conditional load testing (selected at compile time), turned on by default.

Transceiver52M: Remove unused test code from main
The commented out test code is not maintained and behaviour is unknown. Remove for clarity. Signed-off-by: Thomas Tsou <tom@tsou.cc>
2025-11-04 14:13:29 +00:00 · 2013-09-06 00:35:57 +04:00 · 2013-09-05 06:07:51 -04:00 · 2013-09-05 06:07:50 -04:00 · 2013-09-05 06:07:50 -04:00 · 2013-09-05 06:07:50 -04:00
33 changed files with 3892 additions and 2114 deletions
--- a/CommonLibs/Configuration.cpp
+++ b/CommonLibs/Configuration.cpp
@@ -35,7 +35,7 @@
 #ifdef DEBUG_CONFIG
 #define	debugLogEarly gLogEarly
 #else
-#define	debugLogEarly
+#define	debugLogEarly(x,y,z)
 #endif
--- a/Makefile.am
+++ b/Makefile.am
@@ -20,6 +20,9 @@
 include $(top_srcdir)/Makefile.common
 DESTDIR := 
 ACLOCAL_AMFLAGS = -I config
 AM_CPPFLAGS = $(STD_DEFINES_AND_INCLUDES) $(USB_INCLUDES) $(WITH_INCLUDES)
 AM_CXXFLAGS = -Wall -pthread -ldl
 #AM_CXXFLAGS = -Wall -O2 -NDEBUG -pthread -ldl
--- a/Transceiver52M/DriveLoop.cpp
+++ b/Transceiver52M/DriveLoop.cpp
@@ -0,0 +1,304 @@
 /*
 * Copyright 2008, 2009, 2010, 2012 Free Software Foundation, Inc.
 *
 * This software is distributed under the terms of the GNU 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 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 General Public License for more details.
    You should have received a copy of the GNU General Public License
    along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <stdio.h>
 #include "DriveLoop.h"
 #include <Logger.h>
 using namespace GSM;
 DriveLoop::DriveLoop(int wBasePort, const char *TRXAddress,
                     RadioInterface *wRadioInterface,
 		     int wChanM, int wC0, int wSPS,
                     GSM::Time wTransmitLatency)
 	:mClockSocket(wBasePort, TRXAddress, wBasePort + 100), mC0(wC0)
 {
  mChanM = wChanM;
  mRadioDriveLoopThread = NULL;
  mSPS = wSPS;
  mRadioInterface = wRadioInterface;
  mStartTime = (random() % gHyperframe, 0);
  mTransmitDeadlineClock = mStartTime;
  mLatencyUpdateTime = mStartTime;
  mTransmitLatency = wTransmitLatency;
  mLastClockUpdateTime = mStartTime;
  mRadioInterface->getClock()->set(mStartTime);
  txFullScale = mRadioInterface->fullScaleInputValue();
  mOn = false;
 }
 DriveLoop::~DriveLoop()
 {
  if (mOn) {
    mOn = false;
    if (mRadioDriveLoopThread)
      delete mRadioDriveLoopThread;
  }
  sigProcLibDestroy();
 }
 bool DriveLoop::init()
 {
  if (!sigProcLibSetup(mSPS)) {
    LOG(ALERT) << "Failed to initialize signal processing library";
    return false;
  }
  // initialize filler tables with dummy bursts on C0, empty bursts otherwise
  for (int i = 0; i < 8; i++) {
    signalVector* modBurst = modulateBurst(gDummyBurst,
                                           8 + (i % 4 == 0), mSPS);
    if (!modBurst) {
      sigProcLibDestroy();
      LOG(ALERT) << "Failed to initialize filler table";
      return false;
    }
    scaleVector(*modBurst, txFullScale);
    for (int j = 0; j < 102; j++) {
      for (int n = 0; n < mChanM; n++) {
 #ifndef TRX_LOAD_TESTING
        if (n == mC0)
          fillerTable[n][j][i] = new signalVector(*modBurst);
        else
          fillerTable[n][j][i] = new signalVector(modBurst->size());
 #else
          fillerTable[n][j][i] = new signalVector(*modBurst);
 #endif
      }
    }
    delete modBurst;
    for (int n = 0; n < mChanM; n++) {
      fillerModulus[n][i] = 26;
      mChanType[n][i] = NONE;
    }
  }
  return true;
 }
 void DriveLoop::start()
 {
  if (mOn)
    return;
  mOn = true;
  mRadioDriveLoopThread = new Thread(32768);
  mRadioDriveLoopThread->start((void * (*)(void*))RadioDriveLoopAdapter, (void*) this);
 }
 void DriveLoop::pushRadioVector(GSM::Time &nowTime)
 {
  int i;
  radioVector *staleBurst;
  radioVector *next;
  for (i = 0; i < mChanM; i++) {
    // dump stale bursts, if any
    while (staleBurst = mTransmitPriorityQueue[i].getStaleBurst(nowTime)) {
      // Even if the burst is stale, put it in the fillter table.
      // (It might be an idle pattern.)
      LOG(NOTICE) << "dumping STALE burst in TRX->USRP interface";
    }
    int TN = nowTime.TN();
    int modFN = nowTime.FN() % fillerModulus[i][nowTime.TN()];
    mTxBursts[i] = fillerTable[i][modFN][TN];
    mIsFiller[i] = true;
 #ifndef TRX_LOAD_TESTING
    mIsZero[i] = (mChanType[i][TN] == NONE);
 #else
 	mIsZero[i] = false;
 #endif
    // if queue contains data at the desired timestamp, stick it into FIFO
    if (next = (radioVector*) mTransmitPriorityQueue[i].getCurrentBurst(nowTime)) {
      LOG(DEBUG) << "transmitFIFO: wrote burst " << next << " at time: " << nowTime;
      mTxBursts[i] = next;
      mIsFiller[i] = false;
      mIsZero[i] = false;
    }
  }
  mRadioInterface->driveTransmitRadio(mTxBursts, mIsZero);
  for (i = 0; i < mChanM; i++) {
    if (!mIsFiller[i])
      delete mTxBursts[i];
  }
 }
 void DriveLoop::setModulus(int channel, int timeslot)
 {
  switch (mChanType[channel][timeslot]) {
  case NONE:
  case I:
  case II:
  case III:
  case FILL:
    fillerModulus[channel][timeslot] = 26;
    break;
  case IV:
  case VI:
  case V:
    fillerModulus[channel][timeslot] = 51;
    break;
    //case V: 
  case VII:
    fillerModulus[channel][timeslot] = 102;
    break;
  default:
    break;
  }
 }
 DriveLoop::CorrType DriveLoop::expectedCorrType(int channel, GSM::Time currTime)
 {
  unsigned burstTN = currTime.TN();
  unsigned burstFN = currTime.FN();
  switch (mChanType[channel][burstTN]) {
  case NONE:
    return OFF;
    break;
  case FILL:
    return IDLE;
    break;
  case I:
    return TSC;
    /*if (burstFN % 26 == 25) 
      return IDLE;
    else
      return TSC;*/
    break;
  case II:
    if (burstFN % 2 == 1)
      return IDLE;
    else
      return TSC;
    break;
  case III:
    return TSC;
    break;
  case IV:
  case VI:
    return RACH;
    break;
  case V: {
    int mod51 = burstFN % 51;
    if ((mod51 <= 36) && (mod51 >= 14))
      return RACH;
    else if ((mod51 == 4) || (mod51 == 5))
      return RACH;
    else if ((mod51 == 45) || (mod51 == 46))
      return RACH;
    else
      return TSC;
    break;
  }
  case VII:
    if ((burstFN % 51 <= 14) && (burstFN % 51 >= 12))
      return IDLE;
    else
      return TSC;
    break;
  case LOOPBACK:
    if ((burstFN % 51 <= 50) && (burstFN % 51 >=48))
      return IDLE;
    else
      return TSC;
    break;
  default:
    return OFF;
    break;
  }
 }
 void DriveLoop::driveReceiveFIFO() 
 {
  SoftVector *rxBurst = NULL;
  int RSSI;
  int TOA;  // in 1/256 of a symbol
  GSM::Time burstTime;
  mRadioInterface->driveReceiveRadio();
 }
 /*
 *  Features a carefully controlled latency mechanism, to
 *  assure that transmit packets arrive at the radio/USRP
 *  before they need to be transmitted.
 *  
 *  Deadline clock indicates the burst that needs to be
 *  pushed into the FIFO right NOW.  If transmit queue does
 *  not have a burst, stick in filler data.
 */
 void DriveLoop::driveTransmitFIFO() 
 {
  int i;
  RadioClock *radioClock = (mRadioInterface->getClock());
  while (radioClock->get() + mTransmitLatency > mTransmitDeadlineClock) {
    pushRadioVector(mTransmitDeadlineClock);
    mTransmitDeadlineClock.incTN();
  }
  // FIXME -- This should not be a hard spin.
  // But any delay here causes us to throw omni_thread_fatal.
  //else radioClock->wait();
 }
 void DriveLoop::writeClockInterface()
 {
  char command[50];
  // FIXME -- This should be adaptive.
  sprintf(command,"IND CLOCK %llu",
          (unsigned long long) (mTransmitDeadlineClock.FN() + 2));
  LOG(INFO) << "ClockInterface: sending " << command;
  mClockSocket.write(command,strlen(command)+1);
  mLastClockUpdateTime = mTransmitDeadlineClock;
 }
 void *RadioDriveLoopAdapter(DriveLoop *drive)
 {
  drive->setPriority();
  while (drive->on()) {
    drive->driveReceiveFIFO();
    drive->driveTransmitFIFO();
    pthread_testcancel();
  }
  return NULL;
 }
--- a/Transceiver52M/DriveLoop.h
+++ b/Transceiver52M/DriveLoop.h
@@ -0,0 +1,195 @@
 /*
 * Copyright 2008, 2012 Free Software Foundation, Inc.
 *
 * This software is distributed under the terms of the GNU 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 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 General Public License for more details.
    You should have received a copy of the GNU General Public License
    along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 /*
 	Compilation switches
 	TRANSMIT_LOGGING	write every burst on the given slot to a log
 */
 #ifndef _DRIVELOOP_H_
 #define _DRIVELOOP_H_
 #include "radioInterface.h"
 #include "Interthread.h"
 #include "GSMCommon.h"
 #include "Sockets.h"
 #include <sys/types.h>
 #include <sys/socket.h>
 /** Define this to be the slot number to be logged. */
 //#define TRANSMIT_LOGGING 1
 /** The Transceiver class, responsible for physical layer of basestation */
 class DriveLoop {
 private:
  GSM::Time mTransmitLatency;     ///< latency between basestation clock and transmit deadline clock
  GSM::Time mLatencyUpdateTime;   ///< last time latency was updated
  GSM::Time mLastClockUpdateTime; ///< last time clock update was sent up to core
  UDPSocket mClockSocket;	  ///< socket for writing clock updates to GSM core
  VectorQueue  mTransmitPriorityQueue[CHAN_MAX];   ///< priority queue of transmit bursts received from GSM core
  Thread *mRadioDriveLoopThread;  ///< thread to push/pull bursts into transmit/receive FIFO
  GSM::Time mTransmitDeadlineClock;       ///< deadline for pushing bursts into transmit FIFO 
  GSM::Time mStartTime;                   ///< random start time of the radio clock
  RadioInterface *mRadioInterface;	  ///< associated radioInterface object
  double txFullScale;                     ///< full scale input to radio
  double rxFullScale;                     ///< full scale output to radio
  /** Number of channels supported by the channelizer */
  int mChanM;
  /** unmodulate a modulated burst */
 #ifdef TRANSMIT_LOGGING
  void unModulateVector(signalVector wVector); 
 #endif
  /** Push modulated burst into transmit FIFO corresponding to a particular timestamp */
  void pushRadioVector(GSM::Time &nowTime);
  /** Pull and demodulate a burst from the receive FIFO */ 
  SoftVector *pullRadioVector(GSM::Time &wTime, int &RSSI, int &timingOffset);
  int mSPS;               ///< number of samples per GSM symbol
  bool mOn;			       ///< flag to indicate that transceiver is powered on
  int fillerModulus[CHAN_MAX][8];                ///< modulus values of all timeslots, in frames
  signalVector *fillerTable[CHAN_MAX][102][8];   ///< table of modulated filler waveforms for all timeslots
  /** Channelizer path for primary ARFCN */
  int mC0;
  signalVector *mTxBursts[CHAN_MAX];
  bool         mIsFiller[CHAN_MAX];
  bool         mIsZero[CHAN_MAX];
 public:
  /** Transceiver constructor 
      @param wBasePort base port number of UDP sockets
      @param TRXAddress IP address of the TRX manager, as a string
      @param wSPS number of samples per GSM symbol
      @param wTransmitLatency initial setting of transmit latency
      @param radioInterface associated radioInterface object
  */
  DriveLoop(int wBasePort, const char *TRXAddress,
 	    RadioInterface *wRadioInterface,
 	    int wChanM = 1, int wC0 = 0,
            int wSPS = SAMPSPERSYM,
 	    GSM::Time wTransmitLatency = GSM::Time(3, 0));
  /** Destructor */
  ~DriveLoop();
  /** start the Transceiver */
  bool init();
  void start();
  VectorQueue *priorityQueue(int m) { return &mTransmitPriorityQueue[m]; }
  /** Codes for burst types of received bursts*/
  typedef enum {
    OFF,               ///< timeslot is off
    TSC,	       ///< timeslot should contain a normal burst
    RACH,	       ///< timeslot should contain an access burst
    IDLE	       ///< timeslot is an idle (or dummy) burst
  } CorrType;
  /** Codes for channel combinations */
  typedef enum {
    FILL,               ///< Channel is transmitted, but unused
    I,                  ///< TCH/FS
    II,                 ///< TCH/HS, idle every other slot
    III,                ///< TCH/HS
    IV,                 ///< FCCH+SCH+CCCH+BCCH, uplink RACH
    V,                  ///< FCCH+SCH+CCCH+BCCH+SDCCH/4+SACCH/4, uplink RACH+SDCCH/4
    VI,                 ///< CCCH+BCCH, uplink RACH
    VII,                ///< SDCCH/8 + SACCH/8
    NONE,               ///< Channel is inactive, default
    LOOPBACK            ///< similar go VII, used in loopback testing
  } ChannelCombination;
  /** Set modulus for specific timeslot */
  void setModulus(int channel, int timeslot);
  /** return the expected burst type for the specified timestamp */
  CorrType expectedCorrType(int channel, GSM::Time currTime);
  void setTimeslot(int m, int timeslot, ChannelCombination comb)
  {
    mChanType[m][timeslot] = comb;
  }
  GSM::Time getStartTime() { return mStartTime; }
  GSM::Time getLastClockUpdate() { return mLastClockUpdateTime; }
  GSM::Time getDeadlineClock() { return mTransmitDeadlineClock; }
  /** send messages over the clock socket */
  void writeClockInterface(void);
 private:
  ChannelCombination mChanType[CHAN_MAX][8];     ///< channel types for all timeslots
 protected:
  /** drive reception and demodulation of GSM bursts */ 
  void driveReceiveFIFO();
  /** drive transmission of GSM bursts */
  void driveTransmitFIFO();
  /** drive handling of control messages from GSM core */
  void driveControl();
  /**
    drive modulation and sorting of GSM bursts from GSM core
    @return true if a burst was transferred successfully
  */
  bool driveTransmitPriorityQueue();
  friend void *RadioDriveLoopAdapter(DriveLoop *);
  void reset();
  /** return drive loop status */
  bool on() { return mOn; }
  /** set priority on current thread */
  void setPriority() { mRadioInterface->setPriority(); }
 };
 /** FIFO thread loop */
 void *RadioDriveLoopAdapter(DriveLoop *);
 #endif /* _DRIVELOOP_H_ */
--- a/Transceiver52M/Makefile.am
+++ b/Transceiver52M/Makefile.am
@@ -21,19 +21,19 @@
 include $(top_srcdir)/Makefile.common
 LOAD_TEST_FLAGS = -DTRX_LOAD_TESTING
 AM_CFLAGS = $(STD_DEFINES_AND_INCLUDES) -std=gnu99 -march=native
 AM_CPPFLAGS = $(STD_DEFINES_AND_INCLUDES)
 AM_CXXFLAGS = -ldl -lpthread $(LOAD_TEST_FLAGS)
 #UHD wins if both are defined
 if UHD
-AM_CPPFLAGS = $(STD_DEFINES_AND_INCLUDES) $(UHD_CFLAGS)
+AM_CPPFLAGS += $(UHD_CFLAGS)
 else
 if USRP1
-AM_CPPFLAGS = $(STD_DEFINES_AND_INCLUDES) $(USRP_CFLAGS)
+AM_CPPFLAGS += $(USRP_CFLAGS)
 else
 #we should never be here, as this doesn't build if one of the above
 #doesn't exist
 AM_CPPFLAGS = $(STD_DEFINES_AND_INCLUDES)
 endif
 endif
 AM_CXXFLAGS = -ldl -lpthread
 rev2dir = $(datadir)/usrp/rev2
 rev4dir = $(datadir)/usrp/rev4
@@ -52,23 +52,17 @@ COMMON_SOURCES = \
 	radioVector.cpp \
 	radioClock.cpp \
 	sigProcLib.cpp \
 	DriveLoop.cpp \
 	Transceiver.cpp \
-	DummyLoad.cpp
+	DummyLoad.cpp \
 	convolve.c \
 	convert.c
 if RESAMPLE
 libtransceiver_la_SOURCES = \
-	$(COMMON_SOURCES) \
+	$(COMMON_SOURCES)
 	radioIOResamp.cpp
 else
 libtransceiver_la_SOURCES = \
 	$(COMMON_SOURCES) \
 	radioIO.cpp
 endif
 noinst_PROGRAMS = \
-	USRPping \
+	transceiver
 	transceiver \
 	sigProcLibTest 
 noinst_HEADERS = \
 	Complex.h \
@@ -81,37 +75,24 @@ noinst_HEADERS = \
 	USRPDevice.h \
 	DummyLoad.h \
 	rcvLPF_651.h \
-	sendLPF_961.h
+	sendLPF_961.h \
 	convolve.h \
 	convert.h
-USRPping_SOURCES = USRPping.cpp
+transceiver_SOURCES = multiTRX.cpp
 USRPping_LDADD = \
 	libtransceiver.la \
 	$(COMMON_LA) $(SQLITE_LA)
 transceiver_SOURCES = runTransceiver.cpp
 transceiver_LDADD = \
 	libtransceiver.la \
 	$(GSM_LA) \
 	$(COMMON_LA) $(SQLITE_LA)
 sigProcLibTest_SOURCES = sigProcLibTest.cpp
 sigProcLibTest_LDADD = \
 	libtransceiver.la \
 	$(GSM_LA) \
 	$(COMMON_LA) $(SQLITE_LA)
 #uhd wins
 if UHD
 libtransceiver_la_SOURCES += UHDDevice.cpp
 transceiver_LDADD += $(UHD_LIBS)
 USRPping_LDADD += $(UHD_LIBS)
 sigProcLibTest_LDADD += $(UHD_LIBS)
 else
 if USRP1
 libtransceiver_la_SOURCES += USRPDevice.cpp
 transceiver_LDADD += $(USRP_LIBS)
 USRPping_LDADD += $(USRP_LIBS)
 sigProcLibTest_LDADD += $(USRP_LIBS)
 else
 #we should never be here, as one of the above mustbe defined for us to build
 endif
@@ -119,10 +100,3 @@ endif
 MOSTLYCLEANFILES +=
 #radioInterface.cpp
 #ComplexTest.cpp
 #sigProcLibTest.cpp
 #sweepGenerator.cpp
 #testRadio.cpp
--- a/Transceiver52M/Transceiver.cpp
+++ b/Transceiver52M/Transceiver.cpp
@@ -1,5 +1,5 @@
 /*
-* Copyright 2008, 2009, 2010 Free Software Foundation, Inc.
+* Copyright 2008, 2009, 2010, 2012 Free Software Foundation, Inc.
 *
 * This software is distributed under the terms of the GNU Public License.
 * See the COPYING file in the main directory for details.
@@ -48,72 +48,56 @@ using namespace GSM;
 #define INIT_ENERGY_THRSHD		5.0f
-Transceiver::Transceiver(int wBasePort,
+Transceiver::Transceiver(int wBasePort, const char *TRXAddress,
-			 const char *TRXAddress,
+			 DriveLoop *wDriveLoop, RadioInterface *wRadioInterface,
-			 int wSamplesPerSymbol,
+			 int wSPS, int wChannel, bool wPrimary)
 			 GSM::Time wTransmitLatency,
 			 RadioInterface *wRadioInterface)
 	:mDataSocket(wBasePort+2,TRXAddress,wBasePort+102),
 	 mControlSocket(wBasePort+1,TRXAddress,wBasePort+101),
-	 mClockSocket(wBasePort,TRXAddress,wBasePort+100)
+	 mDriveLoop(wDriveLoop), mRadioInterface(wRadioInterface),
 	 mSPS(wSPS), mTransmitPriorityQueue(NULL),
 	 mChannel(wChannel), mPrimary(wPrimary)
 {
-  //GSM::Time startTime(0,0);
+  mFIFOServiceLoopThread = NULL;
-  //GSM::Time startTime(gHyperframe/2 - 4*216*60,0);
+  mControlServiceLoopThread = NULL;
-  GSM::Time startTime(random() % gHyperframe,0);
+  mTransmitPriorityQueueServiceLoopThread = NULL;
-
+#ifndef TRX_LOAD_TESTING
  mFIFOServiceLoopThread = new Thread(32768);  ///< thread to push bursts into transmit FIFO
  mControlServiceLoopThread = new Thread(32768);       ///< thread to process control messages from GSM core
  mTransmitPriorityQueueServiceLoopThread = new Thread(32768);///< thread to process transmit bursts from GSM core
  mSamplesPerSymbol = wSamplesPerSymbol;
  mRadioInterface = wRadioInterface;
  mTransmitLatency = wTransmitLatency;
  mTransmitDeadlineClock = startTime;
  mLastClockUpdateTime = startTime;
  mLatencyUpdateTime = startTime;
  mRadioInterface->getClock()->set(startTime);
  mMaxExpectedDelay = 0;
 #else
  mMaxExpectedDelay = 10;
 #endif
-  // generate pulse and setup up signal processing library
+  mTransmitPriorityQueue = mDriveLoop->priorityQueue(mChannel);
-  gsmPulse = generateGSMPulse(2,mSamplesPerSymbol);
+  mReceiveFIFO = mRadioInterface->receiveFIFO(mChannel);
  LOG(DEBUG) << "gsmPulse: " << *gsmPulse;
  sigProcLibSetup(mSamplesPerSymbol);
  txFullScale = mRadioInterface->fullScaleInputValue();
  rxFullScale = mRadioInterface->fullScaleOutputValue();
-  // initialize filler tables with dummy bursts, initialize other per-timeslot variables
+  // initialize per-timeslot variables
  for (int i = 0; i < 8; i++) {
    signalVector* modBurst = modulateBurst(gDummyBurst,*gsmPulse,
 					   8 + (i % 4 == 0),
 					   mSamplesPerSymbol);
    scaleVector(*modBurst,txFullScale);
    fillerModulus[i]=26;
    for (int j = 0; j < 102; j++) {
      fillerTable[j][i] = new signalVector(*modBurst);
    }
    delete modBurst;
    mChanType[i] = NONE;
    channelResponse[i] = NULL;
    DFEForward[i] = NULL;
    DFEFeedback[i] = NULL;
-    channelEstimateTime[i] = startTime;
+    channelEstimateTime[i] = mDriveLoop->getStartTime();
  }
  mOn = false;
  mRunning = false;
  mTxFreq = 0.0;
  mRxFreq = 0.0;
  mFreqOffset = 0.0;
  mPower = -10;
  mEnergyThreshold = INIT_ENERGY_THRSHD;
-  prevFalseDetectionTime = startTime;
+  prevFalseDetectionTime = mDriveLoop->getStartTime();
 }
 Transceiver::~Transceiver()
 {
-  delete gsmPulse;
+  mTransmitPriorityQueue->clear();
-  sigProcLibDestroy();
+
-  mTransmitPriorityQueue.clear();
+  delete mFIFOServiceLoopThread;
  delete mControlServiceLoopThread;
  delete mTransmitPriorityQueueServiceLoopThread;
 }
@@ -122,187 +106,26 @@ void Transceiver::addRadioVector(BitVector &burst,
 				 GSM::Time &wTime)
 {
  // modulate and stick into queue 
-  signalVector* modBurst = modulateBurst(burst,*gsmPulse,
+  signalVector* modBurst = modulateBurst(burst,
                                         8 + (wTime.TN() % 4 == 0),
-					 mSamplesPerSymbol);
+                                         mSPS);
  scaleVector(*modBurst,txFullScale * pow(10,-RSSI/10));
  radioVector *newVec = new radioVector(*modBurst,wTime);
-  mTransmitPriorityQueue.write(newVec);
+  mTransmitPriorityQueue->write(newVec);
  delete modBurst;
 }
 #ifdef TRANSMIT_LOGGING
 void Transceiver::unModulateVector(signalVector wVector) 
 {
  SoftVector *burst = demodulateBurst(wVector,
 				   *gsmPulse,
 				   mSamplesPerSymbol,
 				   1.0,0.0);
  LOG(DEBUG) << "LOGGED BURST: " << *burst;
 /*
  unsigned char burstStr[gSlotLen+1];
  SoftVector::iterator burstItr = burst->begin();
  for (int i = 0; i < gSlotLen; i++) {
    // FIXME: Demod bits are inverted!
    burstStr[i] = (unsigned char) ((*burstItr++)*255.0);
  }
  burstStr[gSlotLen]='\0';
  LOG(DEBUG) << "LOGGED BURST: " << burstStr;
 */
  delete burst;
 }
 #endif
 void Transceiver::pushRadioVector(GSM::Time &nowTime)
 {
  // dump stale bursts, if any
  while (radioVector* staleBurst = mTransmitPriorityQueue.getStaleBurst(nowTime)) {
    // Even if the burst is stale, put it in the fillter table.
    // (It might be an idle pattern.)
