Ejemplo n.º 1
0
  void Run() {
    Image datImg;
    datImg.LoadRaw(input.c_str());
    const RawImage *datRaw = datImg.GetImage(); 
    //    ShiftTraces(*bfT0, *wellT0, datRaw->frames, datRaw->baseFrameRate, datRaw->timestamps, datRaw->image);
    SynchDat sdat; //GridMesh<TraceChunk> traceChunks;
    AddMetaData(sdat, datRaw, acqNum);
    GenerateDataChunks(*config, *bfT0, datRaw, config->row_step, config->col_step, *sigmaTMid, sdat.mChunks, datImg);
    serializer.Write(output.c_str(), sdat);

    if (config->doDebug) {
      char buffer[2048];
      string tmp = input.substr(input.size()-8,8);
      snprintf(buffer, sizeof(buffer), "comIn_%s", tmp.c_str());
      OutputTraceChunks(sdat.mChunks,buffer);

      TraceChunkSerializer readSer;
      //      GridMesh<TraceChunk> traceIn;
      SynchDat sdatIn;
      readSer.Read(output.c_str(),sdatIn);
      snprintf(buffer, sizeof(buffer), "decomOut_%s", tmp.c_str());
      OutputTraceChunks(sdatIn.mChunks,buffer);
    }
    datImg.Close();
  }
Ejemplo n.º 2
0
//@TODO:  Bad to have side effects on every image load from now on
// should be >explicit< pass of gain correction information to image loader
void ImageTransformer::CalculateGainCorrectionFromBeadfindFlow (char *_datDir, bool gain_debug_output)
{
  // calculate gain of each well from the beadfind and use for correction of all images thereafter
  Mask *gainCalcMask;
  std::string datdir = _datDir;
  std::string preBeadFind = datdir + "/beadfind_pre_0003.dat";
  Image bfImg;
  bfImg.SetImgLoadImmediate (false);
  bool loaded = bfImg.LoadRaw (preBeadFind.c_str());
  if (!loaded)
  {
    ION_ABORT ("*Error* - No beadfind file found, did beadfind run? are files transferred?  (" + preBeadFind + ")");
  }

  gainCalcMask = new Mask (bfImg.GetCols(),bfImg.GetRows());

  bfImg.FilterForPinned (gainCalcMask, MaskEmpty, false);
  bfImg.SetMeanOfFramesToZero (1,3);

  //@TODO:  implicit global variable->explicit global variable-> explicit variable
  GainCalculationFromBeadfind (gainCalcMask,bfImg.raw);
  printf ("Computed gain for each pixel using beadind image\n");

  if (gain_debug_output)
  {
    DumpTextGain(bfImg.GetCols(),bfImg.GetRows());
  }

  bfImg.Close();
  delete gainCalcMask;
}
Ejemplo n.º 3
0
void ImageSpecClass::DeriveSpecsFromDat ( SystemContext &sys_context, ImageControlOpts &img_control, SpatialContext &loc_context )
{
  Image img;

  ReadFirstImage(img, sys_context, img_control, loc_context);

  TimeStampsFromImage(img,img_control);
  DimensionsFromImage(img,loc_context);

  img.Close();
}
Ejemplo n.º 4
0
void LoadTraces(Mask &mask, vector<string> &files, vector<Traces> &flows) {
  flows.resize(files.size());
  for (size_t i = 0; i < files.size(); i++) {
    Image img;
    bool loaded = img.LoadRaw(files[i].c_str());
    if (!loaded) {
      ION_ABORT("Couldn't load file: " + files[i]);
    }
    flows[i].Init(&img, &mask, FRAMEZERO, FRAMELAST, FIRSTDCFRAME,LASTDCFRAME);
    img.Close();
    flows[i].CalcT0(true);
    flows[i].FillCriticalFrames();
    flows[i].CalcReference(50,50,flows[i].mGridMedian);
  }
}
Ejemplo n.º 5
0
void ChkFile(char *fname, size_t maxX=0, size_t maxY=0, size_t maxF=0, bool verbose=false)
{
	Image loader;

	if (loader.LoadRaw(fname))
	{
        // this one is ok
        //printf("File %s OK\n",fname);
        cout << fname << " rows=" << loader.GetRows() << " cols=" << loader.GetCols() << " fames=" << loader.GetFrames() << endl << flush;
        const RawImage *raw = loader.GetImage();

