/* * Copyright 2008, 2009 Free Software Foundation, Inc. * * This software is distributed under the terms of the GNU Affero Public License. * See the COPYING file in the main directory for details. * * This use of this software may be subject to additional restrictions. * See the LEGAL file in the main directory for details. This program is free software: you can redistribute it and/or modify it under the terms of the GNU Affero General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program 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 Affero General Public License for more details. You should have received a copy of the GNU Affero General Public License along with this program. If not, see . */ #include "radioInterface.h" #include bool started = false; RadioInterface::RadioInterface(RadioDevice *wRadio, int wReceiveOffset, int wRadioOversampling, int wTransceiverOversampling, GSM::Time wStartTime) { underrun = false; sendCursor = 0; rcvCursor = 0; mOn = false; mRadio = wRadio; receiveOffset = wReceiveOffset; samplesPerSymbol = wRadioOversampling; mClock.set(wStartTime); loadTest = false; powerScaling = 1.0; } RadioInterface::~RadioInterface(void) { if (rcvBuffer!=NULL) delete rcvBuffer; //mReceiveFIFO.clear(); } double RadioInterface::fullScaleInputValue(void) { return mRadio->fullScaleInputValue(); } double RadioInterface::fullScaleOutputValue(void) { return mRadio->fullScaleOutputValue(); } void RadioInterface::setPowerAttenuation(double atten) { double rfGain, digAtten; rfGain = mRadio->setTxGain(mRadio->maxTxGain() - atten); digAtten = atten - mRadio->maxTxGain() + rfGain; if (digAtten < 1.0) powerScaling = 1.0; else powerScaling = 1.0/sqrt(pow(10, (digAtten/10.0))); } int RadioInterface::radioifyVector(signalVector &wVector, float *retVector, float scale, bool zero) { int i; signalVector::iterator itr = wVector.begin(); if (zero) { memset(retVector, 0, wVector.size() * 2 * sizeof(float)); return wVector.size(); } for (i = 0; i < wVector.size(); i++) { retVector[2 * i + 0] = itr->real() * scale; retVector[2 * i + 1] = itr->imag() * scale; itr++; } return wVector.size(); } int RadioInterface::unRadioifyVector(float *floatVector, signalVector& newVector) { int i; signalVector::iterator itr = newVector.begin(); for (i = 0; i < newVector.size(); i++) { *itr++ = Complex(floatVector[2 * i + 0], floatVector[2 * i + 1]); } return newVector.size(); } bool RadioInterface::tuneTx(double freq) { return mRadio->setTxFreq(freq); } bool RadioInterface::tuneRx(double freq) { return mRadio->setRxFreq(freq); } void RadioInterface::start() { LOG(INFO) << "starting radio interface..."; mAlignRadioServiceLoopThread.start((void * (*)(void*))AlignRadioServiceLoopAdapter, (void*)this); writeTimestamp = mRadio->initialWriteTimestamp(); readTimestamp = mRadio->initialReadTimestamp(); mRadio->start(); LOG(DEBUG) << "Radio started"; mRadio->updateAlignment(writeTimestamp-10000); mRadio->updateAlignment(writeTimestamp-10000); sendBuffer = new float[2*2*INCHUNK*samplesPerSymbol]; rcvBuffer = new float[2*2*OUTCHUNK*samplesPerSymbol]; mOn = true; } void *AlignRadioServiceLoopAdapter(RadioInterface *radioInterface) { while (1) { radioInterface->alignRadio(); pthread_testcancel(); } return NULL; } void RadioInterface::alignRadio() { sleep(60); mRadio->updateAlignment(writeTimestamp+ (TIMESTAMP) 10000); } void RadioInterface::driveTransmitRadio(signalVector &radioBurst, bool zeroBurst) { if (!mOn) return; radioifyVector(radioBurst, sendBuffer + 2 * sendCursor, powerScaling, zeroBurst); sendCursor += radioBurst.size(); pushBuffer(); } void RadioInterface::driveReceiveRadio() { if (!mOn) return; if (mReceiveFIFO.size() > 8) return; pullBuffer(); GSM::Time rcvClock = mClock.get(); rcvClock.decTN(receiveOffset); unsigned tN = rcvClock.TN(); int rcvSz = rcvCursor; int readSz = 0; const int symbolsPerSlot = gSlotLen + 8; // while there's enough data in receive buffer, form received // GSM bursts and pass up to Transceiver // Using the 157-156-156-156 symbols per timeslot format. while (rcvSz > (symbolsPerSlot + (tN % 4 == 0))*samplesPerSymbol) { signalVector rxVector((symbolsPerSlot + (tN % 4 == 0))*samplesPerSymbol); unRadioifyVector(rcvBuffer+readSz*2,rxVector); GSM::Time tmpTime = rcvClock; if (rcvClock.FN() >= 0) { //LOG(DEBUG) << "FN: " << rcvClock.FN(); radioVector *rxBurst = NULL; if (!loadTest) rxBurst = new radioVector(rxVector,tmpTime); else { if (tN % 4 == 0) rxBurst = new radioVector(*finalVec9,tmpTime); else rxBurst = new radioVector(*finalVec,tmpTime); } mReceiveFIFO.put(rxBurst); } mClock.incTN(); rcvClock.incTN(); //if (mReceiveFIFO.size() >= 16) mReceiveFIFO.wait(8); //LOG(DEBUG) << "receiveFIFO: wrote radio vector at time: " << mClock.get() << ", new size: " << mReceiveFIFO.size() ; readSz += (symbolsPerSlot+(tN % 4 == 0))*samplesPerSymbol; rcvSz -= (symbolsPerSlot+(tN % 4 == 0))*samplesPerSymbol; tN = rcvClock.TN(); } if (readSz > 0) { rcvCursor -= readSz; memmove(rcvBuffer,rcvBuffer+2*readSz,sizeof(float) * 2 * rcvCursor); } } bool RadioInterface::isUnderrun() { bool retVal = underrun; underrun = false; return retVal; } void RadioInterface::attach(RadioDevice *wRadio, int wRadioOversampling) { if (!mOn) { mRadio = wRadio; mRadioOversampling = SAMPSPERSYM; } } double RadioInterface::setRxGain(double dB) { if (mRadio) return mRadio->setRxGain(dB); else return -1; } double RadioInterface::getRxGain() { if (mRadio) return mRadio->getRxGain(); else return -1; }