    LOG(NOTICE) << "dumping STALE burst in TRX->USRP interface";
    const GSM::Time& nextTime = staleBurst->getTime();
    int TN = nextTime.TN();
    int modFN = nextTime.FN() % fillerModulus[TN];
    delete fillerTable[modFN][TN];
    fillerTable[modFN][TN] = staleBurst;
  }
  int TN = nowTime.TN();
  int modFN = nowTime.FN() % fillerModulus[nowTime.TN()];
  // if queue contains data at the desired timestamp, stick it into FIFO
  if (radioVector *next = (radioVector*) mTransmitPriorityQueue.getCurrentBurst(nowTime)) {
    LOG(DEBUG) << "transmitFIFO: wrote burst " << next << " at time: " << nowTime;
    delete fillerTable[modFN][TN];
    fillerTable[modFN][TN] = new signalVector(*(next));
    mRadioInterface->driveTransmitRadio(*(next),(mChanType[TN]==NONE)); //fillerTable[modFN][TN]));
    delete next;
 #ifdef TRANSMIT_LOGGING
    if (nowTime.TN()==TRANSMIT_LOGGING) { 
      unModulateVector(*(fillerTable[modFN][TN]));
    }
 #endif
    return;
  }
  // otherwise, pull filler data, and push to radio FIFO
  mRadioInterface->driveTransmitRadio(*(fillerTable[modFN][TN]),(mChanType[TN]==NONE));
 #ifdef TRANSMIT_LOGGING
  if (nowTime.TN()==TRANSMIT_LOGGING) 
    unModulateVector(*fillerTable[modFN][TN]);
 #endif
 }
 void Transceiver::setModulus(int timeslot)
 {
  switch (mChanType[timeslot]) {
  case NONE:
  case I:
  case II:
  case III:
  case FILL:
    fillerModulus[timeslot] = 26;
    break;
  case IV:
  case VI:
  case V:
    fillerModulus[timeslot] = 51;
    break;
    //case V: 
  case VII:
    fillerModulus[timeslot] = 102;
    break;
  case XIII:
    fillerModulus[timeslot] = 52;
    break;
  default:
    break;
  }
 }
 Transceiver::CorrType Transceiver::expectedCorrType(GSM::Time currTime)
 {
  unsigned burstTN = currTime.TN();
  unsigned burstFN = currTime.FN();
  switch (mChanType[burstTN]) {
  case NONE:
    return OFF;
    break;
  case FILL:
    return IDLE;
    break;
  case I:
    return TSC;
    /*if (burstFN % 26 == 25) 
      return IDLE;
    else
      return TSC;*/
    break;
  case II:
    return TSC;
    break;
  case III:
    return TSC;
    break;
  case IV:
  case VI:
    return RACH;
    break;
  case V: {
    int mod51 = burstFN % 51;
    if ((mod51 <= 36) && (mod51 >= 14))
      return RACH;
    else if ((mod51 == 4) || (mod51 == 5))
      return RACH;
    else if ((mod51 == 45) || (mod51 == 46))
      return RACH;
    else
      return TSC;
    break;
  }
  case VII:
    if ((burstFN % 51 <= 14) && (burstFN % 51 >= 12))
      return IDLE;
    else
      return TSC;
    break;
  case XIII: {
    int mod52 = burstFN % 52;
    if ((mod52 == 12) || (mod52 == 38))
      return RACH;
    else if ((mod52 == 25) || (mod52 == 51))
      return IDLE;
    else
      return TSC;
    break;
  }
  case LOOPBACK:
    if ((burstFN % 51 <= 50) && (burstFN % 51 >=48))
      return IDLE;
    else
      return TSC;
    break;
  default:
    return OFF;
    break;
  }
 }
 SoftVector *Transceiver::pullRadioVector(GSM::Time &wTime,
 				      int &RSSI,
 				      int &timingOffset)
 {
-  bool needDFE = (mMaxExpectedDelay > 1);
+  bool needDFE = false;
-  radioVector *rxBurst = (radioVector *) mReceiveFIFO->get();
+  if ((mSPS == 1) && (mMaxExpectedDelay > 1))
    needDFE = true;
  radioVector *rxBurst = (radioVector *) mReceiveFIFO->read();
  if (!rxBurst) return NULL;
@@ -310,19 +133,22 @@ SoftVector *Transceiver::pullRadioVector(GSM::Time &wTime,
  int timeslot = rxBurst->getTime().TN();
-  CorrType corrType = expectedCorrType(rxBurst->getTime());
+  DriveLoop::CorrType corrType = mDriveLoop->expectedCorrType(mChannel, rxBurst->getTime());
-  if ((corrType==OFF) || (corrType==IDLE)) {
+#ifndef TRX_LOAD_TESTING
  if ((corrType == DriveLoop::OFF) || (corrType == DriveLoop::IDLE)) {
    delete rxBurst;
    return NULL;
  }
 #endif
  // check to see if received burst has sufficient 
  signalVector *vectorBurst = rxBurst;
  complex amplitude = 0.0;
  float TOA = 0.0;
  float avgPwr = 0.0;
-  if (!energyDetect(*vectorBurst,20*mSamplesPerSymbol,mEnergyThreshold,&avgPwr)) {
+#ifdef ENERGY_DETECT
  if (!energyDetect(*vectorBurst,20*mSPS,mEnergyThreshold,&avgPwr)) {
     LOG(DEBUG) << "Estimated Energy: " << sqrt(avgPwr) << ", at time " << rxBurst->getTime();
     double framesElapsed = rxBurst->getTime()-prevFalseDetectionTime;
     if (framesElapsed > 50) {  // if we haven't had any false detections for a while, lower threshold
@@ -332,15 +158,18 @@ SoftVector *Transceiver::pullRadioVector(GSM::Time &wTime,
        prevFalseDetectionTime = rxBurst->getTime();
     }
 #ifndef TRX_LOAD_TESTING
     delete rxBurst;
     return NULL;
 #endif
  }
  LOG(DEBUG) << "Estimated Energy: " << sqrt(avgPwr) << ", at time " << rxBurst->getTime();
-
+#endif
  // run the proper correlator
  bool success = false;
-  if (corrType==TSC) {
+  if (corrType == DriveLoop::TSC) {
    LOG(DEBUG) << "looking for TSC at time: " << rxBurst->getTime();
    signalVector *channelResp;
    double framesElapsed = rxBurst->getTime()-channelEstimateTime[timeslot];
    bool estimateChannel = false;
@@ -358,13 +187,16 @@ SoftVector *Transceiver::pullRadioVector(GSM::Time &wTime,
    success = analyzeTrafficBurst(*vectorBurst,
 				  mTSC,
 				  3.0,
-				  mSamplesPerSymbol,
+				  mSPS,
 				  &amplitude,
 				  &TOA,
 				  mMaxExpectedDelay, 
 				  estimateChannel,
 				  &channelResp,
 				  &chanOffset);
 #ifdef TRX_LOAD_TESTING
    success = true;
 #endif
    if (success) {
      LOG(DEBUG) << "FOUND TSC!!!!!! " << amplitude << " " << TOA;
      mEnergyThreshold -= 1.0F/10.0F;
@@ -393,9 +225,12 @@ SoftVector *Transceiver::pullRadioVector(GSM::Time &wTime,
    // RACH burst
    success = detectRACHBurst(*vectorBurst,
 			      5.0,  // detection threshold
-			      mSamplesPerSymbol,
+			      mSPS,
 			      &amplitude,
 			      &TOA);
 #ifdef TRX_LOAD_TESTING
    success = true;
 #endif
    if (success) {
      LOG(DEBUG) << "FOUND RACH!!!!!! " << amplitude << " " << TOA;
      mEnergyThreshold -= (1.0F/10.0F);
@@ -413,24 +248,23 @@ SoftVector *Transceiver::pullRadioVector(GSM::Time &wTime,
  // demodulate burst
  SoftVector *burst = NULL;
  if ((rxBurst) && (success)) {
-    if ((corrType==RACH) || (!needDFE)) {
+    if ((corrType == DriveLoop::RACH) || (!needDFE)) {
      burst = demodulateBurst(*vectorBurst,
-			      *gsmPulse,
+			      mSPS,
 			      mSamplesPerSymbol,
 			      amplitude,TOA);
    }
    else { // TSC
      scaleVector(*vectorBurst,complex(1.0,0.0)/amplitude);
      burst = equalizeBurst(*vectorBurst,
 			    TOA-chanRespOffset[timeslot],
-			    mSamplesPerSymbol,
+			    mSPS,
 			    *DFEForward[timeslot],
 			    *DFEFeedback[timeslot]);
    }
    wTime = rxBurst->getTime();
    RSSI = (int) floor(20.0*log10(rxFullScale/amplitude.abs()));
    LOG(DEBUG) << "RSSI: " << RSSI;
-    timingOffset = (int) round(TOA*256.0/mSamplesPerSymbol);
+    timingOffset = (int) round(TOA*256.0/mSPS);
  }
  //if (burst) LOG(DEBUG) << "burst: " << *burst << '\n';
@@ -440,16 +274,69 @@ SoftVector *Transceiver::pullRadioVector(GSM::Time &wTime,
  return burst;
 }
 void Transceiver::pullFIFO()
 {
  SoftVector *rxBurst = NULL;
  int RSSI;
  int TOA;  // in 1/256 of a symbol
  GSM::Time burstTime;
  rxBurst = pullRadioVector(burstTime,RSSI,TOA);
  if (rxBurst) {
    LOG(DEBUG) << "burst parameters: "
               << " time: " << burstTime
               << " RSSI: " << RSSI
               << " TOA: "  << TOA
               << " bits: " << *rxBurst;
    char burstString[gSlotLen+10];
    burstString[0] = burstTime.TN();
    for (int i = 0; i < 4; i++) {
            burstString[1+i] = (burstTime.FN() >> ((3-i)*8)) & 0x0ff;
    }
    burstString[5] = RSSI;
    burstString[6] = (TOA >> 8) & 0x0ff;
    burstString[7] = TOA & 0x0ff;
    SoftVector::iterator burstItr = rxBurst->begin();
    for (unsigned int i = 0; i < gSlotLen; i++) {
            burstString[8+i] =(char) round((*burstItr++)*255.0);
    }
    burstString[gSlotLen+9] = '\0';
    delete rxBurst;
    mDataSocket.write(burstString,gSlotLen+10);
  }
 }
 void Transceiver::start()
 {
  mRunning = true;
  mControlServiceLoopThread = new Thread(32768);
  mControlServiceLoopThread->start((void * (*)(void*))ControlServiceLoopAdapter,(void*) this);
  if (!mPrimary) {
    mOn = true;
    mFIFOServiceLoopThread = new Thread(32768);
    mFIFOServiceLoopThread->start((void * (*)(void*))FIFOServiceLoopAdapter,(void*) this);
    mTransmitPriorityQueueServiceLoopThread = new Thread(32768);
    mTransmitPriorityQueueServiceLoopThread->start((void * (*)(void*))TransmitPriorityQueueServiceLoopAdapter,(void*) this);
  }
 }
 void Transceiver::shutdown()
 {
  mOn = false;
  mRunning = false;
 }
 void Transceiver::reset()
 {
-  mTransmitPriorityQueue.clear();
+  mTransmitPriorityQueue->clear();
  //mTransmitFIFO->clear();
  //mReceiveFIFO->clear();
 }
@@ -463,11 +350,20 @@ void Transceiver::driveControl()
  int msgLen = -1;
  buffer[0] = '\0';
  try { 
    msgLen = mControlSocket.read(buffer);
    if (msgLen < 1) {
      return;
    }
  } catch (...) {
    /* Ignore the read exception on shutdown */
    if (!mRunning) {
      return;
    }
    LOG(ALERT) << "Caught UHD socket exception";
    return;
  }
  char cmdcheck[4];
  char command[MAX_PACKET_LENGTH];
@@ -475,7 +371,7 @@ void Transceiver::driveControl()
  sscanf(buffer,"%3s %s",cmdcheck,command);
-  writeClockInterface();
+  mDriveLoop->writeClockInterface();
  if (strcmp(cmdcheck,"CMD")!=0) {
    LOG(WARNING) << "bogus message on control interface";
@@ -489,22 +385,24 @@ void Transceiver::driveControl()
  }
  else if (strcmp(command,"POWERON")==0) {
    // turn on transmitter/demod
-    if (!mTxFreq || !mRxFreq) 
+    if (!mTxFreq || !mRxFreq || (mTSC<0))
      sprintf(response,"RSP POWERON 1");
    else {
      sprintf(response,"RSP POWERON 0");
-      if (!mOn) {
+      if (mPrimary && !mOn) {
        // Prepare for thread start
        mPower = -20;
        mRadioInterface->start();
-        generateRACHSequence(*gsmPulse,mSamplesPerSymbol);
+        mDriveLoop->start();
        mDriveLoop->writeClockInterface();
        // Start radio interface threads.
        mFIFOServiceLoopThread->start((void * (*)(void*))FIFOServiceLoopAdapter,(void*) this);
        mTransmitPriorityQueueServiceLoopThread->start((void * (*)(void*))TransmitPriorityQueueServiceLoopAdapter,(void*) this);
        writeClockInterface();
        mOn = true;
        mFIFOServiceLoopThread = new Thread(32768);
        mFIFOServiceLoopThread->start((void * (*)(void*))FIFOServiceLoopAdapter,(void*) this);
        mTransmitPriorityQueueServiceLoopThread = new Thread(32768);
        mTransmitPriorityQueueServiceLoopThread->start((void * (*)(void*))TransmitPriorityQueueServiceLoopAdapter,(void*) this);
      }
    }
  }
@@ -512,15 +410,17 @@ void Transceiver::driveControl()
    //set expected maximum time-of-arrival
    int maxDelay;
    sscanf(buffer,"%3s %s %d",cmdcheck,command,&maxDelay);
 #ifndef TRX_LOAD_TESTING
    mMaxExpectedDelay = maxDelay; // 1 GSM symbol is approx. 1 km
 #endif
    sprintf(response,"RSP SETMAXDLY 0 %d",maxDelay);
  }
  else if (strcmp(command,"SETRXGAIN")==0) {
    //set expected maximum time-of-arrival
    int newGain;
    sscanf(buffer,"%3s %s %d",cmdcheck,command,&newGain);
    newGain = mRadioInterface->setRxGain(newGain);
    mEnergyThreshold = INIT_ENERGY_THRSHD;
    newGain = mRadioInterface->setRxGain(newGain, mChannel);
    sprintf(response,"RSP SETRXGAIN 0 %d",newGain);
  }
  else if (strcmp(command,"NOISELEV")==0) {
@@ -540,7 +440,7 @@ void Transceiver::driveControl()
      sprintf(response,"RSP SETPOWER 1 %d",dbPwr);
    else {
      mPower = dbPwr;
-      mRadioInterface->setPowerAttenuation(dbPwr);
+      mRadioInterface->setPowerAttenuation(dbPwr, mChannel);
      sprintf(response,"RSP SETPOWER 0 %d",dbPwr);
    }
  }
@@ -555,46 +455,45 @@ void Transceiver::driveControl()
      sprintf(response,"RSP ADJPOWER 0 %d",mPower);
    }
  }
 #define FREQOFFSET 0//11.2e3
  else if (strcmp(command,"RXTUNE")==0) {
    // tune receiver
    int freqKhz;
    sscanf(buffer,"%3s %s %d",cmdcheck,command,&freqKhz);
-    mRxFreq = freqKhz*1.0e3+FREQOFFSET;
+    mRxFreq = freqKhz * 1.0e3 + mFreqOffset;
-    if (!mRadioInterface->tuneRx(mRxFreq)) {
+    if (!mRadioInterface->tuneRx(mRxFreq, mChannel)) {
      LOG(ALERT) << "RX failed to tune";
      sprintf(response,"RSP RXTUNE 1 %d",freqKhz);
-    }
+    } else {
    else
      sprintf(response,"RSP RXTUNE 0 %d",freqKhz);
    }
  }
  else if (strcmp(command,"TXTUNE")==0) {
    // tune txmtr
    int freqKhz;
    sscanf(buffer,"%3s %s %d",cmdcheck,command,&freqKhz);
    //freqKhz = 890e3;
-    mTxFreq = freqKhz*1.0e3+FREQOFFSET;
+    mTxFreq = freqKhz * 1.0e3 + mFreqOffset;
-    if (!mRadioInterface->tuneTx(mTxFreq)) {
+    if (!mRadioInterface->tuneTx(mTxFreq, mChannel)) {
      LOG(ALERT) << "TX failed to tune";
      sprintf(response,"RSP TXTUNE 1 %d",freqKhz);
-    }
+    } else {
    else
      sprintf(response,"RSP TXTUNE 0 %d",freqKhz);
    }
  }
  else if (strcmp(command,"SETTSC")==0) {
    // set TSC
    int TSC;
    sscanf(buffer,"%3s %s %d",cmdcheck,command,&TSC);
-    if (mOn)
+    if (mOn || (TSC<0) || (TSC>7))
      sprintf(response,"RSP SETTSC 1 %d",TSC);
    else {
      mTSC = TSC;
-      generateMidamble(*gsmPulse,mSamplesPerSymbol,TSC);
+      generateMidamble(mSPS, TSC);
      sprintf(response,"RSP SETTSC 0 %d",TSC);
    }
  }
  else if (strcmp(command,"SETSLOT")==0) {
-    // set TSC 
+    // set slot type
    int  corrCode;
    int  timeslot;
    sscanf(buffer,"%3s %s %d %d",cmdcheck,command,&timeslot,&corrCode);
@@ -603,13 +502,14 @@ void Transceiver::driveControl()
      sprintf(response,"RSP SETSLOT 1 %d %d",timeslot,corrCode);
      return;
    }     
-    mChanType[timeslot] = (ChannelCombination) corrCode;
+    mDriveLoop->setTimeslot(mChannel, timeslot, (DriveLoop::ChannelCombination) corrCode);
-    setModulus(timeslot);
+    mDriveLoop->setModulus(mChannel, timeslot);
    sprintf(response,"RSP SETSLOT 0 %d %d",timeslot,corrCode);
  }
  else {
    LOG(WARNING) << "bogus command " << command << " on control interface.";
    sprintf(response,"RSP ERR 1");
  }
  mControlSocket.write(response,strlen(response)+1);
@@ -618,44 +518,38 @@ void Transceiver::driveControl()
 bool Transceiver::driveTransmitPriorityQueue() 
 {
  char buffer[gSlotLen+50];
-  // check data socket
+  if (!mOn)
-  size_t msgLen = mDataSocket.read(buffer);
+    return true;
  try { 
    size_t msgLen = mDataSocket.read(buffer);
    if (msgLen!=gSlotLen+1+4+1) {
      LOG(ERR) << "badly formatted packet on GSM->TRX interface";
      return false;
    }
  } catch (...) {
    if (!mOn) {
      /* Shutdown condition. End the thread. */
      return true;
    }
    LOG(ALERT) << "Caught UHD socket exception";
    return false;
  }
  int timeSlot = (int) buffer[0];
  uint64_t frameNum = 0;
  for (int i = 0; i < 4; i++)
    frameNum = (frameNum << 8) | (0x0ff & buffer[i+1]);
  /*
  if (GSM::Time(frameNum,timeSlot) >  mTransmitDeadlineClock + GSM::Time(51,0)) {
    // stale burst
    //LOG(DEBUG) << "FAST! "<< GSM::Time(frameNum,timeSlot);
    //writeClockInterface();
    }*/
 /*
  DAB -- Just let these go through the demod.
  if (GSM::Time(frameNum,timeSlot) < mTransmitDeadlineClock) {
    // stale burst from GSM core
    LOG(NOTICE) << "STALE packet on GSM->TRX interface at time "<< GSM::Time(frameNum,timeSlot);
    return false;
  }
 */
  // periodically update GSM core clock
-  LOG(DEBUG) << "mTransmitDeadlineClock " << mTransmitDeadlineClock
+  LOG(DEBUG) << "mTransmitDeadlineClock " << mDriveLoop->getDeadlineClock()
-		<< " mLastClockUpdateTime " << mLastClockUpdateTime;
+             << " mLastClockUpdateTime " << mDriveLoop->getLastClockUpdate();
-  if (mTransmitDeadlineClock > mLastClockUpdateTime + GSM::Time(216,0))
+  if (mDriveLoop->getDeadlineClock() > mDriveLoop->getLastClockUpdate() + GSM::Time(216,0)) {
-    writeClockInterface();
+    mDriveLoop->writeClockInterface();
-
+  }
  LOG(DEBUG) << "rcvd. burst at: " << GSM::Time(frameNum,timeSlot);
@@ -677,126 +571,10 @@ bool Transceiver::driveTransmitPriorityQueue()
 }
 void Transceiver::driveReceiveFIFO() 
 {
  SoftVector *rxBurst = NULL;
  int RSSI;
  int TOA;  // in 1/256 of a symbol
  GSM::Time burstTime;
  mRadioInterface->driveReceiveRadio();
  rxBurst = pullRadioVector(burstTime,RSSI,TOA);
  if (rxBurst) { 
    LOG(DEBUG) << "burst parameters: "
 	  << " time: " << burstTime
 	  << " RSSI: " << RSSI
 	  << " TOA: "  << TOA
 	  << " bits: " << *rxBurst;
    char burstString[gSlotLen+10];
    burstString[0] = burstTime.TN();
    for (int i = 0; i < 4; i++)
      burstString[1+i] = (burstTime.FN() >> ((3-i)*8)) & 0x0ff;
    burstString[5] = RSSI;
    burstString[6] = (TOA >> 8) & 0x0ff;
    burstString[7] = TOA & 0x0ff;
    SoftVector::iterator burstItr = rxBurst->begin();
    for (unsigned int i = 0; i < gSlotLen; i++) {
      burstString[8+i] =(char) round((*burstItr++)*255.0);
    }
    burstString[gSlotLen+9] = '\0';
    delete rxBurst;
    mDataSocket.write(burstString,gSlotLen+10);
  }
 }
 void Transceiver::driveTransmitFIFO() 
 {
  /**
      Features a carefully controlled latency mechanism, to 
      assure that transmit packets arrive at the radio/USRP
      before they need to be transmitted.
      Deadline clock indicates the burst that needs to be
      pushed into the FIFO right NOW.  If transmit queue does
      not have a burst, stick in filler data.
  */
  RadioClock *radioClock = (mRadioInterface->getClock());
  if (mOn) {
    //radioClock->wait(); // wait until clock updates
    LOG(DEBUG) << "radio clock " << radioClock->get();
    while (radioClock->get() + mTransmitLatency > mTransmitDeadlineClock) {
      // if underrun, then we're not providing bursts to radio/USRP fast
      //   enough.  Need to increase latency by one GSM frame.
      if (mRadioInterface->getBus() == RadioDevice::USB) {
        if (mRadioInterface->isUnderrun()) {
          // only update latency at the defined frame interval
          if (radioClock->get() > mLatencyUpdateTime + GSM::Time(USB_LATENCY_INTRVL)) {
            mTransmitLatency = mTransmitLatency + GSM::Time(1,0);
            LOG(INFO) << "new latency: " << mTransmitLatency;
            mLatencyUpdateTime = radioClock->get();
          }
        }
        else {
          // if underrun hasn't occurred in the last sec (216 frames) drop
          //    transmit latency by a timeslot
          if (mTransmitLatency > GSM::Time(USB_LATENCY_MIN)) {
              if (radioClock->get() > mLatencyUpdateTime + GSM::Time(216,0)) {
              mTransmitLatency.decTN();
              LOG(INFO) << "reduced latency: " << mTransmitLatency;
              mLatencyUpdateTime = radioClock->get();
            }
          }
        }
      }
      // time to push burst to transmit FIFO
      pushRadioVector(mTransmitDeadlineClock);
      mTransmitDeadlineClock.incTN();
    }
  }
  // FIXME -- This should not be a hard spin.
  // But any delay here causes us to throw omni_thread_fatal.
  //else radioClock->wait();
 }
 void Transceiver::writeClockInterface()
 {
  char command[50];
  // FIXME -- This should be adaptive.
  sprintf(command,"IND CLOCK %llu",(unsigned long long) (mTransmitDeadlineClock.FN()+2));
  LOG(INFO) << "ClockInterface: sending " << command;
  mClockSocket.write(command,strlen(command)+1);
  mLastClockUpdateTime = mTransmitDeadlineClock;
 }   
 void *FIFOServiceLoopAdapter(Transceiver *transceiver)
 {
-  transceiver->setPriority();
+  while (transceiver->on()) {
-
+    transceiver->pullFIFO();
  while (1) {
    transceiver->driveReceiveFIFO();
    transceiver->driveTransmitFIFO();
    pthread_testcancel();
  }
  return NULL;
@@ -804,7 +582,7 @@ void *FIFOServiceLoopAdapter(Transceiver *transceiver)
 void *ControlServiceLoopAdapter(Transceiver *transceiver)
 {
-  while (1) {
+  while (transceiver->running()) {
    transceiver->driveControl();
    pthread_testcancel();
  }
@@ -813,15 +591,16 @@ void *ControlServiceLoopAdapter(Transceiver *transceiver)
 void *TransmitPriorityQueueServiceLoopAdapter(Transceiver *transceiver)
 {
-  while (1) {
+  while (transceiver->on()) {
    bool stale = false;
    // Flush the UDP packets until a successful transfer.
    while (!transceiver->driveTransmitPriorityQueue()) {
      stale = true; 
    }
    if (stale) {
      // If a packet was stale, remind the GSM stack of the clock.
-      transceiver->writeClockInterface();
+      transceiver->getDriveLoop()->writeClockInterface();
    }
    pthread_testcancel();
  }
--- a/Transceiver52M/Transceiver.h
+++ b/Transceiver52M/Transceiver.h
@@ -1,5 +1,5 @@
 /*
-* Copyright 2008 Free Software Foundation, Inc.
+* Copyright 2008, 2012 Free Software Foundation, Inc.
 *
 * This software is distributed under the terms of the GNU Public License.
 * See the COPYING file in the main directory for details.
