digis in the address C bit - if(final) { - ssidField |= 0b01100001; - } else { - ssidField |= 0b11100000; - } - appendFCS(ssidField); -} - -#ifdef PACKET_PARSER -// Process the AX25 frame and turn it into a bunch of useful strings -bool AFSK::Packet::parsePacket() { - uint8_t *d = dataPtr; - int i; - - // First 7 bytes are destination-ssid - for(i = 0; i < 6; i++) { - dstCallsign[i] = (*d++)>>1; - if(dstCallsign[i] == ' ') { - dstCallsign[i] = '\0'; - } - } - dstCallsign[6] = '\0'; - dstSSID = ((*d++)>>1) & 0xF; - - // Next 7 bytes are source-ssid - for(i = 0; i < 6; i++) { - srcCallsign[i] = (*d++)>>1; - if(srcCallsign[i] == ' ') { - srcCallsign[i] = '\0'; - } - } - srcCallsign[6] = '\0'; - srcSSID = *d++; // Don't shift yet, we need the LSB - - digipeater[0][0] = '\0'; // Set null in case we have none anyway - if((srcSSID & 1) == 0) { // Not the last address field - int digi; // Which digi we're on - for(digi = 0; digi < 8; digi++) { - for(i = 0; i < 6; i++) { - digipeater[digi][i] = (*d++)>>1; - if(digipeater[digi][i] == ' ') { - digipeater[digi][i] = '\0'; - } - } - uint8_t last = (*d) & 1; - digipeaterSSID[digi] = ((*d++)>>1) & 0xF; - if(last == 1) - break; - } - digipeater[digi][6] = '\0'; - for(digi += 1; digi<8; digi++) { // Empty out the rest of them - digipeater[digi][0] = '\0'; - } - } - - // Now handle the SSID itself - srcSSID >>= 1; - srcSSID &= 0xF; - - // After the address parsing, we end up on the control field - control = *d++; - // We have a PID if control type is U or I - // Control & 1 == 0 == I frame - // Control & 3 == 3 == U frame - if((control & 1) == 0 || (control & 3) == 3) - pid = *d++; - else pid = 0; - - // If there is no PID, we have no data - if(!pid) { - iFrameData = NULL; - return true; - } - - // At this point, we've walked far enough along that data is just at d - iFrameData = d; - - // Cheat a little by setting the first byte of the FCS to 0, making it a string - // First FCS byte is found at -2, HDLC flags aren't in this buffer - dataPtr[len-2] = '\0'; - - return true; -} -#endif - -void AFSK::Packet::printPacket(Stream *s) { - uint8_t i; -#ifdef PACKET_PARSER - if(!parsePacket()) { - s->print(F("Packet not valid")); - return; - } - - s->print(srcCallsign); - if(srcSSID > 0) { - s->write('-'); - s->print(srcSSID); - } - s->print(F(" > ")); - s->print(dstCallsign); - if(dstSSID > 0) { - s->write('-'); - s->print(dstSSID); - } - s->write(' '); - if(digipeater[0][0] != '\0') { - s->print(F("via ")); - for(i = 0; i < 8; i++) { - if(digipeater[i][0] == '\0') - break; - s->print(digipeater[i]); - if(digipeaterSSID[i] != 0) { - s->write('-'); - s->print(digipeaterSSID[i]); - } - if((digipeaterSSID[i] & _BV(7)) == _BV(7)) { - s->write('*'); // Digipeated already - } - // If we might have more, check to add a comma - if(i < 7 && digipeater[i+1][0] != '\0') { - s->write(','); - } - s->write(' '); - } - } - - // This is an S frame, we can only print control info - if(control & 3 == 1) { - switch((control>>2)&3) { - case 0: - s->print(F("RR")); - break; - case 1: - s->print(F("RNR")); - break; - case 2: - s->print(F("REJ")); - break; - case 3: // Undefined - s->print(F("unk")); - break; - } - // Use a + to indicate poll bit - if(control & _BV(4) == _BV(4)) { - s->write('+'); - } - } else if((control & 3) == 3) { // U Frame - s->print(F("U(")); - s->print(control, HEX); - s->write(','); - s->print(pid, HEX); - s->print(F(") ")); - } else if((control & 1) == 0) { // I Frame - s->print(F("I(")); - s->print(control, HEX); - s->write(','); - s->print(pid, HEX); - s->print(F(") ")); - } - s->print(F("len ")); - s->print(len); - s->print(F(": ")); - s->print((char *)iFrameData); - s->println(); -#else // no packet parser, do a rudimentary print - // Second 6 bytes are source callsign - for(i=7; i<13; i++) { - s->write(*(dataPtr+i)>>1); - } - // SSID - s->write('-'); - s->print((*(dataPtr+13) >> 1) & 0xF); - s->print(F(" -> ")); - // First 6 bytes are destination callsign - for(i=0; i<6; i++) { - s->write(*(dataPtr+i)>>1); - } - // SSID - s->write('-'); - s->print((*(dataPtr+6) >> 1) & 0xF); - // Control/PID next two bytes - // Skip those, print payload - for(i = 15; iwrite(*(dataPtr+i)); - } -#endif -} - -// Determine what we want to do on this ADC tick. -void AFSK::timer() { - static uint8_t tcnt = 0; - if(++tcnt == T_BIT && encoder.isSending()) { - PORTD |= _BV(6); - // Only run the encoder every 8th tick - // This is actually DDS RefClk / 1200 = 8, set as T_BIT - // A different refclk needs a different value - encoder.process(); - tcnt = 0; - PORTD &= ~_BV(6); - } else { - decoder.process(((int8_t)(ADCH - 128))); - } -} - -void AFSK::start(DDS *dds) { - afskEnabled = true; - encoder.setDDS(dds); - decoder.start(); -} diff --git a/src/AFSK.h b/src/AFSK.h deleted file mode 100644 index e7b2418..0000000 --- a/src/AFSK.h +++ /dev/null @@ -1,301 +0,0 @@ -#ifndef _AFSK_H_ -#define _AFSK_H_ - -#include -#include -#include - -#define SAMPLERATE 9600 -#define BITRATE 1200 - -#define SAMPLEPERBIT (SAMPLERATE / BITRATE) - -#define RX_FIFO_LEN 16 - -#define