Ejemplo n.º 1
0
void LALTfrWv (LALStatus *stat, REAL4Vector* sig, TimeFreqRep *tfr, TimeFreqParam *param)
{

  INT4    nf;
  INT4    time;
  INT4    column, row;
  INT4    taumax, tau;
  REAL4Vector  *lacf = NULL;      /* local autocorrelation function */
  COMPLEX8Vector  *vtmp = NULL;
  RealFFTPlan  *plan = NULL;

  INITSTATUS(stat);
  ATTATCHSTATUSPTR (stat);

  /* Make sure the arguments are not NULL: */
  ASSERT (sig, stat, TFR_ENULL, TFR_MSGENULL);
  ASSERT (tfr, stat, TFR_ENULL, TFR_MSGENULL);
  ASSERT (param, stat, TFR_ENULL, TFR_MSGENULL);

  /* Make sure the data pointers are not NULL: */
  ASSERT (sig->data, stat, TFR_ENULL, TFR_MSGENULL);
  ASSERT (tfr->timeInstant, stat, TFR_ENULL, TFR_MSGENULL);
  ASSERT (tfr->freqBin, stat, TFR_ENULL, TFR_MSGENULL);
  ASSERT (tfr->map, stat, TFR_ENULL, TFR_MSGENULL);

  /* Make sure the requested TFR type corresponds to what will be done */
  ASSERT (tfr->type == WignerVille , stat, TFR_ENAME, TFR_MSGENAME);
  ASSERT (param->type == WignerVille , stat, TFR_ENAME, TFR_MSGENAME);

  /* Make sure the number of freq bins is a positive number: */
  nf = tfr->fRow;
  ASSERT (nf > 0 , stat, TFR_EFROW, TFR_MSGEFROW);

  /* Make sure the number of freq bins is a power of 2: */
  while(!(nf & 1))
      nf = nf>>1;

  ASSERT (nf == 1, stat, TFR_EFROW, TFR_MSGEFROW);

  /* Make sure the timeInstant indicates existing time instants */
  for (column=0 ; column<tfr->tCol ; column++)
    {
      if ((tfr->timeInstant[column] < 0) || (tfr->timeInstant[column] > (INT4)(sig->length-1)))
	{
	  ASSERT (tfr->timeInstant[column] > 0, stat, TFR_EBADT, TFR_MSGEBADT);
	  ASSERT (tfr->timeInstant[column] < (INT4)sig->length, stat, TFR_EBADT, TFR_MSGEBADT);
	}
    }
    TRY(LALCreateForwardRealFFTPlan(stat->statusPtr, &plan,(UINT4)tfr->fRow,0),stat);

  TRY(LALSCreateVector(stat->statusPtr, &lacf, tfr->fRow), stat);
  TRY(LALCCreateVector(stat->statusPtr, &vtmp, tfr->fRow/2+1), stat);

  for (column = 0; column < tfr->tCol; column++)
    {

      for (row = 0; row < tfr->fRow; row++)
	lacf->data[row] = 0.0;

      time = tfr->timeInstant[column];
      taumax = MIN (time, (INT4)(sig->length -1 - time));
      taumax = MIN (taumax, (tfr->fRow / 2 - 1));

      for (tau = -taumax; tau <= taumax; tau++)
	{
	  row = (tfr->fRow+tau)%tfr->fRow;
	  lacf->data[row] =   sig->data[time + tau]*sig->data[time - tau];
        }

      tau=tfr->fRow/2;
      if ((time<=(INT4)sig->length-tau-1)&(time>=tau))
	lacf->data[tau] =  sig->data[time+tau]*sig->data[time-tau];

      LALForwardRealFFT(stat->statusPtr, vtmp, lacf, plan);

      for (row = 0; row < (tfr->fRow/2+1); row++)
	tfr->map[column][row] = crealf(vtmp->data[row]);

    }
  /* Reflecting frequency halfing in WV distrob so multiply by 1/2 */
  for (row = 0; row < (tfr->fRow/2+1) ; row++)
    tfr->freqBin[row] = (REAL4) row / (2 *tfr->fRow);

  TRY(LALSDestroyVector(stat->statusPtr, &lacf), stat);
  TRY(LALCDestroyVector(stat->statusPtr, &vtmp), stat);

  TRY(LALDestroyRealFFTPlan(stat->statusPtr, &plan), stat);

  DETATCHSTATUSPTR (stat);

  (void)param;

  /* normal exit */
  RETURN (stat);
}
Ejemplo n.º 2
0
/* Actually, we don't need it -- JTW
struct tagRealFFTPlan
{
  INT4  sign;
  UINT4 size;
  void* junk;
};
*/
int
main( int argc, char *argv[] )
{

   static LALStatus         status;

   UINT4      i;
   REAL8      f;


   const REAL4    testInputDataData[SZEROPADANDFFTTESTC_LENGTH]
                     = {1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0};

   COMPLEX8 expectedOutputDataData[SZEROPADANDFFTTESTC_LENGTH]
                     = {crectf(+3.600000000000000e+01, 0.0),
                        crectf(-1.094039137097177e+01, -2.279368601990178e+01),
                        crectf(+3.693524635113721e-01, +9.326003289238411e+00),
                        crectf(-8.090169943749448e-01, -7.918722831227928e+00),
                        crectf(+3.502214272222959e-01, +5.268737078678177e+00),
                        crectf(+5.329070518200751e-15, -5.196152422706625e+00),
                        crectf(+3.090169943749475e-01, +4.306254604896173e+00),
                        crectf(+2.208174802380956e-01, -4.325962305777781e+00)};

   REAL4TimeSeries             goodInput;
   COMPLEX8FrequencySeries     goodOutput;

   int                    result;
   LALUnit                expectedUnit;
   CHAR                   unitString[LALUnitTextSize];

   SZeroPadAndFFTParameters   goodParams;


   goodParams.window = NULL;
   goodParams.fftPlan = NULL;
   goodParams.length = SZEROPADANDFFTTESTC_FULLLENGTH;

   /* build window */
   goodParams.window = XLALCreateRectangularREAL4Window(SZEROPADANDFFTTESTC_LENGTH);
#ifndef LAL_NDEBUG
   SZeroPadAndFFTParameters badParams = goodParams;
#endif

   /* Fill in expected output */

   for (i=0; i<SZEROPADANDFFTTESTC_LENGTH; ++i)
   {
     expectedOutputDataData[i] *= SZEROPADANDFFTTESTC_DELTAT;
   }

   ParseOptions( argc, argv );

   /* TEST INVALID DATA HERE ------------------------------------------- */

   /* define valid parameters */
   goodInput.f0                   = 0.0;
   goodInput.deltaT               = SZEROPADANDFFTTESTC_DELTAT;
   goodInput.epoch.gpsSeconds     = SZEROPADANDFFTTESTC_EPOCHSEC;
   goodInput.epoch.gpsNanoSeconds = SZEROPADANDFFTTESTC_EPOCHNS;
   goodInput.data                 = NULL;
   goodOutput.data                = NULL;

#ifndef LAL_NDEBUG
   REAL4TimeSeries badInput = goodInput;
   COMPLEX8FrequencySeries badOutput = goodOutput;
#endif

   /* construct plan */
   LALCreateForwardRealFFTPlan(&status, &(goodParams.fftPlan),
			       SZEROPADANDFFTTESTC_FULLLENGTH,
			       SZEROPADANDFFTTESTC_FALSE);
   if ( ( code = CheckStatus( &status, 0 , "",
			      SZEROPADANDFFTTESTC_EFLS,
			      SZEROPADANDFFTTESTC_MSGEFLS ) ) )
   {
     return code;
   }
   /* allocate input and output vectors */
   LALSCreateVector(&status, &(goodInput.data), SZEROPADANDFFTTESTC_LENGTH);
   if ( ( code = CheckStatus( &status, 0 , "",
			      SZEROPADANDFFTTESTC_EFLS,
			      SZEROPADANDFFTTESTC_MSGEFLS ) ) )
   {
     return code;
   }
   LALCCreateVector(&status, &(goodOutput.data), SZEROPADANDFFTTESTC_LENGTH);
   if ( ( code = CheckStatus( &status, 0 , "",
			      SZEROPADANDFFTTESTC_EFLS,
			      SZEROPADANDFFTTESTC_MSGEFLS ) ) )
   {
     return code;
   }

#ifndef LAL_NDEBUG
   if ( ! lalNoDebug )
   {
     /* test behavior for null pointer to output series */
     LALSZeroPadAndFFT(&status, NULL, &goodInput, &goodParams);
     if ( ( code = CheckStatus( &status, STOCHASTICCROSSCORRELATIONH_ENULLPTR,
				STOCHASTICCROSSCORRELATIONH_MSGENULLPTR,
				SZEROPADANDFFTTESTC_ECHK,
				SZEROPADANDFFTTESTC_MSGECHK ) ) )
     {
       return code;
     }
     printf("  PASS: null pointer to output series results in error:\n       \"%s\"\n", STOCHASTICCROSSCORRELATIONH_MSGENULLPTR);

     /* test behavior for null pointer to input series */
     LALSZeroPadAndFFT(&status, &goodOutput, NULL, &goodParams);
     if ( ( code = CheckStatus( &status, STOCHASTICCROSSCORRELATIONH_ENULLPTR,
				STOCHASTICCROSSCORRELATIONH_MSGENULLPTR,
				SZEROPADANDFFTTESTC_ECHK,
				SZEROPADANDFFTTESTC_MSGECHK ) ) )
     {
       return code;
     }
     printf("  PASS: null pointer to input series results in error:\n       \"%s\"\n", STOCHASTICCROSSCORRELATIONH_MSGENULLPTR);

     /* test behavior for null pointer to parameter structure */
     LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, NULL);
     if ( ( code = CheckStatus( &status, STOCHASTICCROSSCORRELATIONH_ENULLPTR,
				STOCHASTICCROSSCORRELATIONH_MSGENULLPTR,
				SZEROPADANDFFTTESTC_ECHK,
				SZEROPADANDFFTTESTC_MSGECHK ) ) )
     {
       return code;
     }
     printf("  PASS: null pointer to parameter structure results in error:\n       \"%s\"\n", STOCHASTICCROSSCORRELATIONH_MSGENULLPTR);