@@ -29,6 +29,7 @@
 	TRANSMIT_LOGGING	write every burst on the given slot to a log
 */
 #include "DriveLoop.h"
 #include "radioInterface.h"
 #include "Interthread.h"
 #include "GSMCommon.h"
@@ -44,59 +45,24 @@
 class Transceiver {
 private:
-
+  DriveLoop *mDriveLoop;
  GSM::Time mTransmitLatency;     ///< latency between basestation clock and transmit deadline clock
  GSM::Time mLatencyUpdateTime;   ///< last time latency was updated
  UDPSocket mDataSocket;	  ///< socket for writing to/reading from GSM core
  UDPSocket mControlSocket;	  ///< socket for writing/reading control commands from GSM core
  UDPSocket mClockSocket;	  ///< socket for writing clock updates to GSM core
-  VectorQueue  mTransmitPriorityQueue;   ///< priority queue of transmit bursts received from GSM core
+  VectorQueue  *mTransmitPriorityQueue;   ///< priority queue of transmit bursts received from GSM core
  VectorFIFO*  mTransmitFIFO;     ///< radioInterface FIFO of transmit bursts 
  VectorFIFO*  mReceiveFIFO;      ///< radioInterface FIFO of receive bursts 
  Thread *mFIFOServiceLoopThread;  ///< thread to push/pull bursts into transmit/receive FIFO
  Thread *mControlServiceLoopThread;       ///< thread to process control messages from GSM core
  Thread *mTransmitPriorityQueueServiceLoopThread;///< thread to process transmit bursts from GSM core
-  GSM::Time mTransmitDeadlineClock;       ///< deadline for pushing bursts into transmit FIFO 
+  int mChannel;                           ///< channelizer attach number between 0 and 'M-1'
  GSM::Time mLastClockUpdateTime;         ///< last time clock update was sent up to core
  RadioInterface *mRadioInterface;	  ///< associated radioInterface object
  double txFullScale;                     ///< full scale input to radio
  double rxFullScale;                     ///< full scale output to radio
  /** Codes for burst types of received bursts*/
  typedef enum {
    OFF,               ///< timeslot is off
    TSC,	       ///< timeslot should contain a normal burst
    RACH,	       ///< timeslot should contain an access burst
    IDLE	       ///< timeslot is an idle (or dummy) burst
  } CorrType;
  /** Codes for channel combinations */
  typedef enum {
    FILL,               ///< Channel is transmitted, but unused
    I,                  ///< TCH/FS
    II,                 ///< TCH/HS, idle every other slot
    III,                ///< TCH/HS
    IV,                 ///< FCCH+SCH+CCCH+BCCH, uplink RACH
    V,                  ///< FCCH+SCH+CCCH+BCCH+SDCCH/4+SACCH/4, uplink RACH+SDCCH/4
    VI,                 ///< CCCH+BCCH, uplink RACH
    VII,                ///< SDCCH/8 + SACCH/8
    VIII,               ///< TCH/F + FACCH/F + SACCH/M
    IX,                 ///< TCH/F + SACCH/M
    X,                  ///< TCH/FD + SACCH/MD
    XI,                 ///< PBCCH+PCCCH+PDTCH+PACCH+PTCCH
    XII,                ///< PCCCH+PDTCH+PACCH+PTCCH
    XIII,               ///< PDTCH+PACCH+PTCCH
    NONE,               ///< Channel is inactive, default
    LOOPBACK            ///< similar go VII, used in loopback testing
  } ChannelCombination;
  /** unmodulate a modulated burst */
 #ifdef TRANSMIT_LOGGING
  void unModulateVector(signalVector wVector); 
@@ -115,29 +81,22 @@ private:
 			   int &RSSI,
 			   int &timingOffset);
  /** Set modulus for specific timeslot */
  void setModulus(int timeslot);
  /** return the expected burst type for the specified timestamp */
  CorrType expectedCorrType(GSM::Time currTime);
  /** send messages over the clock socket */
  void writeClockInterface(void);
-  signalVector *gsmPulse;              ///< the GSM shaping pulse for modulation
+  void pullFIFO(void);                 ///< blocking call on receive FIFO 
-  int mSamplesPerSymbol;               ///< number of samples per GSM symbol
+  int mSPS;               ///< number of samples per GSM symbol
  bool mOn;			       ///< flag to indicate that transceiver is powered on
-  ChannelCombination mChanType[8];     ///< channel types for all timeslots
+  bool mRunning;                       ///< flag to indicate control loop is running
  bool mPrimary;                       ///< flag to indicate C0 channel 
  double mTxFreq;                      ///< the transmit frequency
  double mRxFreq;                      ///< the receive frequency
  double mFreqOffset;                  ///< RF frequency offset
  int mPower;                          ///< the transmit power in dB
  unsigned mTSC;                       ///< the midamble sequence code
  double mEnergyThreshold;             ///< threshold to determine if received data is potentially a GSM burst
  GSM::Time prevFalseDetectionTime;    ///< last timestamp of a false energy detection
  int fillerModulus[8];                ///< modulus values of all timeslots, in frames
  signalVector *fillerTable[102][8];   ///< table of modulated filler waveforms for all timeslots
  unsigned mMaxExpectedDelay;            ///< maximum expected time-of-arrival offset in GSM symbols
  GSM::Time    channelEstimateTime[8]; ///< last timestamp of each timeslot's channel estimate
@@ -148,20 +107,21 @@ private:
  float        chanRespOffset[8];      ///< most recent timing offset, e.g. TOA, of all timeslots
  complex      chanRespAmplitude[8];   ///< most recent channel amplitude of all timeslots
  static int mTSC;                     ///< the midamble sequence code
 public:
  /** Transceiver constructor 
      @param wBasePort base port number of UDP sockets
      @param TRXAddress IP address of the TRX manager, as a string
-      @param wSamplesPerSymbol number of samples per GSM symbol
+      @param wSPS number of samples per GSM symbol
      @param wTransmitLatency initial setting of transmit latency
      @param radioInterface associated radioInterface object
  */
-  Transceiver(int wBasePort,
+  Transceiver(int wBasePort, const char *TRXAddress,
-	      const char *TRXAddress,
+	      DriveLoop *wDriveLoop, RadioInterface *wRadioInterface,
-	      int wSamplesPerSymbol,
+	      int wSPS = SAMPSPERSYM,
-	      GSM::Time wTransmitLatency,
+	      int wChannel = 0, bool wPrimary = true);
 	      RadioInterface *wRadioInterface);
  /** Destructor */
  ~Transceiver();
@@ -169,11 +129,8 @@ public:
  /** start the Transceiver */
  void start();
-  /** attach the radioInterface receive FIFO */
+  /** shutdown (teardown threads) the Transceiver */
-  void receiveFIFO(VectorFIFO *wFIFO) { mReceiveFIFO = wFIFO;}
+  void shutdown();
  /** attach the radioInterface transmit FIFO */
  void transmitFIFO(VectorFIFO *wFIFO) { mTransmitFIFO = wFIFO;}
 protected:
@@ -200,9 +157,17 @@ protected:
  void reset();
  /** return transceiver on/off status */ 
  bool on() { return mOn; }
  /** return control loop operational status */ 
  bool running() { return mRunning; }
  /** return the drive loop pointer */
  DriveLoop *getDriveLoop() { return mDriveLoop; }
  /** set priority on current thread */
  void setPriority() { mRadioInterface->setPriority(); }
 };
 /** FIFO thread loop */
@@ -213,4 +178,3 @@ void *ControlServiceLoopAdapter(Transceiver *);
 /** transmit queueing thread loop */
 void *TransmitPriorityQueueServiceLoopAdapter(Transceiver *);
--- a/Transceiver52M/UHDDevice.cpp
+++ b/Transceiver52M/UHDDevice.cpp
@@ -32,31 +32,98 @@
 #include "config.h"
 #endif
-#define U1_DEFAULT_CLK_RT 64e6
+#define NUM_TX_CHANS      2
-#define U2_DEFAULT_CLK_RT 100e6 
+#define NUM_RX_CHANS      NUM_TX_CHANS
 #define TX_CHAN_OFFSET    2e6
 #define B100_CLK_RT       52e6 
 #define USRP2_BASE_RT     400e3
 #define TX_AMPL           0.3;
 #define SAMPLE_BUF_SZ     (1 << 20)
 enum uhd_dev_type {
 	USRP1,
 	USRP2,
 	B100,
 	UMTRX,
 	NUM_USRP_TYPES,
 };
 struct uhd_dev_offset {
 	enum uhd_dev_type type;
 	int sps;
 	double offset;
 };
 static TIMESTAMP init_rd_ts = 0;
 /*
-    master_clk_rt     - Master clock frequency - ignored if host resampling is
+ * Tx / Rx sample offset values. In a perfect world, there is no group delay
-                        enabled
+ * though analog components, and behaviour through digital filters exactly
 * matches calculated values. In reality, there are unaccounted factors,
 * which are captured in these empirically measured (using a loopback test)
 * timing correction values.
 *
 * Notes:
 *   USRP1 with timestamps is not supported by UHD.
 */
 static struct uhd_dev_offset uhd_offsets[NUM_USRP_TYPES * 3] = {
 	{ USRP1, 1, 0.0 },
 	{ USRP1, 2, 0.0 },
 	{ USRP1, 4, 0.0 },
 	{ USRP2, 1, 5.4394e-5 },
 	{ USRP2, 2, 0.0 },
 	{ USRP2, 4, 0.0 },
 	{ B100,  1, 9.4778e-5 },
 	{ B100,  2, 5.1100e-5 },
 	{ B100,  4, 2.9418e-5 },
 	{ UMTRX, 1, 9.1738e-5 },
 	{ UMTRX, 2, 0.0 },
 	{ UMTRX, 4, 4.1813e-5 },
 };
-    rx_smpl_offset    - Timing correction in seconds between receive and
+static double get_dev_offset(enum uhd_dev_type type, int sps)
-                        transmit timestamps. This value corrects for delays on
+{
-                        on the RF side of the timestamping point of the device.
+	if (type == USRP1) {
-                        This value is generally empirically measured.
+		LOG(ERR) << "Invalid device type";
 		return 0.0;
 	}
-    smpl_buf_sz       - The receive sample buffer size in bytes.
+	switch (sps) {
 	case 1:
 		return uhd_offsets[3 * type + 0].offset;
 	case 2:
 		return uhd_offsets[3 * type + 1].offset;
 	case 4:
 		return uhd_offsets[3 * type + 2].offset;
 	}
-    tx_ampl           - Transmit amplitude must be between 0 and 1.0
+	LOG(ERR) << "Unsupported samples-per-symbols: " << sps;
-*/
+	return 0.0;	
-const double master_clk_rt = 52e6;
+}
 const size_t smpl_buf_sz = (1 << 20);
 const float tx_ampl = .3;
-#ifdef RESAMPLE
+/*
-const double rx_smpl_offset = .00005;
+ * Select sample rate based on device type and requested samples-per-symbol.
-#else
+ * The base rate is either GSM symbol rate, 270.833 kHz, or the minimum
-const double rx_smpl_offset = .0000869;
+ * usable channel spacing of 400 kHz.
-#endif
+ */ 
 static double select_rate(uhd_dev_type type, int sps)
 {
 	if ((sps != 4) && (sps != 2) && (sps != 1))
 		return -9999.99;
 	switch (type) {
 	case USRP2:
 		return USRP2_BASE_RT * sps;
 		break;
 	case B100:
 	case UMTRX:
 		return GSMRATE * sps;
 		break;
 	}
 	LOG(ALERT) << "Unknown device type " << type;
 	return -9999.99;
 }
 /** Timestamp conversion
    @param timestamp a UHD or OpenBTS timestamp
@@ -148,44 +215,48 @@ private:
 */
 class uhd_device : public RadioDevice {
 public:
-	uhd_device(double rate, bool skip_rx);
+	uhd_device(int sps, bool skip_rx);
 	~uhd_device();
-	bool open(const std::string &args);
+	int open(const std::string &args);
 	bool start();
 	bool stop();
 	void restart(uhd::time_spec_t ts);
 	void setPriority();
-	enum busType getBus() { return bus; }
+	enum TxWindowType getWindowType() { return tx_window; }
-	int readSamples(short *buf, int len, bool *overrun, 
+	int readSamples(short **buf, int chans, int len, TIMESTAMP timestamp,
-			TIMESTAMP timestamp, bool *underrun, unsigned *RSSI);
+			bool *overrun, bool *underrun, unsigned *RSSI);
-	int writeSamples(short *buf, int len, bool *underrun, 
+	int writeSamples(short **buf, int chans, int len, TIMESTAMP timestamp,
-			 TIMESTAMP timestamp, bool isControl);
+			 bool *underrun, bool isControl);
 	bool updateAlignment(TIMESTAMP timestamp);
-	bool setTxFreq(double wFreq);
+	bool setTxFreq(double wFreq, int chan);
-	bool setRxFreq(double wFreq);
+	bool setRxFreq(double wFreq, int chan);
-	inline TIMESTAMP initialWriteTimestamp() { return 0; }
+	inline TIMESTAMP initialWriteTimestamp() { return init_rd_ts; }
-	inline TIMESTAMP initialReadTimestamp() { return 0; }
+	inline TIMESTAMP initialReadTimestamp() { return init_rd_ts; }
-	inline double fullScaleInputValue() { return 32000 * tx_ampl; }
+	inline double fullScaleInputValue() { return 32000 * TX_AMPL; }
 	inline double fullScaleOutputValue() { return 32000; }
-	double setRxGain(double db);
+	double setRxGain(double db, int chan);
-	double getRxGain(void) { return rx_gain; }
+	double getRxGain(int chan) { return !chan ? rx_gain[0] : tx_gain[1]; }
 	double maxRxGain(void) { return rx_gain_max; }
 	double minRxGain(void) { return rx_gain_min; }
-	double setTxGain(double db);
+	double setTxGain(double db, int chan);
 	double maxTxGain(void) { return tx_gain_max; }
 	double minTxGain(void) { return tx_gain_min; }
 	void setTxAntenna(std::string &name);
 	void setRxAntenna(std::string &name);
 	std::string getRxAntenna();
 	std::string getTxAntenna();
-	double getTxFreq() { return tx_freq; }
+	double getTxFreq(int chan) { return !chan ? tx_freq[0] : tx_freq[1]; }
-	double getRxFreq() { return rx_freq; }
+	double getRxFreq(int chan) { return !chan ? rx_freq[0] : rx_freq[1]; }
 	inline double getSampleRate() { return actual_smpl_rt; }
 	inline double numberRead() { return rx_pkt_cnt; }
@@ -195,6 +266,7 @@ public:
 	    @return true if message received or false on timeout or error
 	*/
 	bool recv_async_msg();
 	bool running() { return started; }
 	enum err_code {
 		ERROR_TIMING = -1,
@@ -204,14 +276,18 @@ public:
 private:
 	uhd::usrp::multi_usrp::sptr usrp_dev;
-	enum busType bus;
+	uhd::tx_streamer::sptr tx_stream;
 	uhd::rx_streamer::sptr rx_stream;
 	enum TxWindowType tx_window;
 	enum uhd_dev_type dev_type;
 	int sps;
 	double desired_smpl_rt, actual_smpl_rt;
-	double tx_gain, tx_gain_min, tx_gain_max;
+	double tx_gain[NUM_TX_CHANS], tx_gain_min, tx_gain_max;
-	double rx_gain, rx_gain_min, rx_gain_max;
+	double rx_gain[NUM_RX_CHANS], rx_gain_min, rx_gain_max;
-	double tx_freq, rx_freq;
+	double tx_freq[NUM_TX_CHANS], rx_freq[NUM_RX_CHANS];
 	size_t tx_spp, rx_spp;
 	bool started;
@@ -223,11 +299,12 @@ private:
 	uhd::time_spec_t prev_ts;
 	TIMESTAMP ts_offset;
-	smpl_buf *rx_smpl_buf;
+	smpl_buf *rx_smpl_buf[NUM_RX_CHANS];
 	void init_gains();
 	void set_ref_clk(bool ext_clk);
-	double set_rates(double rate);
+	int set_master_clk(double rate);
 	int set_rates(double rate);
 	bool parse_dev_type();
 	bool flush_recv(size_t num_pkts);
 	int check_rx_md_err(uhd::rx_metadata_t &md, ssize_t num_smpls);
@@ -235,12 +312,12 @@ private:
 	std::string str_code(uhd::rx_metadata_t metadata);
 	std::string str_code(uhd::async_metadata_t metadata);
-	Thread async_event_thrd;
+	Thread *async_event_thrd;
 };
 void *async_event_loop(uhd_device *dev)
 {
-	while (1) {
+	while (dev->running()) {
 		dev->recv_async_msg();
 		pthread_testcancel();
 	}
@@ -268,23 +345,36 @@ void uhd_msg_handler(uhd::msg::type_t type, const std::string &msg)
 	}
 }
-uhd_device::uhd_device(double rate, bool skip_rx)
+uhd_device::uhd_device(int sps, bool skip_rx)
-	: desired_smpl_rt(rate), actual_smpl_rt(0),
+	: tx_gain_min(0.0), tx_gain_max(0.0),
-	  tx_gain(0.0), tx_gain_min(0.0), tx_gain_max(0.0),
+	  rx_gain_min(0.0), rx_gain_max(0.0),
-	  rx_gain(0.0), rx_gain_min(0.0), rx_gain_max(0.0),
+	  tx_spp(0), rx_spp(0), started(false), aligned(false),
-	  tx_freq(0.0), rx_freq(0.0), tx_spp(0), rx_spp(0),
+	  rx_pkt_cnt(0), drop_cnt(0), prev_ts(0,0), ts_offset(0),
-	  started(false), aligned(false), rx_pkt_cnt(0), drop_cnt(0),
+	  async_event_thrd(NULL)
 	  prev_ts(0,0), ts_offset(0), rx_smpl_buf(NULL)
 {
 	this->sps = sps;
 	this->skip_rx = skip_rx;
 	for (int i = 0; i < NUM_TX_CHANS; i++) {
 		tx_freq[i] = 0.0f;
 		tx_gain[i] = 0.0f;
 	}
 	for (int i = 0; i < NUM_RX_CHANS; i++) {
 		rx_smpl_buf[i] = NULL;
 		rx_freq[i] = 0.0f;
 		rx_gain[i] = 0.0f;
 	}
 }
 uhd_device::~uhd_device()
 {
 	stop();
-	if (rx_smpl_buf)
+	for (int i = 0; i < NUM_RX_CHANS; i++) {
-		delete rx_smpl_buf;
+		if (rx_smpl_buf[i])
 			delete rx_smpl_buf[i];
 	}
 }
 void uhd_device::init_gains()
@@ -299,95 +389,135 @@ void uhd_device::init_gains()
 	rx_gain_min = range.start();
 	rx_gain_max = range.stop();
-	usrp_dev->set_tx_gain((tx_gain_min + tx_gain_max) / 2);
+	for (int i = 0; i < NUM_TX_CHANS; i++) {
-	usrp_dev->set_rx_gain((rx_gain_min + rx_gain_max) / 2);
+		usrp_dev->set_tx_gain((tx_gain_min + tx_gain_max) / 2, i);
 		tx_gain[i] = usrp_dev->get_tx_gain(i);
 	}
-	tx_gain = usrp_dev->get_tx_gain();
+	for (int i = 0; i < NUM_RX_CHANS; i++) {
-	rx_gain = usrp_dev->get_rx_gain();
+		usrp_dev->set_rx_gain((rx_gain_min + rx_gain_max) / 2, i);
 		rx_gain[i] = usrp_dev->get_rx_gain(i);
 	}
 	return;
 }
 void uhd_device::set_ref_clk(bool ext_clk)
 {
 	uhd::clock_config_t clk_cfg;
 	clk_cfg.pps_source = uhd::clock_config_t::PPS_SMA;
 	if (ext_clk)
-		clk_cfg.ref_source = uhd::clock_config_t::REF_SMA;
+		usrp_dev->set_clock_source("external");
 	else
 		clk_cfg.ref_source = uhd::clock_config_t::REF_INT;
 	usrp_dev->set_clock_config(clk_cfg);
 	return;
 }
-double uhd_device::set_rates(double rate)
+int uhd_device::set_master_clk(double clk_rate)
 {
-	double actual_rt, actual_clk_rt;
+	double actual_clk_rt;
-#ifndef RESAMPLE
+	try {
-	// Make sure we can set the master clock rate on this device
+		usrp_dev->set_master_clock_rate(clk_rate);
 		actual_clk_rt = usrp_dev->get_master_clock_rate();
-	if (actual_clk_rt > U1_DEFAULT_CLK_RT) {
+	} catch (const std::exception &ex) {
-		LOG(ALERT) << "Cannot set clock rate on this device";
+		LOG(ALERT) << "UHD clock rate setting failed: " << clk_rate;
-		LOG(ALERT) << "Please compile with host resampling support";
+		LOG(ALERT) << ex.what();
-		return -1.0;
+		return -1;
 	}
-	// Set master clock rate
+	if (actual_clk_rt != clk_rate) {
 	usrp_dev->set_master_clock_rate(master_clk_rt);
 	actual_clk_rt = usrp_dev->get_master_clock_rate();
 	if (actual_clk_rt != master_clk_rt) {
 		LOG(ALERT) << "Failed to set master clock rate";
 		LOG(ALERT) << "Requested clock rate " << clk_rate;
 		LOG(ALERT) << "Actual clock rate " << actual_clk_rt;
-		return -1.0;
+		return -1;
 	}
 	return 0;
 }
 int uhd_device::set_rates(double rate)
 {
 	double offset_limit = 10.0;
 	double tx_offset, rx_offset;
 	// B100 is the only device where we set FPGA clocking
 	if (dev_type == B100) {
 		if (set_master_clk(B100_CLK_RT) < 0)
 			return -1;
 	}
 #endif
 	// Set sample rates
 	try {
 		usrp_dev->set_tx_rate(rate);
 		usrp_dev->set_rx_rate(rate);
-	actual_rt = usrp_dev->get_tx_rate();
+	} catch (const std::exception &ex) {
 		LOG(ALERT) << "UHD rate setting failed: " << rate;
 		LOG(ALERT) << ex.what();
 		return -1;
 	}
 	actual_smpl_rt = usrp_dev->get_tx_rate();
-	if (actual_rt != rate) {
+	tx_offset = actual_smpl_rt - rate;
 	rx_offset = usrp_dev->get_rx_rate() - rate;
 	if ((tx_offset > offset_limit) || (rx_offset > offset_limit)) {
 		LOG(ALERT) << "Actual sample rate differs from desired rate";
-		return -1.0;
+		LOG(ALERT) << "Tx/Rx (" << actual_smpl_rt << "/"
-	}
+			   << usrp_dev->get_rx_rate() << ")";
-	if (usrp_dev->get_rx_rate() != actual_rt) {
+		return -1;
 		LOG(ALERT) << "Transmit and receive sample rates do not match";
 		return -1.0;
 	}
-	return actual_rt;
+	return 0;
 }
-double uhd_device::setTxGain(double db)
+double uhd_device::setTxGain(double db, int chan)
 {
-	usrp_dev->set_tx_gain(db);
+	if (chan >= NUM_TX_CHANS) {
-	tx_gain = usrp_dev->get_tx_gain();
+		LOG(ALERT) << "Attempting to set gain on non-existent channel";
 		return 0.0f;
 	}
-	LOG(INFO) << "Set TX gain to " << tx_gain << "dB";
+	usrp_dev->set_tx_gain(db, chan);
 	tx_gain[chan] = usrp_dev->get_tx_gain(chan);
 	LOG(INFO) << "Set TX gain to " << tx_gain[chan] << "dB";
-	return tx_gain;
+	return tx_gain[chan];
 }
-double uhd_device::setRxGain(double db)
+double uhd_device::setRxGain(double db, int chan)
 {
-	usrp_dev->set_rx_gain(db);
+	if (chan >= NUM_RX_CHANS) {
-	rx_gain = usrp_dev->get_rx_gain();
+		LOG(ALERT) << "Attempting to read gain non-existent channel";
 		return 0.0f;
 	}
-	LOG(INFO) << "Set RX gain to " << rx_gain << "dB";
+	usrp_dev->set_rx_gain(db, chan);
 	rx_gain[chan] = usrp_dev->get_rx_gain(chan);
 	LOG(INFO) << "Set RX gain to " << rx_gain[chan] << "dB";
-	return rx_gain;
+	return rx_gain[chan];
 }
 void uhd_device::setTxAntenna(std::string &name)
 {
 	usrp_dev->set_tx_antenna(name);
 }
 void uhd_device::setRxAntenna(std::string &name)
 {
 	usrp_dev->set_rx_antenna(name);
 }
 std::string uhd_device::getTxAntenna()
 {
 	return usrp_dev->get_tx_antenna();
 }
 std::string uhd_device::getRxAntenna()
 {
 	return usrp_dev->get_rx_antenna();
 }
 /*
    Parse the UHD device tree and mboard name to find out what device we're
-    dealing with. We need the bus type so that the transceiver knows how to
+    dealing with. We need the window type so that the transceiver knows how to
    deal with the transport latency. Reject the USRP1 because UHD doesn't
    support timestamped samples with it.