PACKET_BUFFER_SIZE 2 -#define PACKET_STATIC 0 - -// Enable the packet parser which will tokenize the AX25 frame into easy strings -#define PACKET_PARSER - -// If this is set, all the packet buffers will be pre-allocated at compile time -// This will use more RAM, but can make it easier to do memory planning. -// TODO: Make this actually work right and not crash. -#define PACKET_PREALLOCATE - -// This is with all the digis, two addresses, and full payload -// Dst(7) + Src(7) + Digis(56) + Ctl(1) + PID(1) + Data(0-256) + FCS(2) -#define PACKET_MAX_LEN 330 -// Minimum is Dst + Src + Ctl + FCS -#define AX25_PACKET_HEADER_MINLEN 17 - -// HDLC framing bits -#define HDLC_FRAME 0x7E -#define HDLC_RESET 0x7F -#define HDLC_PREAMBLE 0x00 -#define HDLC_ESCAPE 0x1B -#define HDLC_TAIL 0x1C - -class AFSK { -private: - volatile bool afskEnabled; -public: - bool enabled() { return afskEnabled; }; - - class Packet:public Print { - public: - Packet():Print() {}; - virtual size_t write(uint8_t); - // Stock virtual method does what we want here. - //virtual size_t write(const char *); - virtual size_t write(const uint8_t *, size_t); - using Print::write; - unsigned char ready : 1; - unsigned char type : 2; - unsigned char freeData : 1; - unsigned short len; - unsigned short maxLen; - //void init(uint8_t *buf, unsigned int dlen, bool freeData); - void init(unsigned short dlen); - inline void free() { - if(freeData) - ::free(dataPtr); - } - inline const unsigned char getByte(void) { - return *readPos++; - } - inline const unsigned char getByte(uint16_t p) { - return *(dataPtr+p); - } - inline void start() { - fcs = 0xffff; - // No longer put an explicit frame start here - //*dataPos++ = HDLC_ESCAPE; - //*dataPos++ = HDLC_FRAME; - //len = 2; - len = 0; - } - - inline bool append(char c) { - if(len < maxLen) { - ++len; - *dataPos++ = c; - return true; - } - return false; - } - - #define UPDATE_FCS(d) e=fcs^(d); f=e^(e<<4); fcs=(fcs>>8)^(f<<8)^(f<<3)^(f>>4) - //#define UPDATE_FCS(d) s=(d)^(fcs>>8); t=s^(s>>4); fcs=(fcs<<8)^t^(t<<5)^(t<<12) - inline bool appendFCS(unsigned char c) { - register unsigned char e, f; - if(len < maxLen - 4) { // Leave room for FCS/HDLC - append(c); - UPDATE_FCS(c); - return true; - } - return false; - } - - size_t appendCallsign(const char *callsign, uint8_t ssid, bool final = false); - - inline void finish() { - append(~(fcs & 0xff)); - append(~((fcs>>8) & 0xff)); - // No longer append the frame boundaries themselves - //append(HDLC_ESCAPE); - //append(HDLC_FRAME); - ready = 1; - } - - inline void clear() { - fcs = 0xffff; - len = 0; - readPos = dataPtr; - dataPos = dataPtr; - } - - inline bool crcOK() { - return (fcs == 0xF0B8); - } -#ifdef PACKET_PARSER - bool parsePacket(); -#endif - void printPacket(Stream *s); - private: -#ifdef PACKET_PREALLOCATE - uint8_t dataPtr[PACKET_MAX_LEN]; // 256 byte I frame + headers max of 78 -#else - uint8_t *dataPtr; -#endif -#ifdef PACKET_PARSER - char srcCallsign[7]; - uint8_t srcSSID; - char dstCallsign[7]; - uint8_t dstSSID; - char digipeater[8][7]; - uint8_t digipeaterSSID[8]; - uint8_t *iFrameData; - uint8_t length; - uint8_t control; - uint8_t pid; -#endif - uint8_t *dataPos, *readPos; - unsigned short fcs; - }; - - - class PacketBuffer { - public: - // Initialize the buffers - PacketBuffer(); - // How many packets are in the buffer? - unsigned char count() volatile { return inBuffer; }; - // And how many of those are ready? - unsigned char readyCount() volatile; - // Retrieve the next packet - Packet *getPacket() volatile; - // Create a packet structure as needed - // This does not place it in the queue - static Packet *makePacket(unsigned short); - // Conveniently free packet memory - static void freePacket(Packet *); - // Place a packet into the buffer - bool putPacket(Packet *) volatile; - private: - volatile unsigned char inBuffer; - Packet * volatile packets[PACKET_BUFFER_SIZE]; - volatile unsigned char nextPacketIn; - volatile unsigned char nextPacketOut; - }; - - class Encoder { - public: - Encoder() { - randomWait = 1000; // At the very begin, wait at least one second - sending = false; - done = true; - packet = 0x0; - currentBytePos = 0; - nextByte = 0; - } - void setDDS(DDS *d) { dds = d; } - volatile inline bool isSending() volatile { - return sending; - } - volatile inline bool isDone() volatile { - return done; - } - volatile inline bool hasPackets() volatile { - return (pBuf.count() > 0); - } - inline bool putPacket(Packet *packet) { - return pBuf.putPacket(packet); - } - inline void setRandomWait() { - randomWait = 250 + (rand() % 1000) + millis(); - } - bool start(); - void stop(); - void process(); - private: - volatile bool sending; - byte currentByte; - byte currentBit : 1; - byte currentTone : 1; - byte lastZero : 3; - byte bitPosition : 3; - byte preamble : 6; - //byte bitClock; - bool hdlc; - byte nextByte; - byte maxTx; - Packet *packet; - PacketBuffer pBuf; - unsigned int currentBytePos; - volatile unsigned long randomWait; - volatile bool done; - DDS *dds; - }; - - class HDLCDecode { - public: - bool hdlcParse(bool, SimpleFIFO *fifo); - volatile bool rxstart; - private: - uint8_t demod_bits; - uint8_t bit_idx; - uint8_t currchar; - }; - - class Decoder { - public: - Decoder(); - void start(); - bool read(); - void process(int8_t); - inline bool dataAvailable() { - return (rx_fifo.count() > 0); - } - inline uint8_t getByte() { - return rx_fifo.dequeue(); - } - inline uint8_t packetCount() volatile { - return pBuf.count(); - } - inline Packet *getPacket() { - return pBuf.getPacket(); - } - inline bool isReceiving() volatile { - return hdlc.rxstart; - } - private: - Packet *currentPacket; - //SimpleFIFO delay_fifo; - SimpleFIFO rx_fifo; // This should be drained fairly often - int16_t iir_x[2]; - int16_t iir_y[2]; - uint8_t sampled_bits; - int8_t curr_phase; - uint8_t found_bits; - PacketBuffer pBuf; - HDLCDecode hdlc; - }; - -public: - inline bool read() { - return decoder.read(); - } - volatile inline bool txReady() volatile { - if(encoder.isDone() && encoder.hasPackets()) - return true; - return false; - } - volatile inline bool isDone() volatile { return encoder.isDone(); } - inline bool txStart() { - if(decoder.isReceiving()) { - encoder.setRandomWait(); - return false; - } - return encoder.start(); - } - inline bool putTXPacket(Packet *packet) { - bool ret = encoder.putPacket(packet); - if(!ret) // No room? - PacketBuffer::freePacket(packet); - return ret; - } - inline Packet *getRXPacket() { - return decoder.getPacket(); - } - inline uint8_t rxPacketCount() volatile { - return decoder.packetCount(); - } - //unsigned long lastTx; - //unsigned long lastRx; - void start(DDS *); - void timer(); - Encoder encoder; - Decoder decoder; -}; -#endif /* _AFSK_H_ */ diff --git a/src/DDS.cpp b/src/DDS.cpp deleted file mode 100644 index 9cae0d3..0000000 --- a/src/DDS.cpp +++ /dev/null @@ -1,175 +0,0 @@ -#include -#include "DDS.h" - -// To start the DDS, we use Timer1, set to the reference clock -// We use Timer2 for the PWM output, running as fast as feasible -void DDS::start() { - // Use the clkIO clock rate - ASSR &= ~(_BV(EXCLK) | _BV(AS2)); - - // First, the timer for the PWM output - // Setup the timer to use OC2B (pin 3) in fast PWM mode with a configurable top - // Run it without the prescaler -#ifdef DDS_PWM_PIN_3 - TCCR2A = (TCCR2A | _BV(COM2B1)) & ~(_BV(COM2B0) | _BV(COM2A1) | _BV(COM2A0)) | - _BV(WGM21) | _BV(WGM20); - TCCR2B = (TCCR2B & ~(_BV(CS22) | _BV(CS21))) | _BV(CS20) | _BV(WGM22); -#else - // Alternatively, use pin 11 - // Enable output compare on OC2A, toggle mode - TCCR2A = _BV(COM2A1) | _BV(WGM21) | _BV(WGM20); - //TCCR2A = (TCCR2A | _BV(COM2A1)) & ~(_BV(COM2A0) | _BV(COM2B1) | _BV(COM2B0)) | - // _BV(WGM21) | _BV(WGM20); - TCCR2B = _BV(CS20); -#endif - - // Set the top limit, which will be our duty cycle accuracy. - // Setting Comparator Bits smaller will allow for higher frequency PWM, - // with the loss of resolution. -#ifdef DDS_PWM_PIN_3 - OCR2A = pow(2,COMPARATOR_BITS)-1; - OCR2B = 0; -#else - OCR2A = 0; -#endif - -#ifdef DDS_USE_ONLY_TIMER2 - TIMSK2 |= _BV(TOIE2); -#endif - - // Second, setup Timer1 to trigger the ADC interrupt - // This lets us use decoding functions that run at the same reference - // clock as the DDS. - // We use ICR1 as TOP and prescale by 8 - TCCR1B = _BV(CS10) | _BV(WGM13) | _BV(WGM12); - TCCR1A = 0; - ICR1 = ((F_CPU / 1) / refclk) - 1; -#ifdef DDS_DEBUG_SERIAL - Serial.print(F("DDS SysClk: ")); - Serial.println(F_CPU/8); - Serial.print(F("DDS RefClk: ")); - Serial.println(refclk, DEC); - Serial.print(F("DDS ICR1: ")); - Serial.println(ICR1, DEC); -#endif - - // Configure the ADC here to automatically run and be triggered off Timer1 - ADMUX = _BV(REFS0) | _BV(ADLAR) | 2; // Channel 2, shift result left (ADCH used) - DDRC &= ~_BV(0); - PORTC &= ~_BV(0); - DIDR0 |= _BV(0); - ADCSRB = _BV(ADTS2) | _BV(ADTS1) | _BV(ADTS0); - ADCSRA = _BV(ADEN) | _BV(ADSC) | _BV(ADATE) | _BV(ADIE) | _BV(ADPS2); // | _BV(ADPS0); -} - -void DDS::stop() { - // TODO: Stop the timers. -#ifndef DDS_USE_ONLY_TIMER2 - TCCR1B = 0; -#endif - TCCR2B = 0; -} - -// Set our current sine wave frequency in Hz -ddsAccumulator_t DDS::calcFrequency(unsigned short freq) { - // Fo = (M*Fc)/2^N - // M = (Fo/Fc)*2^N - ddsAccumulator_t newStep; - if(refclk == DDS_REFCLK_DEFAULT) { - // Try to use precalculated values if possible - if(freq == 2200) { - newStep = (2200.0 / (DDS_REFCLK_DEFAULT+DDS_REFCLK_OFFSET)) * pow(2,ACCUMULATOR_BITS); - } else if (freq == 1200) { - newStep = (1200.0 / (DDS_REFCLK_DEFAULT+DDS_REFCLK_OFFSET)) * pow(2,ACCUMULATOR_BITS); - } else if(freq == 2400) { - newStep = (2400.0 / (DDS_REFCLK_DEFAULT+DDS_REFCLK_OFFSET)) * pow(2,ACCUMULATOR_BITS); - } else if (freq == 1500) { - newStep = (1500.0 / (DDS_REFCLK_DEFAULT+DDS_REFCLK_OFFSET)) * pow(2,ACCUMULATOR_BITS); - } else if (freq == 600) { - newStep = (600.0 / (DDS_REFCLK_DEFAULT+DDS_REFCLK_OFFSET)) * pow(2,ACCUMULATOR_BITS); - } - } else { - newStep = pow(2,ACCUMULATOR_BITS)*freq / (refclk+refclkOffset); - } - return newStep; -} - -// Degrees should be between -360 and +360 (others don't