     /* test behavior for null pointer to FFT plan */
     badParams.fftPlan = NULL;
     LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, &badParams);
     if ( ( code = CheckStatus( &status, STOCHASTICCROSSCORRELATIONH_ENULLPTR,
				STOCHASTICCROSSCORRELATIONH_MSGENULLPTR,
				SZEROPADANDFFTTESTC_ECHK,
				SZEROPADANDFFTTESTC_MSGECHK ) ) )
     {
       return code;
     }
     printf("  PASS: null pointer to FFT plan results in error:\n       \"%s\"\n", STOCHASTICCROSSCORRELATIONH_MSGENULLPTR);
     badParams.fftPlan = goodParams.fftPlan;

     /* test behavior for null pointer to data member of output series */
     LALSZeroPadAndFFT(&status, &badOutput, &goodInput, &goodParams);
     if ( ( code = CheckStatus( &status, STOCHASTICCROSSCORRELATIONH_ENULLPTR,
				STOCHASTICCROSSCORRELATIONH_MSGENULLPTR,
				SZEROPADANDFFTTESTC_ECHK,
				SZEROPADANDFFTTESTC_MSGECHK ) ) )
     {
       return code;
     }
     printf("  PASS: null pointer to data member of output series results in error:\n       \"%s\"\n", STOCHASTICCROSSCORRELATIONH_MSGENULLPTR);

     /* test behavior for null pointer to data member of input series */
     LALSZeroPadAndFFT(&status, &goodOutput, &badInput, &goodParams);
     if ( ( code = CheckStatus( &status, STOCHASTICCROSSCORRELATIONH_ENULLPTR,
				STOCHASTICCROSSCORRELATIONH_MSGENULLPTR,
				SZEROPADANDFFTTESTC_ECHK,
				SZEROPADANDFFTTESTC_MSGECHK ) ) )
     {
       return code;
     }
     printf("  PASS: null pointer to data member of input series results in error:\n       \"%s\"\n", STOCHASTICCROSSCORRELATIONH_MSGENULLPTR);

     /* test behavior for null pointer to data member of data member of output series */
     LALCCreateVector(&status, &(badOutput.data), SZEROPADANDFFTTESTC_LENGTH);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }
     COMPLEX8                *cPtr;
     cPtr = badOutput.data->data;
     badOutput.data->data = NULL;
     LALSZeroPadAndFFT(&status, &badOutput, &goodInput, &goodParams);
     if ( ( code = CheckStatus( &status, STOCHASTICCROSSCORRELATIONH_ENULLPTR,
				STOCHASTICCROSSCORRELATIONH_MSGENULLPTR,
				SZEROPADANDFFTTESTC_ECHK,
				SZEROPADANDFFTTESTC_MSGECHK ) ) )
     {
       return code;
     }
     printf("  PASS: null pointer to data member of data member of output series results in error:\n       \"%s\"\n", STOCHASTICCROSSCORRELATIONH_MSGENULLPTR);
     badOutput.data->data = cPtr;
     LALCDestroyVector(&status, &(badOutput.data));
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }

     /* test behavior for null pointer to data member of data member of output series */
     LALSCreateVector(&status, &(badInput.data), SZEROPADANDFFTTESTC_LENGTH);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }
     REAL4                   *sPtr;
     sPtr = badInput.data->data;
     badInput.data->data = NULL;
     LALSZeroPadAndFFT(&status, &goodOutput, &badInput, &goodParams);
     if ( ( code = CheckStatus( &status, STOCHASTICCROSSCORRELATIONH_ENULLPTR,
				STOCHASTICCROSSCORRELATIONH_MSGENULLPTR,
				SZEROPADANDFFTTESTC_ECHK,
				SZEROPADANDFFTTESTC_MSGECHK ) ) )
     {
       return code;
     }
     printf("  PASS: null pointer to data member of data member of input series results in error:\n       \"%s\"\n", STOCHASTICCROSSCORRELATIONH_MSGENULLPTR);
     badInput.data->data = sPtr;
     LALSDestroyVector(&status, &(badInput.data));
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }

     /* test behavior for zero length */
     goodInput.data->length = goodOutput.data->length = 0;
     /* plan->size = -1; */
     LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, &goodParams);
     if ( ( code = CheckStatus(&status, STOCHASTICCROSSCORRELATIONH_EZEROLEN,
			       STOCHASTICCROSSCORRELATIONH_MSGEZEROLEN,
			       SZEROPADANDFFTTESTC_ECHK,
			       SZEROPADANDFFTTESTC_MSGECHK) ) )
     {
       return code;
     }
     printf("  PASS: zero length results in error:\n       \"%s\"\n",
            STOCHASTICCROSSCORRELATIONH_MSGEZEROLEN);
     /* reassign valid length */
     goodInput.data->length = goodOutput.data->length
       = SZEROPADANDFFTTESTC_LENGTH;
     /* plan->size = SZEROPADANDFFTTESTC_FULLLENGTH; */

     /* test behavior for negative time spacing */
     goodInput.deltaT = -SZEROPADANDFFTTESTC_DELTAT;
     LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, &goodParams);
     if ( ( code = CheckStatus(&status,
			       STOCHASTICCROSSCORRELATIONH_ENONPOSDELTAT,
			       STOCHASTICCROSSCORRELATIONH_MSGENONPOSDELTAT,
			       SZEROPADANDFFTTESTC_ECHK,
			       SZEROPADANDFFTTESTC_MSGECHK) ) )
     {
       return code;
     }
     printf("  PASS: negative time spacing results in error:\n       \"%s\"\n",
            STOCHASTICCROSSCORRELATIONH_MSGENONPOSDELTAT);

     /* test behavior for zero time spacing */
     goodInput.deltaT = 0;
     LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, &goodParams);
     if ( ( code = CheckStatus(&status,
			       STOCHASTICCROSSCORRELATIONH_ENONPOSDELTAT,
			       STOCHASTICCROSSCORRELATIONH_MSGENONPOSDELTAT,
			       SZEROPADANDFFTTESTC_ECHK,
			       SZEROPADANDFFTTESTC_MSGECHK) ) )
     {
       return code;
     }
     printf("  PASS: zero time spacing results in error:\n       \"%s\"\n",
            STOCHASTICCROSSCORRELATIONH_MSGENONPOSDELTAT);
     /* reassign valid time spacing */
     goodInput.deltaT = SZEROPADANDFFTTESTC_DELTAT;

   } /* if ( ! lalNoDebug ) */
#endif /* NDEBUG */

   /* test behavior for negative heterodyning frequency */
   goodInput.f0 = -100.0;
   LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, &goodParams);
   if ( ( code = CheckStatus(&status,
			     STOCHASTICCROSSCORRELATIONH_ENONZEROHETERO,
			     STOCHASTICCROSSCORRELATIONH_MSGENONZEROHETERO,
			     SZEROPADANDFFTTESTC_ECHK,
			     SZEROPADANDFFTTESTC_MSGECHK) ) )
   {
     return code;
   }
   printf("  PASS: negative heterodyning frequency results in error:\n       \"%s\"\n",
            STOCHASTICCROSSCORRELATIONH_MSGENONZEROHETERO);
   /* test behavior for positive heterodyning frequency */
   goodInput.f0 = 100.0;
   LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, &goodParams);
   if ( ( code = CheckStatus(&status,
			     STOCHASTICCROSSCORRELATIONH_ENONZEROHETERO,
			     STOCHASTICCROSSCORRELATIONH_MSGENONZEROHETERO,
			     SZEROPADANDFFTTESTC_ECHK,
			     SZEROPADANDFFTTESTC_MSGECHK) ) )
   {
     return code;
   }
   printf("  PASS: positive heterodyning frequency results in error:\n       \"%s\"\n",
          STOCHASTICCROSSCORRELATIONH_MSGENONZEROHETERO);
   goodInput.f0 = 0.0;

   /* test behavior for length mismatch between input series and output series */
   goodOutput.data->length = SZEROPADANDFFTTESTC_LENGTH + 1;
   LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, &goodParams);
   if ( ( code = CheckStatus(&status,
			     STOCHASTICCROSSCORRELATIONH_EMMLEN,
			     STOCHASTICCROSSCORRELATIONH_MSGEMMLEN,
			     SZEROPADANDFFTTESTC_ECHK,
			     SZEROPADANDFFTTESTC_MSGECHK) ) )
   {
     return code;
   }
   printf("  PASS: length mismatch between input series and output series results in error:\n       \"%s\"\n",
          STOCHASTICCROSSCORRELATIONH_MSGEMMLEN);
   goodOutput.data->length = SZEROPADANDFFTTESTC_LENGTH;

   /* TEST VALID DATA HERE --------------------------------------------- */

   /* fill input time-series parameters */
   strncpy(goodInput.name,"Dummy test data",LALNameLength);
   goodInput.sampleUnits  = lalDimensionlessUnit;
   goodInput.sampleUnits.unitNumerator[LALUnitIndexADCCount] = 1;

     /* fill input time-series data */
   for (i=0; i<SZEROPADANDFFTTESTC_LENGTH; ++i)
   {
     goodInput.data->data[i] = testInputDataData[i];
   }

   /* zero-pad and FFT */
   LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, &goodParams);
   if ( ( code = CheckStatus( &status, 0 , "",
			      SZEROPADANDFFTTESTC_EFLS,
			      SZEROPADANDFFTTESTC_MSGEFLS) ) )
   {
     return code;
   }

   /* check output f0 */
   if (optVerbose)
   {
     printf("f0=%g, should be 0\n", goodOutput.f0);
   }
   if (goodOutput.f0)
   {
     printf("  FAIL: Valid data test\n");
     if (optVerbose)
     {
       printf("Exiting with error: %s\n", SZEROPADANDFFTTESTC_MSGEFLS);
     }
     return SZEROPADANDFFTTESTC_EFLS;
   }

   /* check output deltaF */
   if (optVerbose)
   {
     printf("deltaF=%g, should be %g\n", goodOutput.deltaF,
            SZEROPADANDFFTTESTC_DELTAF);
   }
   if ( fabs(goodOutput.deltaF-SZEROPADANDFFTTESTC_DELTAF)
        / SZEROPADANDFFTTESTC_DELTAF > SZEROPADANDFFTTESTC_TOL )
   {
     printf("  FAIL: Valid data test\n");
     if (optVerbose)
     {
       printf("Exiting with error: %s\n", SZEROPADANDFFTTESTC_MSGEFLS);
     }
     return SZEROPADANDFFTTESTC_EFLS;
   }