 */
@@ -395,34 +525,46 @@ bool uhd_device::parse_dev_type()
 {
 	std::string mboard_str, dev_str;
 	uhd::property_tree::sptr prop_tree;
-	size_t usrp1_str, usrp2_str, b100_str1, b100_str2;
+	size_t usrp1_str, usrp2_str, b100_str, umtrx_str;
 	prop_tree = usrp_dev->get_device()->get_tree();
 	dev_str = prop_tree->access<std::string>("/name").get();
 	mboard_str = usrp_dev->get_mboard_name();
 	usrp1_str = dev_str.find("USRP1");
-	b100_str1 = dev_str.find("B-Series");
+	usrp2_str = dev_str.find("USRP2");
-	b100_str2 = mboard_str.find("B100");
+	umtrx_str = dev_str.find("UmTRX");
 	b100_str = mboard_str.find("B100");
 	if (usrp1_str != std::string::npos) {
 		LOG(ALERT) << "USRP1 is not supported using the UHD driver";
 		LOG(ALERT) << "Please compile with GNU Radio libusrp support";
 		dev_type = USRP1;
 		return false;
 	}
-	if ((b100_str1 != std::string::npos) || (b100_str2 != std::string::npos)) {
+	if (b100_str != std::string::npos) {
-		bus = USB;
+		tx_window = TX_WINDOW_USRP1;
-		LOG(INFO) << "Using USB bus for " << dev_str;
+		LOG(INFO) << "Using USRP1 type transmit window for "
 			  << dev_str << " " << mboard_str;
 		dev_type = B100;
 		return true;
 	} else if (usrp2_str != std::string::npos) {
 		dev_type = USRP2;
 	} else if (umtrx_str != std::string::npos) {
 		dev_type = UMTRX;
 	} else {
-		bus = NET;
+		LOG(ALERT) << "Unknown UHD device type";
-		LOG(INFO) << "Using network bus for " << dev_str;
+		return false;
 	}
 	tx_window = TX_WINDOW_FIXED;
 	LOG(INFO) << "Using fixed transmit window for "
 		  << dev_str << " " << mboard_str;
 	return true;
 }
-bool uhd_device::open(const std::string &args)
+int uhd_device::open(const std::string &args)
 {
 	// Register msg handler
 	uhd::msg::register_handler(&uhd_msg_handler);
@@ -432,7 +574,7 @@ bool uhd_device::open(const std::string &args)
 	uhd::device_addrs_t dev_addrs = uhd::device::find(addr);
 	if (dev_addrs.size() == 0) {
 		LOG(ALERT) << "No UHD devices found with address '" << args << "'";
-		return false;
+		return -1;
 	}
 	// Use the first found device
@@ -441,32 +583,51 @@ bool uhd_device::open(const std::string &args)
 		usrp_dev = uhd::usrp::multi_usrp::make(dev_addrs[0]);
 	} catch(...) {
 		LOG(ALERT) << "UHD make failed, device " << dev_addrs[0].to_string();
-		return false;
+		return -1;
 	}
 	// Check for a valid device type and set bus type
 	if (!parse_dev_type())
-		return false;
+		return -1;
 #ifdef EXTREF
 	set_ref_clk(true);
 #endif
-
+	if (NUM_TX_CHANS == 2) {
-	// Number of samples per over-the-wire packet
+		uhd::usrp::subdev_spec_t subdev_spec("A:0 B:0");
-	tx_spp = usrp_dev->get_device()->get_max_send_samps_per_packet();
+		usrp_dev->set_tx_subdev_spec(subdev_spec);
-	rx_spp = usrp_dev->get_device()->get_max_recv_samps_per_packet();
+		usrp_dev->set_rx_subdev_spec(subdev_spec);
 	}
 	// Set rates
-	actual_smpl_rt = set_rates(desired_smpl_rt);
+	desired_smpl_rt = select_rate(dev_type, sps);
-	if (actual_smpl_rt < 0)
+	if (set_rates(desired_smpl_rt) < 0)
-		return false;
+		return -1;
 	// Create TX and RX streamers
 	uhd::stream_args_t stream_args("sc16");
 	for (int i = 0; i < NUM_TX_CHANS; i++)
 		stream_args.channels.push_back(i);
 	tx_stream = usrp_dev->get_tx_stream(stream_args);
 	rx_stream = usrp_dev->get_rx_stream(stream_args);
 	// Number of samples per over-the-wire packet
 	tx_spp = tx_stream->get_max_num_samps();
 	rx_spp = rx_stream->get_max_num_samps();
 	// Create receive buffer
-	size_t buf_len = smpl_buf_sz / sizeof(uint32_t);
+	size_t buf_len = SAMPLE_BUF_SZ / sizeof(uint32_t);
-	rx_smpl_buf = new smpl_buf(buf_len, actual_smpl_rt);
+	for (int i = 0; i < NUM_RX_CHANS; i++)
 		rx_smpl_buf[i] = new smpl_buf(buf_len, actual_smpl_rt);
 	// Set receive chain sample offset 
-	ts_offset = (TIMESTAMP)(rx_smpl_offset * actual_smpl_rt);
+	double offset = get_dev_offset(dev_type, sps);
 	if (offset == 0.0) {
 		LOG(ERR) << "Unsupported configuration, no correction applied";
 		ts_offset = 0;
 	} else  {
 		ts_offset = (TIMESTAMP) (offset * actual_smpl_rt);
 	}
 	// Initialize and shadow gain values 
 	init_gains();
@@ -474,28 +635,30 @@ bool uhd_device::open(const std::string &args)
 	// Print configuration
 	LOG(INFO) << "\n" << usrp_dev->get_pp_string();
-	return true;
+	if (dev_type == USRP2)
 		return RESAMP;
 	return NORMAL;
 }
 bool uhd_device::flush_recv(size_t num_pkts)
 {
 	uhd::rx_metadata_t md;
 	size_t num_smpls;
 	uint32_t buff[rx_spp];
 	float timeout;
 	// Use .01 sec instead of the default .1 sec
 	timeout = .01;
-	for (size_t i = 0; i < num_pkts; i++) {
+	std::vector<std::vector<std::complex<short> > > bufs(
-		num_smpls = usrp_dev->get_device()->recv(
+		NUM_RX_CHANS, std::vector<std::complex<short> >(rx_spp));
-					buff,
+	std::vector<std::complex<short> *> buf_ptrs;
-					rx_spp,
+	for (int i = 0; i < bufs.size(); i++)
-					md,
+		buf_ptrs.push_back(&bufs[i].front());
 					uhd::io_type_t::COMPLEX_INT16,
 					uhd::device::RECV_MODE_ONE_PACKET,
 					timeout);
 	for (size_t i = 0; i < num_pkts; i++) {
 		num_smpls = rx_stream->recv(buf_ptrs, rx_spp, md,
 					    timeout, true);
 		if (!num_smpls) {
 			switch (md.error_code) {
 			case uhd::rx_metadata_t::ERROR_CODE_TIMEOUT:
@@ -511,17 +674,15 @@ bool uhd_device::flush_recv(size_t num_pkts)
 void uhd_device::restart(uhd::time_spec_t ts)
 {
 	uhd::stream_cmd_t cmd = uhd::stream_cmd_t::STREAM_MODE_STOP_CONTINUOUS;
 	usrp_dev->issue_stream_cmd(cmd);
 	flush_recv(50);
 	usrp_dev->set_time_now(ts);
 	aligned = false;
-	cmd = uhd::stream_cmd_t::STREAM_MODE_START_CONTINUOUS;
+	uhd::stream_cmd_t cmd = uhd::stream_cmd_t::STREAM_MODE_START_CONTINUOUS;
-	cmd.stream_now = true;
+	cmd.time_spec = uhd::time_spec_t(0.1);
 	cmd.stream_now = false;
 	usrp_dev->issue_stream_cmd(cmd);
 	uhd::rx_metadata_t md;
 }
 bool uhd_device::start()
@@ -533,10 +694,12 @@ bool uhd_device::start()
 		return false;
 	}
 	started = true;
 	setPriority();
 	// Start asynchronous event (underrun check) loop
-	async_event_thrd.start((void * (*)(void*))async_event_loop, (void*)this);
+	async_event_thrd = new Thread(32768);
 	async_event_thrd->start((void * (*)(void*))async_event_loop, (void*)this);
 	// Start streaming
 	restart(uhd::time_spec_t(0.0));
@@ -545,18 +708,23 @@ bool uhd_device::start()
 	double time_now = usrp_dev->get_time_now().get_real_secs();
 	LOG(INFO) << "The current time is " << time_now << " seconds";
 	started = true;
 	return true;
 }
 bool uhd_device::stop()
 {
 	if (!started)
 		return false;
 	started = false;
 	uhd::stream_cmd_t stream_cmd = 
 		uhd::stream_cmd_t::STREAM_MODE_STOP_CONTINUOUS;
 	usrp_dev->issue_stream_cmd(stream_cmd);
-	started = false;
+	delete async_event_thrd;
 	return true;
 }
@@ -607,40 +775,48 @@ int uhd_device::check_rx_md_err(uhd::rx_metadata_t &md, ssize_t num_smpls)
 	return 0;
 }
-int uhd_device::readSamples(short *buf, int len, bool *overrun,
+int uhd_device::readSamples(short **buf, int chans, int len,
-			TIMESTAMP timestamp, bool *underrun, unsigned *RSSI)
+			    TIMESTAMP timestamp, bool *overrun,
 			    bool *underrun, unsigned *RSSI)
 {
 	ssize_t rc;
 	uhd::time_spec_t ts;
 	uhd::rx_metadata_t metadata;
 	uint32_t pkt_buf[rx_spp];
-	if (skip_rx)
+	if (skip_rx) {
 		LOG(INFO) << "Skipping Rx";
 		return 0;
 	}
 	if (chans != NUM_RX_CHANS) {
 		LOG(ERR) << "Number of requested channels does not match build";
 		return -1;
 	}
 	// Shift read time with respect to transmit clock
 	timestamp += ts_offset;
 	ts = convert_time(timestamp, actual_smpl_rt);
-	LOG(DEBUG) << "Requested timestamp = " << ts.get_real_secs();
+	LOG(DEBUG) << "Requested UHD timestamp = " << ts.get_real_secs();
 	// Check that timestamp is valid
-	rc = rx_smpl_buf->avail_smpls(timestamp);
+	rc = rx_smpl_buf[0]->avail_smpls(timestamp);
 	if (rc < 0) {
-		LOG(ERR) << rx_smpl_buf->str_code(rc);
+		LOG(ERR) << rx_smpl_buf[0]->str_code(rc);
-		LOG(ERR) << rx_smpl_buf->str_status();
+		LOG(ERR) << rx_smpl_buf[0]->str_status();
 		return 0;
 	}
-	// Receive samples from the usrp until we have enough
+	std::vector<std::vector<std::complex<short> > > bufs(
-	while (rx_smpl_buf->avail_smpls(timestamp) < len) {
+		NUM_RX_CHANS, std::vector<std::complex<short> >(rx_spp));
-		size_t num_smpls = usrp_dev->get_device()->recv(
+	std::vector<std::complex<short> *> buf_ptrs;
-					(void*)pkt_buf,
+	for (int i = 0; i < bufs.size(); i++)
-					rx_spp,
+		buf_ptrs.push_back(&bufs[i].front());
 					metadata,
 					uhd::io_type_t::COMPLEX_INT16,
 					uhd::device::RECV_MODE_ONE_PACKET);
 	// Receive samples from the usrp until we have enough
 	while (rx_smpl_buf[0]->avail_smpls(timestamp) < len) {
 		size_t num_smpls = rx_stream->recv(buf_ptrs, rx_spp,
 						   metadata, 0.1, true);
 		rx_pkt_cnt++;
 		// Check for errors 
@@ -653,39 +829,45 @@ int uhd_device::readSamples(short *buf, int len, bool *overrun,
 		case ERROR_TIMING:
 			restart(prev_ts);
 		case ERROR_UNHANDLED:
 			LOG(ALERT) << "UHD: Unhandled error";
 			continue;
 		}
 		ts = metadata.time_spec;
-		LOG(DEBUG) << "Received timestamp = " << ts.get_real_secs();
+		LOG(DEBUG) << "Received " << num_smpls << " samples "
 			   << "with timestamp = " << ts.get_real_secs();
-		rc = rx_smpl_buf->write(pkt_buf,
+		for (int i = 0; i < NUM_RX_CHANS; i++) {
 			rc = rx_smpl_buf[i]->write((short *) &bufs[i].front(),
 						   num_smpls,
 						   metadata.time_spec);
 			// Continue on local overrun, exit on other errors
 			if ((rc < 0)) {
-			LOG(ERR) << rx_smpl_buf->str_code(rc);
+				LOG(ERR) << rx_smpl_buf[i]->str_code(rc);
-			LOG(ERR) << rx_smpl_buf->str_status();
+				LOG(ERR) << rx_smpl_buf[i]->str_status();
 				if (rc != smpl_buf::ERROR_OVERFLOW)
 					return 0;
 			}
 		}
 	}
 	// We have enough samples
-	rc = rx_smpl_buf->read(buf, len, timestamp);
+	for (int i = 0; i < NUM_RX_CHANS; i++) {
 		rc = rx_smpl_buf[i]->read(buf[i], len, timestamp);
 		if ((rc < 0) || (rc != len)) {
-		LOG(ERR) << rx_smpl_buf->str_code(rc);
+			LOG(ERR) << rx_smpl_buf[i]->str_code(rc);
-		LOG(ERR) << rx_smpl_buf->str_status();
+			LOG(ERR) << rx_smpl_buf[i]->str_status();
 			return 0;
 		}
 	}
 	return len;
 }
-int uhd_device::writeSamples(short *buf, int len, bool *underrun,
+int uhd_device::writeSamples(short **buf, int chans, int len,
-			unsigned long long timestamp,bool isControl)
+			     TIMESTAMP timestamp, bool *underrun,
 			     bool isControl)
 {
 	uhd::tx_metadata_t metadata;
 	metadata.has_time_spec = true;
@@ -718,12 +900,11 @@ int uhd_device::writeSamples(short *buf, int len, bool *underrun,
 		}
 	}
-	size_t num_smpls = usrp_dev->get_device()->send(buf,
+	std::vector<short *> bufs(NUM_TX_CHANS);
-					len,
+	for (int i = 0; i < NUM_TX_CHANS; i++)
-					metadata,
+		bufs[i] = buf[i];
 					uhd::io_type_t::COMPLEX_INT16,
 					uhd::device::SEND_MODE_FULL_BUFF);
 	size_t num_smpls = tx_stream->send(bufs, len, metadata);
 	if (num_smpls != (unsigned) len) {
 		LOG(ALERT) << "UHD: Device send timed out";
 		LOG(ALERT) << "UHD: Version " << uhd::get_version_string();
@@ -736,24 +917,33 @@ int uhd_device::writeSamples(short *buf, int len, bool *underrun,
 bool uhd_device::updateAlignment(TIMESTAMP timestamp)
 {
 	aligned = false;
 	return true;
 }
-bool uhd_device::setTxFreq(double wFreq)
+bool uhd_device::setTxFreq(double wFreq, int chan)
 {
-	uhd::tune_result_t tr = usrp_dev->set_tx_freq(wFreq);
+	if (chan >= NUM_TX_CHANS) {
 		LOG(ALERT) << "Attempting to tune non-existent channel";
 		return false;
 	}
 	uhd::tune_result_t tr = usrp_dev->set_tx_freq(wFreq, chan);
 	LOG(INFO) << "\n" << tr.to_pp_string();
-	tx_freq = usrp_dev->get_tx_freq();
+	tx_freq[chan] = usrp_dev->get_tx_freq(chan);
 	return true;
 }
-bool uhd_device::setRxFreq(double wFreq)
+bool uhd_device::setRxFreq(double wFreq, int chan)
 {
-	uhd::tune_result_t tr = usrp_dev->set_rx_freq(wFreq);
+	if (chan >= NUM_RX_CHANS) {
 		LOG(ALERT) << "Attempting to tune non-existent channel";
 		return false;
 	}
 	uhd::tune_result_t tr = usrp_dev->set_rx_freq(wFreq, chan);
 	LOG(INFO) << "\n" << tr.to_pp_string();
-	rx_freq = usrp_dev->get_rx_freq();
+	rx_freq[chan] = usrp_dev->get_rx_freq(chan);
 	return true;
 }
@@ -888,7 +1078,7 @@ ssize_t smpl_buf::read(void *buf, size_t len, TIMESTAMP timestamp)
 		num_smpls = len;
 	// Starting index
-	size_t read_start = data_start + (timestamp - time_start);
+	size_t read_start = (data_start + (timestamp - time_start)) % buf_len;
 	// Read it
 	if (read_start + num_smpls < buf_len) {
@@ -986,7 +1176,7 @@ std::string smpl_buf::str_code(ssize_t code)
 	}
 }
-RadioDevice *RadioDevice::make(double smpl_rt, bool skip_rx)
+RadioDevice *RadioDevice::make(int sps, bool skip_rx)
 {
-	return new uhd_device(smpl_rt, skip_rx);
+	return new uhd_device(sps, skip_rx);
 }
--- a/Transceiver52M/USRPDevice.cpp
+++ b/Transceiver52M/USRPDevice.cpp
@@ -59,11 +59,11 @@ const dboardConfigType dboardConfig = TXA_RXB;
 const double USRPDevice::masterClockRate = 52.0e6;
-USRPDevice::USRPDevice (double _desiredSampleRate, bool skipRx)
+USRPDevice::USRPDevice(int sps, bool skipRx)
  : skipRx(skipRx)
 {
  LOG(INFO) << "creating USRP device...";
-  decimRate = (unsigned int) round(masterClockRate/_desiredSampleRate);
+  decimRate = (unsigned int) round(masterClockRate/((GSMRATE) * (double) sps));
  actualSampleRate = masterClockRate/decimRate;
  rxGain = 0;
@@ -75,7 +75,7 @@ USRPDevice::USRPDevice (double _desiredSampleRate, bool skipRx)
 #endif
 }
-bool USRPDevice::open(const std::string &)
+int USRPDevice::open(const std::string &)
 {
  writeLock.unlock();
@@ -97,7 +97,7 @@ bool USRPDevice::open(const std::string &)
  catch(...) {
    LOG(ALERT) << "make failed on Rx";
    m_uRx.reset();
-    return false;
+    return -1;
  }
  if (m_uRx->fpga_master_clock_freq() != masterClockRate)
@@ -105,7 +105,7 @@ bool USRPDevice::open(const std::string &)
    LOG(ALERT) << "WRONG FPGA clock freq = " << m_uRx->fpga_master_clock_freq()
               << ", desired clock freq = " << masterClockRate;
    m_uRx.reset();
-    return false;
+    return -1;
  }
  }
@@ -120,7 +120,7 @@ bool USRPDevice::open(const std::string &)
  catch(...) {
    LOG(ALERT) << "make failed on Tx";
    m_uTx.reset();
-    return false;
+    return -1;
  }
  if (m_uTx->fpga_master_clock_freq() != masterClockRate)
@@ -128,7 +128,7 @@ bool USRPDevice::open(const std::string &)
    LOG(ALERT) << "WRONG FPGA clock freq = " << m_uTx->fpga_master_clock_freq()
               << ", desired clock freq = " << masterClockRate;
    m_uTx.reset();
-    return false;
+    return -1;
  }
  if (!skipRx) m_uRx->stop();
@@ -165,7 +165,7 @@ bool USRPDevice::open(const std::string &)
  samplesWritten = 0;
  started = false;
-  return true;
+  return NORMAL;
 }
@@ -556,7 +556,7 @@ bool USRPDevice::setTxFreq(double wFreq) { return true;};
 bool USRPDevice::setRxFreq(double wFreq) { return true;};
 #endif
-RadioDevice *RadioDevice::make(double desiredSampleRate, bool skipRx)
+RadioDevice *RadioDevice::make(int sps, bool skipRx)
 {
-	return new USRPDevice(desiredSampleRate, skipRx);
+	return new USRPDevice(sps, skipRx);
 }
--- a/Transceiver52M/USRPDevice.h
+++ b/Transceiver52M/USRPDevice.h
@@ -112,10 +112,10 @@ private:
 public:
  /** Object constructor */
-  USRPDevice (double _desiredSampleRate, bool skipRx);
+  USRPDevice(int sps, bool skipRx);
  /** Instantiate the USRP */
-  bool open(const std::string &);
+  int open(const std::string &);
  /** Start the USRP */
  bool start();
@@ -126,8 +126,7 @@ private:
  /** Set priority not supported */
  void setPriority() { return; }
-  /** Only USB bus supported */
+  enum TxWindowType getWindowType() { return TX_WINDOW_USRP1; }
  busType getBus() { return USB; }
  /**
 	Read samples from the USRP.
--- a/Transceiver52M/USRPping.cpp
+++ b/Transceiver52M/USRPping.cpp
@@ -41,7 +41,7 @@ int main(int argc, char *argv[]) {
  else gLogInit("DEBUG");
  //if (argc>2) gSetLogFile(argv[2]);
-  RadioDevice *usrp = RadioDevice::make(52.0e6/192.0);
+  RadioDevice *usrp = RadioDevice::make(52.0e6/192.0, 1);
  usrp->open("");
--- a/Transceiver52M/convert.c
+++ b/Transceiver52M/convert.c
@@ -0,0 +1,171 @@
 /*
 * SSE type conversions
 * Copyright (C) 2013  Thomas Tsou <tom@tsou.cc>
 *
 * 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; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * 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 Street, Fifth Floor, Boston, MA 02110-1301 USA
 */
 #include <malloc.h>
 #include <string.h>
 #ifdef HAVE_CONFIG_H
 #include "config.h"
 #endif
 #ifdef HAVE_SSE3
 #include <xmmintrin.h>
 #include <emmintrin.h>
 #ifdef HAVE_SSE4_1
 #include <smmintrin.h>
 /* 16*N 16-bit signed integer converted to single precision floats */
 static void _sse_convert_si16_ps_16n(float *restrict out,
 				     short *restrict in,
 				     int len)
 {
 	__m128i m0, m1, m2, m3, m4, m5;
 	__m128 m6, m7, m8, m9;
 	for (int i = 0; i < len / 16; i++) {
 		/* Load (unaligned) packed floats */
 		m0 = _mm_load_si128((__m128i *) &in[16 * i + 0]);
 		m1 = _mm_load_si128((__m128i *) &in[16 * i + 8]);
 		/* Unpack */
 		m2 = _mm_cvtepi16_epi32(m0);
 		m4 = _mm_cvtepi16_epi32(m1);
 		m0 = _mm_shuffle_epi32(m0, _MM_SHUFFLE(1, 0, 3, 2));
 		m1 = _mm_shuffle_epi32(m1, _MM_SHUFFLE(1, 0, 3, 2));
 		m3 = _mm_cvtepi16_epi32(m0);
 		m5 = _mm_cvtepi16_epi32(m1);
 		/* Convert */
 		m6 = _mm_cvtepi32_ps(m2);
 		m7 = _mm_cvtepi32_ps(m3);
 		m8 = _mm_cvtepi32_ps(m4);
 		m9 = _mm_cvtepi32_ps(m5);
 		/* Store */
 		_mm_store_ps(&out[16 * i + 0], m6);
 		_mm_store_ps(&out[16 * i + 4], m7);
 		_mm_store_ps(&out[16 * i + 8], m8);
 		_mm_store_ps(&out[16 * i + 12], m9);
 	}
 }
 #endif /* HAVE_SSE4_1 */
 /* 8*N single precision floats scaled and converted to 16-bit signed integer */
 static void _sse_convert_scale_ps_si16_8n(short *restrict out,
 					  float *restrict in,
 					  float scale, int len)
 {
 	__m128 m0, m1, m2;
 	__m128i m4, m5;
 	for (int i = 0; i < len / 8; i++) {
 		/* Load (unaligned) packed floats */
 		m0 = _mm_loadu_ps(&in[8 * i + 0]);
 		m1 = _mm_loadu_ps(&in[8 * i + 4]);
 		m2 = _mm_load1_ps(&scale);
 		/* Scale */
 		m0 = _mm_mul_ps(m0, m2);
 		m1 = _mm_mul_ps(m1, m2);
 		/* Convert */
 		m4 = _mm_cvtps_epi32(m0);
 		m5 = _mm_cvtps_epi32(m1);
 		/* Pack and store */
 		m5 = _mm_packs_epi32(m4, m5);
 		_mm_store_si128((__m128i *) &out[8 * i], m5);
 	}
 }
 /* 16*N single precision floats scaled and converted to 16-bit signed integer */
 static void _sse_convert_scale_ps_si16_16n(short *restrict out,
 					   float *restrict in,
 					   float scale, int len)
 {
 	__m128 m0, m1, m2, m3, m4;
 	__m128i m5, m6, m7, m8;
 	for (int i = 0; i < len / 16; i++) {
 		/* Load (unaligned) packed floats */
 		m0 = _mm_loadu_ps(&in[16 * i + 0]);
 		m1 = _mm_loadu_ps(&in[16 * i + 4]);
 		m2 = _mm_loadu_ps(&in[16 * i + 8]);
 		m3 = _mm_loadu_ps(&in[16 * i + 12]);
 		m4 = _mm_load1_ps(&scale);
 		/* Scale */
 		m0 = _mm_mul_ps(m0, m4);
 		m1 = _mm_mul_ps(m1, m4);
 		m2 = _mm_mul_ps(m2, m4);
 		m3 = _mm_mul_ps(m3, m4);
 		/* Convert */
 		m5 = _mm_cvtps_epi32(m0);
 		m6 = _mm_cvtps_epi32(m1);
 		m7 = _mm_cvtps_epi32(m2);
 		m8 = _mm_cvtps_epi32(m3);
 		/* Pack and store */
 		m5 = _mm_packs_epi32(m5, m6);
 		m7 = _mm_packs_epi32(m7, m8);
 		_mm_store_si128((__m128i *) &out[16 * i + 0], m5);
 		_mm_store_si128((__m128i *) &out[16 * i + 8], m7);
 	}
 }
 #endif /* HAVE_SSE3 */
 static void convert_si16_ps(float *out, short *in, int len)
 {
 	for (int i = 0; i < len; i++)
 		out[i] = in[i];
 }
 static void convert_scale_ps_si16(short *out, float *in, float scale, int len)
 {
 	for (int i = 0; i < len; i++)
 		out[i] = in[i] * scale;
 }
 void convert_float_short(short *out, float *in, float scale, int len)
 {
 #ifdef HAVE_SSE3
 	if (!(len % 16))
 		_sse_convert_scale_ps_si16_16n(out, in, scale, len);
 	else if (!(len % 8))
 		_sse_convert_scale_ps_si16_8n(out, in, scale, len);
 	else
 		convert_scale_ps_si16(out, in, scale, len);
 #else
 	convert_scale_ps_si16(out, in, scale, len);
 #endif
 }
 void convert_short_float(float *out, short *in, int len)
 {
 #ifdef HAVE_SSE4_1
 	if (!(len % 16))
 		_sse_convert_si16_ps_16n(out, in, len);
 	else
 		convert_si16_ps(out, in, len);
 #else
 	convert_si16_ps(out, in, len);
 #endif
 }
--- a/Transceiver52M/convert.h
+++ b/Transceiver52M/convert.h
@@ -0,0 +1,7 @@
 #ifndef _CONVERT_H_
 #define _CONVERT_H_
 void convert_float_short(short *out, float *in, float scale, int len);
 void convert_short_float(float *out, short *in, int len);
 #endif /* _CONVERT_H_ */
--- a/Transceiver52M/convolve.c
+++ b/Transceiver52M/convolve.c
@@ -0,0 +1,676 @@
 /*
 * SSE Convolution
 * Copyright (C) 2012, 2013  Thomas Tsou <tom@tsou.cc>
 *
 * 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; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * 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 Street, Fifth Floor, Boston, MA 02110-1301 USA
 */
 #include <malloc.h>
 #include <string.h>
 #include <stdio.h>
 #ifdef HAVE_CONFIG_H
 #include "config.h"
 #endif
 #ifdef HAVE_SSE3
 #include <xmmintrin.h>
 #include <pmmintrin.h>
 /* 4-tap SSE complex-real convolution */
 static void sse_conv_real4(float *restrict x,
 			   float *restrict h,
 			   float *restrict y,
 			   int len)
 {
 	__m128 m0, m1, m2, m3, m4, m5, m6, m7;
 	/* Load (aligned) filter taps */
 	m0 = _mm_load_ps(&h[0]);
 	m1 = _mm_load_ps(&h[4]);
 	m7 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 	for (int i = 0; i < len; i++) {
 		/* Load (unaligned) input data */
 		m0 = _mm_loadu_ps(&x[2 * i + 0]);
 		m1 = _mm_loadu_ps(&x[2 * i + 4]);
 		m2 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 		m3 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 		/* Quad multiply */
 		m4 = _mm_mul_ps(m2, m7);
 		m5 = _mm_mul_ps(m3, m7);
 		/* Sum and store */
 		m6 = _mm_hadd_ps(m4, m5);