        if (verbose)
        {
            size_t frames = loader.GetFrames();
            size_t rows = loader.GetRows();
            size_t cols = loader.GetCols();
            size_t stride = rows*cols;
            cout << "flow\tx(col)\ty(row)\tvalue" << endl << flush;
            for (size_t f = 0; f < frames; f++) {
                if (maxF>0 && f>=maxF)
                    break;
              // First image copied in for this frame
              for (size_t r = 0; r < rows; r++) {
                  if (maxY>0 && r>=maxY)
                      break;
                for (size_t c = 0; c < cols; c++) {
                    if (maxX>0 && c>=maxX)
                        break;
                  cout << f << "\t" << c << "\t" << r << "\t" << raw->image[r * cols + c + stride * f] << endl << flush;
                }
              }
            }
        }
        loader.Close();
    }
	else
	{
		printf("File %s FAILED\n",fname);
		Error=1;
		exit(-1);
	}

}
Ejemplo n.º 6
0
int main(int argc, const char *argv[]) {
  OptArgs opts;  
  TraceConfig config;
  string inputDir;
  string outputDir;
  bool help;

  opts.ParseCmdLine(argc, argv);
  opts.GetOption(inputDir, "", '-', "source-dir");
  opts.GetOption(outputDir, "", '-', "output-dir");
  opts.GetOption(config.precision, "5", '-', "precision");
  opts.GetOption(config.numEvec, "7", '-', "num-evec");
  opts.GetOption(config.doDebug, "false", '-', "debug-files");
  opts.GetOption(config.compressionType, "delta", '-', "compression");
  opts.GetOption(config.numFlows, "-1", '-', "num-flows");
  opts.GetOption(config.numCores, "6", '-', "num-cores");
  opts.GetOption(config.errCon,"0",'-',"err-con");
  opts.GetOption(config.rankGood,"0",'-',"rank-good");
  opts.GetOption(config.pivot,"0",'-',"pivot");
  opts.GetOption(help, "false", 'h', "help");
  opts.GetOption(config.isThumbnail, "false", '-', "thumbnail");
  opts.GetOption(config.use_hard_est, "false",'-', "use-hard-est");
  opts.GetOption(config.t0_hard, "0", '-', "t0-hard");
  opts.GetOption(config.tmid_hard, "0", '-', "tmid-hard");
  opts.GetOption(config.sigma_hard, "0", '-', "sigma-hard");
  opts.GetOption(config.row_step, "100", '-', "row-step");
  opts.GetOption(config.col_step, "100", '-', "col-step");
  opts.GetOption(config.bg_param, "", '-', "region-param");
  opts.GetOption(config.grind_acq_0, "0", '-', "grind-acq0");
  if(help || inputDir.empty() || outputDir.empty()) {
    usage();
  }
  char *explog_path = NULL;
  explog_path = MakeExpLogPathFromDatDir(inputDir.c_str());
  int numFlows = config.numFlows;
  if (numFlows < 0) { 
    numFlows = GetTotalFlows(explog_path); 
  }

  // Check and setup our compression type
  TraceChunkSerializer serializer;
  serializer.SetRecklessAbandon(true);
  if (config.compressionType == "svd") {
    SvdDatCompress *dc = new SvdDatCompress(config.precision, config.numEvec);
    serializer.SetCompressor(dc);
    cout << "Doing lossy svd compression. (" << serializer.GetCompressionType() << ")" << endl;
  }
  // else if (config.compressionType == "svd+") {
  //   SvdDatCompressPlus *dc = new SvdDatCompressPlus();
  //   serializer.SetCompressor(dc);
  //   cout << "Doing lossy svd compression. (" << serializer.GetCompressionType() << ")" << endl;
  // }
  // else if (config.compressionType == "svd++") {
  //   SvdDatCompressPlusPlus *dc = new SvdDatCompressPlusPlus();
  //   if (config.errCon >0 )
  //     dc->SetErrCon(config.errCon);
  //   if (config.rankGood > 0 )
  //     dc->SetRankGood(config.rankGood);
  //   if (config.pivot > 0)
  //     dc->SetPivot(config.pivot);
  //   serializer.SetCompressor(dc);
  //   cout << "Doing lossy svd compression for good traces and delta for bad ones. (" << serializer.GetCompressionType() << ")" << endl;
  // }
  else if (config.compressionType == "delta") {
    VencoLossless *venco = new VencoLossless();
    serializer.SetCompressor(venco);
    cout << "Doing lossless delta compression. (" << serializer.GetCompressionType() << ")" << endl;
  }
  else if (config.compressionType == "delta-plain") {
    DeltaComp *delta = new DeltaComp();
    serializer.SetCompressor(delta);
    cout << "Doing lossless delta plain compression. (" << serializer.GetCompressionType() << ")" << endl;
  }
  else if (config.compressionType == "delta-plain-fst") {
    DeltaCompFst *delta = new DeltaCompFst();
    serializer.SetCompressor(delta);
    cout << "Doing lossless delta plain fast compression. (" << serializer.GetCompressionType() << ")" << endl;
  }
  else if (config.compressionType == "delta-plain-fst-smx") {
   DeltaCompFstSmX *delta = new DeltaCompFstSmX();
    serializer.SetCompressor(delta);
    cout << "Doing lossless delta plain fast compression. (" << serializer.GetCompressionType() << ")" << endl;
  }
  else if (config.compressionType == "none") {
    TraceCompressor *vanilla = new TraceNoCompress();
    serializer.SetCompressor(vanilla);
    cout << "Doing no compression. (" << serializer.GetCompressionType() << ")" << endl;
  }
  else {
    ION_ABORT("Don't recognize compression type: " + config.compressionType);
  }