   /* check output epoch */
   if (optVerbose)
   {
     printf("epoch=%d seconds, %d nanoseconds; should be %d seconds, %d nanoseconds\n",
            goodOutput.epoch.gpsSeconds, goodOutput.epoch.gpsNanoSeconds,
            SZEROPADANDFFTTESTC_EPOCHSEC, SZEROPADANDFFTTESTC_EPOCHNS);
   }
   if ( goodOutput.epoch.gpsSeconds != SZEROPADANDFFTTESTC_EPOCHSEC
        || goodOutput.epoch.gpsNanoSeconds != SZEROPADANDFFTTESTC_EPOCHNS )
   {
     printf("  FAIL: Valid data test\n");
     if (optVerbose)
     {
       printf("Exiting with error: %s\n", SZEROPADANDFFTTESTC_MSGEFLS);
     }
     return SZEROPADANDFFTTESTC_EFLS;
   }

   /* check output units */
   expectedUnit = lalDimensionlessUnit;
   expectedUnit.unitNumerator[LALUnitIndexADCCount] = 1;
   expectedUnit.unitNumerator[LALUnitIndexSecond] = 1;
   result = XLALUnitCompare(&expectedUnit, &(goodOutput.sampleUnits));
   if (optVerbose)
   {
     if ( XLALUnitAsString( unitString, LALUnitTextSize, &(goodOutput.sampleUnits)) == NULL ) {
       return SZEROPADANDFFTTESTC_EFLS;
     }
     printf( "Units are \"%s\", ", unitString );
     if ( XLALUnitAsString( unitString, LALUnitTextSize, &expectedUnit) == NULL ) {
       return SZEROPADANDFFTTESTC_EFLS;
     }
     printf( "should be \"%s\"\n", unitString );
   }

   if (result != 0)
   {
     printf("  FAIL: Valid data test #1\n");
     if (optVerbose)
     {
       printf("Exiting with error: %s\n",
              SZEROPADANDFFTTESTC_MSGEFLS);
     }
     return SZEROPADANDFFTTESTC_EFLS;
   }

   /* check output values */
   if (optVerbose)
   {
     printf("hBarTilde(0)=%g + %g i, should be %g\n",
            crealf(goodOutput.data->data[0]), cimagf(goodOutput.data->data[0]),
            crealf(expectedOutputDataData[0]));
   }
   if ( fabsf(crealf(goodOutput.data->data[0]) - crealf(expectedOutputDataData[0]))
        /* / expectedOutputDataData[0].re */> SZEROPADANDFFTTESTC_TOL
        || fabsf(cimagf(goodOutput.data->data[0])) > SZEROPADANDFFTTESTC_TOL )
   {
     printf("  FAIL: Valid data test\n");
     if (optVerbose)
       {
         printf("Exiting with error: %s\n", SZEROPADANDFFTTESTC_MSGEFLS);
       }
     return SZEROPADANDFFTTESTC_EFLS;
   }

   for (i=1; i<SZEROPADANDFFTTESTC_LENGTH; ++i)
   {
     f = i * SZEROPADANDFFTTESTC_DELTAF;
     if (optVerbose)
     {
       printf("hBarTilde(%f Hz)=%g + %g i, should be %g + %g i\n",
              f, crealf(goodOutput.data->data[i]), cimagf(goodOutput.data->data[i]),
              crealf(expectedOutputDataData[i]), cimagf(expectedOutputDataData[i]));
     }
     if (fabsf(crealf(goodOutput.data->data[i]) - crealf(expectedOutputDataData[i]))
         /* / expectedOutputDataData[0].re */> SZEROPADANDFFTTESTC_TOL
         || fabsf(cimagf(goodOutput.data->data[i]) - cimagf(expectedOutputDataData[i]))
         /* / expectedOutputDataData[0].re */> SZEROPADANDFFTTESTC_TOL)
     {
       printf("  FAIL: Valid data test\n");
       if (optVerbose)
       {
         printf("Exiting with error: %s\n", SZEROPADANDFFTTESTC_MSGEFLS);
       }
       return SZEROPADANDFFTTESTC_EFLS;
     }
   }

    /* write results to output file
   LALSPrintTimeSeries(&input, "zeropadgoodInput.dat");
   LALCPrintFrequencySeries(&output, "zeropadgoodOutput.dat");*/

   /* clean up valid data */
   LALSDestroyVector(&status, &goodInput.data);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
   {
     return code;
   }
   LALCDestroyVector(&status, &goodOutput.data);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
   {
     return code;
   }
   LALDestroyRealFFTPlan(&status, &(goodParams.fftPlan));
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
   {
     return code;
   }
   XLALDestroyREAL4Window(goodParams.window);

   LALCheckMemoryLeaks();

   printf("PASS: all tests\n");

   /**************** Process User-Entered Data, If Any **************/

   /* ::TODO:: Fix this with length and window type to be specified */

   if (optInputFile[0] && optOutputFile[0]){
     /* construct plan*/
     LALCreateForwardRealFFTPlan(&status, &(goodParams.fftPlan), 2*optLength - 1,
				   optMeasurePlan);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }

     goodInput.data  = NULL;
     goodOutput.data = NULL;

     LALSCreateVector(&status, &goodInput.data, optLength);
     if ( ( code = CheckStatus( &status, 0 , "",
				SZEROPADANDFFTTESTC_EUSE,
				SZEROPADANDFFTTESTC_MSGEUSE) ) )
     {
       return code;
     }
     LALCCreateVector(&status, &goodOutput.data, optLength);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }

     /* Read input file */
     LALSReadTimeSeries(&status, &goodInput, optInputFile);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }

     /* calculate zero-pad and FFT */
     LALSZeroPadAndFFT(&status, &goodOutput, &goodInput, &goodParams);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }

     LALCPrintFrequencySeries(&goodOutput, optOutputFile);

     printf("===== FFT of Zero-Padded User-Specified Data Written to File %s =====\n", optOutputFile);

     /* clean up valid data */
     LALSDestroyVector(&status, &goodInput.data);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }
     LALCDestroyVector(&status, &goodOutput.data);
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }
     LALDestroyRealFFTPlan(&status, &(goodParams.fftPlan));
     if ( ( code = CheckStatus(&status, 0 , "",
			       SZEROPADANDFFTTESTC_EFLS,
			       SZEROPADANDFFTTESTC_MSGEFLS) ) )
     {
       return code;
     }
     LALCheckMemoryLeaks();
   }
   return SZEROPADANDFFTTESTC_ENOM;
}
int main( int argc, char *argv[] )
{
  LALStatus                     status = blank_status;

  UINT4                         k;
  UINT4                         kLow;
  UINT4                         kHi;
  INT4                          numPoints       = 524288;
  REAL4                         fSampling       = 2048.;
  REAL4                         fLow            = 70.;
  REAL4                         fLowInj         = 40.;
  REAL8                         deltaT          = 1./fSampling;
  REAL8                         deltaF          = fSampling / numPoints;

  REAL4                          statValue;
 
  /* vars required to make freq series */
  LIGOTimeGPS                   epoch = { 0, 0 };
  LIGOTimeGPS                   gpsStartTime = {0, 0}; 
  REAL8                         f0 = 0.;
  REAL8                         offset = 0.;
  INT8                          waveformStartTime = 0;

  /* files contain PSD info */
  CHAR                         *injectionFile = NULL;         
  CHAR                         *outputFile    = NULL;         
  CHAR                         *specFileH1    = NULL;         
  CHAR                         *specFileH2    = NULL;         
  CHAR                         *specFileL1    = NULL;         

  COMPLEX8Vector               *unity = NULL;
  const LALUnit strainPerCount = {0,{0,0,0,0,0,1,-1},{0,0,0,0,0,0,0}};

  int                           numInjections = 0;
  int                           numTriggers = 0;

  /* template bank simulation variables */
  INT4                         injSimCount = 0;
  SimInspiralTable            *injectionHead  = NULL;
  SimInspiralTable            *thisInjection  = NULL;
  SnglInspiralTable           *snglHead       = NULL;
  SearchSummaryTable          *searchSummHead = NULL;
  /*SummValueTable              *summValueHead  = NULL;    */

  /* raw input data storage */
  REAL8FrequencySeries          *specH1        = NULL;
  REAL8FrequencySeries          *specH2        = NULL;
  REAL8FrequencySeries          *specL1        = NULL;
  REAL8FrequencySeries          *thisSpec      = NULL;
  COMPLEX8FrequencySeries       *resp          = NULL;
  COMPLEX8FrequencySeries       *detTransDummy = NULL;
  REAL4TimeSeries               *chan          = NULL;
  RealFFTPlan                   *pfwd          = NULL;
  COMPLEX8FrequencySeries       *fftData       = NULL;
  REAL8                          thisSnrsq     = 0;
  REAL8                          thisSnr       = 0;
  REAL8                          thisCombSnr   = 0;
  REAL8                          snrVec[3];
  REAL8                          dynRange      = 1./(3.0e-23);

  /* needed for inj */
  CoherentGW                 waveform;
  PPNParamStruc              ppnParams;
  DetectorResponse           detector;
  InterferometerNumber       ifoNumber   = LAL_UNKNOWN_IFO;

  /* output data */
  LIGOLwXMLStream       xmlStream;
  MetadataTable         proctable;
  MetadataTable         outputTable;
  MetadataTable         procparams;
  CHAR                  fname[256];         
  CHAR                  comment[LIGOMETA_COMMENT_MAX];
  ProcessParamsTable   *this_proc_param = NULL;

  CHAR   chanfilename[FILENAME_MAX];

  REAL4 sum = 0;
  REAL4 bitten_H1 = 0;
  REAL4 bitten_H2 = 0;
  REAL4 thisCombSnr_H1H2 = 0;

  /* create the process and process params tables */
  proctable.processTable = (ProcessTable *) calloc( 1, sizeof(ProcessTable) );
  XLALGPSTimeNow(&(proctable.processTable->start_time));
  XLALPopulateProcessTable(proctable.processTable, PROGRAM_NAME, lalAppsVCSIdentId,
      lalAppsVCSIdentStatus, lalAppsVCSIdentDate, 0);
  this_proc_param = procparams.processParamsTable = (ProcessParamsTable *) 
                                      calloc( 1, sizeof(ProcessParamsTable) );
  memset( comment, 0, LIGOMETA_COMMENT_MAX * sizeof(CHAR) );

