complete all basic programs for single evt to _raw.root and root

This commit is contained in:
Ryan Tang 2022-01-06 13:18:29 -05:00
parent ac7246bc13
commit 60af179708
11 changed files with 836 additions and 537 deletions

6
.gitignore vendored
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@ -6,11 +6,12 @@
xia2root
xia2ev2*
pixie2root
to2root
scan
pxi-time-order
evt2root
evt2hist
ev22txt
*.so
*.d
@ -18,3 +19,6 @@ evt2hist
ti74pt7a
fsu_run_2021
data
test.cpp

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@ -7,25 +7,19 @@
#include <TCanvas.h>
#include <TMath.h>
#include <vector>
#include <TStopwatch.h>
#include <stdio.h>
//############################################ User setting
int rawEnergyRange[2] = {500, 6000}; // in ch
int energyRange[3] = {1, 100, 2000}; // keV {resol, min, max}
int rawEnergyRange[2] = {0, 6000}; // in ch
int energyRange[3] = {1, 0, 6000}; // keV {resol, min, max}
double BGO_threshold = 100; // in ch
double BGO_threshold = 0; // in ch
TString e_corr = "correction_e.dat";
TString e_corr = "";//"correction_e.dat";
//############################################ end of user setting
ULong64_t NumEntries = 0;
ULong64_t ProcessedEntries = 0;
Float_t Frac = 0.1; ///Progress bar
TStopwatch StpWatch;
vector<vector<double>> eCorr;
//############################################ histogram declaration
@ -41,12 +35,19 @@ TH2F * heCalvID;
TH1F * heCal[NCRYSTAL];
TH2F * hcoinBGO;
TH2F * hcrystalBGO;
//############################################ BEGIN
void Analyzer::Begin(TTree * tree){
TString option = GetOption();
NumEntries = tree->GetEntries();
totnumEntry = tree->GetEntries();
printf( "=========================================================================== \n");
printf( "========================== Analysis.C/h ================================ \n");
printf( "====== total Entry : %lld \n", totnumEntry);
printf( "=========================================================================== \n");
printf("======================== Histograms declaration\n");
@ -70,7 +71,9 @@ void Analyzer::Begin(TTree * tree){
}
hcoin = new TH2F("hcoin", "detector coin.; det ID; det ID", NCRYSTAL, 0, NCRYSTAL, NCRYSTAL, 0 , NCRYSTAL);
hcoinBGO = new TH2F("hcoinBGO", Form("detector coin. (BGO veto > %.1f); det ID; det ID", BGO_threshold), NCRYSTAL, 0, NCRYSTAL, NCRYSTAL, 0 , NCRYSTAL);
hcrystalBGO = new TH2F("hcrystalBGO", Form("crystal vs BGO ; det ID; BGO ID"), NCRYSTAL, 0, NCRYSTAL, NBGO, 0 , NBGO);
printf("======================== End of histograms declaration\n");
@ -78,9 +81,6 @@ void Analyzer::Begin(TTree * tree){
eCorr = LoadCorrectionParameters(e_corr);
StpWatch.Start();
printf("======================== Start processing....\n");
}
//############################################ PROCESS
Bool_t Analyzer::Process(Long64_t entry){
@ -88,24 +88,31 @@ Bool_t Analyzer::Process(Long64_t entry){
ProcessedEntries++;
/*********** Progress Bar ******************************************/
if (ProcessedEntries>NumEntries*Frac-1) {
TString msg; msg.Form("%llu", NumEntries/1000);
if (ProcessedEntries>totnumEntry*Frac-1) {
TString msg; msg.Form("%llu", totnumEntry/1000);
int len = msg.Sizeof();
printf(" %3.0f%% (%*llu/%llu k) processed in %6.1f sec | expect %6.1f sec\n",
Frac*100, len, ProcessedEntries/1000,NumEntries/1000,StpWatch.RealTime(), StpWatch.RealTime()/Frac);
Frac*100, len, ProcessedEntries/1000,totnumEntry/1000,StpWatch.RealTime(), StpWatch.RealTime()/Frac);
StpWatch.Start(kFALSE);
Frac+=0.1;
}
b_energy->GetEntry(entry);
b_time->GetEntry(entry);
//b_pileup->GetEntry(entry);
b_pileup->GetEntry(entry);
b_hit->GetEntry(entry);
b_bgo->GetEntry(entry);
//b_other->GetEntry(entry);
//b_multiplicity->GetEntry(entry);
b_bgoTime->GetEntry(entry);
b_other->GetEntry(entry);
b_multi->GetEntry(entry);
if( multi == 0 ) return kTRUE;
int numGatedData=0;
vector<int> gatedID;
gatedID.clear();
double eCal[NCRYSTAL] ={0.0};
///=========== Looping Crystals
for( int detID = 0; detID < NCRYSTAL ; detID ++){
@ -117,6 +124,10 @@ Bool_t Analyzer::Process(Long64_t entry){
hevID->Fill( detID, e[detID]);
he[detID]->Fill(e[detID]);
for( int kk = 0 ; kk < NBGO; kk++){
if( bgo[kk] > 0 ) hcrystalBGO->Fill(detID, kk);
}
for( int detJ = detID +1; detJ < NCRYSTAL; detJ++) {
if( TMath::IsNaN(e[detJ])) continue;
@ -127,35 +138,74 @@ Bool_t Analyzer::Process(Long64_t entry){
//======== BGO veto
for( int kk = 0; kk < NBGO ; kk++){
if( TMath::IsNaN(bgo[kk]) ) continue;
if( bgo[kk] > BGO_threshold ) {
if( bgo[kk] > BGO_threshold && 4*kk <= detID && detID < 4*(kk+1) ) {
return kTRUE;
}
}
//========= apply correction
double eCal = 0 ;
int order = (int) eCorr[detID].size();
for( int i = 0; i < order ; i++){
eCal += eCorr[detID][i] * TMath::Power(e[detID], i);
//----- for ev2 file
if( saveEV2 ){
numGatedData ++;
gatedID.push_back(detID);
}
//========= apply correction
int order = (int) eCorr[detID].size();
for( int i = 0; i < order ; i++){
eCal[detID] += eCorr[detID][i] * TMath::Power(e[detID], i);
}
heCalvID->Fill( detID, eCal);
heCal[detID]->Fill(eCal);
heCalvID->Fill( detID, eCal[detID]);
heCal[detID]->Fill(eCal[detID]);
for( int detJ = detID +1; detJ < NCRYSTAL; detJ++) {
if( TMath::IsNaN(e[detJ])) continue;
hcoinBGO->Fill(detID, detJ);
}
}
if ( saveEV2){
short * out0 = new short[1];
short * outa = new short[1];
short * outb = new short[1];
out0[0] = numGatedData;
fwrite(out0, 1, 1, outEV2);
for( int i = 0; i < (int) gatedID.size(); i++){
int id = gatedID[i];
outa[0] = id;
fwrite(outa, 1, 1, outEV2);
outb[0] = eCal[id];
fwrite(outb, 2, 1, outEV2);
}
fwrite(out0, 1, 1, outEV2);
/**
int len = (int) gatedID.size();
char out[2*len+2];
out[0] = numGatedData;
for( int i = 0; i < (int) gatedID.size(); i++){
int id = gatedID[i];
out[2*i+1] = id;
out[2*i+2] = eCal[id];
}
out[2*len+1]=numGatedData;
fwrite(out,3*len+2,sizeof(out),outEV2);
*/
}
return kTRUE;
}
//############################################ TERMINATE
void Analyzer::Terminate(){
if(saveEV2) fclose(outEV2);
printf("============================== finishing.\n");
gROOT->cd();
@ -177,11 +227,14 @@ void Analyzer::Terminate(){
cCanvas->cd(3);
cCanvas->cd(3)->SetLogz(1);
hcoin->Draw("colz");
hcrystalBGO->Draw("colz");
cCanvas->cd(4);
cCanvas->cd(4)->SetLogz(1);
hcoinBGO->Draw("colz");
//cCanvas->cd(4)->SetLogz(1);
he[0]->SetLineColor(2);
he[0]->Draw();
heCal[0]->Draw("same");
//hcoinBGO->Draw("colz");
printf("=============== loaded AutoFit.C, try showFitMethos()\n");
gROOT->ProcessLine(".L armory/AutoFit.C");