  const char *id = GetChipId(explog_path);
  if (explog_path) free (explog_path);
  ChipIdDecoder::SetGlobalChipId(id);
  ImageTransformer::CalibrateChannelXTCorrection(inputDir.c_str(), "lsrowimage.dat");

  Image bfImg1;
  string bfFile = inputDir + "/beadfind_pre_0003.dat";
  bfImg1.LoadRaw(bfFile.c_str());
  const RawImage *bf1raw = bfImg1.GetImage(); 
  Mask mask(bf1raw->cols, bf1raw->rows);
  ImageTransformer::XTChannelCorrect(bfImg1.raw,bfImg1.results_folder);

  bfImg1.FilterForPinned (&mask, MaskEmpty, false);

  Image bfImg2;
  string bfFile2 = inputDir + "/beadfind_pre_0001.dat";
  bfImg2.LoadRaw(bfFile2.c_str());
  ImageTransformer::XTChannelCorrect(bfImg2.raw,bfImg1.results_folder);

  bfImg2.FilterForPinned (&mask, MaskEmpty, false);
  const RawImage *bf2raw = bfImg2.GetImage(); 


  GridMesh<T0Prior> t0Prior;
  T0Calc bfT0;
  /* Calc t0 and get prior. */
  cout << "Doing beadfind t0" << endl;
  GenerateBfT0Prior(config, bf1raw->image, bf1raw->baseFrameRate, bf1raw->rows, bf1raw->cols,
                    bf1raw->frames, bf1raw->timestamps,
                    config.row_step, config.col_step, &mask, bfT0, t0Prior);

  GridMesh<T0Prior> t0Prior2;
  T0Calc bfT02;
  GenerateBfT0Prior(config, bf2raw->image, bf2raw->baseFrameRate, bf2raw->rows, bf2raw->cols,
                    bf2raw->frames, bf2raw->timestamps,
                    config.row_step, config.col_step, &mask, bfT02, t0Prior2);

  SigmaTMidNucEstimation sigmaEst;
  sigmaEst.Init(config.rate_sigma_intercept, config.rate_sigma_slope, 
                config.t0_tmid_intercept, config.t0_tmid_slope, bf1raw->baseFrameRate);
  GridMesh<SigmaEst> sigmaTMid;
  bfImg1.Close();
  bfImg2.Close();

  // Calculate individual well t0 by looking at neighboring regions
  vector<float> wellT0;
  bfT0.CalcIndividualT0(wellT0, 0);
  vector<float> wellT02;
  bfT02.CalcIndividualT0(wellT02, 0);
  for (size_t i =0; i< wellT0.size();i++) {
    if (wellT0[i] > 0 && wellT02[i] > 0) {
      wellT0[i] = (wellT0[i] + wellT02[i])/2.0f;
    }
    else {
      wellT0[i] = max(wellT0[i], wellT02[i]);
    }
  }

  // Average the region level t0, should we do this first and then just do sinle well level?
  for (size_t bIx = 0; bIx < bfT0.GetNumRegions(); bIx++) {
    double t1 = bfT0.GetT0(bIx);
    double t2 = bfT02.GetT0(bIx);
    if (t1 > 0 && t2 > 0) {
      t1 = (t1 + t2)/2.0;
    }
    else {
      t1 = max(t1,t2);
    }
    bfT0.SetT0(bIx, t1);
  }

  // Single thread first dat
  for (size_t datIx = 0; datIx < 1; ++datIx) {
    cout << "Doing: " << datIx << endl;
    char buffer[2048];
    snprintf(buffer, sizeof(buffer), "%s/acq_%.4d.dat", inputDir.c_str(), (int) datIx);
    string datFile = buffer;
    /* Use prior to calculate t0 and slope. */
    Image datImg;
    T0Calc t0;
    datImg.LoadRaw(datFile.c_str());
    //    ImageTransformer::XTChannelCorrect(datImg.raw,datImg.results_folder);
    const RawImage *datRaw = datImg.GetImage(); 