  /* look at input args, write process params where required */
  while ( 1 )
  {

  /* getopt arguments */
  static struct option long_options[] =
  {
    /* these options set a flag */
    /* these options do not set a flag */
    {"help",                    no_argument,       0,                'h'},
    {"verbose",                 no_argument,       &vrbflg,           1 },
    {"version",                 no_argument,       0,                'V'},
    {"spectrum-H1",             required_argument, 0,                'a'},
    {"spectrum-H2",             required_argument, 0,                'b'},
    {"spectrum-L1",             required_argument, 0,                'c'},
    {"inj-file",                required_argument, 0,                'd'},
    {"comment",                 required_argument, 0,                'e'},
    {"output-file",             required_argument, 0,                'f'},
    {"coire-flag",              no_argument,       &coireflg,         1 },
    {"ligo-srd",                no_argument,       &ligosrd,          1 },
    {"write-chan",              no_argument,       &writechan,        1 },
    {"inject-overhead",         no_argument,       &injoverhead,      1 },
    {"f-lower",                 required_argument, 0,                'g'},
    {0, 0, 0, 0}
  };
  int c;
  
  /*
   *
   * parse command line arguments
   *
   */

    /* getopt_long stores long option here */
    int option_index = 0;
    size_t optarg_len;

    c = getopt_long_only( argc, argv, "a:b:c:d:e:f:g:hV", long_options, &option_index );

    /* detect the end of the options */
    if ( c == - 1 )
    {
      break;
    }

    switch ( c )
    {
      case 0:
        /* if this option set a flag, do nothing else now */
        if ( long_options[option_index].flag != 0 )
        {
          break;
        }
        else
        {
          fprintf( stderr, "error parsing option %s with argument %s\n",
              long_options[option_index].name, optarg );
          exit( 1 );
        }
        break;

      case 'h':
        fprintf( stderr, USAGE );
        exit( 0 );
        break;

      case 'a':
        /* create storage for the spectrum file name */
        optarg_len = strlen( optarg ) + 1;
        specFileH1 = (CHAR *) calloc( optarg_len, sizeof(CHAR));
        memcpy( specFileH1, optarg, optarg_len );
        ADD_PROCESS_PARAM( "string", "%s", optarg );
        break;

      case 'b':
        /* create storage for the spectrum file name */
        optarg_len = strlen( optarg ) + 1;
        specFileH2 = (CHAR *) calloc( optarg_len, sizeof(CHAR));
        memcpy( specFileH2, optarg, optarg_len );
        ADD_PROCESS_PARAM( "string", "%s", optarg );
        break;

      case 'c':
        /* create storage for the spectrum file name */
        optarg_len = strlen( optarg ) + 1;
        specFileL1 = (CHAR *) calloc( optarg_len, sizeof(CHAR));
        memcpy( specFileL1, optarg, optarg_len );
        ADD_PROCESS_PARAM( "string", "%s", optarg );
        break;

      case 'd':
        /* create storage for the injection file name */
        optarg_len = strlen( optarg ) + 1;
        injectionFile = (CHAR *) calloc( optarg_len, sizeof(CHAR));
        memcpy( injectionFile, optarg, optarg_len );
        ADD_PROCESS_PARAM( "string", "%s", optarg );
        break;

      case 'f':
        /* create storage for the output file name */
        optarg_len = strlen( optarg ) + 1;
        outputFile = (CHAR *) calloc( optarg_len, sizeof(CHAR));
        memcpy( outputFile, optarg, optarg_len );
        ADD_PROCESS_PARAM( "string", "%s", optarg );
        break;
    
      case 'g':
        fLow = (INT4) atof( optarg );
        if ( fLow < 40 )
        {
          fprintf( stderr, "invalid argument to --%s:\n"
              "f-lower must be > 40Hz (%e specified)\n",
              long_options[option_index].name, fLow );
          exit( 1 );
        }
        ADD_PROCESS_PARAM( "float", "%e", fLow );
        break;


     case 'e':
        if ( strlen( optarg ) > LIGOMETA_COMMENT_MAX - 1 )
        {
          fprintf( stderr, "invalid argument to --%s:\n"
              "comment must be less than %d characters\n",
              long_options[option_index].name, LIGOMETA_COMMENT_MAX );
          exit( 1 );
        }
        else
        {
          snprintf( comment, LIGOMETA_COMMENT_MAX, "%s", optarg);
        }
        break;

      case 'V':
        /* print version information and exit */
        fprintf( stdout, "calculation of expected SNR of injections\n"
            "Gareth Jones\n");
        XLALOutputVersionString(stderr, 0);
        exit( 0 );
        break;

     default:
        fprintf( stderr, "unknown error while parsing options\n" );
        fprintf( stderr, USAGE );
        exit( 1 );
    }
  }  

  if ( optind < argc )
  {
    fprintf( stderr, "extraneous command line arguments:\n" );
    while ( optind < argc )
    {
      fprintf ( stderr, "%s\n", argv[optind++] );
    }
    exit( 1 );
  }

  /* check the input arguments */
  if ( injectionFile == NULL )
  {
    fprintf( stderr, "Must specify the --injection-file\n" );
    exit( 1 );
  }

  if ( outputFile == NULL )
  {
    fprintf( stderr, "Must specify the --output-file\n" );
    exit( 1 );
  }

  if ( !ligosrd && specFileH1 == NULL )
  {
    fprintf( stderr, "Must specify the --spectrum-H1\n" );
    exit( 1 );
  }

  if ( !ligosrd && specFileH2 == NULL )
  {
    fprintf( stderr, "Must specify the --spectrum-H2\n" );
    exit( 1 );
  }

  if ( !ligosrd && specFileL1 == NULL )
  {
    fprintf( stderr, "Must specify the --spectrum-L1\n" );
    exit( 1 );
  }

  if ( ligosrd && (specFileH1 || specFileH2 || specFileL1 ))
  {
    fprintf( stdout, "WARNING: using LIGOI SRD power spectral density \n" );
  } 
 
  if ( vrbflg ){
    fprintf( stdout, "injection file is %s\n", injectionFile );
    fprintf( stdout, "output file is %s\n", outputFile );
    fprintf( stdout, "H1 spec file is   %s\n", specFileH1 );
    fprintf( stdout, "H2 spec file is   %s\n", specFileH2 );
    fprintf( stdout, "L1 spec file is   %s\n", specFileL1 );
  }

  /* create vector for H1, H2 and L1 spectrums */
  specH1 = XLALCreateREAL8FrequencySeries ( "",&epoch, f0, deltaF, &lalADCCountUnit, (numPoints / 2 + 1) );
  specH2 = XLALCreateREAL8FrequencySeries ( "",&epoch, f0, deltaF, &lalADCCountUnit, (numPoints / 2 + 1) );
  specL1 = XLALCreateREAL8FrequencySeries ( "",&epoch, f0, deltaF, &lalADCCountUnit, (numPoints / 2 + 1) );
  if (!specH1 || !specH2 || !specL1){
    XLALDestroyREAL8FrequencySeries ( specH1 );
    XLALDestroyREAL8FrequencySeries ( specH2 );
    XLALDestroyREAL8FrequencySeries ( specL1 );
    XLALPrintError("failure allocating H1, H2 and L1 spectra");
    exit(1);
  }

  if (!ligosrd){
    /* read in H1 spectrum */ 
    LAL_CALL( LALDReadFrequencySeries(&status, specH1, specFileH1), &status );
    if ( vrbflg ){
       fprintf( stdout, "read in H1 spec file\n" );
       fflush( stdout );
    } 

    /* read in H2 spectrum */ 
    LAL_CALL( LALDReadFrequencySeries(&status, specH2, specFileH2), &status );
    if ( vrbflg ){
       fprintf( stdout, "read in H2 spec file\n" );
       fflush( stdout );
    }

    /* read in L1 spectrum */ 
    LAL_CALL( LALDReadFrequencySeries(&status, specL1, specFileL1), &status );
    if ( vrbflg ){
       fprintf( stdout, "read in L1 spec file\n" );
       fflush( stdout );
     }
  }

  chan = XLALCreateREAL4TimeSeries( "", &epoch, f0, deltaT, 
                                     &lalADCCountUnit, numPoints );
  if ( !chan ){
    XLALPrintError("failure allocating chan");
    exit(1);
  }

  /*
   *
   * set up the response function
   *
   */
  resp = XLALCreateCOMPLEX8FrequencySeries( chan->name, 
     &chan->epoch, f0, deltaF, &strainPerCount, (numPoints / 2 + 1) );
  if ( !resp ){
    XLALPrintError("failure allocating response function");
    exit(1);
  }

  /* create vector that will contain detector.transfer info, since this 
   * is constant I calculate it once outside of all the loops and pass it 
   * in to detector.transfer when required 
   */
  detTransDummy = XLALCreateCOMPLEX8FrequencySeries( chan->name, &chan->epoch,
                  f0, deltaF, &strainPerCount, (numPoints / 2 + 1) );
  if ( !detTransDummy ){
    XLALPrintError("failure allocating detector.transfer info");
    exit(1);
  }

  /* invert the response function to get the transfer function */
  unity = XLALCreateCOMPLEX8Vector( resp->data->length );
  for ( k = 0; k < unity->length; ++k )
     {
        unity->data[k] = 1.0;
     }

  /* set response */
  for ( k = 0; k < resp->data->length; ++k )
  {
      resp->data->data[k] = 1.0;
  }

  XLALCCVectorDivide( detTransDummy->data, unity, resp->data );
  XLALDestroyCOMPLEX8Vector( unity );

  /* read in injections from injection file */
  /* set endtime to 0 so that we read in all events */
  if ( vrbflg ) fprintf( stdout, "Reading sim_inspiral table of %s\n", injectionFile );
  LAL_CALL(numInjections = SimInspiralTableFromLIGOLw( &injectionHead, injectionFile, 0, 0), &status);
  if ( vrbflg ) fprintf( stdout, "Read %d injections from sim_inspiral table of %s\n", 
                                    numInjections, injectionFile );

  if (coireflg){
     if ( vrbflg ) fprintf( stdout, "Reading sngl_inspiral table of %s\n", injectionFile );
     LAL_CALL(numTriggers = LALSnglInspiralTableFromLIGOLw(&snglHead, injectionFile, 0, -1), &status);
     if ( vrbflg ) fprintf( stdout, "Read %d triggers from sngl_inspiral table of %s\n", 
                                    numTriggers, injectionFile );
     if ( vrbflg ) {
           fprintf( stdout, "Reading search_summary table of %s ...", injectionFile );
           fflush( stdout );
           }
     searchSummHead = XLALSearchSummaryTableFromLIGOLw (injectionFile);
     if ( vrbflg ) fprintf( stdout, " done\n");
  }

