// SPDX-License-Identifier: LGPL-3.0-or-other // Copyright (C) 2021 Contributors to the SLS Detector Package //#include "sls/ansi.h" #include //#include "moench03T1ZmqData.h" #ifdef NEWRECEIVER #ifndef RECT #include "moench03T1ReceiverDataNew.h" #endif #ifdef RECT #include "moench03T1ReceiverDataNewRect.h" #endif #endif #ifdef CSAXS_FP #include "moench03T1ReceiverData.h" #endif #ifdef OLDDATA #include "moench03Ctb10GbT1Data.h" #endif #ifdef REORDERED #include "moench03T1ReorderedData.h" #endif // #include "interpolatingDetector.h" //#include "etaInterpolationPosXY.h" // #include "linearInterpolation.h" // #include "noInterpolation.h" #include "multiThreadedAnalogDetector.h" #include "singlePhotonDetector.h" //#include "interpolatingDetector.h" #include #include #include #include #include using namespace std; int main(int argc, char *argv[]) { if (argc<6) { cout << "Usage is " << argv[0] << "indir outdir fname runmin runmax " << endl; return 1; } int p=10000; int fifosize=1000; int nthreads=1; int nsubpix=25; int etabins=nsubpix*10; double etamin=-1, etamax=2; int csize=3; int nx=400, ny=400; int save=1; int nsigma=5; int nped=1000; int ndark=100; int ok; int iprog=0; #ifdef NEWRECEIVER #ifdef RECT cout << "Should be rectangular!" <getDetectorSize(nx,ny); cout << "nx " << nx << " ny " << ny << endl; //moench03T1ZmqData *decoder=new moench03T1ZmqData(); singlePhotonDetector *filter=new singlePhotonDetector(decoder,csize, nsigma, 1, 0, nped, 200); // char tit[10000]; cout << "filter " << endl; // filter->readPedestals("/scratch/ped_100.tiff"); // interp->readFlatField("/scratch/eta_100.tiff",etamin,etamax); // cout << "filter "<< endl; int size = 327680;////atoi(argv[3]); int* image; //int* image =new int[327680/sizeof(int)]; filter->newDataSet(); int ff, np; int dsize=decoder->getDataSize(); cout << " data size is " << dsize; char data[dsize]; ifstream filebin; char *indir=argv[1]; char *outdir=argv[2]; char *fformat=argv[3]; int runmin=atoi(argv[4]); int runmax=atoi(argv[5]); char fname[10000]; char outfname[10000]; char imgfname[10000]; char pedfname[10000]; // strcpy(pedfname,argv[6]); char fn[10000]; std::time_t end_time; FILE *of=NULL; cout << "input directory is " << indir << endl; cout << "output directory is " << outdir << endl; cout << "fileformat is " << fformat << endl; std::time(&end_time); cout << std::ctime(&end_time) << endl; char* buff; multiThreadedAnalogDetector *mt=new multiThreadedAnalogDetector(filter,nthreads,fifosize); mt->setDetectorMode(ePhotonCounting); mt->setFrameMode(eFrame); mt->StartThreads(); mt->popFree(buff); cout << "mt " << endl; int ifr=0; for (int irun=runmin; irunsetFilePointer(of); // cout << "file pointer set " << endl; } else { cout << "Could not open "<< outfname << " for writing " << endl; mt->setFilePointer(NULL); return 1; } // //while read frame ff=-1; while (decoder->readNextFrame(filebin, ff, np,buff)) { // cout << "*"<getChannel(buff, ix, iy)<3000 || decoder->getChannel(buff, ix, iy)>8000) { // cout << ifr << " " << ff << " " << ix << " " << iy << " " << decoder->getChannel(buff, ix, iy) << endl ; // } // } mt->pushData(buff); // // //pop mt->nextThread(); // // // cout << " " << (void*)buff; mt->popFree(buff); ifr++; if (ifr%10000==0) cout << ifr << " " << ff << endl; ff=-1; } cout << "--" << endl; filebin.close(); // //close file // //join threads while (mt->isBusy()) {;}//wait until all data are processed from the queues if (of) fclose(of); mt->writeImage(imgfname); mt->clearImage(); std::time(&end_time); cout << std::ctime(&end_time) << endl; } else cout << "Could not open "<< fname << " for reading " << endl; } return 0; }