    /* Estimate sigma and t_mid_nuc */
    if (datIx == 0) {
      cout << "Doing acquisition t0" << endl;

      GenerateAcqT0Prior(config, datRaw->image, datRaw->baseFrameRate, datRaw->rows, datRaw->cols,
                         datRaw->frames, datRaw->timestamps,
                         config.row_step, config.col_step, &mask, t0, t0Prior);
      
      ClockTimer timer;
      cout << "Estimating sigma." << endl;
      sigmaTMid.Init(datRaw->rows, datRaw->cols, config.row_step, config.col_step);
      for (size_t bIx = 0; bIx < t0.GetNumRegions(); bIx++) {
        t0.SetT0(bIx, bfT0.GetT0(bIx));
      }
      int neighbors = 2;
      if (config.isThumbnail) {
        cout << "Doing thumbnail version of slope." << endl;
        neighbors = 1;
      }
      EstimateSigmaValue(t0, sigmaEst, sigmaTMid, neighbors);
      timer.PrintMilliSeconds(cout,"Sigma Est took:");
      string sigmaFile = outputDir + "/sigma_tmid_est.txt";
      OutputSigmaTmidEstimates(sigmaTMid, sigmaFile.c_str());
    }

    /* For each region do shifting */
    ClockTimer timer;
    cout << "Shifting traces" << endl;
    timer.StartTimer();
    //    ShiftTraces(bfT0, wellT0, datRaw->frames, datRaw->baseFrameRate, datRaw->timestamps, datRaw->image);
    timer.PrintMilliSeconds(cout,"Shift took:");
    if (!config.bg_param.empty()) {
      DataCube<int> rowsCols;
      DataCube<float> tmidSigma;
      DataCube<float> fitTmidSigma;
      string path = config.bg_param + ":/region/region_location";
      if (!H5File::ReadDataCube(path, rowsCols)) {
        ION_ABORT("Couldn't read file: " + path);
      }
      path = config.bg_param + ":/region/region_init_param";
      if (!H5File::ReadDataCube(path, fitTmidSigma)) {
        ION_ABORT("Couldn't read file: " + path);
      }
      for (size_t i = 0; i < rowsCols.GetNumX(); i++) {
        int row = rowsCols.At(i,1,0);
        int col = rowsCols.At(i,0,0);
        SigmaEst &est = sigmaTMid.GetItemByRowCol(row, col);
        float tmid_est =  fitTmidSigma.At(i,0,0);
        float sigma_est = fitTmidSigma.At(i,1,0);
        est.mTMidNuc = tmid_est;
        est.mSigma = sigma_est;
      }
      string fitSigmaFile = outputDir + "/bg_fit_sigma_tmid_est.txt";
      OutputSigmaTmidEstimates(sigmaTMid, fitSigmaFile.c_str());