make much sense) -void DDS::setPhaseDeg(int16_t degrees) { - accumulator = degrees * (pow(2,ACCUMULATOR_BITS)/360.0); -} -void DDS::changePhaseDeg(int16_t degrees) { - accumulator += degrees * (pow(2,ACCUMULATOR_BITS)/360.0); -} - -// TODO: Clean this up a bit.. -void DDS::clockTick() { -/* if(running) { - accumulator += stepRate; - OCR2A = getDutyCycle(); - } - return;*/ - if(running) { - accumulator += stepRate; - if(timeLimited && tickDuration == 0) { -#ifndef DDS_PWM_PIN_3 - OCR2A = 0; -#else -#ifdef DDS_IDLE_HIGH - // Set the duty cycle to 50% - OCR2B = pow(2,COMPARATOR_BITS)/2; -#else - // Set duty cycle to 0, effectively off - OCR2B = 0; -#endif -#endif - running = false; - accumulator = 0; - } else { -#ifdef DDS_PWM_PIN_3 - OCR2B = getDutyCycle(); -#else - OCR2A = getDutyCycle(); -#endif - } - // Reduce our playback duration by one tick - tickDuration--; - } else { - // Hold it low -#ifndef DDS_PWM_PIN_3 - OCR2A = 0; -#else -#ifdef DDS_IDLE_HIGH - // Set the duty cycle to 50% - OCR2B = pow(2,COMPARATOR_BITS)/2; -#else - // Set duty cycle to 0, effectively off - OCR2B = 0; -#endif -#endif - } -} - -uint8_t DDS::getDutyCycle() { - #if ACCUMULATOR_BIT_SHIFT >= 24 - uint16_t phAng; - #else - uint8_t phAng; - #endif - if(amplitude == 0) // Shortcut out on no amplitude - return 128>>(8-COMPARATOR_BITS); - phAng = (accumulator >> ACCUMULATOR_BIT_SHIFT); - int8_t position = pgm_read_byte_near(ddsSineTable + phAng); //>>(8-COMPARATOR_BITS); - // Apply scaling and return - int16_t scaled = position; - // output = ((duty * amplitude) / 256) + 128 - // This keeps amplitudes centered around 50% duty - if(amplitude != 255) { // Amplitude is reduced, so do the full math - scaled *= amplitude; - scaled >>= 8+(8-COMPARATOR_BITS); - } else { // Otherwise, only shift for the comparator bits - scaled >>= (8-COMPARATOR_BITS); - } - scaled += 128>>(8-COMPARATOR_BITS); - return scaled; -} diff --git a/src/DDS.h b/src/DDS.h deleted file mode 100644 index 57cf40b..0000000 --- a/src/DDS.h +++ /dev/null @@ -1,228 +0,0 @@ -#ifndef _DDS_H_ -#define _DDS_H_ - -#include - -// Use pin 3 for PWM? If not defined, use pin 11 -// Quality on pin 3 is higher than on 11, as it can be clocked faster -// when the COMPARATOR_BITS value is less than 8 -#define DDS_PWM_PIN_3 - -// Normally, we turn on timer2 and timer1, and have ADC sampling as our clock -// Define this to only use Timer2, and not start the ADC clock -// #define DDS_USE_ONLY_TIMER2 - -// Use a short (16 bit) accumulator. Phase accuracy is reduced, but speed -// is increased, along with a reduction in memory use. -#define SHORT_ACCUMULATOR - -#ifdef SHORT_ACCUMULATOR -#define ACCUMULATOR_BITS 16 -typedef uint16_t ddsAccumulator_t; -#else -#define ACCUMULATOR_BITS 32 -typedef uint32_t ddsAccumulator_t; -#endif - -// If defined, the timer will idle at 50% duty cycle -// This leaves it floating in the centre of the PWM/DAC voltage range -#define DDS_IDLE_HIGH - -// Select how fast the PWM is, at the expense of level accuracy. -// A faster PWM rate will make for easier filtering of the output wave, -// while a slower one will allow for more accurate voltage level outputs, -// but will increase the filtering requirements on the output. -// 8 = 62.5kHz PWM -// 7 = 125kHz PWM -// 6 = 250kHz PWM -#ifdef DDS_PWM_PIN_3 -#define COMPARATOR_BITS 6 -#else // When using pin 11, we always want 8 bits -#define COMPARATOR_BITS 8 -#endif - -// This is how often we'll perform a phase advance, as well as ADC sampling -// rate. The higher this value, the smoother the output wave will be, at the -// expense of CPU time. It maxes out around 62000 (TBD) -// May be overridden in the sketch to improve performance -#ifndef DDS_REFCLK_DEFAULT -#define DDS_REFCLK_DEFAULT 9600 -#endif -// As each Arduino crystal is a little different, this can be fine tuned to -// provide more accurate frequencies. Adjustments in the range of hundreds -// is a good start. -#ifndef DDS_REFCLK_OFFSET -#define DDS_REFCLK_OFFSET 0 -#endif - -#ifdef DDS_USE_ONLY_TIMER2 -// TODO: Figure out where this clock value is generated from -#define DDS_REFCLK_DEFAULT (62500/4) -#endif - -// Output some of the calculations and information about the DDS over serial -//#define DDS_DEBUG_SERIAL - -// When defined, use the 1024 element sine lookup table. This improves phase -// accuracy, at the cost of more flash and CPU requirements. -// #define DDS_TABLE_LARGE - -#ifdef DDS_TABLE_LARGE -// How many bits to keep from the accumulator to look up in this table -#define ACCUMULATOR_BIT_SHIFT (ACCUMULATOR_BITS-10) -static const int8_t ddsSineTable[1024] PROGMEM = { - 0, 0, 1, 2, 3, 3, 4, 5, 6, 7, 7, 8, 9, 10, 10, 11, 12, 13, 13, 14, 15, 16, 17, 17, 18, 19, 20, 20, 21, 22, 23, 24, - 24, 25, 26, 27, 27, 28, 29, 30, 30, 31, 32, 33, 33, 34, 35, 36, 36, 37, 38, 39, 39, 40, 41, 42, 42, 43, 44, 44, 45, 46, 47, 47, - 48, 49, 50, 50, 51, 52, 52, 53, 54, 55, 55, 56, 57, 57, 58, 59, 59, 60, 61, 61, 62, 63, 63, 64, 65, 65, 66, 67, 67, 68, 69, 69, - 70, 71, 71, 72, 73, 73, 74, 75, 75, 76, 76, 77, 78, 78, 79, 79, 80, 81, 