 /* make sure we start at head of linked list */
 thisInjection = injectionHead;

  /* setting fixed waveform injection parameters */
  memset( &ppnParams, 0, sizeof(PPNParamStruc) );
  ppnParams.deltaT   = deltaT;
  ppnParams.lengthIn = 0;
  ppnParams.ppn      = NULL;

  /* loop over injections */
  injSimCount = 0;
    
        
  do
  {
     fprintf( stdout, "injection %d/%d\n", injSimCount+1, numInjections );

     /* reset waveform structure */
     memset( &waveform, 0, sizeof(CoherentGW) );

     /* reset chan structure */
     memset( chan->data->data, 0, chan->data->length * sizeof(REAL4) );

     if (thisInjection->f_lower == 0){
        fprintf( stdout, "WARNING: f_lower in sim_inpiral = 0, ");
        fprintf( stdout, "changing this to %e\n ", fLowInj);
        thisInjection->f_lower = fLowInj;
     }

     /* create the waveform, amp, freq phase etc */
     LAL_CALL( LALGenerateInspiral(&status, &waveform, thisInjection, &ppnParams), &status);
     if (vrbflg) fprintf( stdout, "ppnParams.tc %e\n ", ppnParams.tc);

    statValue = 0.;
  
    /* calc lower index for integration */
    kLow = ceil(fLow / deltaF);
    if ( vrbflg ) {
        fprintf( stdout, "starting integration to find SNR at frequency %e ", fLow);
        fprintf( stdout, "at index %d \n", kLow);
    }
    /* calc upper index for integration */
    kHi = floor(fSampling / (2. * deltaF));
    if ( vrbflg ) {
        fprintf( stdout, "ending integration to find SNR at frequency %e ", fSampling / 2.);
        fprintf( stdout, "at index %d \n", kHi);
    }

    /* loop over ifo */
    for ( ifoNumber = 1; ifoNumber < 4; ifoNumber++ )
    {
        /* allocate memory and copy the parameters describing the freq series */
        memset( &detector, 0, sizeof( DetectorResponse ) );
        detector.site = (LALDetector *) LALMalloc( sizeof(LALDetector) );

        if (injoverhead){ 
           if ( vrbflg ) fprintf( stdout, "WARNING: perform overhead injections\n");
           /* setting detector.site to NULL causes SimulateCoherentGW to
            * perform overhead injections */  
           detector.site = NULL; 
        }
        else {
           /* if not overhead, set detector.site using ifonumber */  
           XLALReturnDetector( detector.site, ifoNumber );
        } 

        switch ( ifoNumber )
        {
        case 1:
           if ( vrbflg ) fprintf( stdout, "looking at H1 \n");
           thisSpec = specH1;
           break;
        case 2:
           if ( vrbflg ) fprintf( stdout, "looking at H2 \n");
           thisSpec = specH2;
           break;
        case 3:
           if ( vrbflg ) fprintf( stdout, "looking at L1 \n");
           thisSpec = specL1;
           break;
        default:
           fprintf( stderr, "Error: ifoNumber %d does not correspond to H1, H2 or L1: \n", ifoNumber );
           exit( 1 );
        }

        /* get the gps start time of the signal to inject */
        waveformStartTime = XLALGPSToINT8NS( &(thisInjection->geocent_end_time) );
        waveformStartTime -= (INT8) ( 1000000000.0 * ppnParams.tc );

        offset = (chan->data->length / 2.0) * chan->deltaT;
        gpsStartTime.gpsSeconds     = thisInjection->geocent_end_time.gpsSeconds - offset;
        gpsStartTime.gpsNanoSeconds = thisInjection->geocent_end_time.gpsNanoSeconds;
        chan->epoch = gpsStartTime;


       if (vrbflg) fprintf(stdout, "offset start time of injection by %f seconds \n", offset ); 
       
       /* is this okay? copying in detector transfer which so far only contains response info  */
       detector.transfer = detTransDummy;

       XLALUnitInvert( &(detector.transfer->sampleUnits), &(resp->sampleUnits) );

       /* set the start times for injection */
       XLALINT8NSToGPS( &(waveform.a->epoch), waveformStartTime );
       memcpy(&(waveform.f->epoch), &(waveform.a->epoch), sizeof(LIGOTimeGPS) );
       memcpy(&(waveform.phi->epoch), &(waveform.a->epoch), sizeof(LIGOTimeGPS) );
 
       /* perform the injection */
       LAL_CALL( LALSimulateCoherentGW(&status, chan, &waveform, &detector ), &status); 

       if (writechan){ 
          /* write out channel data */
          if (vrbflg) fprintf(stdout, "writing channel data to file... \n" ); 
          switch ( ifoNumber )
          {
          case 1:
             snprintf( chanfilename, FILENAME_MAX, "chanTest_H1_inj%d.dat", injSimCount+1);
             if (vrbflg) fprintf( stdout, "writing H1 channel time series out to %s\n", chanfilename );
             LALSPrintTimeSeries(chan, chanfilename );
             break;
          case 2:
             snprintf( chanfilename, FILENAME_MAX, "chanTest_H2_inj%d.dat", injSimCount+1);
             if (vrbflg) fprintf( stdout, "writing H2 channel time series out to %s\n", chanfilename );
             LALSPrintTimeSeries(chan, chanfilename );
             break;
          case 3:
             snprintf( chanfilename, FILENAME_MAX, "chanTest_L1_inj%d.dat", injSimCount+1);
             if (vrbflg) fprintf( stdout, "writing L1 channel time series out to %s\n", chanfilename );
             LALSPrintTimeSeries(chan, chanfilename );
             break;
         default:
             fprintf( stderr, "Error: ifoNumber %d does not correspond to H1, H2 or L1: \n", ifoNumber );
             exit( 1 );
         }  
      } 

      LAL_CALL( LALCreateForwardRealFFTPlan( &status, &pfwd, chan->data->length, 0), &status);

      fftData = XLALCreateCOMPLEX8FrequencySeries( chan->name, &chan->epoch, f0, deltaF, 
                                                   &lalDimensionlessUnit, (numPoints / 2 + 1) );
      if ( !fftData ){
        XLALPrintError("failure allocating fftData");
        exit(1);
      }
   
      LAL_CALL( LALTimeFreqRealFFT( &status, fftData, chan, pfwd ), &status);
   
      LAL_CALL( LALDestroyRealFFTPlan( &status, &pfwd ), &status);
      pfwd = NULL;

       /* compute the SNR */
       thisSnrsq = 0;
       /* avoid f=0 part of psd */  

       if (ligosrd){
          if (vrbflg) fprintf( stdout, "using LIGOI PSD \n");
          for ( k = kLow; k < kHi; k++ )
          {
           REAL8 freq;
           REAL8 sim_psd_value;
           freq = fftData->deltaF * k;
           LALLIGOIPsd( NULL, &sim_psd_value, freq ); 

           thisSnrsq += ((crealf(fftData->data->data[k]) * dynRange) * 
                      (crealf(fftData->data->data[k]) * dynRange)) / sim_psd_value;
           thisSnrsq += ((cimagf(fftData->data->data[k]) * dynRange) * 
                      (cimagf(fftData->data->data[k]) * dynRange)) / sim_psd_value;
           }
       }
       else {
          if (vrbflg) fprintf( stdout, "using input spectra \n");
          for ( k = kLow; k < kHi; k++ )
          {
           thisSnrsq += ((crealf(fftData->data->data[k]) * dynRange) * 
              (crealf(fftData->data->data[k]) * dynRange))  /
              (thisSpec->data->data[k] * dynRange * dynRange);
           thisSnrsq += ((cimagf(fftData->data->data[k]) * dynRange) * 
              (cimagf(fftData->data->data[k]) * dynRange)) /
              (thisSpec->data->data[k] * dynRange * dynRange);
        } 
      }

       thisSnrsq *= 4*fftData->deltaF;
       thisSnr    = pow(thisSnrsq, 0.5);
       /* Note indexing on snrVec, ifoNumber runs from 1..3 to get source correct,
        * we must index snrVec 0..2 
        */ 
       snrVec[ifoNumber-1] = thisSnr; 
       XLALDestroyCOMPLEX8FrequencySeries(fftData);

       if ( vrbflg ){
          fprintf( stdout, "thisSnrsq %e\n", thisSnrsq );
          fprintf( stdout, "snrVec    %e\n", snrVec[ifoNumber-1] );
          fflush( stdout );
       }

       /* sum thisSnrsq to eventually get combined snr*/
       statValue += thisSnrsq; 

       /* free some memory */
       if (detector.transfer) detector.transfer = NULL;
       if ( detector.site ) {LALFree( detector.site); detector.site = NULL;}
     }
     /* end loop over ifo */
  
    destroyCoherentGW( &waveform );

    /* store inverse eff snrs in eff_dist columns */
    thisInjection->eff_dist_h = 1./snrVec[0];
    thisInjection->eff_dist_g = 1./snrVec[1];
    thisInjection->eff_dist_l = 1./snrVec[2];

    /* store inverse sum of squares snr in eff_dist_t */
    thisCombSnr = pow(statValue, 0.5);
    if ( vrbflg ) fprintf( stdout, "thisCombSnr %e\n", thisCombSnr);
    thisInjection->eff_dist_t = 1./thisCombSnr;

    /* calc inverse bittenL snr for H1H2 and store in eff_dist_v */
    thisCombSnr_H1H2 = 0.;
    sum = snrVec[0] * snrVec[0] + snrVec[1] * snrVec[1];
    bitten_H1 = 3 * snrVec[0] -3;
    bitten_H2 = 3 * snrVec[1] -3;

    if (sum < bitten_H1){
       thisCombSnr_H1H2 = sum;
    }
    else
    {
       thisCombSnr_H1H2 = bitten_H1;
    }

    if (bitten_H2 < thisCombSnr_H1H2){
       thisCombSnr_H1H2 = bitten_H2;
    }
    thisInjection->eff_dist_v = 1./thisCombSnr_H1H2;


    /* increment the bank sim sim_inspiral table if necessary */
    if ( injectionHead )
    {
      thisInjection = thisInjection->next;
    }