      // path = config.bg_param + ":/region/region_init_param";
      // if (!H5File::ReadMatrix(path, tmidSigma)) {
      //   ION_ABORT("Couldn't read file: " + path);
      // }
      // for (size_t i = 0; i < rowsCols.n_rows; i++) {
      //   int row = rowsCols.at(i,0);
      //   int col = rowsCols.at(i,1);
      //   SigmaEst &est = sigmaTMid.GetItemByRowCol(row, col);
      //   float tmid_est =  tmidSigma.at(i,0);
      //   float sigma_est = tmidSigma.at(i,1);
      //   est.mTMidNuc = tmid_est;
      //   est.mSigma = sigma_est;
      // }
      // string sigmaFile = outputDir + "/supplied_sigma_tmid_est.txt";
      // OutputSigmaTmidEstimates(sigmaTMid, sigmaFile.c_str());
    }
    else if (config.use_hard_est) {
      for (size_t i = 0; i < bfT0.GetNumRegions(); i++) {
        bfT0.SetT0(i,config.t0_hard * datRaw->baseFrameRate + config.time_start_slop);
      }
      for (size_t i = 0; i < sigmaTMid.GetNumBin(); i++) {
        SigmaEst &est = sigmaTMid.GetItem(i);
        est.mTMidNuc = config.tmid_hard;
        est.mSigma = config.sigma_hard;
        est.mT0 = config.t0_hard;
      }
    }
    /* Use t0 and sigma to get the time compression bkgModel wants. */
    cout << "Generating chunks" << endl;
    //    GridMesh<TraceChunk> traceChunks;
    SynchDat sdat;
    if (datIx == 0  && config.grind_acq_0 > 0) {
      int nTimes = config.grind_acq_0;
      timer.StartTimer();
      size_t processMicroSec = 0;
      size_t hdf5MicroSec = 0;
      size_t compressMicroSec = 0;
      size_t convertMicroSec = 0;
      for (int i = 0; i <nTimes; i++) {
        //GridMesh<TraceChunk> traceChunken;
        SynchDat sdatIn;
        AddMetaData(sdat, datRaw, datIx);
	ClockTimer convTimer;
        GenerateDataChunks(config, bfT0, datRaw, config.row_step, config.col_step, sigmaTMid, sdatIn.mChunks,datImg);
	convertMicroSec += convTimer.GetMicroSec();
        snprintf(buffer, sizeof(buffer), "%s/acq_%.4d.sdat", outputDir.c_str(), (int)datIx);
        serializer.Write(buffer, sdatIn);
	processMicroSec += serializer.computeMicroSec;
	hdf5MicroSec += serializer.ioMicroSec;
	compressMicroSec += serializer.compressMicroSec;
      }
      size_t usec = timer.GetMicroSec();
      cout << "Took: " << usec / 1.0e6 << " seconds, " << usec / (nTimes * 1.0f) << " usec per write." << endl;
      timer.PrintMilliSeconds(cout,"Chunks took:");
      cout << "Read took: " << processMicroSec / (1e3 * nTimes) << " milli seconds per sdat compute." << endl;
      cout << "Read took: " << hdf5MicroSec / (1e3 * nTimes) << " milli seconds per sdat hdf5." << endl;
      cout << "Read took: " << compressMicroSec / (1e3 * nTimes) << " milli seconds per sdat compressing." << endl;
      cout << "Read took: " << convertMicroSec / (1e3 * nTimes) << " milli seconds per sdat converting." << endl;
      exit(0);
    }
    else {
      timer.StartTimer();
      AddMetaData(sdat, datRaw, datIx);
      GenerateDataChunks(config, bfT0, datRaw, config.row_step, config.col_step, sigmaTMid, sdat.mChunks,datImg);
      timer.PrintMilliSeconds(cout,"Chunks took:");
        if (datIx == 0 && config.doDebug) {
          OutputTraceChunks(sdat.mChunks,"flow_0_data_chunks.txt");
        }
    }
    datImg.Close();    

    /* Serialize onto disk. */
    snprintf(buffer, sizeof(buffer), "%s/acq_%.4d.sdat", outputDir.c_str(), (int)datIx);
    serializer.Write(buffer, sdat);
    /* Read back in first flow for checking */
    if (datIx == 0) {
      TraceChunkSerializer readSerializer;
      readSerializer.SetRecklessAbandon(true);
      //      GridMesh<TraceChunk> traceChunksIn;  
      SynchDat sdatIn;
      readSerializer.Read(buffer, sdatIn);
      if (datIx == 0 && config.doDebug) {
        OutputTraceChunks(sdatIn.mChunks, "flow_0_data_chunks_read.txt");
      }
      SampleQuantiles<float> s(50000);
      SampleQuantiles<float> s2(50000);
      SampleQuantiles<float> sAbs(50000);
      SampleStats<double> ss;
      int diffCount = 0;
      for (size_t bIx = 0; bIx < sdatIn.mChunks.mBins.size(); bIx++) {
        if (sdatIn.mChunks.mBins[bIx].mT0 != sdat.mChunks.mBins[bIx].mT0) {
          cout << "Got: " << sdatIn.mChunks.mBins[bIx].mT0 << " vs: " << sdat.mChunks.mBins[bIx].mT0 << endl;
          exit(1);
        }
        for (size_t i = 0; i < sdatIn.mChunks.mBins[bIx].mData.size(); i++) {
          double diff = (double)sdatIn.mChunks.mBins[bIx].mData[i] - (double)sdat.mChunks.mBins[bIx].mData[i];
          if (!std::isfinite(diff)) {
            cout << "NaNs!!" << endl;
          }
          if (diffCount < 10 && fabs(diff) > .00001) { // != 0) {
            diffCount++;
            cout << "Bin: " << bIx << " well: " << i << " diff is: " << diff << endl;
          }
          s.AddValue(diff);
          sAbs.AddValue(fabs(diff));
          ss.AddValue(sqrt(diff * diff));
          s2.AddValue(sqrt(diff * diff));
        }
      }
      cout << "Median rms: " << s2.GetMedian()  << " Avg: " << ss.GetMean() << " diff: " << s.GetMedian() << endl;
      cout << "Abs(diff) Quantiles:" << endl;
      for (size_t i = 0; i <= 100; i+=10) {
        cout << i << "\t" << sAbs.GetQuantile(i/100.0) << endl;
      }
    }      
  }
  // do the next N flows multithreaded
  if (numFlows > 1) {
    PJobQueue jQueue (config.numCores, numFlows-1);  
    vector<CreateSDat> jobs(numFlows -1);
    // for (int i = 0; i < 4; i++) {
    //   char buffer[2048];
    //   snprintf(buffer, sizeof(buffer), "%s/beadfind_pre_%.4d.dat", inputDir.c_str(), (int) i);
    //   string input = buffer;
    //   snprintf(buffer, sizeof(buffer), "%s/beadfind_pre_%.4d.sdat", outputDir.c_str(), (int)i);
    //   string output = buffer;
    //   jobs[i].Init(&config, input, output, &wellT0, &bfT0, &sigmaTMid);
    //   jQueue.AddJob(jobs[i]);
    // }