81, 82, 82, 83, 84, 84, 85, 85, 86, 87, 87, 88, 88, 89, - 89, 90, 90, 91, 91, 92, 93, 93, 94, 94, 95, 95, 96, 96, 97, 97, 98, 98, 99, 99, 100, 100, 101, 101, 102, 102, 102, 103, 103, 104, 104, 105, - 105, 106, 106, 106, 107, 107, 108, 108, 108, 109, 109, 110, 110, 110, 111, 111, 112, 112, 112, 113, 113, 113, 114, 114, 114, 115, 115, 115, 116, 116, 116, 117, - 117, 117, 117, 118, 118, 118, 119, 119, 119, 119, 120, 120, 120, 120, 121, 121, 121, 121, 121, 122, 122, 122, 122, 123, 123, 123, 123, 123, 123, 124, 124, 124, - 124, 124, 124, 124, 125, 125, 125, 125, 125, 125, 125, 125, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, - 127, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 126, 125, 125, 125, 125, 125, 125, 125, 125, 124, 124, 124, - 124, 124, 124, 124, 123, 123, 123, 123, 123, 123, 122, 122, 122, 122, 121, 121, 121, 121, 121, 120, 120, 120, 120, 119, 119, 119, 119, 118, 118, 118, 117, 117, - 117, 117, 116, 116, 116, 115, 115, 115, 114, 114, 114, 113, 113, 113, 112, 112, 112, 111, 111, 110, 110, 110, 109, 109, 108, 108, 108, 107, 107, 106, 106, 106, - 105, 105, 104, 104, 103, 103, 102, 102, 102, 101, 101, 100, 100, 99, 99, 98, 98, 97, 97, 96, 96, 95, 95, 94, 94, 93, 93, 92, 91, 91, 90, 90, - 89, 89, 88, 88, 87, 87, 86, 85, 85, 84, 84, 83, 82, 82, 81, 81, 80, 79, 79, 78, 78, 77, 76, 76, 75, 75, 74, 73, 73, 72, 71, 71, - 70, 69, 69, 68, 67, 67, 66, 65, 65, 64, 63, 63, 62, 61, 61, 60, 59, 59, 58, 57, 57, 56, 55, 55, 54, 53, 52, 52, 51, 50, 50, 49, - 48, 47, 47, 46, 45, 44, 44, 43, 42, 42, 41, 40, 39, 39, 38, 37, 36, 36, 35, 34, 33, 33, 32, 31, 30, 30, 29, 28, 27, 27, 26, 25, - 24, 24, 23, 22, 21, 20, 20, 19, 18, 17, 17, 16, 15, 14, 13, 13, 12, 11, 10, 10, 9, 8, 7, 7, 6, 5, 4, 3, 3, 2, 1, 0, - 0, 0, -1, -2, -3, -3, -4, -5, -6, -7, -7, -8, -9, -10, -10, -11, -12, -13, -13, -14, -15, -16, -17, -17, -18, -19, -20, -20, -21, -22, -23, -24, - -24, -25, -26, -27, -27, -28, -29, -30, -30, -31, -32, -33, -33, -34, -35, -36, -36, -37, -38, -39, -39, -40, -41, -42, -42, -43, -44, -44, -45, -46, -47, -47, - -48, -49, -50, -50, -51, -52, -52, -53, -54, -55, -55, -56, -57, -57, -58, -59, -59, -60, -61, -61, -62, -63, -63, -64, -65, -65, -66, -67, -67, -68, -69, -69, - -70, -71, -71, -72, -73, -73, -74, -75, -75, -76, -76, -77, -78, -78, -79, -79, -80, -81, -81, -82, -82, -83, -84, -84, -85, -85, -86, -87, -87, -88, -88, -89, - -89, -90, -90, -91, -91, -92, -93, -93, -94, -94, -95, -95, -96, -96, -97, -97, -98, -98, -99, -99, -100, -100, -101, -101, -102, -102, -102, -103, -103, -104, -104, -105, - -105, -106, -106, -106, -107, -107, -108, -108, -108, -109, -109, -110, -110, -110, -111, -111, -112, -112, -112, -113, -113, -113, -114, -114, -114, -115, -115, -115, -116, -116, -116, -117, - -117, -117, -117, -118, -118, -118, -119, -119, -119, -119, -120, -120, -120, -120, -121, -121, -121, -121, -121, -122, -122, -122, -122, -123, -123, -123, -123, -123, -123, -124, -124, -124, - -124, -124, -124, -124, -125, -125, -125, -125, -125, -125, -125, -125, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, - -127, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -126, -125, -125, -125, -125, -125, -125, -125, -125, -124, -124, -124, - -124, -124, -124, -124, -123, -123, -123, -123, -123, -123, -122, -122, -122, -122, -121, -121, -121, -121, -121, -120, -120, -120, -120, -119, -119, -119, -119, -118, -118, -118, -117, -117, - -117, -117, -116, -116, -116, -115, -115, -115, -114, -114, -114, -113, -113, -113, -112, -112, -112, -111, -111, -110, -110, -110, -109, -109, -108, -108, -108, -107, -107, -106, -106, -106, - -105, -105, -104, -104, -103, -103, -102, -102, -102, -101, -101, -100, -100, -99, -99, -98, -98, -97, -97, -96, -96, -95, -95, -94, -94, -93, -93, -92, -91, -91, -90, -90, - -89, -89, -88, -88, -87, -87, -86, -85, -85, -84, -84, -83, -82, -82, -81, -81, -80, -79, -79, -78, -78, -77, -76, -76, -75, -75, -74, -73, -73, -72, -71, -71, - -70, -69, -69, -68, -67, -67, -66, -65, -65, -64, -63, -63, -62, -61, -61, -60, -59, -59, -58, -57, -57, -56, -55, -55, -54, -53, -52, -52, -51, -50, -50, -49, - -48, -47, -47, -46, -45, -44, -44, -43, -42, -42, -41, -40, -39, -39, -38, -37, -36, -36, -35, -34, -33, -33, -32, -31, -30, -30, -29, -28, -27, -27, -26, -25, - -24, -24, -23, -22, -21, -20, -20, -19, -18, -17, -17, -16, -15, -14, -13, -13, -12, -11, -10, -10, -9, -8, -7, -7, -6, -5, -4, -3, -3, -2, -1, 0 -}; -#else -#define ACCUMULATOR_BIT_SHIFT (ACCUMULATOR_BITS-8) -static const int8_t ddsSineTable[256] PROGMEM = { - 0, 3, 6, 9, 12, 16, 19, 22, 25, 28, 31, 34, 37, 40, 43, 46, 49, - 51, 54, 57, 60, 63, 65, 68, 71, 73, 76, 78, 81, 83, 85, 88, 90, - 92, 94, 96, 98, 100, 102, 104, 106, 107, 109, 111, 112, 113, 115, - 116, 117, 118, 120, 121, 122, 122, 123, 124, 125, 125, 126, 126, - 126, 127, 127, 127, 127, 127, 127, 127, 126, 126, 126, 125, 125, - 124, 123, 122, 122, 121, 120, 118, 117, 116, 115, 113, 112, 111, - 109, 107, 106, 104, 102, 100, 98, 96, 94, 92, 90, 88, 85, 83, 81, - 78, 76, 73, 71, 68, 65, 63, 60, 57, 54, 51, 49, 46, 43, 40, 37, - 34, 31, 28, 25, 22, 19, 