  } while ( ++injSimCount < numInjections ); 
  /* end loop over injections */

  /* try opening, writing and closing an xml file */

  /* open the output xml file */
  memset( &xmlStream, 0, sizeof(LIGOLwXMLStream) );
  snprintf( fname, sizeof(fname), "%s", outputFile);
  LAL_CALL( LALOpenLIGOLwXMLFile  ( &status, &xmlStream, fname), &status);

  /* write out the process and process params tables */
  if ( vrbflg ) fprintf( stdout, "process... " );
  XLALGPSTimeNow(&(proctable.processTable->end_time));
  LAL_CALL( LALBeginLIGOLwXMLTable( &status, &xmlStream, process_table ), &status );
  LAL_CALL( LALWriteLIGOLwXMLTable( &status, &xmlStream, proctable, process_table ), &status );
  LAL_CALL( LALEndLIGOLwXMLTable ( &status, &xmlStream ), &status );
  free( proctable.processTable );
  /* Just being pedantic here ... */
  proctable.processTable = NULL;
 
  /* free the unused process param entry */
  this_proc_param = procparams.processParamsTable;
  procparams.processParamsTable = procparams.processParamsTable->next;
  free( this_proc_param );
  this_proc_param = NULL;

  /* write the process params table */
  if ( vrbflg ) fprintf( stdout, "process_params... " );
  LAL_CALL( LALBeginLIGOLwXMLTable( &status, &xmlStream, process_params_table ), &status );
  LAL_CALL( LALWriteLIGOLwXMLTable( &status, &xmlStream, procparams, process_params_table ), &status );
  LAL_CALL( LALEndLIGOLwXMLTable ( &status, &xmlStream ), &status );

  /* write the search summary table */
  if ( coireflg ){
     if ( vrbflg ) fprintf( stdout, "search_summary... " );
     outputTable.searchSummaryTable = searchSummHead;
     LAL_CALL( LALBeginLIGOLwXMLTable( &status, &xmlStream, search_summary_table), &status);
     LAL_CALL( LALWriteLIGOLwXMLTable( &status, &xmlStream, outputTable, search_summary_table), &status);
     LAL_CALL( LALEndLIGOLwXMLTable  ( &status, &xmlStream), &status);
   }

  /* write the sim inspiral table */
  if ( vrbflg ) fprintf( stdout, "sim_inspiral... " );
  outputTable.simInspiralTable = injectionHead;
  LAL_CALL( LALBeginLIGOLwXMLTable( &status, &xmlStream, sim_inspiral_table), &status);
  LAL_CALL( LALWriteLIGOLwXMLTable( &status, &xmlStream, outputTable, sim_inspiral_table), &status);
  LAL_CALL( LALEndLIGOLwXMLTable  ( &status, &xmlStream), &status);

  /* write the sngl inspiral table */
  if ( coireflg ){
     if ( vrbflg ) fprintf( stdout, "sngl_inspiral... " );
     outputTable.snglInspiralTable = snglHead;
     LAL_CALL( LALBeginLIGOLwXMLTable( &status, &xmlStream, sngl_inspiral_table), &status);
     LAL_CALL( LALWriteLIGOLwXMLTable( &status, &xmlStream, outputTable, sngl_inspiral_table), &status);
     LAL_CALL( LALEndLIGOLwXMLTable  ( &status, &xmlStream), &status);
  } 

  /* close the xml file */ 
  LAL_CALL( LALCloseLIGOLwXMLFile ( &status, &xmlStream), &status);

  /* Freeing memory */
  XLALDestroyREAL4TimeSeries(chan);
  XLALDestroyCOMPLEX8FrequencySeries(resp);
  XLALDestroyCOMPLEX8FrequencySeries(detTransDummy);
  XLALDestroyREAL8FrequencySeries ( specH1 );
  XLALDestroyREAL8FrequencySeries ( specH2 );
  XLALDestroyREAL8FrequencySeries ( specL1 );


  free( specFileH1 );
  specFileH1 = NULL;
  free( specFileH2 );
  specFileH2 = NULL;
  free( specFileL1 );
  specFileL1 = NULL;
  free( injectionFile ); 
  injectionFile = NULL;

  /* free the process params */
  while( procparams.processParamsTable )
  {
    this_proc_param = procparams.processParamsTable;
    procparams.processParamsTable = this_proc_param->next;
    free( this_proc_param );
    this_proc_param = NULL;
  }

  /* free the sim inspiral tables */
  while ( injectionHead )
  {
    thisInjection = injectionHead;
    injectionHead = injectionHead->next;
    LALFree( thisInjection );
  }

  /*check for memory leaks */
  LALCheckMemoryLeaks(); 

  exit( 0 ); 
}
Ejemplo n.º 4
0
int main( void )
{
  const UINT4 n = 65536;
  const UINT4 m = 8;
  static AverageSpectrumParams specpar;
  static REAL4FrequencySeries fseries;
  static REAL4TimeSeries tseries;
  static LALStatus status;
  static RandomParams *randpar;
  REAL8 ave;
  UINT4 i;


  /* allocate memory for time and frequency series */
  tseries.deltaT = 1;
  LALCreateVector( &status, &tseries.data, n * m );
  TESTSTATUS( &status );
  LALCreateVector( &status, &fseries.data, n / 2 + 1 );
  TESTSTATUS( &status );

  /* set time series data to be a unit impulse */
  /*
  memset( tseries.data->data, 0, tseries.data->length * sizeof(
        *tseries.data->data ) );
  tseries.data->data[0] = 1;
  */
  randpar = XLALCreateRandomParams( 1 );
  XLALNormalDeviates( tseries.data, randpar );
  XLALDestroyRandomParams( randpar );

  /* prepare average spectrum parameters */
  specpar.method  = useMedian;
  specpar.overlap = n / 2;
  /* specpar.overlap = 0; */
  LALCreateForwardRealFFTPlan( &status, &specpar.plan, n, 0 );
  TESTSTATUS( &status );
  specpar.window = XLALCreateWelchREAL4Window(n);

  /* compute spectrum */
  LALREAL4AverageSpectrum( &status, &fseries, &tseries, &specpar );
  TESTSTATUS( &status );

  /* output results -- omit DC & Nyquist */
  /*
  for ( i = 1; i < fseries.data->length - 1; ++i )
    fprintf( stdout, "%e\t%e\n", i * fseries.deltaF,
        fseries.data->data[i] );
   */

  /* average values of power spectrum (omit DC & Nyquist ) */
  ave = 0;
  for ( i = 1; i < fseries.data->length - 1; ++i )
    ave += fseries.data->data[i];
  ave /= fseries.data->length - 2;
  fprintf( stdout, "median:\t%e\terror:\t%f%%\n", ave, fabs( ave - 2.0 ) / 0.02 );

  /* now do the same for mean */
  specpar.method  = useMean;
  LALREAL4AverageSpectrum( &status, &fseries, &tseries, &specpar );
  TESTSTATUS( &status );
  /* average values of power spectrum (omit DC & Nyquist ) */
  ave = 0;
  for ( i = 1; i < fseries.data->length - 1; ++i )
    ave += fseries.data->data[i];
  ave /= fseries.data->length - 2;
  fprintf( stdout, "mean:\t%e\terror:\t%f%%\n", ave, fabs( ave - 2.0 ) / 0.02 );


  /* cleanup */
  XLALDestroyREAL4Window( specpar.window );
  LALDestroyRealFFTPlan( &status, &specpar.plan );
  TESTSTATUS( &status );
  LALDestroyVector( &status, &fseries.data );
  TESTSTATUS( &status );
  LALDestroyVector( &status, &tseries.data );
  TESTSTATUS( &status );

  /* exit */
  LALCheckMemoryLeaks();
  return 0;
}
Ejemplo n.º 5
0
int main( int argc, char *argv[] )
{
  const UINT4 n  = 65536;
  const REAL4 dt = 1.0 / 16384.0;
  static LALStatus status;

  static REAL4TimeSeries         x;
  static COMPLEX8FrequencySeries X;

  static REAL4TimeSeries         y;
  static REAL4FrequencySeries    Y;

  static COMPLEX8TimeSeries      z;
  static COMPLEX8FrequencySeries Z;

  RealFFTPlan    *fwdRealPlan    = NULL;
  RealFFTPlan    *revRealPlan    = NULL;
  ComplexFFTPlan *fwdComplexPlan = NULL;
  ComplexFFTPlan *revComplexPlan = NULL;
  RandomParams   *randpar        = NULL;

  AverageSpectrumParams avgSpecParams;

  UINT4 srate[] = { 4096, 9000 };
  UINT4 npts[] = { 262144, 1048576 };
  REAL4 var[] = { 5, 16 };

  UINT4 j, sr, np, vr;


  /*CHAR fname[2048];*/

  ParseOptions( argc, argv );

  LALSCreateVector( &status, &x.data, n );
  TestStatus( &status, CODES( 0 ), 1 );
  LALCCreateVector( &status, &X.data, n / 2 + 1 );
  TestStatus( &status, CODES( 0 ), 1 );

  LALCCreateVector( &status, &z.data, n );
  TestStatus( &status, CODES( 0 ), 1 );
  LALCCreateVector( &status, &Z.data, n );
  TestStatus( &status, CODES( 0 ), 1 );

  LALCreateForwardRealFFTPlan( &status, &fwdRealPlan, n, 0 );
  TestStatus( &status, CODES( 0 ), 1 );
  LALCreateReverseRealFFTPlan( &status, &revRealPlan, n, 0 );
  TestStatus( &status, CODES( 0 ), 1 );
  LALCreateForwardComplexFFTPlan( &status, &fwdComplexPlan, n, 0 );
  TestStatus( &status, CODES( 0 ), 1 );
  LALCreateReverseComplexFFTPlan( &status, &revComplexPlan, n, 0 );
  TestStatus( &status, CODES( 0 ), 1 );

  randpar = XLALCreateRandomParams( 100 );


  /*
   *
   * Try the real transform.
   *
   */


  x.f0 = 0;
  x.deltaT = dt;
  x.sampleUnits = lalMeterUnit;
  snprintf( x.name, sizeof( x.name ), "x" );
  XLALNormalDeviates( x.data, randpar );
  for ( j = 0; j < n; ++j ) /* add a 60 Hz line */
  {
    REAL4 t = j * dt;
    x.data->data[j] += 0.1 * cos( LAL_TWOPI * 60.0 * t );
  }
  LALSPrintTimeSeries( &x, "x.out" );

  snprintf( X.name, sizeof( X.name ), "X" );
  LALTimeFreqRealFFT( &status, &X, &x, fwdRealPlan );
  TestStatus( &status, CODES( 0 ), 1 );
  LALCPrintFrequencySeries( &X, "X.out" );