    // jQueue.WaitUntilDone();
    for (int i = 1; i < numFlows; i++) {
      char buffer[2048];
      snprintf(buffer, sizeof(buffer), "%s/acq_%.4d.dat", inputDir.c_str(), (int) i);
      string input = buffer;
      snprintf(buffer, sizeof(buffer), "%s/acq_%.4d.sdat", outputDir.c_str(), (int)i);
      string output = buffer;
      jobs[i-1].Init(&config, input, output, &wellT0, &bfT0, &sigmaTMid, i);
      jQueue.AddJob(jobs[i-1]);
    }
    jQueue.WaitUntilDone();
  }
  /* Serialize into backbround models */
  cout << "Done." << endl;
}
Ejemplo n.º 7
0
void BFReference::CalcSignalReference(const std::string &datFile, const std::string &bgFile,
				      Mask &mask, int traceFrame) {
  Image bfImg;
  Image bfBkgImg;
  bfImg.SetImgLoadImmediate (false);
  bfBkgImg.SetImgLoadImmediate (false);
  bool loaded = bfImg.LoadRaw(datFile.c_str());
  bool bgLoaded = bfBkgImg.LoadRaw(bgFile.c_str());
  if (!loaded) {
    ION_ABORT("*Error* - No beadfind file found, did beadfind run? are files transferred?  (" + datFile + ")");
  }
  if (!bgLoaded) {
    ION_ABORT("*Error* - No beadfind background file found, did beadfind run? are files transferred?  (" + bgFile + ")");
  }
  const RawImage *raw = bfImg.GetImage();
  
  assert(raw->cols == GetNumCol());
  assert(raw->rows == GetNumRow());
  assert(raw->cols == mask.W());
  assert(raw->rows == mask.H());
  bfImg.FilterForPinned(&mask, MaskEmpty, false);
  bfBkgImg.FilterForPinned(&mask, MaskEmpty, false);

  // bfImg.XTChannelCorrect(&mask);
  bfImg.XTChannelCorrect();
  // bfBkgImg.XTChannelCorrect(&mask);
  bfBkgImg.XTChannelCorrect();

  Traces trace;  
  trace.Init(&bfImg, &mask, FRAMEZERO, FRAMELAST, FIRSTDCFRAME,LASTDCFRAME);
  bfImg.Close();
  Traces bgTrace;
  bgTrace.Init(&bfBkgImg, &mask, FRAMEZERO, FRAMELAST, FIRSTDCFRAME,LASTDCFRAME);
  bfBkgImg.Close();
  if (mDoRegionalBgSub) {
    trace.SetMeshDist(0);
    bgTrace.SetMeshDist(0);
  }
  trace.SetT0Step(mRegionXSize);
  bgTrace.SetT0Step(mRegionXSize);
  trace.CalcT0(true);
  size_t numWells = trace.GetNumRow() * trace.GetNumCol();
  for (size_t i = 0; i < numWells; i++) {
    trace.SetT0(max(trace.GetT0(i) - 3, 0.0f), i);
  }
  bgTrace.SetT0(trace.GetT0());
  trace.T0DcOffset(0,4);
  trace.FillCriticalFrames();
  trace.CalcReference(mRegionXSize,mRegionYSize,trace.mGridMedian);
  bgTrace.T0DcOffset(0,4);
  bgTrace.FillCriticalFrames();
  bgTrace.CalcReference(mRegionXSize,mRegionYSize,bgTrace.mGridMedian);