16, 12, 9, 6, 3, 0, -3, -6, -9, -12, -16, - -19, -22, -25, -28, -31, -34, -37, -40, -43, -46, -49, -51, -54, - -57, -60, -63, -65, -68, -71, -73, -76, -78, -81, -83, -85, -88, - -90, -92, -94, -96, -98, -100, -102, -104, -106, -107, -109, -111, - -112, -113, -115, -116, -117, -118, -120, -121, -122, -122, -123, - -124, -125, -125, -126, -126, -126, -127, -127, -127, -127, -127, - -127, -127, -126, -126, -126, -125, -125, -124, -123, -122, -122, - -121, -120, -118, -117, -116, -115, -113, -112, -111, -109, -107, - -106, -104, -102, -100, -98, -96, -94, -92, -90, -88, -85, -83, - -81, -78, -76, -73, -71, -68, -65, -63, -60, -57, -54, -51, -49, - -46, -43, -40, -37, -34, -31, -28, -25, -22, -19, -16, -12, -9, -6, -3 - }; -#endif /* DDS_TABLE_LARGE */ - -class DDS { -public: - DDS(): refclk(DDS_REFCLK_DEFAULT), refclkOffset(DDS_REFCLK_OFFSET), - accumulator(0), running(false), - timeLimited(false), tickDuration(0), amplitude(255) - {}; - - // Start all of the timers needed - void start(); - // Is the DDS presently producing a tone? - const bool isRunning() { return running; }; - // Stop the DDS timers - void stop(); - - // Start and stop the PWM output - void on() { - timeLimited = false; - running = true; - } - // Provide a duration in ms for the tone - void on(unsigned short duration) { - // Duration in ticks from milliseconds is: - // t = (1/refclk) - tickDuration = (unsigned long)((unsigned long)duration * (unsigned long)refclk) / 1000; - timeLimited = true; - running = true; - } - void off() { - running = false; - } - - // Generate a tone for a specific amount of time - void play(unsigned short freq, unsigned short duration) { - setFrequency(freq); - on(duration); - } - // Blocking version - void playWait(unsigned short freq, unsigned short duration) { - play(freq, duration); - delay(duration); - } - - // Use these to get some calculated values for specific frequencies - // or to get the current frequency stepping rate. - ddsAccumulator_t calcFrequency(unsigned short freq); - ddsAccumulator_t getPhaseAdvance() { return stepRate; }; - - // Our maximum clock isn't very high, so our highest - // frequency supported will fit in a short. - void setFrequency(unsigned short freq) { stepRate = calcFrequency(freq); }; - void setPrecalcFrequency(ddsAccumulator_t freq) { stepRate = freq; }; - - // Handle phase shifts - void setPhaseDeg(int16_t degrees); - void changePhaseDeg(int16_t degrees); - - // Adjustable reference clock. This shoud be done before the timers are - // started, or they will need to be restarted. Frequencies will need to - // be set again to use the new clock. - void setReferenceClock(unsigned long ref) { - refclk = ref; - } - unsigned long getReferenceClock() { - return refclk; - } - - void setReferenceOffset(int16_t offset) { - refclkOffset = offset; - } - int16_t getReferenceOffset() { - return refclkOffset; - } - - uint8_t getDutyCycle(); - - // Set a scaling factor. To keep things quick, this is a power of 2 value. - // Set it with 0 for lowest (which will be off), 8 is highest. - void setAmplitude(unsigned char amp) { - amplitude = amp; - } - - // This is the function called by the ADC_vect ISR to produce the tones - void clockTick(); - -private: - volatile bool running; - volatile unsigned long tickDuration; - volatile bool timeLimited; - volatile unsigned char amplitude; - volatile ddsAccumulator_t accumulator; - volatile ddsAccumulator_t stepRate; - ddsAccumulator_t refclk; - int16_t refclkOffset; - static DDS *sDDS; -}; - -#endif /* _DDS_H_ */ diff --git a/src/HamShield.cpp b/src/HamShield.cpp index c51badf..62c0f9b 100644 --- a/src/HamShield.cpp +++ b/src/HamShield.cpp @@ -122,10 +122,12 @@ HamShield::HamShield() { devAddr = A1; // devAddr is the chip select pin used by the HamShield sHamShield = this; - pinMode(A1, OUTPUT); - digitalWrite(A1, HIGH); - pinMode(A4, OUTPUT); - pinMode(A5, OUTPUT); + pinMode(devAddr, OUTPUT); + digitalWrite(devAddr, HIGH); + pinMode(CLK, OUTPUT); + digitalWrite(CLK, HIGH); + pinMode(DAT, OUTPUT); + digitalWrite(DAT, HIGH); } /** Specific address constructor. @@ -138,9 +140,11 @@ HamShield::HamShield(uint8_t cs_pin) { devAddr = cs_pin; pinMode(devAddr, OUTPUT); - digitalWrite(A1, HIGH); - pinMode(A4, OUTPUT); - pinMode(A5, OUTPUT); + digitalWrite(devAddr, HIGH); + pinMode(CLK, OUTPUT); + digitalWrite(CLK, HIGH); + pinMode(DAT, OUTPUT); + digitalWrite(DAT, HIGH); } /** Power on and prepare for general usage. diff --git a/src/HamShield.h b/src/HamShield.h index 57d3852..f7efe6e 100644 --- a/src/HamShield.h +++ b/src/HamShield.h @@ -9,9 +9,9 @@ #define _HAMSHIELD_H_ #include "HamShield_comms.h" -#include "SimpleFIFO.h" -#include "AFSK.h" -#include "DDS.h" +//#include "SimpleFIFO.h" +//#include "AFSK.h" +//#include "DDS.h" #include // HamShield constants @@ -22,8 +22,6 @@ #define HAMSHIELD_PWM_PIN 3 // Pin assignment for PWM output #define HAMSHIELD_EMPTY_CHANNEL_RSSI -110 // Default threshold where channel is considered "clear" -#define HAMSHIELD_AFSK_RX_FIFO_LEN 16 - // button modes #define PTT_MODE 1 #define RESET_MODE 