 		m0 = _mm_hadd_ps(m6, m6);
 		_mm_store_ss(&y[2 * i + 0], m0);
 		m0 = _mm_shuffle_ps(m0, m0, _MM_SHUFFLE(0, 3, 2, 1));
 		_mm_store_ss(&y[2 * i + 1], m0);
 	}
 }
 /* 8-tap SSE complex-real convolution */
 static void sse_conv_real8(float *restrict x,
 			   float *restrict h,
 			   float *restrict y,
 			   int len)
 {
 	__m128 m0, m1, m2, m3, m4, m5, m6, m7, m8, m9;
 	/* Load (aligned) filter taps */
 	m0 = _mm_load_ps(&h[0]);
 	m1 = _mm_load_ps(&h[4]);
 	m2 = _mm_load_ps(&h[8]);
 	m3 = _mm_load_ps(&h[12]);
 	m4 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 	m5 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 	for (int i = 0; i < len; i++) {
 		/* Load (unaligned) input data */
 		m0 = _mm_loadu_ps(&x[2 * i + 0]);
 		m1 = _mm_loadu_ps(&x[2 * i + 4]);
 		m2 = _mm_loadu_ps(&x[2 * i + 8]);
 		m3 = _mm_loadu_ps(&x[2 * i + 12]);
 		m6 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 		m7 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 		m8 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 		m9 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(1, 3, 1, 3));
 		/* Quad multiply */
 		m6 = _mm_mul_ps(m6, m4);
 		m7 = _mm_mul_ps(m7, m4);
 		m8 = _mm_mul_ps(m8, m5);
 		m9 = _mm_mul_ps(m9, m5);
 		/* Sum and store */
 		m6 = _mm_add_ps(m6, m8);
 		m7 = _mm_add_ps(m7, m9);
 		m6 = _mm_hadd_ps(m6, m7);
 		m6 = _mm_hadd_ps(m6, m6);
 		_mm_store_ss(&y[2 * i + 0], m6);
 		m6 = _mm_shuffle_ps(m6, m6, _MM_SHUFFLE(0, 3, 2, 1));
 		_mm_store_ss(&y[2 * i + 1], m6);
 	}
 }
 /* 12-tap SSE complex-real convolution */
 static void sse_conv_real12(float *restrict x,
 			    float *restrict h,
 			    float *restrict y,
 			    int len)
 {
 	__m128 m0, m1, m2, m3, m4, m5, m6, m7;
 	__m128 m8, m9, m10, m11, m12, m13, m14;
 	/* Load (aligned) filter taps */
 	m0 = _mm_load_ps(&h[0]);
 	m1 = _mm_load_ps(&h[4]);
 	m2 = _mm_load_ps(&h[8]);
 	m3 = _mm_load_ps(&h[12]);
 	m4 = _mm_load_ps(&h[16]);
 	m5 = _mm_load_ps(&h[20]);
 	m12 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 	m13 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 	m14 = _mm_shuffle_ps(m4, m5, _MM_SHUFFLE(0, 2, 0, 2));
 	for (int i = 0; i < len; i++) {
 		/* Load (unaligned) input data */
 		m0 = _mm_loadu_ps(&x[2 * i + 0]);
 		m1 = _mm_loadu_ps(&x[2 * i + 4]);
 		m2 = _mm_loadu_ps(&x[2 * i + 8]);
 		m3 = _mm_loadu_ps(&x[2 * i + 12]);
 		m4 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 		m5 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 		m6 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 		m7 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(1, 3, 1, 3));
 		m0 = _mm_loadu_ps(&x[2 * i + 16]);
 		m1 = _mm_loadu_ps(&x[2 * i + 20]);
 		m8 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 		m9 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 		/* Quad multiply */
 		m0 = _mm_mul_ps(m4, m12);
 		m1 = _mm_mul_ps(m5, m12);
 		m2 = _mm_mul_ps(m6, m13);
 		m3 = _mm_mul_ps(m7, m13);
 		m4 = _mm_mul_ps(m8, m14);
 		m5 = _mm_mul_ps(m9, m14);
 		/* Sum and store */
 		m8  = _mm_add_ps(m0, m2);
 		m9  = _mm_add_ps(m1, m3);
 		m10 = _mm_add_ps(m8, m4);
 		m11 = _mm_add_ps(m9, m5);
 		m2 = _mm_hadd_ps(m10, m11);
 		m3 = _mm_hadd_ps(m2, m2);
 		_mm_store_ss(&y[2 * i + 0], m3);
 		m3 = _mm_shuffle_ps(m3, m3, _MM_SHUFFLE(0, 3, 2, 1));
 		_mm_store_ss(&y[2 * i + 1], m3);
 	}
 }
 /* 16-tap SSE complex-real convolution */
 static void sse_conv_real16(float *restrict x,
 			    float *restrict h,
 			    float *restrict y,
 			    int len)
 {
 	__m128 m0, m1, m2, m3, m4, m5, m6, m7;
 	__m128 m8, m9, m10, m11, m12, m13, m14, m15;
 	/* Load (aligned) filter taps */
 	m0 = _mm_load_ps(&h[0]);
 	m1 = _mm_load_ps(&h[4]);
 	m2 = _mm_load_ps(&h[8]);
 	m3 = _mm_load_ps(&h[12]);
 	m4 = _mm_load_ps(&h[16]);
 	m5 = _mm_load_ps(&h[20]);
 	m6 = _mm_load_ps(&h[24]);
 	m7 = _mm_load_ps(&h[28]);
 	m12 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 	m13 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 	m14 = _mm_shuffle_ps(m4, m5, _MM_SHUFFLE(0, 2, 0, 2));
 	m15 = _mm_shuffle_ps(m6, m7, _MM_SHUFFLE(0, 2, 0, 2));
 	for (int i = 0; i < len; i++) {
 		/* Load (unaligned) input data */
 		m0 = _mm_loadu_ps(&x[2 * i + 0]);
 		m1 = _mm_loadu_ps(&x[2 * i + 4]);
 		m2 = _mm_loadu_ps(&x[2 * i + 8]);
 		m3 = _mm_loadu_ps(&x[2 * i + 12]);
 		m4 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 		m5 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 		m6 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 		m7 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(1, 3, 1, 3));
 		m0 = _mm_loadu_ps(&x[2 * i + 16]);
 		m1 = _mm_loadu_ps(&x[2 * i + 20]);
 		m2 = _mm_loadu_ps(&x[2 * i + 24]);
 		m3 = _mm_loadu_ps(&x[2 * i + 28]);
 		m8  = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 		m9  = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 		m10 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 		m11 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(1, 3, 1, 3));
 		/* Quad multiply */
 		m0 = _mm_mul_ps(m4, m12);
 		m1 = _mm_mul_ps(m5, m12);
 		m2 = _mm_mul_ps(m6, m13);
 		m3 = _mm_mul_ps(m7, m13);
 		m4 = _mm_mul_ps(m8, m14);
 		m5 = _mm_mul_ps(m9, m14);
 		m6 = _mm_mul_ps(m10, m15);
 		m7 = _mm_mul_ps(m11, m15);
 		/* Sum and store */
 		m8  = _mm_add_ps(m0, m2);
 		m9  = _mm_add_ps(m1, m3);
 		m10 = _mm_add_ps(m4, m6);
 		m11 = _mm_add_ps(m5, m7);
 		m0 = _mm_add_ps(m8, m10);
 		m1 = _mm_add_ps(m9, m11);
 		m2 = _mm_hadd_ps(m0, m1);
 		m3 = _mm_hadd_ps(m2, m2);
 		_mm_store_ss(&y[2 * i + 0], m3);
 		m3 = _mm_shuffle_ps(m3, m3, _MM_SHUFFLE(0, 3, 2, 1));
 		_mm_store_ss(&y[2 * i + 1], m3);
 	}
 }
 /* 20-tap SSE complex-real convolution */
 static void sse_conv_real20(float *restrict x,
 			    float *restrict h,
 			    float *restrict y,
 			    int len)
 {
 	__m128 m0, m1, m2, m3, m4, m5, m6, m7;
 	__m128 m8, m9, m11, m12, m13, m14, m15;
 	/* Load (aligned) filter taps */
 	m0 = _mm_load_ps(&h[0]);
 	m1 = _mm_load_ps(&h[4]);
 	m2 = _mm_load_ps(&h[8]);
 	m3 = _mm_load_ps(&h[12]);
 	m4 = _mm_load_ps(&h[16]);
 	m5 = _mm_load_ps(&h[20]);
 	m6 = _mm_load_ps(&h[24]);
 	m7 = _mm_load_ps(&h[28]);
 	m8 = _mm_load_ps(&h[32]);
 	m9 = _mm_load_ps(&h[36]);
 	m11 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 	m12 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 	m13 = _mm_shuffle_ps(m4, m5, _MM_SHUFFLE(0, 2, 0, 2));
 	m14 = _mm_shuffle_ps(m6, m7, _MM_SHUFFLE(0, 2, 0, 2));
 	m15 = _mm_shuffle_ps(m8, m9, _MM_SHUFFLE(0, 2, 0, 2));
 	for (int i = 0; i < len; i++) {
 		/* Multiply-accumulate first 12 taps */
 		m0 = _mm_loadu_ps(&x[2 * i + 0]);
 		m1 = _mm_loadu_ps(&x[2 * i + 4]);
 		m2 = _mm_loadu_ps(&x[2 * i + 8]);
 		m3 = _mm_loadu_ps(&x[2 * i + 12]);
 		m4 = _mm_loadu_ps(&x[2 * i + 16]);
 		m5 = _mm_loadu_ps(&x[2 * i + 20]);
 		m6  = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 		m7  = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 		m8  = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 		m9  = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(1, 3, 1, 3));
 		m0  = _mm_shuffle_ps(m4, m5, _MM_SHUFFLE(0, 2, 0, 2));
 		m1  = _mm_shuffle_ps(m4, m5, _MM_SHUFFLE(1, 3, 1, 3));
 		m2 = _mm_mul_ps(m6, m11);
 		m3 = _mm_mul_ps(m7, m11);
 		m4 = _mm_mul_ps(m8, m12);
 		m5 = _mm_mul_ps(m9, m12);
 		m6 = _mm_mul_ps(m0, m13);
 		m7 = _mm_mul_ps(m1, m13);
 		m0  = _mm_add_ps(m2, m4);
 		m1  = _mm_add_ps(m3, m5);
 		m8  = _mm_add_ps(m0, m6);
 		m9  = _mm_add_ps(m1, m7);
 		/* Multiply-accumulate last 8 taps */
 		m0 = _mm_loadu_ps(&x[2 * i + 24]);
 		m1 = _mm_loadu_ps(&x[2 * i + 28]);
 		m2 = _mm_loadu_ps(&x[2 * i + 32]);
 		m3 = _mm_loadu_ps(&x[2 * i + 36]);
 		m4 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 		m5 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 		m6 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 		m7 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(1, 3, 1, 3));
 		m0 = _mm_mul_ps(m4, m14);
 		m1 = _mm_mul_ps(m5, m14);
 		m2 = _mm_mul_ps(m6, m15);
 		m3 = _mm_mul_ps(m7, m15);
 		m4  = _mm_add_ps(m0, m2);
 		m5  = _mm_add_ps(m1, m3);
 		/* Final sum and store */
 		m0 = _mm_add_ps(m8, m4);
 		m1 = _mm_add_ps(m9, m5);
 		m2 = _mm_hadd_ps(m0, m1);
 		m3 = _mm_hadd_ps(m2, m2);
 		_mm_store_ss(&y[2 * i + 0], m3);
 		m3 = _mm_shuffle_ps(m3, m3, _MM_SHUFFLE(0, 3, 2, 1));
 		_mm_store_ss(&y[2 * i + 1], m3);
 	}
 }
 /* 4*N-tap SSE complex-complex convolution */
 static void sse_conv_cmplx_4n(float *x, float *h, float *y, int h_len, int len)
 {
 	__m128 m0, m1, m2, m3, m4, m5, m6, m7;
 	for (int i = 0; i < len; i++) {
 		/* Zero */
 		m6 = _mm_setzero_ps();
 		m7 = _mm_setzero_ps();
 		for (int n = 0; n < h_len / 4; n++) {
 			/* Load (aligned) filter taps */
 			m0 = _mm_load_ps(&h[8 * n + 0]);
 			m1 = _mm_load_ps(&h[8 * n + 4]);
 			m2 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 			m3 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 			/* Load (unaligned) input data */
 			m0 = _mm_loadu_ps(&x[2 * i + 8 * n + 0]);
 			m1 = _mm_loadu_ps(&x[2 * i + 8 * n + 4]);
 			m4 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 			m5 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 			/* Quad multiply */
 			m0 = _mm_mul_ps(m2, m4);
 			m1 = _mm_mul_ps(m3, m5);
 			m2 = _mm_mul_ps(m2, m5);
 			m3 = _mm_mul_ps(m3, m4);
 			/* Sum */
 			m0 = _mm_sub_ps(m0, m1);
 			m2 = _mm_add_ps(m2, m3);
 			/* Accumulate */
 			m6 = _mm_add_ps(m6, m0);
 			m7 = _mm_add_ps(m7, m2);
 		}
 		m0 = _mm_hadd_ps(m6, m7);
 		m0 = _mm_hadd_ps(m0, m0);
 		_mm_store_ss(&y[2 * i + 0], m0);
 		m0 = _mm_shuffle_ps(m0, m0, _MM_SHUFFLE(0, 3, 2, 1));
 		_mm_store_ss(&y[2 * i + 1], m0);
 	}
 }
 /* 8*N-tap SSE complex-complex convolution */
 static void sse_conv_cmplx_8n(float *x, float *h, float *y, int h_len, int len)
 {
 	__m128 m0, m1, m2, m3, m4, m5, m6, m7;
 	__m128 m8, m9, m10, m11, m12, m13, m14, m15;
 	for (int i = 0; i < len; i++) {
 		/* Zero */
 		m12 = _mm_setzero_ps();
 		m13 = _mm_setzero_ps();
 		m14 = _mm_setzero_ps();
 		m15 = _mm_setzero_ps();
 		for (int n = 0; n < h_len / 8; n++) {
 			/* Load (aligned) filter taps */
 			m0 = _mm_load_ps(&h[16 * n + 0]);
 			m1 = _mm_load_ps(&h[16 * n + 4]);
 			m2 = _mm_load_ps(&h[16 * n + 8]);
 			m3 = _mm_load_ps(&h[16 * n + 12]);
 			m4 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 			m5 = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 			m6 = _mm_shuffle_ps(m2, m2, _MM_SHUFFLE(0, 2, 0, 2));
 			m7 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(1, 3, 1, 3));
 			/* Load (unaligned) input data */
 			m0 = _mm_loadu_ps(&x[2 * i + 16 * n + 0]);
 			m1 = _mm_loadu_ps(&x[2 * i + 16 * n + 4]);
 			m2 = _mm_loadu_ps(&x[2 * i + 16 * n + 8]);
 			m3 = _mm_loadu_ps(&x[2 * i + 16 * n + 12]);
 			m8  = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(0, 2, 0, 2));
 			m9  = _mm_shuffle_ps(m0, m1, _MM_SHUFFLE(1, 3, 1, 3));
 			m10 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(0, 2, 0, 2));
 			m11 = _mm_shuffle_ps(m2, m3, _MM_SHUFFLE(1, 3, 1, 3));
 			/* Quad multiply */
 			m0 = _mm_mul_ps(m4, m8);
 			m1 = _mm_mul_ps(m5, m9);
 			m2 = _mm_mul_ps(m6, m10);
 			m3 = _mm_mul_ps(m7, m11);
 			m4 = _mm_mul_ps(m4, m9);
 			m5 = _mm_mul_ps(m5, m8);
 			m6 = _mm_mul_ps(m6, m11);
 			m7 = _mm_mul_ps(m7, m10);
 			/* Sum */
 			m0 = _mm_sub_ps(m0, m1);
 			m2 = _mm_sub_ps(m2, m3);
 			m4 = _mm_add_ps(m4, m5);
 			m6 = _mm_add_ps(m6, m7);
 			/* Accumulate */
 			m12 = _mm_add_ps(m12, m0);
 			m13 = _mm_add_ps(m13, m2);
 			m14 = _mm_add_ps(m14, m4);
 			m15 = _mm_add_ps(m15, m6);
 		}
 		m0 = _mm_add_ps(m12, m13);
 		m1 = _mm_add_ps(m14, m15);
 		m2 = _mm_hadd_ps(m0, m1);
 		m2 = _mm_hadd_ps(m2, m2);
 		_mm_store_ss(&y[2 * i + 0], m2);
 		m2 = _mm_shuffle_ps(m2, m2, _MM_SHUFFLE(0, 3, 2, 1));
 		_mm_store_ss(&y[2 * i + 1], m2);
 	}
 }
 #endif
 /* Base multiply and accumulate complex-real */
 static void mac_real(float *x, float *h, float *y)
 {
 	y[0] += x[0] * h[0];
 	y[1] += x[1] * h[0];
 }
 /* Base multiply and accumulate complex-complex */
 static void mac_cmplx(float *x, float *h, float *y)
 {
 	y[0] += x[0] * h[0] - x[1] * h[1];
 	y[1] += x[0] * h[1] + x[1] * h[0];
 }
 /* Base vector complex-complex multiply and accumulate */
 static void mac_real_vec_n(float *x, float *h, float *y,
 			   int len, int step, int offset)
 {
 	for (int i = offset; i < len; i += step)
 		mac_real(&x[2 * i], &h[2 * i], y);
 }
 /* Base vector complex-complex multiply and accumulate */
 static void mac_cmplx_vec_n(float *x, float *h, float *y,
 			    int len, int step, int offset)
 {
 	for (int i = offset; i < len; i += step)
 		mac_cmplx(&x[2 * i], &h[2 * i], y);
 }
 /* Base complex-real convolution */
 static int _base_convolve_real(float *x, int x_len,
 			       float *h, int h_len,
 			       float *y, int y_len,
 			       int start, int len,
 			       int step, int offset)
 {
 	for (int i = 0; i < len; i++) {
 		mac_real_vec_n(&x[2 * (i - (h_len - 1) + start)],
 			       h,
 			       &y[2 * i], h_len,
 			       step, offset);
 	}
 	return len;
 }
 /* Base complex-complex convolution */
 static int _base_convolve_complex(float *x, int x_len,
 				  float *h, int h_len,
 				  float *y, int y_len,
 				  int start, int len,
 				  int step, int offset)
 {
 	for (int i = 0; i < len; i++) {
 		mac_cmplx_vec_n(&x[2 * (i - (h_len - 1) + start)],
 				h,
 				&y[2 * i],
 				h_len, step, offset);
 	}
 	return len;
 }
 /* Buffer validity checks */
 static int bounds_check(int x_len, int h_len, int y_len,
 			int start, int len, int step)
 {
 	if ((x_len < 1) || (h_len < 1) ||
 	    (y_len < 1) || (len < 1) || (step < 1)) {
 		fprintf(stderr, "Convolve: Invalid input\n");
 		return -1;
 	}
 	if ((start + len > x_len) || (len > y_len) || (x_len < h_len)) {
 		fprintf(stderr, "Convolve: Boundary exception\n");
 		fprintf(stderr, "start: %i, len: %i, x: %i, h: %i, y: %i\n",
 				start, len, x_len, h_len, y_len);
 		return -1;
 	}
 	return 0;
 }
 /* API: Aligned complex-real */
 int convolve_real(float *x, int x_len,
 		  float *h, int h_len,
 		  float *y, int y_len,
 		  int start, int len,
 		  int step, int offset)
 {
 	void (*conv_func)(float *, float *, float *, int);
 	if (bounds_check(x_len, h_len, y_len, start, len, step) < 0)
 		return -1;
 	memset(y, 0, len * 2 * sizeof(float));
 #ifdef HAVE_SSE3
 	if (step <= 4) {
 		switch (h_len) {
 		case 4:
 			conv_func = sse_conv_real4;
 			break;
 		case 8:
 			conv_func = sse_conv_real8;
 			break;
 		case 12:
 			conv_func = sse_conv_real12;
 			break;
 		case 16:
 			conv_func = sse_conv_real16;
 			break;
 		case 20:
 			conv_func = sse_conv_real20;
 			break;
 		default:
 			conv_func = NULL;
 		}
 	} else {
 		conv_func = NULL;
 	}
 #else
 	conv_func = NULL;
 #endif
 	if (conv_func) {
 		conv_func(&x[2 * (-(h_len - 1) + start)],
 			  h, y, len);
 	} else {
 		_base_convolve_real(x, x_len,
 				    h, h_len,
 				    y, y_len,
 				    start, len, step, offset);
 	}
 	return len;
 }
 /* API: Aligned complex-complex */
 int convolve_complex(float *x, int x_len,
 		     float *h, int h_len,
 		     float *y, int y_len,
 		     int start, int len,
 		     int step, int offset)
 {
 	void (*conv_func)(float *, float *, float *, int, int);
 	if (bounds_check(x_len, h_len, y_len, start, len, step) < 0)
 		return -1;
 	memset(y, 0, len * 2 * sizeof(float));
 #ifdef HAVE_SSE3
 	if (step <= 4) {
 		if (!(h_len % 8))
 			conv_func = sse_conv_cmplx_8n;
 		else if (!(h_len % 4))
 			conv_func = sse_conv_cmplx_4n;
 	} else
 		conv_func = NULL;
 #else
 	conv_func = NULL;
 #endif
 	if (conv_func) {
 		conv_func(&x[2 * (-(h_len - 1) + start)],
 			  h, y, h_len, len);
 	} else {
 		_base_convolve_complex(x, x_len,
 				       h, h_len,
 				       y, y_len,
 				       start, len, step, offset);
 	}
 	return len;
 }
 /* API: Non-aligned (no SSE) complex-real */
 int base_convolve_real(float *x, int x_len,
 		       float *h, int h_len,
 		       float *y, int y_len,
 		       int start, int len,
 		       int step, int offset)
 {
 	if (bounds_check(x_len, h_len, y_len, start, len, step) < 0)
 		return -1;
 	memset(y, 0, len * 2 * sizeof(float));
 	return _base_convolve_real(x, x_len,
 				   h, h_len,
 				   y, y_len,
 				   start, len, step, offset);
 }
 /* API: Non-aligned (no SSE) complex-complex */
 int base_convolve_complex(float *x, int x_len,
 			  float *h, int h_len,
 			  float *y, int y_len,
 			  int start, int len,
 			  int step, int offset)
 {
 	if (bounds_check(x_len, h_len, y_len, start, len, step) < 0)
 		return -1;
 	memset(y, 0, len * 2 * sizeof(float));
 	return _base_convolve_complex(x, x_len,
 				      h, h_len,
 				      y, y_len,
 				      start, len, step, offset);
 }
 /* Aligned filter tap allocation */
 void *convolve_h_alloc(int len)
 {
 #ifdef HAVE_SSE3
 	return memalign(16, len * 2 * sizeof(float));
 #else
 	return malloc(len * 2 * sizeof(float));
 #endif
 }
--- a/Transceiver52M/convolve.h
+++ b/Transceiver52M/convolve.h
@@ -0,0 +1,30 @@
 #ifndef _CONVOLVE_H_
 #define _CONVOLVE_H_
 void *convolve_h_alloc(int num);
 int convolve_real(float *x, int x_len,
 		  float *h, int h_len,
 		  float *y, int y_len,
 		  int start, int len,
 		  int step, int offset);
 int convolve_complex(float *x, int x_len,
 		     float *h, int h_len,
 		     float *y, int y_len,
 		     int start, int len,
 		     int step, int offset);
 int base_convolve_real(float *x, int x_len,
 		       float *h, int h_len,
 		       float *y, int y_len,
 		       int start, int len,
 		       int step, int offset);
 int base_convolve_complex(float *x, int x_len,
 			  float *h, int h_len,
 			  float *y, int y_len,
 			  int start, int len,
 			  int step, int offset);
 #endif /* _CONVOLVE_H_ */
--- a/Transceiver52M/laurent.m
+++ b/Transceiver52M/laurent.m
@@ -0,0 +1,83 @@
 %
 % Laurent decomposition of GMSK signals
 % Generates C0, C1, and C2 pulse shapes
 %
 % Pierre Laurent, "Exact and Approximate Construction of Digital Phase
 %   Modulations by Superposition of Amplitude Modulated Pulses", IEEE
 %   Transactions of Communications, Vol. 34, No. 2, Feb 1986.
 %
 % Author: Thomas Tsou <tom@tsou.cc>
 %
 % Modulation parameters
 oversamp = 16;
 L = 3;
 f = 270.83333e3;
 T = 1/f;
 h = 0.5;
 BT = 0.30;
 B = BT / T;
 % Generate sampling points for L symbol periods
 t = -(L*T/2):T/oversamp:(L*T/2);
 t = t(1:end-1) + (T/oversamp/2);
 % Generate Gaussian pulse
 g = qfunc(2*pi*B*(t - T/2)/(log(2)^.5)) - qfunc(2*pi*B*(t + T/2)/(log(2)^.5));
 g = g / sum(g) * pi/2;
 g = [0 g];
 % Integrate phase 
 q = 0;
 for i = 1:size(g,2);
    q(i) = sum(g(1:i));
 end
 % Compute two sided "generalized phase pulse" function
 s = 0;
 for i = 1:size(g,2);
    s(i) = sin(q(i)) / sin(pi*h);
 end
 for i = (size(g,2) + 1):(2 * size(g,2) - 1);
    s(i) = sin(pi*h - q(i - (size(g,2) - 1))) / sin(pi*h);
 end
 % Compute C0 pulse: valid for all L values
 c0 = s(1:end-(oversamp*(L-1)));
 for i = 1:L-1;
    c0 = c0 .* s((1 + i*oversamp):end-(oversamp*(L - 1 - i)));
 end
 % Compute C1 pulse: valid for L = 3 only!
 %   C1 = S0 * S4 * S2
 c1 = s(1:end-(oversamp*(4)));
 c1 = c1 .* s((1 + 4*oversamp):end-(oversamp*(4 - 1 - 3)));
 c1 = c1 .* s((1 + 2*oversamp):end-(oversamp*(4 - 1 - 1)));
 % Compute C2 pulse: valid for L = 3 only!
 %   C2 = S0 * S1 * S5
 c2 = s(1:end-(oversamp*(5)));
 c2 = c2 .* s((1 + 1*oversamp):end-(oversamp*(5 - 1 - 0)));
 c2 = c2 .* s((1 + 5*oversamp):end-(oversamp*(5 - 1 - 4)));
 % Plot C0, C1, C2 Laurent pulse series
 figure(1);
 hold off;
 plot((0:size(c0,2)-1)/oversamp - 2,c0, 'b');
 hold on;
 plot((0:size(c1,2)-1)/oversamp - 2,c1, 'r');
 plot((0:size(c2,2)-1)/oversamp - 2,c2, 'g');
 % Generate OpenBTS pulse
 numSamples = size(c0,2); 
 centerPoint = (numSamples - 1)/2;
 i = ((0:numSamples) - centerPoint) / oversamp;
 xP = .96*exp(-1.1380*i.^2 - 0.527*i.^4);
 xP = xP / max(xP) * max(c0);
 % Plot C0 pulse compared to OpenBTS pulse
 figure(2);
 hold off;
 plot((0:size(c0,2)-1)/oversamp, c0, 'b');
 hold on;
 plot((0:size(xP,2)-1)/oversamp, xP, 'r');
--- a/Transceiver52M/multiTRX.cpp
+++ b/Transceiver52M/multiTRX.cpp
@@ -0,0 +1,201 @@
 /*
 * Copyright 2012  Thomas Tsou <ttsou@vt.edu>
 *
 * 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 <http://www.gnu.org/licenses/>.
 * See the COPYING file in the main directory for details.
 */
 #include <time.h>
 #include <signal.h>
 #include <GSMCommon.h>
 #include <Logger.h>
 #include <Configuration.h>
 #include "Transceiver.h"
 #include "radioDevice.h"
 #define CONFIGDB	"/etc/OpenBTS/OpenBTS.db"
 ConfigurationTable gConfig(CONFIGDB);
 volatile bool gbShutdown = false;
 int Transceiver::mTSC = -1;
 static void sigHandler(int signum)
 {
 	LOG(NOTICE) << "Received shutdown signal";
 	gbShutdown = true;
 }
 static int setupSignals()
 {
 	struct sigaction action;
 	action.sa_handler = sigHandler;
 	sigemptyset(&action.sa_mask);
 	action.sa_flags = 0;
 	if (sigaction(SIGINT, &action, NULL) < 0)
 		return -1;
 	if (sigaction(SIGTERM, &action, NULL) < 0)
 		return -1;
 	return 0;
 }
 /*
 * Attempt to open and test the database file before
 * accessing the configuration table. We do this because
 * the global table constructor cannot provide notification
 * in the event of failure.
 */
 static int testConfig(const char *filename)
 {
 	int rc, val = 9999;
 	sqlite3 *db;
 	std::string test = "sadf732zdvj2";
 	const char *keys[3] = {
 		"Log.Level",
 		"TRX.Port",
 		"TRX.IP",
 	};
 	/* Try to open the database	*/
 	rc = sqlite3_open(filename, &db);
 	if (rc || !db) {
 		std::cerr << "Config: Database could not be opened"
 			  << std::endl;
 		return -1;
 	} else {
 		sqlite3_close(db);
 	}
 	/* Attempt to set a value in the global config */
 	if (!gConfig.set(test, val)) {
 		std::cerr << "Config: Failed to set test key - "
 			  << "permission to access the database?"