  int length = GetNumRow() * GetNumCol();
  mBfMetric.resize(length, std::numeric_limits<double>::signaling_NaN());
  vector<double> rawTrace(trace.GetNumFrames());
  vector<double> bgRawTrace(bgTrace.GetNumFrames());
  int pinned =0, excluded = 0;
  for (int i = 0; i < length; i++) {
    if (mask[i] & MaskExclude || mask[i] & MaskPinned) {
      continue;
      if (mask[i] & MaskExclude) {
        excluded++;
      }
      else if (mask[i] & MaskPinned) {
        pinned++;
      }
    }
    trace.GetTraces(i, rawTrace.begin());
    bgTrace.GetTraces(i, bgRawTrace.begin());
    mBfMetric[i] = 0;
    for (int s = 3; s < 15; s++) {
      mBfMetric[i] += rawTrace[s] - bgRawTrace[s];
    }
  }
  cout << "Pinned: " << pinned << " excluded: " << excluded << endl;
  for (int i = 0; i < length; i++) {
    if (mask[i] & MaskExclude || mask[i] & MaskPinned || mask[i] & MaskIgnore) {
      mWells[i] = Exclude;
    }
    else {
      mask[i] = MaskIgnore;
    }
  }
  cout << "Filling reference. " << endl;
  FillInReference(mWells, mBfMetric, mGrid, mMinQuantile, mMaxQuantile, mNumEmptiesPerRegion);
  for (int i = 0; i < length; i++) {
    if (mWells[i] == Reference) {
      mask[i] = MaskEmpty;
    }
  }
  bfImg.Close();
}
Ejemplo n.º 8
0
void BFReference::CalcSignalReference2(const std::string &datFile, const std::string &bgFile,
				      Mask &mask, int traceFrame) {
  Image bfImg;
  Image bfBkgImg;
  bfImg.SetImgLoadImmediate (false);
  bfBkgImg.SetImgLoadImmediate (false);
  bool loaded = bfImg.LoadRaw(datFile.c_str());
  bool bgLoaded = bfBkgImg.LoadRaw(bgFile.c_str());
  if (!loaded) {
    ION_ABORT("*Error* - No beadfind file found, did beadfind run? are files transferred?  (" + datFile + ")");
  }
  if (!bgLoaded) {
    ION_ABORT("*Error* - No beadfind background file found, did beadfind run? are files transferred?  (" + bgFile + ")");
  }
  const RawImage *raw = bfImg.GetImage();
  
  assert(raw->cols == GetNumCol());
  assert(raw->rows == GetNumRow());
  assert(raw->cols == mask.W());
  assert(raw->rows == mask.H());
  int StartFrame = bfImg.GetFrame(-663); //5
  int EndFrame = bfImg.GetFrame(350); //20
  int NNinnerx = 1, NNinnery = 1, NNouterx = 12, NNoutery = 8;
  cout << "DC start frame: " << StartFrame << " end frame: " << EndFrame << endl;
  bfImg.FilterForPinned(&mask, MaskEmpty, false);
  bfImg.XTChannelCorrect();
  // bfImg.XTChannelCorrect(&mask);
  Traces trace;  
  trace.Init(&bfImg, &mask, FRAMEZERO, FRAMELAST, FIRSTDCFRAME,LASTDCFRAME);
  bfImg.Normalize(StartFrame, EndFrame);
  if (mDoRegionalBgSub) {
     trace.SetMeshDist(0);
  }
  trace.CalcT0(true);
  if (mDoRegionalBgSub) {
    GridMesh<float> grid;
    grid.Init(raw->rows, raw->cols, mRegionYSize, mRegionXSize);
    int numBin = grid.GetNumBin();
    int rowStart = -1, rowEnd = -1, colStart = -1, colEnd = -1;
    for (int binIx = 0; binIx < numBin; binIx++) {
      cout << "BG Subtract Region: " << binIx << endl;
      grid.GetBinCoords(binIx, rowStart, rowEnd, colStart, colEnd);
      Region reg;
      reg.row = rowStart;
      reg.h = rowEnd - rowStart;
      reg.col = colStart;
      reg.w = colEnd - colStart;
      bfImg.BackgroundCorrectRegion(&mask, reg, MaskAll, MaskEmpty, NNinnerx, NNinnery, NNouterx, NNoutery, NULL);
    }
  }
  else {
    bfImg.BackgroundCorrect(&mask, MaskEmpty, MaskEmpty, NNinnerx, NNinnery, NNouterx, NNoutery, NULL);
  }
  int length = GetNumRow() * GetNumCol();
  mBfMetric.resize(length, std::numeric_limits<double>::signaling_NaN());
  for (int wIx = 0; wIx < length; wIx++) {
    if (mask[wIx] & MaskExclude || mask[wIx] & MaskPinned) 
      continue;
    int t0 = (int)trace.GetT0(wIx);
    mBfMetric[wIx] = 0;
    float zSum  = 0;
    int count = 0;
    for (int fIx = min(t0-20, 0); fIx < t0-10; fIx++) {
      zSum += bfImg.At(wIx,fIx);
      count ++;
    }
    for (int fIx = t0+3; fIx < t0+15; fIx++) {
      mBfMetric[wIx] += (bfImg.At(wIx,fIx) - (zSum / count));
    }
  }
  bfImg.Close();
  for (int i = 0; i < length; i++) {
    if (mask[i] & MaskExclude || mWells[i] == Exclude) {
      mWells[i] = Exclude;
    }
    else {
      mask[i] = MaskIgnore;
    }
  }
  cout << "Filling reference. " << endl;
  FillInReference(mWells, mBfMetric, mGrid, mMinQuantile, mMaxQuantile, mNumEmptiesPerRegion);
  for (int i = 0; i < length; i++) {
    if (mWells[i] == Reference) {
      mask[i] = MaskEmpty;
    }
  }
}
Ejemplo n.º 9
0
void BFReference::CalcReference(const std::string &datFile, Mask &mask, std::vector<float> &metric) {
  Image bfImg;
  bfImg.SetImgLoadImmediate (false);
  bool loaded = bfImg.LoadRaw(datFile.c_str());
  if (!loaded) {
    ION_ABORT("*Error* - No beadfind file found, did beadfind run? are files transferred?  (" + datFile + ")");
  }