  LALFreqTimeRealFFT( &status, &x, &X, revRealPlan );
  TestStatus( &status, CODES( 0 ), 1 );
  LALSPrintTimeSeries( &x, "xx.out" );


  /*
   *
   * Try the average power spectum.
   *
   */


  avgSpecParams.method = useMean;

  for ( np = 0; np < XLAL_NUM_ELEM(npts) ; ++np )
  {
    /* length of time series for 7 segments, overlapped by 1/2 segment */
    UINT4 tsLength = npts[np] * 7 - 6 * npts[np] / 2;
    LALCreateVector( &status, &y.data, tsLength );
    TestStatus( &status, CODES( 0 ), 1 );
    LALCreateVector( &status, &Y.data, npts[np] / 2 + 1  );
    TestStatus( &status, CODES( 0 ), 1 );
    avgSpecParams.overlap = npts[np] / 2;

    /* create the window */
    avgSpecParams.window = XLALCreateHannREAL4Window(npts[np]);
    avgSpecParams.plan = NULL;
    LALCreateForwardRealFFTPlan( &status, &avgSpecParams.plan, npts[np], 0 );
    TestStatus( &status, CODES( 0 ), 1 );

    for ( sr = 0; sr < XLAL_NUM_ELEM(srate) ; ++sr )
    {
      /* set the sample rate of the time series */
      y.deltaT = 1.0 / (REAL8) srate[sr];
      for ( vr = 0; vr < XLAL_NUM_ELEM(var) ; ++vr )
      {
        REAL4 eps = 1e-6; /* very conservative fp precision */
        REAL4 Sfk = 2.0 * var[vr] * var[vr] * y.deltaT;
        REAL4 sfk = 0;
        REAL4 lbn;
        REAL4 sig;
        REAL4 ssq;
        REAL4 tol;

        /* create the data */
        XLALNormalDeviates( y.data, randpar );
        ssq = 0;
        for ( j = 0; j < y.data->length; ++j )
        {
          y.data->data[j] *= var[vr];
          ssq += y.data->data[j] * y.data->data[j];
        }

        /* compute tolerance for comparison */
        lbn = log( y.data->length ) / log( 2 );
        sig = sqrt( 2.5 * lbn * eps * eps * ssq / y.data->length );
        tol = 5 * sig;

        /* compute the psd and find the average */
        LALREAL4AverageSpectrum( &status, &Y, &y, &avgSpecParams );
        TestStatus( &status, CODES( 0 ), 1 );
        LALSMoment( &status, &sfk, Y.data, 1 );
        TestStatus( &status, CODES( 0 ), 1 );

        /* check the result */
        if ( fabs(Sfk-sfk) > tol )
        {
          fprintf( stderr, "FAIL: PSD estimate appears incorrect\n");
          fprintf( stderr, "expected %e, got %e ", Sfk, sfk );
          fprintf( stderr, "(difference = %e, tolerance = %e)\n",
              fabs(Sfk-sfk), tol );
          exit(2);
        }

      }
    }

    /* destroy structures that need to be resized */
    LALDestroyRealFFTPlan( &status, &avgSpecParams.plan );
    TestStatus( &status, CODES( 0 ), 1 );
    XLALDestroyREAL4Window( avgSpecParams.window );
    LALDestroyVector( &status, &y.data );
    TestStatus( &status, CODES( 0 ), 1 );
    LALDestroyVector( &status, &Y.data );
    TestStatus( &status, CODES( 0 ), 1 );
  }


  /*
   *
   * Try the complex transform.
   *
   */


  z.f0 = 0;
  z.deltaT = dt;
  z.sampleUnits = lalVoltUnit;
  snprintf( z.name, sizeof( z.name ), "z" );
  { /* dirty hack */
    REAL4Vector tmp;
    tmp.length = 2 * z.data->length;
    tmp.data   = (REAL4 *)z.data->data;
    XLALNormalDeviates( &tmp, randpar );
  }
  for ( j = 0; j < n; ++j ) /* add a 50 Hz line and a 500 Hz ringdown */
  {
    REAL4 t = j * dt;
    z.data->data[j] += 0.2 * cos( LAL_TWOPI * 50.0 * t );
    z.data->data[j] += I * exp( -t ) * sin( LAL_TWOPI * 500.0 * t );
  }
  LALCPrintTimeSeries( &z, "z.out" );
  TestStatus( &status, CODES( 0 ), 1 );

  snprintf( Z.name, sizeof( Z.name ), "Z" );
  LALTimeFreqComplexFFT( &status, &Z, &z, fwdComplexPlan );
  TestStatus( &status, CODES( 0 ), 1 );
  LALCPrintFrequencySeries( &Z, "Z.out" );

  LALFreqTimeComplexFFT( &status, &z, &Z, revComplexPlan );
  TestStatus( &status, CODES( 0 ), 1 );
  LALCPrintTimeSeries( &z, "zz.out" );

  XLALDestroyRandomParams( randpar );

  LALDestroyRealFFTPlan( &status, &fwdRealPlan );
  TestStatus( &status, CODES( 0 ), 1 );
  LALDestroyRealFFTPlan( &status, &revRealPlan );
  TestStatus( &status, CODES( 0 ), 1 );
  LALDestroyComplexFFTPlan( &status, &fwdComplexPlan );
  TestStatus( &status, CODES( 0 ), 1 );
  LALDestroyComplexFFTPlan( &status, &revComplexPlan );
  TestStatus( &status, CODES( 0 ), 1 );

  LALCDestroyVector( &status, &Z.data );
  TestStatus( &status, CODES( 0 ), 1 );
  LALCDestroyVector( &status, &z.data );
  TestStatus( &status, CODES( 0 ), 1 );

  LALCDestroyVector( &status, &X.data );
  TestStatus( &status, CODES( 0 ), 1 );
  LALSDestroyVector( &status, &x.data );
  TestStatus( &status, CODES( 0 ), 1 );

  LALCheckMemoryLeaks();
  return 0;
}
Ejemplo n.º 6
0
int main( void )
{
  UINT4 resamplefac = 4;
  UINT4 seglen = 64 * 1024; /* after resampling */
  UINT4 numovrlpseg = 10; /* after resampling */
  UINT4 stride = seglen / 2; /* after resampling */
  UINT4 reclen = numovrlpseg * stride + stride; /* after resampling */
  /* UINT4 numovrlpseg = 8; */ /* after resampling */
  /* UINT4 stride = seglen; */ /* after resampling */
  /* UINT4 reclen = numovrlpseg * stride; */ /* after resampling */

  static LALStatus status;

  static AverageSpectrumParams  specpar;
  static REAL4FrequencySeries   fseries;
  static REAL4TimeSeries        tseries;
  static RandomParams          *randpar;
  static ResampleTSParams       resamplepar;
  static PassBandParamStruc     highpasspar;
  REAL8 avg;
  UINT4 j;
  UINT4 k;
  FILE *fp;


  /* allocate memory for time and frequency series */
  tseries.deltaT = 0.1;
  LALCreateVector( &status, &tseries.data, reclen * resamplefac );
  TESTSTATUS( &status );
  LALCreateVector( &status, &fseries.data, seglen / 2 + 1 );
  TESTSTATUS( &status );

  for ( j = 0; j < tseries.data->length; ++j )
    tseries.data->data[j] = sin( 0.1 * j );
  /*
  memset( tseries.data->data, 0,
      tseries.data->length * sizeof( *tseries.data->data ) );
  tseries.data->data[seglen/2-1] = 1;
  tseries.data->data[seglen/2] = 1;
  tseries.data->data[seglen/2+1] = 1;
  */
  /* create white Gaussian noise */
  LALCreateRandomParams( &status, &randpar, 0 );
  TESTSTATUS( &status );
  LALNormalDeviates( &status, tseries.data, randpar );
  TESTSTATUS( &status );
  LALDestroyRandomParams( &status, &randpar );
  TESTSTATUS( &status );

  /* resample */
  resamplepar.deltaT = resamplefac * tseries.deltaT;
  resamplepar.filterType = defaultButterworth;
  LALResampleREAL4TimeSeries( &status, &tseries, &resamplepar );
  TESTSTATUS( &status );

  /* do some simple colouring: high-pass filter */
  highpasspar.nMax = 4;
  highpasspar.f1   = -1;
  highpasspar.a1   = -1;
  highpasspar.f2   = 0.1 / tseries.deltaT; /* ~20% of Nyquist */
  highpasspar.a2   = 0.9; /* this means 10% attenuation at f2 */
  LALDButterworthREAL4TimeSeries( &status, &tseries, &highpasspar );
  TESTSTATUS( &status );

  specpar.method  = useMean;
  specpar.overlap = seglen - stride;

  LALCreateForwardRealFFTPlan( &status, &specpar.plan, seglen, 0 );
  TESTSTATUS( &status );
  specpar.window = XLALCreateRectangularREAL4Window(seglen);

  /* compute spectrum */
  LALREAL4AverageSpectrum( &status, &fseries, &tseries, &specpar );
  TESTSTATUS( &status );

  /* output results */
  fp = fopen( "out1.dat", "w" );
  for ( k = 0; k < fseries.data->length; ++k )
    fprintf( fp, "%e\t%e\n", k * fseries.deltaF, fseries.data->data[k] );
  fclose( fp );

  /* compute average */
  avg = 0;
  for ( k = 1; k < fseries.data->length - 1; ++k )
    avg += fseries.data->data[k];
  avg /= ( fseries.data->length - 2 );
  printf( "lal mean:\t%g\n", avg );

  /* use the xlal function */
  XLALREAL4AverageSpectrumWelch( &fseries, &tseries, seglen, stride,
      specpar.window, specpar.plan );
  if ( xlalErrno )
  {
    XLAL_PERROR();
    exit( 1 );
  }

  /* output results */
  fp = fopen( "out2.dat", "w" );
  for ( k = 0; k < fseries.data->length; ++k )
    fprintf( fp, "%e\t%e\n", k * fseries.deltaF, fseries.data->data[k] );
  fclose( fp );

  /* compute average */
  avg = 0;
  for ( k = 1; k < fseries.data->length - 1; ++k )
    avg += fseries.data->data[k];
  avg /= ( fseries.data->length - 2 );
  printf( "xlal mean:\t%g\n", avg );