 			  << std::endl;
 		return -1;
 	} else {
 		gConfig.remove(test);
 	}
 	/* Attempt to query */
 	for (int i = 0; i < 3; i++) {
 		try {
 			gConfig.getStr(keys[i]); 
 		} catch (...) {
 			std::cerr << "Config: Failed query on "
 				  << keys[i] << std::endl;
 			return -1;
 		}
 	}
 	return 0; 
 }
 int main(int argc, char *argv[])
 {
 	int trxPort, numARFCN = 1;
 	std::string logLevel, trxAddr, deviceArgs = "";
 	switch (argc) {
 	case 3:
 		deviceArgs = std::string(argv[2]);
 	case 2:
 		numARFCN = atoi(argv[1]);
 		if (numARFCN > CHAN_MAX) {
 			LOG(ALERT) << numARFCN  << " channels not supported "
 						<< " with with current build";
 			exit(-1);
 		}
 	case 1:
 		break;
 	default:
 		std::cout << argv[0] << " <chans> <device args>" << std::endl;
 		return -1;
 	}
 	if (setupSignals() < 0) {
 		LOG(ERR) << "Failed to setup signal handlers, exiting...";
 		exit(-1);
 	}
 	/* Configure logger */
 	if (testConfig(CONFIGDB) < 0) {
 		std::cerr << "Config: Database failure" << std::endl;
 		return EXIT_FAILURE;
 	}
 	logLevel = gConfig.getStr("Log.Level");
 	trxPort = gConfig.getNum("TRX.Port");
 	trxAddr = gConfig.getStr("TRX.IP");
 	gLogInit("transceiver", logLevel.c_str(), LOG_LOCAL7);
 	srandom(time(NULL));
 	RadioDevice *device = RadioDevice::make(SAMPSPERSYM);
 	int radioType = device->open(deviceArgs);
 	if (radioType < 0) {
 		LOG(ALERT) << "Failed to open device, exiting...";
 		return EXIT_FAILURE;
 	}
 	RadioInterface *radio;
 	switch (radioType) {
 	case RadioDevice::NORMAL:
 		radio = new RadioInterface(device, numARFCN);
 		break;
 	case RadioDevice::RESAMP:
 	default:
 		LOG(ALERT) << "Unsupported configuration";
 		return EXIT_FAILURE;
 	}
 	DriveLoop *drive;
 	drive = new DriveLoop(trxPort, trxAddr.c_str(), radio, numARFCN, 0);
 	if (!drive->init()) {
 		LOG(ALERT) << "Failed to initialize drive loop";
 	}
 	Transceiver *trx[CHAN_MAX];
 	bool primary = true;
 	for (int i = 0; i < numARFCN; i++) {
 		trx[i] = new Transceiver(trxPort + 2 * i, trxAddr.c_str(),
 					 drive, radio, SAMPSPERSYM,
 					 i, primary);
 		trx[i]->start();
 		primary = false;
 	}
 	while (!gbShutdown)
 		sleep(1);
 	LOG(NOTICE) << "Shutting down transceivers...";
 	for (int i = 0; i < numARFCN; i++)
 		trx[i]->shutdown();
 	/* Allow time for threads to end before we start freeing objects */
 	sleep(2);
 	for (int i = 0; i < numARFCN; i++)
 		delete trx[i];
 	delete drive;
 	delete radio;
 	delete device;
 }
--- a/Transceiver52M/radioDevice.h
+++ b/Transceiver52M/radioDevice.h
@@ -21,6 +21,8 @@
 #include "config.h"
 #endif
 #define GSMRATE       1625e3/6
 /** a 64-bit virtual timestamp for radio data */
 typedef unsigned long long TIMESTAMP;
@@ -29,12 +31,17 @@ class RadioDevice {
  public:
  /* Available transport bus types */
-  enum busType { USB, NET };
+  enum TxWindowType { TX_WINDOW_USRP1, TX_WINDOW_FIXED };
-  static RadioDevice *make(double desiredSampleRate, bool skipRx = false);
+  /* Radio interface types */
  enum RadioInterfaceType { NORMAL, RESAMP };
  static RadioDevice *make(int sps, bool skipRx = false);
  virtual ~RadioDevice() {};
  /** Initialize the USRP */
-  virtual bool open(const std::string &args)=0;
+  virtual int open(const std::string &args)=0;
  /** Start the USRP */
  virtual bool start()=0;
@@ -42,8 +49,8 @@ class RadioDevice {
  /** Stop the USRP */
  virtual bool stop()=0;
-  /** Get the bus type */
+  /** Get the Tx window type */
-  virtual enum busType getBus()=0;
+  virtual enum TxWindowType getWindowType()=0;
  /** Enable thread priority */
  virtual void setPriority()=0;
@@ -58,10 +65,9 @@ class RadioDevice {
 	@param RSSI The received signal strength of the read result
 	@return The number of samples actually read
  */
-  virtual int readSamples(short *buf, int len, bool *overrun, 
+  virtual int readSamples(short **buf, int chans, int len, TIMESTAMP timestamp,
-		   TIMESTAMP timestamp = 0xffffffff,
+                          bool *overrun = NULL, bool *underrun = NULL,
-		   bool *underrun = 0,
+                          unsigned *RSSI = NULL)=0;
 		   unsigned *RSSI = 0)=0;
  /**
        Write samples to the radio.
        @param buf Contains the data to be written.
@@ -71,18 +77,17 @@ class RadioDevice {
        @param isControl Set if data is a control packet, e.g. a ping command
        @return The number of samples actually written
  */
-  virtual int writeSamples(short *buf, int len, bool *underrun, 
+  virtual int writeSamples(short **buf, int chans, int len, TIMESTAMP timestamp,
-		    TIMESTAMP timestamp,
+                           bool *underrun = NULL, bool isControl = false)=0;
 		    bool isControl=false)=0;
  /** Update the alignment between the read and write timestamps */
  virtual bool updateAlignment(TIMESTAMP timestamp)=0;
  /** Set the transmitter frequency */
-  virtual bool setTxFreq(double wFreq)=0;
+  virtual bool setTxFreq(double wFreq, int chan = 0)=0;
  /** Set the receiver frequency */
-  virtual bool setRxFreq(double wFreq)=0;
+  virtual bool setRxFreq(double wFreq, int chan = 0)=0;
  /** Returns the starting write Timestamp*/
  virtual TIMESTAMP initialWriteTimestamp(void)=0;
@@ -97,10 +102,10 @@ class RadioDevice {
  virtual double fullScaleOutputValue()=0;
  /** sets the receive chan gain, returns the gain setting **/
-  virtual double setRxGain(double dB)=0;
+  virtual double setRxGain(double dB, int chan = 0)=0;
  /** gets the current receive gain **/
-  virtual double getRxGain(void)=0;
+  virtual double getRxGain(int chan = 0)=0;
  /** return maximum Rx Gain **/
  virtual double maxRxGain(void) = 0;
@@ -109,7 +114,7 @@ class RadioDevice {
  virtual double minRxGain(void) = 0;
  /** sets the transmit chan gain, returns the gain setting **/
-  virtual double setTxGain(double dB)=0;
+  virtual double setTxGain(double dB, int chan = 0)=0;
  /** return maximum Tx Gain **/
  virtual double maxTxGain(void) = 0;
@@ -117,13 +122,18 @@ class RadioDevice {
  /** return minimum Tx Gain **/
  virtual double minTxGain(void) = 0;
  /** set and return antennas selection **/
  virtual void setTxAntenna(std::string &name) = 0;
  virtual void setRxAntenna(std::string &name) = 0;
  virtual std::string getRxAntenna() = 0;
  virtual std::string getTxAntenna() = 0;
  /** Return internal status values */
-  virtual double getTxFreq()=0;
+  virtual double getTxFreq(int chan = 0)=0;
-  virtual double getRxFreq()=0;
+  virtual double getRxFreq(int chan = 0)=0;
  virtual double getSampleRate()=0;
  virtual double numberRead()=0;
  virtual double numberWritten()=0;
 };
 #endif
--- a/Transceiver52M/radioIO.cpp
+++ b/Transceiver52M/radioIO.cpp
@@ -1,91 +0,0 @@
 /*
 * Radio device I/O interface
 * Written by Thomas Tsou <ttsou@vt.edu>
 *
 * Copyright 2011 Free Software Foundation, Inc.
 *
 * 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 <http://www.gnu.org/licenses/>.
 * See the COPYING file in the main directory for details.
 */
 #include <radioInterface.h>
 #include <Logger.h>
 /* Device side buffers */
 static short rx_buf[OUTCHUNK * 2 * 2];
 static short tx_buf[INCHUNK * 2 * 2];
 /* Complex float to short conversion */
 static int float_to_short(short *shrt_out, float *flt_in, int num)
 {
 	int i;
 	for (i = 0; i < num; i++) {
 		shrt_out[2 * i + 0] = flt_in[2 * i + 0];
 		shrt_out[2 * i + 1] = flt_in[2 * i + 1];
 	}
 	return i;
 }
 /* Comlpex short to float conversion */
 static int short_to_float(float *flt_out, short *shrt_in, int num)
 {
 	int i;
 	for (i = 0; i < num; i++) {
 		flt_out[2 * i + 0] = shrt_in[2 * i + 0];
 		flt_out[2 * i + 1] = shrt_in[2 * i + 1];
 	}
 	return i;
 }
 /* Receive a timestamped chunk from the device */ 
 void RadioInterface::pullBuffer()
 {
 	bool local_underrun;
 	/* Read samples. Fail if we don't get what we want. */
 	int num_rd = mRadio->readSamples(rx_buf, OUTCHUNK, &overrun,
 					    readTimestamp, &local_underrun);
 	LOG(DEBUG) << "Rx read " << num_rd << " samples from device";
 	assert(num_rd == OUTCHUNK);
 	underrun |= local_underrun;
 	readTimestamp += (TIMESTAMP) num_rd;
 	short_to_float(rcvBuffer + 2 * rcvCursor, rx_buf, num_rd);
 	rcvCursor += num_rd;
 }
 /* Send timestamped chunk to the device with arbitrary size */ 
 void RadioInterface::pushBuffer()
 {
 	if (sendCursor < INCHUNK)
 		return;
 	float_to_short(tx_buf, sendBuffer, sendCursor);
 	/* Write samples. Fail if we don't get what we want. */
 	int num_smpls = mRadio->writeSamples(tx_buf,
 					     sendCursor,
 					     &underrun,
 					     writeTimestamp);
 	assert(num_smpls == sendCursor);
 	writeTimestamp += (TIMESTAMP) num_smpls;
 	sendCursor = 0;
 }
--- a/Transceiver52M/radioIOResamp.cpp
+++ b/Transceiver52M/radioIOResamp.cpp
@@ -1,324 +0,0 @@
 /*
 * Radio device interface with sample rate conversion
 * Written by Thomas Tsou <ttsou@vt.edu>
 *
 * Copyright 2011 Free Software Foundation, Inc.
 *
 * 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 <http://www.gnu.org/licenses/>.
 * See the COPYING file in the main directory for details.
 */
 #include <radioInterface.h>
 #include <Logger.h>
 /* New chunk sizes for resampled rate */
 #ifdef INCHUNK
  #undef INCHUNK
 #endif
 #ifdef OUTCHUNK
  #undef OUTCHUNK
 #endif
 /* Resampling parameters */
 #define INRATE       65 * SAMPSPERSYM
 #define INHISTORY    INRATE * 2
 #define INCHUNK      INRATE * 9
 #define OUTRATE      96 * SAMPSPERSYM
 #define OUTHISTORY   OUTRATE * 2
 #define OUTCHUNK     OUTRATE * 9
 /* Resampler low pass filters */
 signalVector *tx_lpf = 0;
 signalVector *rx_lpf = 0;
 /* Resampler history */
 signalVector *tx_hist = 0;
 signalVector *rx_hist = 0;
 /* Resampler input buffer */
 signalVector *tx_vec = 0;
 signalVector *rx_vec = 0;
 /*
 * High rate (device facing) buffers
 *
 * Transmit side samples are pushed after each burst so accomodate
 * a resampled burst plus up to a chunk left over from the previous
 * resampling operation.
 *
 * Receive side samples always pulled with a fixed size.
 */
 short tx_buf[INCHUNK * 2 * 4];
 short rx_buf[OUTCHUNK * 2 * 2];
 /* 
 * Utilities and Conversions 
 *
 * Manipulate signal vectors dynamically for two reasons. For one,
 * it's simpler. And two, it doesn't make any reasonable difference
 * relative to the high overhead generated by the resampling.
 */
 /* Concatenate signal vectors. Deallocate input vectors. */
 signalVector *concat(signalVector *a, signalVector *b)
 {
 	signalVector *vec = new signalVector(*a, *b);
 	delete a;
 	delete b;
 	return vec;
 }
 /* Segment a signal vector. Deallocate the input vector. */
 signalVector *segment(signalVector *a, int indx, int sz)
 {
 	signalVector *vec = new signalVector(sz);
 	a->segmentCopyTo(*vec, indx, sz);
 	delete a;
 	return vec;
 }
 /* Create a new signal vector from a short array. */
 signalVector *short_to_sigvec(short *smpls, size_t sz)
 {
 	int i;
 	signalVector *vec = new signalVector(sz);
 	signalVector::iterator itr = vec->begin();
 	for (i = 0; i < sz; i++) {
 		*itr++ = Complex<float>(smpls[2 * i + 0], smpls[2 * i + 1]);
 	}
 	return vec;
 }
 /* Convert and deallocate a signal vector into a short array. */
 int sigvec_to_short(signalVector *vec, short *smpls)
 {
 	int i;
 	signalVector::iterator itr = vec->begin();
 	for (i = 0; i < vec->size(); i++) {
 		smpls[2 * i + 0] = itr->real();
 		smpls[2 * i + 1] = itr->imag();
 		itr++;
 	}
 	delete vec;
 	return i;
 }
 /* Create a new signal vector from a float array. */
 signalVector *float_to_sigvec(float *smpls, int sz)
 {
 	int i;
 	signalVector *vec = new signalVector(sz);
 	signalVector::iterator itr = vec->begin();
 	for (i = 0; i < sz; i++) {
 		*itr++ = Complex<float>(smpls[2 * i + 0], smpls[2 * i + 1]);
 	}
 	return vec;
 }
 /* Convert and deallocate a signal vector into a float array. */
 int sigvec_to_float(signalVector *vec, float *smpls)
 {
 	int i;
 	signalVector::iterator itr = vec->begin();
 	for (i = 0; i < vec->size(); i++) {
 		smpls[2 * i + 0] = itr->real();
 		smpls[2 * i + 1] = itr->imag();
 		itr++;
 	}
 	delete vec;
 	return i;
 }
 /* Initialize resampling signal vectors */
 void init_resampler(signalVector **lpf,
 	   	    signalVector **buf,
 		    signalVector **hist,
 		    int tx)
 {
 	int P, Q, taps, hist_len;
 	float cutoff_freq;
 	if (tx) {
 		LOG(INFO) << "Initializing Tx resampler";
 		P = OUTRATE;
 		Q = INRATE;
 		taps = 651;
 		hist_len = INHISTORY;
 	} else {
 		LOG(INFO) << "Initializing Rx resampler";
 		P = INRATE;
 		Q = OUTRATE;
 		taps = 961;
 		hist_len = OUTHISTORY;
 	}
 	if (!*lpf) {
 		cutoff_freq = (P < Q) ? (1.0/(float) Q) : (1.0/(float) P);
 		*lpf = createLPF(cutoff_freq, taps, P);
 	}
 	if (!*buf) {
 		*buf = new signalVector();
 	}
 	if (!*hist);
 		*hist = new signalVector(hist_len);
 }
 /* Resample a signal vector
 *
 * The input vector is deallocated and the pointer returned with a vector
 * of any unconverted samples.
 */
 signalVector *resmpl_sigvec(signalVector *hist, signalVector **vec,
 			    signalVector *lpf, double in_rate,
 			    double out_rate, int chunk_sz)
 {
 	signalVector *resamp_vec;
 	int num_chunks = (*vec)->size() / chunk_sz;
 	/* Truncate to a chunk multiple */
 	signalVector trunc_vec(num_chunks * chunk_sz);
 	(*vec)->segmentCopyTo(trunc_vec, 0, num_chunks * chunk_sz);
 	/* Update sample buffer with remainder */
 	*vec = segment(*vec, trunc_vec.size(), (*vec)->size() - trunc_vec.size());
 	/* Add history and resample */
 	signalVector input_vec(*hist, trunc_vec);
 	resamp_vec = polyphaseResampleVector(input_vec, in_rate,
 					     out_rate, lpf);
 	/* Update history */
 	trunc_vec.segmentCopyTo(*hist, trunc_vec.size() - hist->size(),
 				hist->size());
 	return resamp_vec;
 }
 /* Wrapper for receive-side integer-to-float array resampling */
 int rx_resmpl_int_flt(float *smpls_out, short *smpls_in, int num_smpls)
 {
 	int num_resmpld, num_chunks;
 	signalVector *convert_vec, *resamp_vec, *trunc_vec;
 	if (!rx_lpf || !rx_vec || !rx_hist)
 		init_resampler(&rx_lpf, &rx_vec, &rx_hist, false);
 	/* Convert and add samples to the receive buffer */
 	convert_vec = short_to_sigvec(smpls_in, num_smpls);
 	rx_vec = concat(rx_vec, convert_vec);
 	num_chunks = rx_vec->size() / OUTCHUNK;
 	if (num_chunks < 1)
 		return 0;
 	/* Resample */ 
 	resamp_vec = resmpl_sigvec(rx_hist, &rx_vec, rx_lpf,
 				   INRATE, OUTRATE, OUTCHUNK);
 	/* Truncate */
 	trunc_vec = segment(resamp_vec, INHISTORY,
                            resamp_vec->size() - INHISTORY);
 	/* Convert */
 	num_resmpld = sigvec_to_float(trunc_vec, smpls_out);
 	return num_resmpld; 
 }
 /* Wrapper for transmit-side float-to-int array resampling */
 int tx_resmpl_flt_int(short *smpls_out, float *smpls_in, int num_smpls)
 {
 	int num_resmpl, num_chunks;
 	signalVector *convert_vec, *resamp_vec;
 	if (!tx_lpf || !tx_vec || !tx_hist)
 		init_resampler(&tx_lpf, &tx_vec, &tx_hist, true);
 	/* Convert and add samples to the transmit buffer */
 	convert_vec = float_to_sigvec(smpls_in, num_smpls);
 	tx_vec = concat(tx_vec, convert_vec);
 	num_chunks = tx_vec->size() / INCHUNK;
 	if (num_chunks < 1)
 		return 0;
 	/* Resample and convert to an integer array */
 	resamp_vec = resmpl_sigvec(tx_hist, &tx_vec, tx_lpf,
 				   OUTRATE, INRATE, INCHUNK);
 	num_resmpl = sigvec_to_short(resamp_vec, smpls_out);
 	return num_resmpl; 
 }
 /* Receive a timestamped chunk from the device */ 
 void RadioInterface::pullBuffer()
 {
 	int num_cv, num_rd;
 	bool local_underrun;
 	/* Read samples. Fail if we don't get what we want. */
 	num_rd = mRadio->readSamples(rx_buf, OUTCHUNK, &overrun,
 				     readTimestamp, &local_underrun);
 	LOG(DEBUG) << "Rx read " << num_rd << " samples from device";
 	assert(num_rd == OUTCHUNK);
 	underrun |= local_underrun;
 	readTimestamp += (TIMESTAMP) num_rd;
 	/* Convert and resample */
 	num_cv = rx_resmpl_int_flt(rcvBuffer + 2 * rcvCursor,
 				   rx_buf, num_rd);
 	LOG(DEBUG) << "Rx read " << num_cv << " samples from resampler";
 	rcvCursor += num_cv;
 }
 /* Send a timestamped chunk to the device */ 
 void RadioInterface::pushBuffer()
 {
 	int num_cv, num_wr;
 	if (sendCursor < INCHUNK)
 		return;
 	LOG(DEBUG) << "Tx wrote " << sendCursor << " samples to resampler";
 	/* Resample and convert */
 	num_cv = tx_resmpl_flt_int(tx_buf, sendBuffer, sendCursor);
 	assert(num_cv > sendCursor);
 	/* Write samples. Fail if we don't get what we want. */
 	num_wr = mRadio->writeSamples(tx_buf + OUTHISTORY * 2,
 				      num_cv - OUTHISTORY,
 				      &underrun,
 				      writeTimestamp);
 	LOG(DEBUG) << "Tx wrote " << num_wr << " samples to device";
 	assert(num_wr == num_wr);
 	writeTimestamp += (TIMESTAMP) num_wr;
 	sendCursor = 0;
 }
--- a/Transceiver52M/radioInterface.cpp
+++ b/Transceiver52M/radioInterface.cpp
@@ -1,5 +1,5 @@
 /*
-* Copyright 2008, 2009 Free Software Foundation, Inc.
+* Copyright 2008, 2009, 2012 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.
@@ -25,25 +25,43 @@
 #include "radioInterface.h"
 #include <Logger.h>
 extern "C" {
 #include "convert.h"
 }
 bool started = false;
 /* Device side buffers */
 static short *rx_buf[CHAN_MAX];
 static short *tx_buf[CHAN_MAX];
 RadioInterface::RadioInterface(RadioDevice *wRadio,
 			       int wChanM,
 			       int wSPS,
                               int wReceiveOffset,
 			       int wRadioOversampling,
 			       int wTransceiverOversampling,
 			       GSM::Time wStartTime)
-  : underrun(false), sendCursor(0), rcvCursor(0), mOn(false),
+  : mChanM(wChanM), underrun(false), sendCursor(0), rcvCursor(0), mOn(false),
-    mRadio(wRadio), receiveOffset(wReceiveOffset),
+    mRadio(wRadio), receiveOffset(wReceiveOffset), sps(wSPS),
-    samplesPerSymbol(wRadioOversampling), powerScaling(1.0),
+    powerScaling(1.0), loadTest(false)
    loadTest(false)
 {
  mClock.set(wStartTime);
 }
 RadioInterface::~RadioInterface(void)
 {
  if (mOn) {
    mRadio->stop();
    close();
-RadioInterface::~RadioInterface(void) {
+    delete mAlignRadioServiceLoopThread;
-  if (rcvBuffer!=NULL) delete rcvBuffer;
+
-  //mReceiveFIFO.clear();
+    for (int i = 0; i < mChanM; i++) {
      if (rcvBuffer[i] != NULL)
        delete rcvBuffer[i];
      if (sendBuffer[i] != NULL)
        delete sendBuffer[i];
    }
  }
 }
 double RadioInterface::fullScaleInputValue(void) {
@@ -55,11 +73,11 @@ double RadioInterface::fullScaleOutputValue(void) {
 }
-void RadioInterface::setPowerAttenuation(double atten)
+void RadioInterface::setPowerAttenuation(double atten, int chan)
 {
  double rfGain, digAtten;
-  rfGain = mRadio->setTxGain(mRadio->maxTxGain() - atten);
+  rfGain = mRadio->setTxGain(mRadio->maxTxGain() - atten, chan);
  digAtten = atten - mRadio->maxTxGain() + rfGain;
  if (digAtten < 1.0)
@@ -90,53 +108,75 @@ int RadioInterface::radioifyVector(signalVector &wVector,
  return wVector.size();
 }
-int RadioInterface::unRadioifyVector(float *floatVector,
+int RadioInterface::unRadioifyVector(float *floatVector, int offset,
-				     signalVector& newVector)
+				     signalVector &newVector)
 {
  int i;
  signalVector::iterator itr = newVector.begin();
  for (i = 0; i < newVector.size(); i++) {
-    *itr++ = Complex<float>(floatVector[2 * i + 0],
+    *itr++ = Complex<float>(floatVector[offset + 2 * i + 0],
-			    floatVector[2 * i + 1]);
+			    floatVector[offset + 2 * i + 1]);
  }
  return newVector.size();
 }
-bool RadioInterface::tuneTx(double freq)
+bool RadioInterface::tuneTx(double freq, int chan)
 {
-  return mRadio->setTxFreq(freq);
+  return mRadio->setTxFreq(freq, chan);
 }
-bool RadioInterface::tuneRx(double freq)
+bool RadioInterface::tuneRx(double freq, int chan)
 {
-  return mRadio->setRxFreq(freq);
+  return mRadio->setRxFreq(freq, chan);
 }
-void RadioInterface::start()
+bool RadioInterface::start()
 {
-  LOG(INFO) << "starting radio interface...";
+  int i;
-  mAlignRadioServiceLoopThread.start((void * (*)(void*))AlignRadioServiceLoopAdapter,
+
  if (mOn)
    return false;
  mOn = true;
 #ifdef USRP1
  mAlignRadioServiceLoopThread = new Thread(32768);
  mAlignRadioServiceLoopThread->start((void * (*)(void*))AlignRadioServiceLoopAdapter,
                                      (void*)this);
 #endif
  writeTimestamp = mRadio->initialWriteTimestamp();
  readTimestamp = mRadio->initialReadTimestamp();
  for (i = 0; i < mChanM; i++) {
    sendBuffer[i] = new float[8*2*INCHUNK];
    rcvBuffer[i] = new float[8*2*OUTCHUNK];
  }
  /* Init I/O specific variables if applicable */ 
  init();
  mRadio->start(); 
  LOG(DEBUG) << "Radio started";
  mRadio->updateAlignment(writeTimestamp-10000); 
  mRadio->updateAlignment(writeTimestamp-10000);
-  sendBuffer = new float[2*2*INCHUNK*samplesPerSymbol];
+  return true;
  rcvBuffer = new float[2*2*OUTCHUNK*samplesPerSymbol];
  mOn = true;
 }
 bool RadioInterface::stop()
 {
  if (!mOn)
    return false;
  mOn = false;
  mRadio->stop();
 }
 #ifdef USRP1
 void *AlignRadioServiceLoopAdapter(RadioInterface *radioInterface)
 {
-  while (1) {
+  while (radioInterface->on()) {
    radioInterface->alignRadio();
    pthread_testcancel();
  }
@@ -147,23 +187,55 @@ void RadioInterface::alignRadio() {
  sleep(60);
  mRadio->updateAlignment(writeTimestamp+ (TIMESTAMP) 10000);
 }
 #endif
-void RadioInterface::driveTransmitRadio(signalVector &radioBurst, bool zeroBurst) {
+void RadioInterface::driveTransmitRadio(signalVector **radioBurst, bool *zeroBurst)
 {
  int i;
-  if (!mOn) return;
+  if (!mOn)
    return;
-  radioifyVector(radioBurst, sendBuffer + 2 * sendCursor, powerScaling, zeroBurst);
+  for (i = 0; i < mChanM; i++) {
    radioifyVector(*radioBurst[i], sendBuffer[i] + 2 * sendCursor,
                   powerScaling, zeroBurst[i]);
  }
-  sendCursor += radioBurst.size();
+  /* 
   * All bursts should be the same size since all transceivers are
   * tied with a single clock in the radio interface.
   */
  sendCursor += radioBurst[0]->size();
  pushBuffer();
 }
-void RadioInterface::driveReceiveRadio() {
+static inline void shiftRxBuffers(float **buf, int offset, int len, int chanM)
 {
  for (int i = 0; i < chanM; i++)
      memmove(buf[i], buf[i] + offset, sizeof(float) * len);
 }
-  if (!mOn) return;
+void RadioInterface::loadVectors(unsigned tN, int samplesPerBurst,
                                 int idx, GSM::Time rxClock)
 {
  int i;
-  if (mReceiveFIFO.size() > 8) return;
+  for (i = 0; i < mChanM; i++) {
    signalVector rxVector(samplesPerBurst);
    unRadioifyVector(rcvBuffer[i], idx * 2, rxVector);
    radioVector *rxBurst = new radioVector(rxVector, rxClock);
    mReceiveFIFO[i].write(rxBurst);
  }
 }
 void RadioInterface::driveReceiveRadio()
 {
  if (!mOn)
    return;
  if (mReceiveFIFO[0].size() > 8)
    return;
  pullBuffer();
@@ -173,71 +245,98 @@ void RadioInterface::driveReceiveRadio() {
  int rcvSz = rcvCursor;
  int readSz = 0;
  const int symbolsPerSlot = gSlotLen + 8;
  int samplesPerBurst = (symbolsPerSlot + (tN % 4 == 0)) * sps;
  // 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) {
+  while (rcvSz >= samplesPerBurst) { 
    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();
+      loadVectors(tN, samplesPerBurst, readSz, rcvClock);
      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 += samplesPerBurst;
-    readSz += (symbolsPerSlot+(tN % 4 == 0))*samplesPerSymbol;
+    rcvSz -= samplesPerBurst;
    rcvSz -= (symbolsPerSlot+(tN % 4 == 0))*samplesPerSymbol;
    tN = rcvClock.TN();
    samplesPerBurst = (symbolsPerSlot + (tN % 4 == 0)) * sps;
  }
  if (readSz > 0) {
    rcvCursor -= readSz;
-    memmove(rcvBuffer,rcvBuffer+2*readSz,sizeof(float) * 2 * rcvCursor);
+    shiftRxBuffers(rcvBuffer, 2 * readSz, 2 * rcvCursor, mChanM);
  }
 }
-bool RadioInterface::isUnderrun()
+double RadioInterface::setRxGain(double dB, int chan)
 {
  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);
+    return mRadio->setRxGain(dB, chan);
  else
    return -1;
 }
-double RadioInterface::getRxGain()
+double RadioInterface::getRxGain(int chan)
 {
  if (mRadio)
-    return mRadio->getRxGain();
+    return mRadio->getRxGain(chan);
  else
    return -1;
 }
 bool RadioInterface::init()
 {
 	for (int i = 0; i < CHAN_MAX; i++) {
 		rx_buf[i] = new short[2 * OUTCHUNK];
 		tx_buf[i] = new short[4 * 2 * INCHUNK];
 	}
 }
 void RadioInterface::close()
 {
 	for (int i = 0; i < CHAN_MAX; i++) {
 		delete rx_buf[i];
 		delete tx_buf[i];
 	}
 }
 /* Receive a timestamped chunk from the device */ 
 void RadioInterface::pullBuffer()
 {
  bool local_underrun;
  /* Read samples. Fail if we don't get what we want. */
  int num_rd = mRadio->readSamples(rx_buf, mChanM, OUTCHUNK, readTimestamp);
  LOG(DEBUG) << "Rx read " << num_rd << " samples from device";
  assert(num_rd == OUTCHUNK);
  underrun |= local_underrun;
  readTimestamp += (TIMESTAMP) num_rd;
  for (int i = 0; i < mChanM; i++)
    convert_short_float(rcvBuffer[i] + 2 * rcvCursor, rx_buf[i], num_rd * 2);
  rcvCursor += num_rd;
 }
 /* Send timestamped chunk to the device with arbitrary size */ 
 void RadioInterface::pushBuffer()
 {
  if (sendCursor < INCHUNK)
    return;
  for (int i = 0; i < mChanM; i++)
    convert_float_short(tx_buf[i], sendBuffer[i], 1.0, sendCursor * 2);
  /* Write samples. Fail if we don't get what we want. */
  int num_smpls = mRadio->writeSamples(tx_buf, mChanM, sendCursor,
                                       writeTimestamp, &underrun);
  assert(num_smpls == sendCursor);
  writeTimestamp += (TIMESTAMP) num_smpls;
  sendCursor = 0;
 }
--- a/Transceiver52M/radioInterface.h
+++ b/Transceiver52M/radioInterface.h
@@ -1,5 +1,5 @@
 /*
-* Copyright 2008 Free Software Foundation, Inc.