2 @@ -491,15 +489,17 @@ class HamShield { void toneWait(uint16_t freq, long timer); void toneWaitU(uint16_t freq, long timer); bool parityCalc(int code); - // void AFSKOut(char buffer[80]); - + + + + //TODO: split AFSK out so it can be left out // AFSK routines - bool AFSKStart(); - bool AFSKEnabled() { return afsk.enabled(); } - bool AFSKStop(); - bool AFSKOut(const char *); + //bool AFSKStart(); + //bool AFSKEnabled() { return afsk.enabled(); } + //bool AFSKStop(); + //bool AFSKOut(const char *); - class AFSK afsk; + //class AFSK afsk; private: uint8_t devAddr; @@ -507,11 +507,11 @@ class HamShield { bool tx_active; bool rx_active; uint32_t radio_frequency; - uint32_t FRS[]; +/* uint32_t FRS[]; uint32_t GMRS[]; uint32_t MURS[]; uint32_t WX[]; - +*/ // private utility functions // these functions should not be called in the Arduino sketch // just use the above public functions to do everything diff --git a/src/HamShield_comms.cpp b/src/HamShield_comms.cpp index bbf1381..d3c173d 100644 --- a/src/HamShield_comms.cpp +++ b/src/HamShield_comms.cpp @@ -33,54 +33,27 @@ int8_t HSreadWord(uint8_t devAddr, uint8_t regAddr, uint16_t *data) uint16_t temp_dat; // bitbang for great justice! *data = 0; - cli(); - DDRC |= ((1<<5) | (1<<4)); // set direction to output - sei(); + pinMode(DAT, OUTPUT); regAddr = regAddr | (1 << 7); - //cli(); digitalWrite(devAddr, 0); //PORTC &= ~(1<<1); //devAddr used as chip select - //sei(); for (int i = 0; i < 8; i++) { temp = ((regAddr & (0x80 >> i)) != 0); - cli(); - PORTC &= ~(1<<5); //digitalWrite(CLK, 0); - sei(); - //digitalWrite(DAT, regAddr & (0x80 >> i)); - temp = (PORTC & ~(1<<4)) + (temp << 4); - cli(); - PORTC = temp; - sei(); - delayMicroseconds(9); - cli(); - PORTC |= (1<<5); //digitalWrite(CLK, 1); - sei(); - delayMicroseconds(9); + digitalWrite(CLK, 0); //PORTC &= ~(1<<5); // + digitalWrite(DAT, temp); + digitalWrite(CLK, 1); //PORTC |= (1<<5); // } // change direction of DAT - cli(); - DDRC &= ~(1<<4); //pinMode(DAT, INPUT); - sei(); + pinMode(DAT, INPUT); // DDRC &= ~(1<<4); // for (int i = 15; i >= 0; i--) { - cli(); - PORTC &= ~(1<<5); //digitalWrite(CLK, 0); - sei(); - delayMicroseconds(9); - cli(); - PORTC |= (1<<5); //digitalWrite(CLK, 1); - sei(); - cli(); - temp_dat = ((PINC & (1<<4)) != 0); - sei(); + digitalWrite(CLK, 0); //PORTC &= ~(1<<5); // + digitalWrite(CLK, 1); //PORTC |= (1<<5); // + temp_dat = digitalRead(DAT); //((PINC & (1<<4)) != 0); temp_dat = temp_dat << i; - *data |= temp_dat; // digitalRead(DAT); - delayMicroseconds(9); + *data |= temp_dat; } digitalWrite(devAddr, 1); //PORTC |= (1<<1);// CS - cli(); - DDRC &= ~((1<<5) | (1<<4)); // set direction all input (for ADC) - sei(); return 1; } @@ -118,52 +91,24 @@ bool HSwriteWord(uint8_t devAddr, uint8_t regAddr, uint16_t data) //digitalWrite(13, HIGH); // bitbang for great justice! - cli(); - DDRC |= ((1<<5) | (1<<4)); // set direction all output - //PORTC |= (1<<5) & (1<<4); - sei(); + pinMode(DAT, OUTPUT); regAddr = regAddr & ~(1 << 7); - //cli(); digitalWrite(devAddr, 0); // PORTC &= ~(1<<1); //CS - //sei(); for (int i = 0; i < 8; i++) { temp_reg = ((regAddr & (0x80 >> i)) != 0); - cli(); - PORTC &= ~(1<<5); //digitalWrite(CLK, 0); - sei(); - //digitalWrite(DAT, regAddr & (0x80 >> i)); - temp_reg = (PORTC & ~(1<<4)) + (temp_reg << 4); - cli(); - PORTC = temp_reg; - sei(); - delayMicroseconds(8); - cli(); - PORTC |= (1<<5); //digitalWrite(CLK, 1); - sei(); - delayMicroseconds(10); + digitalWrite(CLK, 0); //PORTC &= ~(1<<5); // + digitalWrite(DAT, regAddr & (0x80 >> i)); + digitalWrite(CLK, 1); // PORTC |= (1<<5); // } for (int i = 0; i < 16; i++) { temp_dat = ((data & (0x8000 >> i)) != 0); - cli(); - PORTC &= ~(1<<5); //digitalWrite(CLK, 0); - sei(); - //digitalWrite(DAT, data & (0x80000 >> i)); - temp_reg = (PORTC & ~(1<<4)) + (temp_dat << 4); - cli(); - PORTC = temp_reg; - sei(); - delayMicroseconds(7); - cli(); - PORTC |= (1<<5); //digitalWrite(CLK, 1); - sei(); - delayMicroseconds(10); + digitalWrite(CLK, 0); //PORTC &= ~(1<<5); // + digitalWrite(DAT, temp_dat); + digitalWrite(CLK, 1); // PORTC |= (1<<5); // } digitalWrite(devAddr, 1); //PORTC |= (1<<1); //CS - cli(); - DDRC &= ~((1<<5) | (1<<4)); // set direction to input for ADC - sei(); return true; } \ No newline at end of file diff --git a/src/KISS.cpp b/src/KISS.cpp deleted file mode 100644 index fdcd52a..0000000 --- a/src/KISS.cpp +++ /dev/null @@ -1,88 +0,0 @@ -#include -#include "AFSK.h" -#include "KISS.h" - -//AFSK::Packet kissPacket; -bool inFrame = false; -uint8_t kissBuffer[PACKET_MAX_LEN]; -uint16_t kissLen = 0; - -// Inside the KISS loop, we basically wait for data to come in from the -// KISS equipment, and look if we have anything to relay along -void KISS::loop() { - static bool currentlySending = false; - if(radio->afsk.decoder.read() || radio->afsk.rxPacketCount()) { - // A true return means something was put onto the packet FIFO - // If we actually have data packets in the buffer, process them all now - while(radio->afsk.rxPacketCount()) { - AFSK::Packet *packet = radio->afsk.getRXPacket(); - if(packet) { - writePacket(packet); - AFSK::PacketBuffer::freePacket(packet); - } - } - } - // Check if we have incoming data to turn into a packet - while(io->available()) { - uint8_t c = (uint8_t)io->read(); - if(c == KISS_FEND) { - if(inFrame && kissLen > 0) { - int i; - AFSK::Packet *packet = AFSK::PacketBuffer::makePacket(PACKET_MAX_LEN); - packet->start(); - for(i = 0; i < kissLen; i++) { - packet->appendFCS(kissBuffer[i]); - } - packet->finish(); - radio->afsk.encoder.putPacket(packet); - } - kissLen = 0; - inFrame = false; - } - // We're inside the boundaries of a FEND - if(inFrame) { - // Unescape the incoming data - if(c == KISS_FESC) { - c = io->read(); - if(c == KISS_TFESC) { - c = KISS_FESC; - } else { - c = KISS_FEND; - } - } - kissBuffer[kissLen++] = c; - } - if(kissLen == 0 && c != KISS_FEND) { - if((c & 0xf) == 0) // First byte<3:0> should be a 0, otherwise we're having options - inFrame = true; - } - } - if(radio->afsk.txReady()) { - radio->setModeTransmit(); - currentlySending = true; - if(!radio->afsk.txStart()) { // Unable to start for some reason - radio->setModeReceive(); - currentlySending = false; - } - } - if(currentlySending && radio->afsk.encoder.isDone()) { - radio->setModeReceive(); - currentlySending = false; - } -} - -void KISS::writePacket(AFSK::Packet *p) { - int i; - io->write(KISS_FEND); - io->write((uint8_t)0); // Host to TNC port identifier - for(i = 0; i < p->len-2; i++) { - char c = p->getByte(i); - if(c == KISS_FEND || c == KISS_FESC) { - io->write(KISS_FESC); - io->write((c==KISS_FEND?KISS_TFEND:KISS_TFESC)); - } else { - io->write(c); - } - } - io->write(KISS_FEND); -} diff --git a/src/KISS.h b/src/KISS.h deleted file mode 100644 index d89ecaf..0000000 --- a/src/KISS.h +++ /dev/null @@ -1,35 +0,0 @@ -#ifndef _KISS_H_ -#define _KISS_H_ - -#include -#include "AFSK.h" - -#define KISS_FEND 0xC0 -#define KISS_FESC 0xDB -#define KISS_TFEND 0xDC -#define KISS_TFESC 0xDD - -class KISS { -public: - KISS(Stream *_io, HamShield *h, DDS *d) : io(_io), radio(h), dds(d) {} - bool read(); - void writePacket(AFSK::Packet *); - void loop(); - inline void isr() { - static uint8_t tcnt = 0; - TIFR1 = _BV(ICF1); // Clear the timer flag - dds->clockTick(); - if(++tcnt == (DDS_REFCLK_DEFAULT/9600)) { - //PORTD |= _BV(2); // Diagnostic pin (D2) - radio->afsk.timer(); - tcnt = 0; - } - //PORTD &= ~(_BV(2)); - } -private: - Stream *io; - HamShield *radio; - DDS *dds; -}; - -#endif /* _KISS_H_ */ diff --git a/src/SimpleFIFO.h b/src/SimpleFIFO.h deleted file mode 100644 index 6965ce6..0000000 --- a/src/SimpleFIFO.h +++ /dev/null @@ -1,89 +0,0 @@ -#ifndef SimpleFIFO_h -#define SimpleFIFO_h -/* -|| -|| @file SimpleFIFO.h -|| @version 1.2 -|| @author Alexander Brevig -|| @contact alexanderbrevig@gmail.com -|| -|| @description -|| | A simple FIFO class, mostly for primitive types but can be used with classes if assignment to int is allowed -|| | This FIFO is not dynamic, so be sure to choose an appropriate size for it -|| # -|| -|| @license -|| | Copyright (c) 2010 Alexander Brevig -|| | This library is free software; you can redistribute it and/or -|| | modify it under the terms of the GNU Lesser General Public -|| | License as published by the Free Software Foundation; version -|| | 2.1 of the License. -|| | -|| | This library is distributed in the hope that it will be useful, -|| | but WITHOUT ANY WARRANTY; without even the implied warranty of -|| | MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU -|| | Lesser General Public License for more details. -|| | -|| | You should have received a copy of the GNU Lesser General Public -|| | License along with this library; if not, write to the Free Software -|| | Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA -|| # -|| -*/ -template -class SimpleFIFO { -public: - const int size; //speculative feature, in case it's needed - - SimpleFIFO(); - - T dequeue(); //get next element - bool enqueue( T element ); //add an element - T peek() const; //get the next element without releasing it from the FIFO - void flush(); //[1.1] reset to default state - - //how many elements are currently in the FIFO? - unsigned char count() { return numberOfElements; } - -private: -#ifndef SimpleFIFO_NONVOLATILE - volatile unsigned char numberOfElements; - volatile unsigned char nextIn; - volatile unsigned char nextOut; - volatile T raw[rawSize]; -#else - unsigned char numberOfElements; - unsigned char nextIn; - unsigned char nextOut; - T raw[rawSize]; -#endif -}; - -template -SimpleFIFO::SimpleFIFO() : size(rawSize) { - flush(); -} -template -bool SimpleFIFO::enqueue( T element ) { - if ( count() >= rawSize ) { return false; } - numberOfElements++; - nextIn %= size; - raw[nextIn] = element; - nextIn++; //advance to next index - return true; -} -template -T SimpleFIFO::dequeue() { - numberOfElements--; - nextOut %= size; - return raw[ nextOut++]; -} -template -T SimpleFIFO::peek() const { - return raw[ nextOut % size]; -} -template -void SimpleFIFO::flush() { - nextIn = nextOut = numberOfElements = 0; -} -#endif