  /* median-mean method */
  XLALREAL4AverageSpectrumMedianMean( &fseries, &tseries, seglen, stride,
      specpar.window, specpar.plan );
  if ( xlalErrno )
  {
    XLAL_PERROR();
    exit( 1 );
  }

  /* output results */
  fp = fopen( "out3.dat", "w" );
  for ( k = 0; k < fseries.data->length; ++k )
    fprintf( fp, "%e\t%e\n", k * fseries.deltaF, fseries.data->data[k] );
  fclose( fp );

  /* compute average */
  avg = 0;
  for ( k = 1; k < fseries.data->length - 1; ++k )
    avg += fseries.data->data[k];
  avg /= ( fseries.data->length - 2 );
  printf( "med mean:\t%g\n", avg );

  /* median method */
  XLALREAL4AverageSpectrumMedian( &fseries, &tseries, seglen, stride,
      specpar.window, specpar.plan );
  if ( xlalErrno )
  {
    XLAL_PERROR();
    exit( 1 );
  }

  /* output results */
  fp = fopen( "out4.dat", "w" );
  for ( k = 0; k < fseries.data->length; ++k )
    fprintf( fp, "%e\t%e\n", k * fseries.deltaF, fseries.data->data[k] );
  fclose( fp );

  /* compute average */
  avg = 0;
  for ( k = 1; k < fseries.data->length - 1; ++k )
    avg += fseries.data->data[k];
  avg /= ( fseries.data->length - 2 );
  printf( "median:\t\t%g\n", avg );

  /* cleanup */
  XLALDestroyREAL4Window( specpar.window );
  LALDestroyRealFFTPlan( &status, &specpar.plan );
  TESTSTATUS( &status );
  LALDestroyVector( &status, &fseries.data );
  TESTSTATUS( &status );
  LALDestroyVector( &status, &tseries.data );
  TESTSTATUS( &status );

  /* exit */
  LALCheckMemoryLeaks();
  return 0;
}
int main( int argc, char *argv[] )
{
  static LALStatus status;

  RealFFTPlan    *fwd = NULL;
  RealFFTPlan    *rev = NULL;
  REAL4Vector    *dat = NULL;
  REAL4Vector    *rfft = NULL;
  REAL4Vector    *ans = NULL;
  COMPLEX8Vector *dft = NULL;
  COMPLEX8Vector *fft = NULL;
#if LAL_CUDA_ENABLED
  /* The test itself should pass at 1e-4, but it might fail at
   * some rare cases where accuracy is bad for some numbers. */
  REAL8           eps = 3e-4;
#else
  /* very conservative floating point precision */
  REAL8           eps = 1e-6;
#endif
  REAL8           lbn;
  REAL8           ssq;
  REAL8           var;
  REAL8           tol;

  UINT4 nmax;
  UINT4 m;
  UINT4 n;
  UINT4 i;
  UINT4 j;
  UINT4 k;
  UINT4 s = 0;

  FILE *fp;


  ParseOptions( argc, argv );
  m = m_;
  n = n_;

  fp = verbose ? stdout : NULL ;

  if ( n == 0 )
  {
    nmax = 65536;
  }
  else
  {
    nmax = n--;
  }

  while ( n < nmax )
  {
    if ( n < 128 )
    {
      ++n;
    }
    else
    {
      n *= 2;
    }

    LALSCreateVector( &status, &dat, n );
    TestStatus( &status, CODES( 0 ), 1 );
    LALSCreateVector( &status, &rfft, n );
    TestStatus( &status, CODES( 0 ), 1 );
    LALSCreateVector( &status, &ans, n );
    TestStatus( &status, CODES( 0 ), 1 );
    LALCCreateVector( &status, &dft, n / 2 + 1 );
    TestStatus( &status, CODES( 0 ), 1 );
    LALCCreateVector( &status, &fft, n / 2 + 1 );
    TestStatus( &status, CODES( 0 ), 1 );
    LALCreateForwardRealFFTPlan( &status, &fwd, n, 0 );
    TestStatus( &status, CODES( 0 ), 1 );
    LALCreateReverseRealFFTPlan( &status, &rev, n, 0 );
    TestStatus( &status, CODES( 0 ), 1 );

    /*
     *
     * Do m trials of random data.
     *
     */
    for ( i = 0; i < m; ++i )
    {
      srand( s++ ); /* seed the random number generator */

      /*
       *
       * Create data and compute error tolerance.
       *
       * Reference: Kaneko and Liu,
       * "Accumulation of round-off error in fast fourier tranforms"
       * J. Asssoc. Comp. Mach, Vol 17 (No 4) 637-654, October 1970.
       *
       */
      srand( i ); /* seed the random number generator */
      ssq = 0;
      for ( j = 0; j < n; ++j )
      {
        dat->data[j] = 20.0 * rand() / (REAL4)( RAND_MAX + 1.0 ) - 10.0;
        ssq += dat->data[j] * dat->data[j];
        fp ? fprintf( fp, "%e\n", dat->data[j] ) : 0;
      }
      lbn = log( n ) / log( 2 );
      var = 2.5 * lbn * eps * eps * ssq / n;
      tol = 5 * sqrt( var ); /* up to 5 sigma excursions */
      fp ? fprintf( fp, "\neps = %e \ntol = %e\n", eps, tol ) : 0;

      /*
       *
       * Perform forward FFT and DFT (only if n < 100).
       *
       */
      LALForwardRealFFT( &status, fft, dat, fwd );
      TestStatus( &status, CODES( 0 ), 1 );
      LALREAL4VectorFFT( &status, rfft, dat, fwd );
      TestStatus( &status, CODES( 0 ), 1 );
      LALREAL4VectorFFT( &status, ans, rfft, rev );
      TestStatus( &status, CODES( 0 ), 1 );
      fp ?  fprintf( fp, "rfft()\t\trfft(rfft())\trfft(rfft())\n\n"  ) : 0;
      for ( j = 0; j < n; ++j )
      {
        fp ? fprintf( fp, "%e\t%e\t%e\n",
            rfft->data[j], ans->data[j], ans->data[j] / n ) : 0;
      }
      if ( n < 128 )
      {
        LALForwardRealDFT( &status, dft, dat );
        TestStatus( &status, CODES( 0 ), 1 );

        /*
         *
         * Check accuracy of FFT vs DFT.
         *
         */
        fp ? fprintf( fp, "\nfftre\t\tfftim\t\t" ) : 0;
        fp ? fprintf( fp, "dtfre\t\tdftim\n" ) : 0;
        for ( k = 0; k <= n / 2; ++k )
        {
          REAL8 fftre = creal(fft->data[k]);
          REAL8 fftim = cimag(fft->data[k]);
          REAL8 dftre = creal(dft->data[k]);
          REAL8 dftim = cimag(dft->data[k]);
          REAL8 errre = fabs( dftre - fftre );
          REAL8 errim = fabs( dftim - fftim );
          REAL8 avere = fabs( dftre + fftre ) / 2 + eps;
          REAL8 aveim = fabs( dftim + fftim ) / 2 + eps;
          REAL8 ferre = errre / avere;
          REAL8 ferim = errim / aveim;
          fp ? fprintf( fp, "%e\t%e\t", fftre, fftim ) : 0;
          fp ? fprintf( fp, "%e\t%e\n", dftre, dftim ) : 0;
          /* fp ? fprintf( fp, "%e\t%e\t", errre, errim ) : 0; */
          /* fp ? fprintf( fp, "%e\t%e\n", ferre, ferim ) : 0; */
          if ( ferre > eps && errre > tol )
          {
            fputs( "FAIL: Incorrect result from forward transform\n", stderr );
            fprintf( stderr, "\tdifference = %e\n", errre );
            fprintf( stderr, "\ttolerance  = %e\n", tol );
            fprintf( stderr, "\tfrac error = %e\n", ferre );
            fprintf( stderr, "\tprecision  = %e\n", eps );
            return 1;
          }
          if ( ferim > eps && errim > tol )
          {
            fputs( "FAIL: Incorrect result from forward transform\n", stderr );
            fprintf( stderr, "\tdifference = %e\n", errim );
            fprintf( stderr, "\ttolerance  = %e\n", tol );
            fprintf( stderr, "\tfrac error = %e\n", ferim );
            fprintf( stderr, "\tprecision  = %e\n", eps );
            return 1;
          }
        }
      }

      /*
       *
       * Perform reverse FFT and check accuracy vs original data.
       *
       */
      LALReverseRealFFT( &status, ans, fft, rev );
      TestStatus( &status, CODES( 0 ), 1 );
      fp ? fprintf( fp, "\ndat->data[j]\tans->data[j] / n\n" ) : 0;
      for ( j = 0; j < n; ++j )
      {
        REAL8 err = fabs( dat->data[j] - ans->data[j] / n );
        REAL8 ave = fabs( dat->data[j] + ans->data[j] / n ) / 2 + eps;
        REAL8 fer = err / ave;
        fp ? fprintf( fp, "%e\t%e\n", dat->data[j], ans->data[j] / n ) : 0;
        /* fp ? fprintf( fp, "%e\t%e\n", err, fer ) : 0; */
        if ( fer > eps && err > tol )
        {
          fputs( "FAIL: Incorrect result after reverse transform\n", stderr );
          fprintf( stderr, "\tdifference = %e\n", err );
          fprintf( stderr, "\ttolerance  = %e\n", tol );
          fprintf( stderr, "\tfrac error = %e\n", fer );
          fprintf( stderr, "\tprecision  = %e\n", eps );
          return 1;
        }
      }
    }

    LALSDestroyVector( &status, &dat );
    TestStatus( &status, CODES( 0 ), 1 );
    LALSDestroyVector( &status, &rfft );
    TestStatus( &status, CODES( 0 ), 1 );
    LALSDestroyVector( &status, &ans );
    TestStatus( &status, CODES( 0 ), 1 );
    LALCDestroyVector( &status, &dft );
    TestStatus( &status, CODES( 0 ), 1 );
    LALCDestroyVector( &status, &fft );
    TestStatus( &status, CODES( 0 ), 1 );
    LALDestroyRealFFTPlan( &status, &fwd );
    TestStatus( &status, CODES( 0 ), 1 );
    LALDestroyRealFFTPlan( &status, &rev );
    TestStatus( &status, CODES( 0 ), 1 );
  }

  LALCheckMemoryLeaks();
  return 0;
}