+* Copyright 2008, 2012 Free Software Foundation, Inc.
 *
 * This software is distributed under multiple licenses; see the COPYING file in the main directory for licensing information for this specific distribuion.
 *
@@ -12,7 +12,8 @@
 */
-
+#ifndef _RADIOINTEFACE_H_
 #define _RADIOINTEFACE_H_
 #include "sigProcLib.h"  
 #include "GSMCommon.h"
@@ -22,27 +23,30 @@
 #include "radioClock.h"
 /** samples per GSM symbol */
-#define SAMPSPERSYM 1 
+#define SAMPSPERSYM 4
 #define INCHUNK    (625)
 #define OUTCHUNK   (625)
 #define CHAN_MAX    2
 static const unsigned gSlotLen = 148;      ///< number of symbols per slot, not counting guard periods
 /** class to interface the transceiver with the USRP */
 class RadioInterface {
-private:
+protected:
-  Thread mAlignRadioServiceLoopThread;	      ///< thread that synchronizes transmit and receive sections
+  int mChanM;                                 ///< channelizer width
  Thread *mAlignRadioServiceLoopThread;	      ///< thread that synchronizes transmit and receive sections
-  VectorFIFO  mReceiveFIFO;		      ///< FIFO that holds receive  bursts
+  VectorFIFO mReceiveFIFO[CHAN_MAX];	      ///< FIFO that holds receive  bursts
  RadioDevice *mRadio;			      ///< the USRP object
-  float *sendBuffer;
+  float *sendBuffer[CHAN_MAX];
  unsigned sendCursor;
-  float *rcvBuffer;
+  float *rcvBuffer[CHAN_MAX];
  unsigned rcvCursor;
  bool underrun;			      ///< indicates writes to USRP are too slow
@@ -52,10 +56,8 @@ private:
  RadioClock mClock;                          ///< the basestation clock!
-  int samplesPerSymbol;			      ///< samples per GSM symbol
+  int sps;                                    ///< samples per GSM symbol
  int receiveOffset;                          ///< offset b/w transmit and receive GSM timestamps, in timeslots
  int mRadioOversampling;
  int mTransceiverOversampling;
  bool mOn;				      ///< indicates radio is on
@@ -65,6 +67,10 @@ private:
  int mNumARFCNs;
  signalVector *finalVec, *finalVec9;
 private:
  /** initialize I/O internals */
  bool init();
  /** format samples to USRP */ 
  int radioifyVector(signalVector &wVector,
                     float *floatVector,
@@ -72,64 +78,67 @@ private:
                     bool zero);
  /** format samples from USRP */
-  int unRadioifyVector(float *floatVector, signalVector &wVector);
+  int unRadioifyVector(float *floatVector, int offset, signalVector &wVector);
  /** push GSM bursts into the transmit buffer */
-  void pushBuffer(void);
+  virtual void pushBuffer(void);
  /** pull GSM bursts from the receive buffer */
-  void pullBuffer(void);
+  virtual void pullBuffer(void);
  /** load receive vectors into FIFO's */
  void loadVectors(unsigned tN, int samplesPerBurst, int index, GSM::Time rxClock);
 public:
  /** start the interface */
-  void start();
+  bool start();
  bool stop();
  bool started() { return mOn; };
  /** shutdown interface */
  void close();
  /** constructor */
-  RadioInterface(RadioDevice* wRadio = NULL,
+  RadioInterface(RadioDevice* wRadio,
 		 int wChanM = 1,
 		 int wSPS = SAMPSPERSYM,
                 int receiveOffset = 3,
-		 int wRadioOversampling = SAMPSPERSYM,
+		 GSM::Time wStartTime = GSM::Time(0, 0));
 		 int wTransceiverOversampling = SAMPSPERSYM,
 		 GSM::Time wStartTime = GSM::Time(0));
  /** destructor */
  ~RadioInterface();
-  void setSamplesPerSymbol(int wSamplesPerSymbol) {if (!mOn) samplesPerSymbol = wSamplesPerSymbol;}
+  void setSamplesPerSymbol(int sps) {if (!mOn) this->sps = sps;}
-  int getSamplesPerSymbol() { return samplesPerSymbol;}
+  int getSamplesPerSymbol() { return sps;}
  /** check for underrun, resets underrun value */
  bool isUnderrun();
  /** attach an existing USRP to this interface */
  void attach(RadioDevice *wRadio, int wRadioOversampling);
  /** return the receive FIFO */
-  VectorFIFO* receiveFIFO() { return &mReceiveFIFO;}
+  VectorFIFO* receiveFIFO(int num) { return &mReceiveFIFO[num];}
  /** return the basestation clock */
  RadioClock* getClock(void) { return &mClock;};
  /** set transmit frequency */
-  bool tuneTx(double freq);
+  bool tuneTx(double freq, int chan = 0);
  /** set receive frequency */
-  bool tuneRx(double freq);
+  bool tuneRx(double freq, int chan = 0);
  /** set receive gain */
-  double setRxGain(double dB);
+  double setRxGain(double dB, int chan = 0);
  /** get receive gain */
-  double getRxGain(void);
+  double getRxGain(int chan = 0);
  /** drive transmission of GSM bursts */
-  void driveTransmitRadio(signalVector &radioBurst, bool zeroBurst);
+  void driveTransmitRadio(signalVector **radioBurst, bool *zeroBurst);
  /** drive reception of GSM bursts */
  void driveReceiveRadio();
-  void setPowerAttenuation(double atten);
+  void setPowerAttenuation(double atten, int chan = 0);
  /** returns the full-scale transmit amplitude **/
  double fullScaleInputValue();
@@ -140,20 +149,8 @@ public:
  /** set thread priority on current thread */
  void setPriority() { mRadio->setPriority(); }
-  /** get transport bus type of attached device */ 
+  /** get transport window type of attached device */ 
-  enum RadioDevice::busType getBus() { return mRadio->getBus(); }
+  enum RadioDevice::TxWindowType getWindowType() { return mRadio->getWindowType(); }
 protected:
  /** drive synchronization of Tx/Rx of USRP */
  void alignRadio();
  /** reset the interface */
  void reset();
  friend void *AlignRadioServiceLoopAdapter(RadioInterface*);
 };
-/** synchronization thread loop */
+#endif /* _RADIOINTEFACE_H_ */
 void *AlignRadioServiceLoopAdapter(RadioInterface*);
--- a/Transceiver52M/radioVector.cpp
+++ b/Transceiver52M/radioVector.cpp
@@ -2,7 +2,7 @@
 * Written by Thomas Tsou <ttsou@vt.edu>
 * Based on code by Harvind S Samra <hssamra@kestrelsp.com>
 *
- * Copyright 2011 Free Software Foundation, Inc.
+ * Copyright 2011, 2012 Free Software Foundation, Inc.
 *
 * 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
@@ -41,21 +41,6 @@ bool radioVector::operator>(const radioVector& other) const
 	return mTime > other.mTime;
 }
 unsigned VectorFIFO::size()
 {
 	return mQ.size();
 }
 void VectorFIFO::put(radioVector *ptr)
 {
 	mQ.put((void*) ptr);
 }
 radioVector *VectorFIFO::get()
 {
 	return (radioVector*) mQ.get();
 }
 GSM::Time VectorQueue::nextTime() const
 {
 	GSM::Time retVal;
--- a/Transceiver52M/radioVector.h
+++ b/Transceiver52M/radioVector.h
@@ -2,7 +2,7 @@
 * Written by Thomas Tsou <ttsou@vt.edu>
 * Based on code by Harvind S Samra <hssamra@kestrelsp.com>
 *
- * Copyright 2011 Free Software Foundation, Inc.
+ * Copyright 2011, 2012 Free Software Foundation, Inc.
 *
 * 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
@@ -37,14 +37,7 @@ private:
 	GSM::Time mTime;
 };
-class VectorFIFO {
+class VectorFIFO : public InterthreadQueue<radioVector> {
 public:
 	unsigned size();
 	void put(radioVector *ptr);
 	radioVector *get();
 private:
 	PointerFIFO mQ;
 };
 class VectorQueue : public InterthreadPriorityQueue<radioVector> {
--- a/Transceiver52M/runTransceiver.cpp
+++ b/Transceiver52M/runTransceiver.cpp
@@ -28,6 +28,7 @@
 #include "Transceiver.h"
 #include "radioDevice.h"
 #include "DummyLoad.h"
 #include <fstream>
 #include <time.h>
 #include <signal.h>
@@ -36,28 +37,90 @@
 #include <Logger.h>
 #include <Configuration.h>
-#ifdef RESAMPLE
+#define CONFIGDB            "/etc/OpenBTS/OpenBTS.db"
  #define DEVICERATE 400e3
 #else
  #define DEVICERATE 1625e3/6 
 #endif
 using namespace std;
-ConfigurationTable gConfig("/etc/OpenBTS/OpenBTS.db");
+ConfigurationTable gConfig(CONFIGDB);
 volatile bool gbShutdown = false;
 static void ctrlCHandler(int signo)
 {
   cout << "Received shutdown signal" << endl;;
   gbShutdown = true;
 }
 /*
 * Attempt to open and test the database file before
 * accessing the configuration table. We do this because
 * the global table constructor cannot provide notification
 * in the event of failure.
 */
 int testConfig(const char *filename)
 {
  int rc, val = 9999;
  bool status;
  sqlite3 *db;
  std::string result;
  std::string test = "sadf732zdvj2";
  const char *keys[3] = {
    "Log.Level",
    "TRX.Port",
    "TRX.IP",
  };
  /* Check for file existence */
  std::ifstream file(filename);
  if (!file.good()) {
    std::cerr << "Config: File not readable \""
              << filename << "\"" << std::endl;
    return -1;
  } else {
    file.close();
  }
  /* Try to open the database  */
  rc = sqlite3_open(filename, &db);
  if (rc || !db) {
    std::cerr << "Config: Database could not be opened" << std::endl;
    return -1;
  } else {
    sqlite3_close(db);
  }
  /* Attempt to set a value in the global config */
  if (!gConfig.set(test, val)) {
    std::cerr << "Config: Failed to set test key - "
              << "permission to access the database?" << std::endl;
    return -1;
  } else {
    gConfig.remove(test);
  }
  /* Attempt to query */
  for (int i = 0; i < 3; i++) {
    try {
      result = gConfig.getStr(keys[i]); 
    } catch (...) {
      std::cerr << "Config: Failed query on " << keys[i] << std::endl;
      return -1;
    }
  }
  return 0; 
 }
 int main(int argc, char *argv[])
 {
-  std::string deviceArgs;
+  int trxPort;
  std::string deviceArgs, logLevel, trxAddr, txAntenna, rxAntenna;
  RadioDevice *usrp;
  RadioInterface* radio;
  DriveLoop *drive;
  Transceiver *trx;
  if (argc == 3)
  {
@@ -79,63 +142,70 @@ int main(int argc, char *argv[])
    cerr << "Couldn't install signal handler for SIGTERM" << endl;
    exit(1);
  }
  // Configure logger.
-  gLogInit("transceiver",gConfig.getStr("Log.Level").c_str(),LOG_LOCAL7);
+  if (testConfig(CONFIGDB) < 0) {
    std::cerr << "Config: Database failure" << std::endl;
    return EXIT_FAILURE;
  }
-  int numARFCN=1;
+  logLevel = gConfig.getStr("Log.Level");
  trxPort = gConfig.getNum("TRX.Port");
  trxAddr = gConfig.getStr("TRX.IP");
  gLogInit("transceiver", logLevel.c_str(), LOG_LOCAL7);
-  LOG(NOTICE) << "starting transceiver with " << numARFCN << " ARFCNs (argc=" << argc << ")";
+  if (gConfig.defines("GSM.Radio.TxAntenna"))
    txAntenna = gConfig.getStr("GSM.Radio.TxAntenna").c_str();
  if (gConfig.defines("GSM.Radio.RxAntenna"))
    rxAntenna = gConfig.getStr("GSM.Radio.RxAntenna").c_str();
  if (txAntenna != "")  
    usrp->setTxAntenna(txAntenna);
  if (rxAntenna != "")  
    usrp->setRxAntenna(rxAntenna);
  LOG(INFO) << "transceiver using transmit antenna " << usrp->getRxAntenna();
  LOG(INFO) << "transceiver using receive antenna " << usrp->getTxAntenna();
  srandom(time(NULL));
-  int mOversamplingRate = numARFCN/2 + numARFCN;
+  usrp = RadioDevice::make(SAMPSPERSYM);
-  RadioDevice *usrp = RadioDevice::make(DEVICERATE * SAMPSPERSYM);
+  int radioType = usrp->open(deviceArgs);
-  if (!usrp->open(deviceArgs)) {
+  if (radioType < 0) {
    LOG(ALERT) << "Transceiver exiting..." << std::endl;
    return EXIT_FAILURE;
  }
-  RadioInterface* radio = new RadioInterface(usrp,3,SAMPSPERSYM,mOversamplingRate,false);
+  switch (radioType) {
-  Transceiver *trx = new Transceiver(gConfig.getNum("TRX.Port"),gConfig.getStr("TRX.IP").c_str(),SAMPSPERSYM,GSM::Time(3,0),radio);
+  case RadioDevice::NORMAL:
-  trx->receiveFIFO(radio->receiveFIFO());
+    radio = new RadioInterface(usrp, 3, SAMPSPERSYM, false);
-/*
+    break;
-  signalVector *gsmPulse = generateGSMPulse(2,1);
+  case RadioDevice::RESAMP:
-  BitVector normalBurstSeg = "0000101010100111110010101010010110101110011000111001101010000";
+  default:
-  BitVector normalBurst(BitVector(normalBurstSeg,gTrainingSequence[0]),normalBurstSeg);
+    LOG(ALERT) << "Unsupported configuration";
-  signalVector *modBurst = modulateBurst(normalBurst,*gsmPulse,8,1);
+    return EXIT_FAILURE;
  signalVector *modBurst9 = modulateBurst(normalBurst,*gsmPulse,9,1);
  signalVector *interpolationFilter = createLPF(0.6/mOversamplingRate,6*mOversamplingRate,1);
  signalVector totalBurst1(*modBurst,*modBurst9);
  signalVector totalBurst2(*modBurst,*modBurst);
  signalVector totalBurst(totalBurst1,totalBurst2);
  scaleVector(totalBurst,usrp->fullScaleInputValue());
  double beaconFreq = -1.0*(numARFCN-1)*200e3;
  signalVector finalVec(625*mOversamplingRate);
  for (int j = 0; j < numARFCN; j++) {
 	signalVector *frequencyShifter = new signalVector(625*mOversamplingRate);
 	frequencyShifter->fill(1.0);
 	frequencyShift(frequencyShifter,frequencyShifter,2.0*M_PI*(beaconFreq+j*400e3)/(1625.0e3/6.0*mOversamplingRate));
  	signalVector *interpVec = polyphaseResampleVector(totalBurst,mOversamplingRate,1,interpolationFilter);
 	multVector(*interpVec,*frequencyShifter);
 	addVector(finalVec,*interpVec); 	
  }
-  signalVector::iterator itr = finalVec.begin();
+
-  short finalVecShort[2*finalVec.size()];
+  drive = new DriveLoop(SAMPSPERSYM, GSM::Time(3,0), radio);
-  short *shortItr = finalVecShort;
+  if (!drive->init()) {
-  while (itr < finalVec.end()) {
+    LOG(ALERT) << "Failed to initialize drive loop";
 	*shortItr++ = (short) (itr->real());
 	*shortItr++ = (short) (itr->imag());
 	itr++;
  }
-  usrp->loadBurst(finalVecShort,finalVec.size());
+
-*/
+  trx = new Transceiver(trxPort, trxAddr.c_str(), SAMPSPERSYM, radio, drive, 0);
  radio->activateChan(0);
  if (!trx->init()) {
    LOG(ALERT) << "Failed to initialize transceiver";
  }
  trx->start();
-  //int i = 0;
+
-  while(!gbShutdown) { sleep(1); }//i++; if (i==60) break;}
+  while (!gbShutdown)
    sleep(1);
  cout << "Shutting down transceiver..." << endl;
  trx->shutdown();
 //  trx->stop();
  delete trx;
-//  delete radio;
+  delete drive;
  delete radio;
 }
--- a/Transceiver52M/sigProcLib.cpp
+++ b/Transceiver52M/sigProcLib.cpp
--- a/Transceiver52M/sigProcLib.h
+++ b/Transceiver52M/sigProcLib.h
@@ -27,13 +27,10 @@ enum Symmetry {
 /** Convolution type indicator */
 enum ConvType {
-  FULL_SPAN = 0,
+  START_ONLY,
-  OVERLAP_ONLY = 1,
+  NO_DELAY,
-  START_ONLY = 2,
+  CUSTOM,
-  WITH_TAIL = 3,
+  UNDEFINED,
  NO_DELAY = 4,
  CUSTOM = 5,
  UNDEFINED = 255
 };
 /** the core data structure of the Transceiver */
@@ -44,13 +41,14 @@ class signalVector: public Vector<complex>
  Symmetry symmetry;   ///< the symmetry of the vector
  bool realOnly;       ///< true if vector is real-valued, not complex-valued
  bool aligned;
 public:
  /** Constructors */
  signalVector(int dSize=0, Symmetry wSymmetry = NONE):
    Vector<complex>(dSize),
-    realOnly(false)
+    realOnly(false), aligned(false)
    { 
      symmetry = wSymmetry; 
    };
@@ -58,26 +56,45 @@ class signalVector: public Vector<complex>
  signalVector(complex* wData, size_t start, 
 	       size_t span, Symmetry wSymmetry = NONE):
    Vector<complex>(NULL,wData+start,wData+start+span),
-    realOnly(false)
+    realOnly(false), aligned(false)
    { 
      symmetry = wSymmetry; 
    };
  signalVector(const signalVector &vec1, const signalVector &vec2):
    Vector<complex>(vec1,vec2),
-    realOnly(false)
+    realOnly(false), aligned(false)
    { 
      symmetry = vec1.symmetry; 
    };
  signalVector(const signalVector &wVector):
    Vector<complex>(wVector.size()),
-    realOnly(false)
+    realOnly(false), aligned(false)
    {
      wVector.copyTo(*this); 
      symmetry = wVector.getSymmetry();
    };
  signalVector(size_t size, size_t start):
    Vector<complex>(size + start),
    realOnly(false), aligned(false)
    {
      mStart = mData + start;
      symmetry = NONE;
    };
  signalVector(const signalVector &wVector, size_t start, size_t tail = 0):
    Vector<complex>(start + wVector.size() + tail),
    realOnly(false), aligned(false)
    {
      mStart = mData + start;
      wVector.copyTo(*this);
      memset(mData, 0, start * sizeof(complex));
      memset(mStart + wVector.size(), 0, tail * sizeof(complex));
      symmetry = NONE;
    };
  /** symmetry operators */
  Symmetry getSymmetry() const { return symmetry;};
  void setSymmetry(Symmetry wSymmetry) { symmetry = wSymmetry;}; 
@@ -85,6 +102,10 @@ class signalVector: public Vector<complex>
  /** real-valued operators */
  bool isRealOnly() const { return realOnly;};
  void isRealOnly(bool wOnly) { realOnly = wOnly;};
  /** alignment markers */
  bool isAligned() const { return aligned; };
  void setAligned(bool aligned) { this->aligned = aligned; };
 };
 /** Convert a linear number to a dB value */
@@ -100,7 +121,7 @@ float vectorNorm2(const signalVector &x);
 float vectorPower(const signalVector &x);
 /** Setup the signal processing library */
-void sigProcLibSetup(int samplesPerSymbol);
+bool sigProcLibSetup(int sps);
 /** Destroy the signal processing library */
 void sigProcLibDestroy(void);
@@ -110,23 +131,23 @@ void sigProcLibDestroy(void);
 	@param a,b The vectors to be convolved.
 	@param c, A preallocated vector to hold the convolution result.
 	@param spanType The type/span of the convolution.
-	@return The convolution result.
+	@return The convolution result or NULL on error.
 */
-signalVector* convolve(const signalVector *a,
+signalVector *convolve(const signalVector *a,
                       const signalVector *b,
                       signalVector *c,
                       ConvType spanType,
-		       unsigned startIx = 0,
+                       int start = 0,
-		       unsigned len = 0);
+                       unsigned len = 0,
                       unsigned step = 1, int offset = 0);
 /** 
 	Generate the GSM pulse. 
-	@param samplesPerSymbol The number of samples per GSM symbol.
+	@param sps The number of samples per GSM symbol.
 	@param symbolLength The size of the pulse.
 	@return The GSM pulse.
 */
-signalVector* generateGSMPulse(int samplesPerSymbol,
+void generateGSMPulse(int sps, int symbolLength);
 			       int symbolLength);
 /** 
        Frequency shift a vector.
@@ -163,16 +184,14 @@ bool vectorSlicer(signalVector *x);
 /** GMSK modulate a GSM burst of bits */
 signalVector *modulateBurst(const BitVector &wBurst,
 			    const signalVector &gsmPulse,
 			    int guardPeriodLength,
-			    int samplesPerSymbol);
+			    int sps, bool emptyPulse = false);
 /** Sinc function */
 float sinc(float x);
 /** Delay a vector */
-void delayVector(signalVector &wBurst,
+bool delayVector(signalVector &wBurst, float delay);
 		 float delay);
 /** Add two vectors in-place */
 bool addVector(signalVector &x,
@@ -226,21 +245,18 @@ void offsetVector(signalVector &x,
 /**
        Generate a modulated GSM midamble, stored within the library.
        @param gsmPulse The GSM pulse used for modulation.
-        @param samplesPerSymbol The number of samples per GSM symbol.
+        @param sps The number of samples per GSM symbol.
        @param TSC The training sequence [0..7]
        @return Success.
 */
-bool generateMidamble(signalVector &gsmPulse,
+bool generateMidamble(int sps, int tsc);
 		      int samplesPerSymbol,
 		      int TSC);
 /**
        Generate a modulated RACH sequence, stored within the library.
        @param gsmPulse The GSM pulse used for modulation.
-        @param samplesPerSymbol The number of samples per GSM symbol.
+        @param sps The number of samples per GSM symbol.
        @return Success.
 */
-bool generateRACHSequence(signalVector &gsmPulse,
+bool generateRACHSequence(int sps);
 			  int samplesPerSymbol);
 /**
        Energy detector, checks to see if received burst energy is above a threshold.
@@ -259,14 +275,14 @@ bool energyDetect(signalVector &rxBurst,
        RACH correlator/detector.
        @param rxBurst The received GSM burst of interest.
        @param detectThreshold The threshold that the received burst's post-correlator SNR is compared against to determine validity.
-        @param samplesPerSymbol The number of samples per GSM symbol.
+        @param sps The number of samples per GSM symbol.
        @param amplitude The estimated amplitude of received RACH burst.
        @param TOA The estimate time-of-arrival of received RACH burst.
-        @return True if burst SNR is larger that the detectThreshold value.
+        @return positive if threshold value is reached, negative on error, zero otherwise
 */
-bool detectRACHBurst(signalVector &rxBurst,
+int detectRACHBurst(signalVector &rxBurst,
                    float detectThreshold,
-		     int samplesPerSymbol,
+                    int sps,
                    complex *amplitude,
                    float* TOA);
@@ -275,19 +291,19 @@ bool detectRACHBurst(signalVector &rxBurst,
        @param rxBurst The received GSM burst of interest.
        @param detectThreshold The threshold that the received burst's post-correlator SNR is compared against to determine validity.
-        @param samplesPerSymbol The number of samples per GSM symbol.
+        @param sps The number of samples per GSM symbol.
        @param amplitude The estimated amplitude of received TSC burst.
        @param TOA The estimate time-of-arrival of received TSC burst.
        @param maxTOA The maximum expected time-of-arrival
        @param requestChannel Set to true if channel estimation is desired.
        @param channelResponse The estimated channel.
        @param channelResponseOffset The time offset b/w the first sample of the channel response and the reported TOA.
-        @return True if burst SNR is larger that the detectThreshold value.
+        @return positive if threshold value is reached, negative on error, zero otherwise
 */
-bool analyzeTrafficBurst(signalVector &rxBurst,
+int analyzeTrafficBurst(signalVector &rxBurst,
 			unsigned TSC,
 			float detectThreshold,
-			 int samplesPerSymbol,
+			int sps,
 			complex *amplitude,
 			float *TOA,
                        unsigned maxTOA,
@@ -308,16 +324,13 @@ signalVector *decimateVector(signalVector &wVector,
        Demodulates a received burst using a soft-slicer.
 	@param rxBurst The burst to be demodulated.
        @param gsmPulse The GSM pulse.
-        @param samplesPerSymbol The number of samples per GSM symbol.
+        @param sps The number of samples per GSM symbol.
        @param channel The amplitude estimate of the received burst.
        @param TOA The time-of-arrival of the received burst.
        @return The demodulated bit sequence.
 */
-SoftVector *demodulateBurst(signalVector &rxBurst,
+SoftVector *demodulateBurst(signalVector &rxBurst, int sps,
-			 const signalVector &gsmPulse,
+                            complex channel, float TOA);
 			 int samplesPerSymbol,
 			 complex channel,
 			 float TOA);
 /**
        Creates a simple Kaiser-windowed low-pass FIR filter.
@@ -372,14 +385,14 @@ bool designDFE(signalVector &channelResponse,
 	Equalize/demodulate a received burst via a decision-feedback equalizer.
 	@param rxBurst The received burst to be demodulated.