  const RawImage *raw = bfImg.GetImage();
  
  assert(raw->cols == GetNumCol());
  assert(raw->rows == GetNumRow());
  assert(raw->cols == mask.W());
  assert(raw->rows == mask.H());
  if (!mDebugFile.empty()) {
    DebugTraces(mDebugFile, mask, bfImg);
  }
  bfImg.FilterForPinned(&mask, MaskEmpty, false);
  // int StartFrame= bfImg.GetFrame((GetDcStart()*1000/15)-1000);
  // int EndFrame = bfImg.GetFrame((GetDcEnd()*1000/15)-1000);
  int StartFrame = bfImg.GetFrame(-663); //5
  int EndFrame = bfImg.GetFrame(350); //20
  cout << "DC start frame: " << StartFrame << " end frame: " << EndFrame << endl;
  bfImg.XTChannelCorrect();
  FilterForOutliers(bfImg, mask, mIqrOutlierMult, mRegionYSize, mRegionXSize);
  bfImg.Normalize(StartFrame, EndFrame);
  // bfImg.XTChannelCorrect(&mask);

  int NNinnerx = 1, NNinnery = 1, NNouterx = 12, NNoutery = 8;
  if (mDoRegionalBgSub) {
    GridMesh<float> grid;
    grid.Init(raw->rows, raw->cols, mRegionYSize, mRegionXSize);
    int numBin = grid.GetNumBin();
    int rowStart = -1, rowEnd = -1, colStart = -1, colEnd = -1;
    for (int binIx = 0; binIx < numBin; binIx++) {
      grid.GetBinCoords(binIx, rowStart, rowEnd, colStart, colEnd);
      Region reg;
      reg.row = rowStart;
      reg.h = rowEnd - rowStart;
      reg.col = colStart;
      reg.w = colEnd - colStart;
      bfImg.BackgroundCorrectRegion(&mask, reg, MaskAll, MaskEmpty, NNinnerx, NNinnery, NNouterx, NNoutery, NULL);
    }
  }
  else {
    bfImg.BackgroundCorrect(&mask, MaskEmpty, MaskEmpty, NNinnerx, NNinnery, NNouterx, NNoutery, NULL);
  }
  Region region;
  region.col = 0;
  region.row = 0;
  region.w = GetNumCol(); //mGrid.GetColStep();
  region.h = GetNumRow(); // mGrid.GetRowStep();

  int startFrame = bfImg.GetFrame(12); // frame 15 on uncompressed 314
  //  int endFrame = bfImg.GetFrame(raw->timestamps[bfImg.Ge]5300); // frame 77 or so
  int endFrame = bfImg.GetFrame(5000); // frame 77 or so
  bfImg.CalcBeadfindMetric_1(&mask, region, "pre", startFrame, endFrame);
  const double *results = bfImg.GetResults();

  int length = GetNumRow() * GetNumCol();
  metric.resize(length);
  copy(&results[0], &results[0] + (length), metric.begin());
  bfImg.Close();
}