 	@param TOA The time-of-arrival of the received burst.
-	@param samplesPerSymbol The number of samples per GSM symbol.
+	@param sps The number of samples per GSM symbol.
 	@param w The feed forward filter of the DFE.
 	@param b The feedback filter of the DFE.
 	@return The demodulated bit sequence.
 */
 SoftVector *equalizeBurst(signalVector &rxBurst,
 		       float TOA,
-		       int samplesPerSymbol,
+		       int sps,
 		       signalVector &w, 
 		       signalVector &b);
--- a/Transceiver52M/sigProcLibTest.cpp
+++ b/Transceiver52M/sigProcLibTest.cpp
@@ -1,170 +0,0 @@
 /*
 * Copyright 2011 Free Software Foundation, Inc.
 * Copyright 2008, 2010 Kestrel Signal Processing, 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 <http://www.gnu.org/licenses/>.
 */
 /*
 Contributors:
 Harvind S. Samra, hssamra@kestrelsp.com
 */
 #include "sigProcLib.h"
 //#include "radioInterface.h"
 #include <Logger.h>
 #include <Configuration.h>
 #include <GSMCommon.h>
 using namespace std;
 using namespace GSM;
 ConfigurationTable gConfig;
 int main(int argc, char **argv) {
  gLogInit("sigProcLibTest","DEBUG");
  int samplesPerSymbol = 1;
  int TSC = 2;
  sigProcLibSetup(samplesPerSymbol);
  signalVector *gsmPulse = generateGSMPulse(2,samplesPerSymbol);
  cout << *gsmPulse << endl;
  BitVector RACHBurstStart = "01010101";
  BitVector RACHBurstRest = "000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000";
  BitVector RACHBurst(BitVector(RACHBurstStart,gRACHSynchSequence),RACHBurstRest);
  signalVector *RACHSeq = modulateBurst(RACHBurst,
                                        *gsmPulse,
                                        9,
                                        samplesPerSymbol);
  generateRACHSequence(*gsmPulse,samplesPerSymbol);
  complex a; float t;
  detectRACHBurst(*RACHSeq, 5, samplesPerSymbol,&a,&t); 
  //cout << *RACHSeq << endl;
  //signalVector *autocorr = correlate(RACHSeq,RACHSeq,NULL,NO_DELAY);
  //cout << *autocorr;
  //exit(1);
  /*signalVector x(6500);
  x.fill(1.0);
  frequencyShift(&x,&x,0.48*M_PI);
  signalVector *y = polyphaseResampleVector(x,96,65,NULL);
  cout << *y << endl;
  exit(1);*/
  //CommSig normalBurstSeg = "0000000000000000000000000000000000000000000000000000000000000";
  BitVector normalBurstSeg = "0000101010100111110010101010010110101110011000111001101010000";
  BitVector normalBurst(BitVector(normalBurstSeg,gTrainingSequence[TSC]),normalBurstSeg);
  generateMidamble(*gsmPulse,samplesPerSymbol,TSC);
  signalVector *modBurst = modulateBurst(normalBurst,*gsmPulse,
                                         0,samplesPerSymbol);
  //delayVector(*rsVector2,6.932);
  complex ampl = 1;
  float TOA = 0;
  //modBurst = rsVector2;
  //delayVector(*modBurst,0.8);
  /*
  signalVector channelResponse(4);
  signalVector::iterator c=channelResponse.begin();
  *c = (complex) 9000.0; c++;
  *c = (complex) 0.4*9000.0; c++; c++;
  *c = (complex) -1.2*0;
  signalVector *guhBurst = convolve(modBurst,&channelResponse,NULL,NO_DELAY);
  delete modBurst; modBurst = guhBurst;
  */
  signalVector *chanResp;
  /*
  double noisePwr = 0.001/sqrtf(2);
  signalVector *noise = gaussianNoise(modBurst->size(),noisePwr);
  */
  float chanRespOffset;
  analyzeTrafficBurst(*modBurst,TSC,8.0,samplesPerSymbol,&ampl,&TOA,1,true,&chanResp,&chanRespOffset);
  //addVector(*modBurst,*noise);
  cout << "ampl:" << ampl << endl;
  cout << "TOA: " << TOA << endl;
  //cout << "chanResp: " << *chanResp << endl;
  SoftVector *demodBurst = demodulateBurst(*modBurst,*gsmPulse,samplesPerSymbol,(complex) ampl, TOA);
  cout << *demodBurst << endl;
  /*
  COUT("chanResp: " << *chanResp);
  signalVector *w,*b;
  designDFE(*chanResp,1.0/noisePwr,7,&w,&b); 
  COUT("w: " << *w);
  COUT("b: " << *b);
  SoftSig *DFEBurst = equalizeBurst(*modBurst,TOA-chanRespOffset,samplesPerSymbol,*w,*b);
  COUT("DFEBurst: " << *DFEBurst);
  delete gsmPulse;
  delete RACHSeq;
  delete modBurst;
  delete sendLPF;
  delete rcvLPF;
  delete rsVector;
  //delete rsVector2;
  delete autocorr;
  delete chanResp;
  delete noise;
  delete demodBurst;
  delete w;
  delete b;
  delete DFEBurst;  
  */
  sigProcLibDestroy();
 }
--- a/config/ax_check_compile_flag.m4
+++ b/config/ax_check_compile_flag.m4
@@ -0,0 +1,72 @@
 # ===========================================================================
 #   http://www.gnu.org/software/autoconf-archive/ax_check_compile_flag.html
 # ===========================================================================
 #
 # SYNOPSIS
 #
 #   AX_CHECK_COMPILE_FLAG(FLAG, [ACTION-SUCCESS], [ACTION-FAILURE], [EXTRA-FLAGS])
 #
 # DESCRIPTION
 #
 #   Check whether the given FLAG works with the current language's compiler
 #   or gives an error.  (Warnings, however, are ignored)
 #
 #   ACTION-SUCCESS/ACTION-FAILURE are shell commands to execute on
 #   success/failure.
 #
 #   If EXTRA-FLAGS is defined, it is added to the current language's default
 #   flags (e.g. CFLAGS) when the check is done.  The check is thus made with
 #   the flags: "CFLAGS EXTRA-FLAGS FLAG".  This can for example be used to
 #   force the compiler to issue an error when a bad flag is given.
 #
 #   NOTE: Implementation based on AX_CFLAGS_GCC_OPTION. Please keep this
 #   macro in sync with AX_CHECK_{PREPROC,LINK}_FLAG.
 #
 # LICENSE
 #
 #   Copyright (c) 2008 Guido U. Draheim <guidod@gmx.de>
 #   Copyright (c) 2011 Maarten Bosmans <mkbosmans@gmail.com>
 #
 #   This program is free software: you can redistribute it and/or modify it
 #   under the terms of the GNU 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 General
 #   Public License for more details.
 #
 #   You should have received a copy of the GNU General Public License along
 #   with this program. If not, see <http://www.gnu.org/licenses/>.
 #
 #   As a special exception, the respective Autoconf Macro's copyright owner
 #   gives unlimited permission to copy, distribute and modify the configure
 #   scripts that are the output of Autoconf when processing the Macro. You
 #   need not follow the terms of the GNU General Public License when using
 #   or distributing such scripts, even though portions of the text of the
 #   Macro appear in them. The GNU General Public License (GPL) does govern
 #   all other use of the material that constitutes the Autoconf Macro.
 #
 #   This special exception to the GPL applies to versions of the Autoconf
 #   Macro released by the Autoconf Archive. When you make and distribute a
 #   modified version of the Autoconf Macro, you may extend this special
 #   exception to the GPL to apply to your modified version as well.
 #serial 2
 AC_DEFUN([AX_CHECK_COMPILE_FLAG],
 [AC_PREREQ(2.59)dnl for _AC_LANG_PREFIX
 AS_VAR_PUSHDEF([CACHEVAR],[ax_cv_check_[]_AC_LANG_ABBREV[]flags_$4_$1])dnl
 AC_CACHE_CHECK([whether _AC_LANG compiler accepts $1], CACHEVAR, [
  ax_check_save_flags=$[]_AC_LANG_PREFIX[]FLAGS
  _AC_LANG_PREFIX[]FLAGS="$[]_AC_LANG_PREFIX[]FLAGS $4 $1"
  AC_COMPILE_IFELSE([AC_LANG_PROGRAM()],
    [AS_VAR_SET(CACHEVAR,[yes])],
    [AS_VAR_SET(CACHEVAR,[no])])
  _AC_LANG_PREFIX[]FLAGS=$ax_check_save_flags])
 AS_IF([test x"AS_VAR_GET(CACHEVAR)" = xyes],
  [m4_default([$2], :)],
  [m4_default([$3], :)])
 AS_VAR_POPDEF([CACHEVAR])dnl
 ])dnl AX_CHECK_COMPILE_FLAGS
--- a/config/ax_ext.m4
+++ b/config/ax_ext.m4
@@ -0,0 +1,221 @@
 # ===========================================================================
 #          http://www.gnu.org/software/autoconf-archive/ax_ext.html
 # ===========================================================================
 #
 # SYNOPSIS
 #
 #   AX_EXT
 #
 # DESCRIPTION
 #
 #   Find supported SIMD extensions by requesting cpuid. When an SIMD
 #   extension is found, the -m"simdextensionname" is added to SIMD_FLAGS if
 #   compiler supports it. For example, if "sse2" is available, then "-msse2"
 #   is added to SIMD_FLAGS.
 #
 #   This macro calls:
 #
 #     AC_SUBST(SIMD_FLAGS)
 #
 #   And defines:
 #
 #     HAVE_MMX / HAVE_SSE / HAVE_SSE2 / HAVE_SSE3 / HAVE_SSSE3 / HAVE_SSE4.1 / HAVE_SSE4.2 / HAVE_AVX
 #
 # LICENSE
 #
 #   Copyright (c) 2007 Christophe Tournayre <turn3r@users.sourceforge.net>
 #   Copyright (c) 2013 Michael Petch <mpetch@capp-sysware.com>
 #
 #   Copying and distribution of this file, with or without modification, are
 #   permitted in any medium without royalty provided the copyright notice
 #   and this notice are preserved. This file is offered as-is, without any
 #   warranty.
 #serial 12
 AC_DEFUN([AX_EXT],
 [
  AC_REQUIRE([AC_CANONICAL_HOST])
  case $host_cpu in
    i[[3456]]86*|x86_64*|amd64*)
      AC_REQUIRE([AX_GCC_X86_CPUID])
      AC_REQUIRE([AX_GCC_X86_AVX_XGETBV])
      AX_GCC_X86_CPUID(0x00000001)
      ecx=`echo $ax_cv_gcc_x86_cpuid_0x00000001 | cut -d ":" -f 3`
      edx=`echo $ax_cv_gcc_x86_cpuid_0x00000001 | cut -d ":" -f 4`
      AC_CACHE_CHECK([whether mmx is supported], [ax_cv_have_mmx_ext],
      [
        ax_cv_have_mmx_ext=no
        if test "$((0x$edx>>23&0x01))" = 1; then
          ax_cv_have_mmx_ext=yes
        fi
      ])
      AC_CACHE_CHECK([whether sse is supported], [ax_cv_have_sse_ext],
      [
        ax_cv_have_sse_ext=no
        if test "$((0x$edx>>25&0x01))" = 1; then
          ax_cv_have_sse_ext=yes
        fi
      ])
      AC_CACHE_CHECK([whether sse2 is supported], [ax_cv_have_sse2_ext],
      [
        ax_cv_have_sse2_ext=no
        if test "$((0x$edx>>26&0x01))" = 1; then
          ax_cv_have_sse2_ext=yes
        fi
      ])
      AC_CACHE_CHECK([whether sse3 is supported], [ax_cv_have_sse3_ext],
      [
        ax_cv_have_sse3_ext=no
        if test "$((0x$ecx&0x01))" = 1; then
          ax_cv_have_sse3_ext=yes
        fi
      ])
      AC_CACHE_CHECK([whether ssse3 is supported], [ax_cv_have_ssse3_ext],
      [
        ax_cv_have_ssse3_ext=no
        if test "$((0x$ecx>>9&0x01))" = 1; then
          ax_cv_have_ssse3_ext=yes
        fi
      ])
      AC_CACHE_CHECK([whether sse4.1 is supported], [ax_cv_have_sse41_ext],
      [
        ax_cv_have_sse41_ext=no
        if test "$((0x$ecx>>19&0x01))" = 1; then
          ax_cv_have_sse41_ext=yes
        fi
      ])
      AC_CACHE_CHECK([whether sse4.2 is supported], [ax_cv_have_sse42_ext],
      [
        ax_cv_have_sse42_ext=no
        if test "$((0x$ecx>>20&0x01))" = 1; then
          ax_cv_have_sse42_ext=yes
        fi
      ])
      AC_CACHE_CHECK([whether avx is supported by processor], [ax_cv_have_avx_cpu_ext],
      [
        ax_cv_have_avx_cpu_ext=no
        if test "$((0x$ecx>>28&0x01))" = 1; then
          ax_cv_have_avx_cpu_ext=yes
        fi
      ])
      if test x"$ax_cv_have_avx_cpu_ext" = x"yes"; then
        AX_GCC_X86_AVX_XGETBV(0x00000000)
        xgetbv_eax="0"
        if test x"$ax_cv_gcc_x86_avx_xgetbv_0x00000000" != x"unknown"; then
          xgetbv_eax=`echo $ax_cv_gcc_x86_avx_xgetbv_0x00000000 | cut -d ":" -f 1`
        fi
        AC_CACHE_CHECK([whether avx is supported by operating system], [ax_cv_have_avx_ext],
        [
          ax_cv_have_avx_ext=no
          if test "$((0x$ecx>>27&0x01))" = 1; then
            if test "$((0x$xgetbv_eax&0x6))" = 6; then
              ax_cv_have_avx_ext=yes
            fi
          fi
        ])
        if test x"$ax_cv_have_avx_ext" = x"no"; then
          AC_MSG_WARN([Your processor supports AVX, but your operating system doesn't])
        fi
      fi
      if test "$ax_cv_have_mmx_ext" = yes; then
        AX_CHECK_COMPILE_FLAG(-mmmx, ax_cv_support_mmx_ext=yes, [])
        if test x"$ax_cv_support_mmx_ext" = x"yes"; then
          SIMD_FLAGS="$SIMD_FLAGS -mmmx"
          AC_DEFINE(HAVE_MMX,,[Support mmx instructions])
        else
          AC_MSG_WARN([Your processor supports mmx instructions but not your compiler, can you try another compiler?])
        fi
      fi
      if test "$ax_cv_have_sse_ext" = yes; then
        AX_CHECK_COMPILE_FLAG(-msse, ax_cv_support_sse_ext=yes, [])
        if test x"$ax_cv_support_sse_ext" = x"yes"; then
          SIMD_FLAGS="$SIMD_FLAGS -msse"
          AC_DEFINE(HAVE_SSE,,[Support SSE (Streaming SIMD Extensions) instructions])
        else
          AC_MSG_WARN([Your processor supports sse instructions but not your compiler, can you try another compiler?])
        fi
      fi
      if test "$ax_cv_have_sse2_ext" = yes; then
        AX_CHECK_COMPILE_FLAG(-msse2, ax_cv_support_sse2_ext=yes, [])
        if test x"$ax_cv_support_sse2_ext" = x"yes"; then
          SIMD_FLAGS="$SIMD_FLAGS -msse2"
          AC_DEFINE(HAVE_SSE2,,[Support SSE2 (Streaming SIMD Extensions 2) instructions])
        else
          AC_MSG_WARN([Your processor supports sse2 instructions but not your compiler, can you try another compiler?])
        fi
      fi
      if test "$ax_cv_have_sse3_ext" = yes; then
        AX_CHECK_COMPILE_FLAG(-msse3, ax_cv_support_sse3_ext=yes, [])
        if test x"$ax_cv_support_sse3_ext" = x"yes"; then
          SIMD_FLAGS="$SIMD_FLAGS -msse3"
          AC_DEFINE(HAVE_SSE3,,[Support SSE3 (Streaming SIMD Extensions 3) instructions])
        else
          AC_MSG_WARN([Your processor supports sse3 instructions but not your compiler, can you try another compiler?])
        fi
      fi
      if test "$ax_cv_have_ssse3_ext" = yes; then
        AX_CHECK_COMPILE_FLAG(-mssse3, ax_cv_support_ssse3_ext=yes, [])
        if test x"$ax_cv_support_ssse3_ext" = x"yes"; then
          SIMD_FLAGS="$SIMD_FLAGS -mssse3"
          AC_DEFINE(HAVE_SSSE3,,[Support SSSE3 (Supplemental Streaming SIMD Extensions 3) instructions])
        else
          AC_MSG_WARN([Your processor supports ssse3 instructions but not your compiler, can you try another compiler?])
        fi
      fi
      if test "$ax_cv_have_sse41_ext" = yes; then
        AX_CHECK_COMPILE_FLAG(-msse4.1, ax_cv_support_sse41_ext=yes, [])
        if test x"$ax_cv_support_sse41_ext" = x"yes"; then
          SIMD_FLAGS="$SIMD_FLAGS -msse4.1"
          AC_DEFINE(HAVE_SSE4_1,,[Support SSSE4.1 (Streaming SIMD Extensions 4.1) instructions])
        else
          AC_MSG_WARN([Your processor supports sse4.1 instructions but not your compiler, can you try another compiler?])
        fi
      fi
      if test "$ax_cv_have_sse42_ext" = yes; then
        AX_CHECK_COMPILE_FLAG(-msse4.2, ax_cv_support_sse42_ext=yes, [])
        if test x"$ax_cv_support_sse42_ext" = x"yes"; then
          SIMD_FLAGS="$SIMD_FLAGS -msse4.2"
          AC_DEFINE(HAVE_SSE4_2,,[Support SSSE4.2 (Streaming SIMD Extensions 4.2) instructions])
        else
          AC_MSG_WARN([Your processor supports sse4.2 instructions but not your compiler, can you try another compiler?])
        fi
      fi
      if test "$ax_cv_have_avx_ext" = yes; then
        AX_CHECK_COMPILE_FLAG(-mavx, ax_cv_support_avx_ext=yes, [])
        if test x"$ax_cv_support_avx_ext" = x"yes"; then
          SIMD_FLAGS="$SIMD_FLAGS -mavx"
          AC_DEFINE(HAVE_AVX,,[Support AVX (Advanced Vector Extensions) instructions])
        else
          AC_MSG_WARN([Your processor supports avx instructions but not your compiler, can you try another compiler?])
        fi
      fi
  ;;
  esac
  AC_SUBST(SIMD_FLAGS)
 ])
--- a/config/ax_gcc_x86_avx_xgetbv.m4
+++ b/config/ax_gcc_x86_avx_xgetbv.m4
@@ -0,0 +1,79 @@
 # ===========================================================================
 #   http://www.gnu.org/software/autoconf-archive/ax_gcc_x86_avx_xgetbv.html
 # ===========================================================================
 #
 # SYNOPSIS
 #
 #   AX_GCC_X86_AVX_XGETBV
 #
 # DESCRIPTION
 #
 #   On later x86 processors with AVX SIMD support, with gcc or a compiler
 #   that has a compatible syntax for inline assembly instructions, run a
 #   small program that executes the xgetbv instruction with input OP. This
 #   can be used to detect if the OS supports AVX instruction usage.
 #
 #   On output, the values of the eax and edx registers are stored as
 #   hexadecimal strings as "eax:edx" in the cache variable
 #   ax_cv_gcc_x86_avx_xgetbv.
 #
 #   If the xgetbv instruction fails (because you are running a
 #   cross-compiler, or because you are not using gcc, or because you are on
 #   a processor that doesn't have this instruction),
 #   ax_cv_gcc_x86_avx_xgetbv_OP is set to the string "unknown".
 #
 #   This macro mainly exists to be used in AX_EXT.
 #
 # LICENSE
 #
 #   Copyright (c) 2013 Michael Petch <mpetch@capp-sysware.com>
 #
 #   This program is free software: you can redistribute it and/or modify it
 #   under the terms of the GNU 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 General
 #   Public License for more details.
 #
 #   You should have received a copy of the GNU General Public License along
 #   with this program. If not, see <http://www.gnu.org/licenses/>.
 #
 #   As a special exception, the respective Autoconf Macro's copyright owner
 #   gives unlimited permission to copy, distribute and modify the configure
 #   scripts that are the output of Autoconf when processing the Macro. You
 #   need not follow the terms of the GNU General Public License when using
 #   or distributing such scripts, even though portions of the text of the
 #   Macro appear in them. The GNU General Public License (GPL) does govern
 #   all other use of the material that constitutes the Autoconf Macro.
 #
 #   This special exception to the GPL applies to versions of the Autoconf
 #   Macro released by the Autoconf Archive. When you make and distribute a
 #   modified version of the Autoconf Macro, you may extend this special
 #   exception to the GPL to apply to your modified version as well.
 #serial 1
 AC_DEFUN([AX_GCC_X86_AVX_XGETBV],
 [AC_REQUIRE([AC_PROG_CC])
 AC_LANG_PUSH([C])
 AC_CACHE_CHECK(for x86-AVX xgetbv $1 output, ax_cv_gcc_x86_avx_xgetbv_$1,
 [AC_RUN_IFELSE([AC_LANG_PROGRAM([#include <stdio.h>], [
     int op = $1, eax, edx;
     FILE *f;
      /* Opcodes for xgetbv */
      __asm__(".byte 0x0f, 0x01, 0xd0"
        : "=a" (eax), "=d" (edx)
        : "c" (op));
     f = fopen("conftest_xgetbv", "w"); if (!f) return 1;
     fprintf(f, "%x:%x\n", eax, edx);
     fclose(f);
     return 0;
 ])],
     [ax_cv_gcc_x86_avx_xgetbv_$1=`cat conftest_xgetbv`; rm -f conftest_xgetbv],
     [ax_cv_gcc_x86_avx_xgetbv_$1=unknown; rm -f conftest_xgetbv],
     [ax_cv_gcc_x86_avx_xgetbv_$1=unknown])])
 AC_LANG_POP([C])
 ])
--- a/config/ax_gcc_x86_cpuid.m4
+++ b/config/ax_gcc_x86_cpuid.m4
@@ -0,0 +1,79 @@
 # ===========================================================================
 #     http://www.gnu.org/software/autoconf-archive/ax_gcc_x86_cpuid.html
 # ===========================================================================
 #
 # SYNOPSIS
 #
 #   AX_GCC_X86_CPUID(OP)
 #
 # DESCRIPTION
 #
 #   On Pentium and later x86 processors, with gcc or a compiler that has a
 #   compatible syntax for inline assembly instructions, run a small program
 #   that executes the cpuid instruction with input OP. This can be used to
 #   detect the CPU type.
 #
 #   On output, the values of the eax, ebx, ecx, and edx registers are stored
 #   as hexadecimal strings as "eax:ebx:ecx:edx" in the cache variable
 #   ax_cv_gcc_x86_cpuid_OP.
 #
 #   If the cpuid instruction fails (because you are running a
 #   cross-compiler, or because you are not using gcc, or because you are on
 #   a processor that doesn't have this instruction), ax_cv_gcc_x86_cpuid_OP
 #   is set to the string "unknown".
 #
 #   This macro mainly exists to be used in AX_GCC_ARCHFLAG.
 #
 # LICENSE
 #
 #   Copyright (c) 2008 Steven G. Johnson <stevenj@alum.mit.edu>
 #   Copyright (c) 2008 Matteo Frigo
 #
 #   This program is free software: you can redistribute it and/or modify it
 #   under the terms of the GNU 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 General
 #   Public License for more details.
 #
 #   You should have received a copy of the GNU General Public License along
 #   with this program. If not, see <http://www.gnu.org/licenses/>.
 #
 #   As a special exception, the respective Autoconf Macro's copyright owner
 #   gives unlimited permission to copy, distribute and modify the configure
 #   scripts that are the output of Autoconf when processing the Macro. You
 #   need not follow the terms of the GNU General Public License when using
 #   or distributing such scripts, even though portions of the text of the
 #   Macro appear in them. The GNU General Public License (GPL) does govern
 #   all other use of the material that constitutes the Autoconf Macro.
 #
 #   This special exception to the GPL applies to versions of the Autoconf
 #   Macro released by the Autoconf Archive. When you make and distribute a
 #   modified version of the Autoconf Macro, you may extend this special
 #   exception to the GPL to apply to your modified version as well.
 #serial 7
 AC_DEFUN([AX_GCC_X86_CPUID],
 [AC_REQUIRE([AC_PROG_CC])
 AC_LANG_PUSH([C])
 AC_CACHE_CHECK(for x86 cpuid $1 output, ax_cv_gcc_x86_cpuid_$1,
 [AC_RUN_IFELSE([AC_LANG_PROGRAM([#include <stdio.h>], [
     int op = $1, eax, ebx, ecx, edx;
     FILE *f;
      __asm__("cpuid"
        : "=a" (eax), "=b" (ebx), "=c" (ecx), "=d" (edx)
        : "a" (op));
     f = fopen("conftest_cpuid", "w"); if (!f) return 1;
     fprintf(f, "%x:%x:%x:%x\n", eax, ebx, ecx, edx);
     fclose(f);
     return 0;
 ])],
     [ax_cv_gcc_x86_cpuid_$1=`cat conftest_cpuid`; rm -f conftest_cpuid],
     [ax_cv_gcc_x86_cpuid_$1=unknown; rm -f conftest_cpuid],
     [ax_cv_gcc_x86_cpuid_$1=unknown])])
 AC_LANG_POP([C])
 ])
--- a/configure.ac
+++ b/configure.ac
@@ -22,6 +22,7 @@ AC_INIT(openbts,P2.8TRUNK)
 AC_PREREQ(2.57)
 AC_CONFIG_SRCDIR([Transceiver52M/Makefile.am])
 AC_CONFIG_AUX_DIR([.])	
 AC_CONFIG_MACRO_DIR([config])
 AM_CONFIG_HEADER(config.h)
 AC_CANONICAL_BUILD
@@ -72,11 +73,6 @@ AC_ARG_WITH(singledb, [
        [enable single daughterboard use on USRP1])
 ])
 AC_ARG_WITH(resamp, [
    AS_HELP_STRING([--with-resamp],
        [enable resampling for non-52MHz devices])
 ])
 AC_ARG_WITH(extref, [
    AS_HELP_STRING([--with-extref],
        [enable external reference on UHD devices])
@@ -98,12 +94,10 @@ AS_IF([test "x$with_usrp1" = "xyes"], [
 ])
 AS_IF([test "x$with_uhd" = "xyes"],[
-    PKG_CHECK_MODULES(UHD, uhd >= 003.002.000)
+    PKG_CHECK_MODULES(UHD, uhd >= 003.004.000)
    AC_DEFINE(USE_UHD, 1, Define to 1 if using UHD)
-])
+    # Find and define supported SIMD extensions
-
+    AX_EXT
 AS_IF([test "x$with_resamp" = "xyes"], [
    AC_DEFINE(RESAMPLE, 1, Define to 1 for resampling)
 ])
 AS_IF([test "x$with_extref" = "xyes"], [
@@ -114,7 +108,6 @@ AS_IF([test "x$with_singledb" = "xyes"], [
    AC_DEFINE(SINGLEDB, 1, Define to 1 for single daughterboard)
 ])
 AM_CONDITIONAL(RESAMPLE, [test "x$with_resamp" = "xyes"])
 AM_CONDITIONAL(UHD, [test "x$with_uhd" = "xyes"])
 AM_CONDITIONAL(USRP1, [test "x$with_usrp1" = "xyes"])