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@ -13,6 +13,7 @@
#include <TChain.h>
#include <TFile.h>
#include <TSelector.h>
#include <TStopwatch.h>
#include "mapping.h"
#include "armory/AnalysisLibrary.h"
@ -28,9 +29,11 @@ public :
// Declaration of leaf types
ULong64_t evID;
Double_t e[NCRYSTAL];
ULong64_t t[NCRYSTAL];
ULong64_t e_t[NCRYSTAL];
UShort_t p[NCRYSTAL];
UShort_t hit[NCRYSTAL];
Double_t bgo[NBGO];
ULong64_t bgo_t[NBGO];
Double_t other[NOTHER];
Int_t multi;
@ -39,11 +42,18 @@ public :
TBranch *b_energy; //!
TBranch *b_time; //!
TBranch *b_pileup; //!
TBranch *b_hit; //!
TBranch *b_bgo; //!
TBranch *b_bgoTime; //!
TBranch *b_other; //!
TBranch *b_multiplicity; //!
TBranch *b_multi; //!
Analyzer(TTree * /*tree*/ =0) : fChain(0) { }
Analyzer(TTree * /*tree*/ =0) : fChain(0) { totnumEntry = 0;
Frac = 0.1;
ProcessedEntries = 0;
saveEV2 = true;
outEV2Name = "test.ev2";
}
virtual ~Analyzer() { }
virtual Int_t Version() const { return 2; }
virtual void Begin(TTree *tree);
@ -60,6 +70,21 @@ public :
virtual void Terminate();
ClassDef(Analyzer,0);
ULong64_t totnumEntry;
vector<vector<double>> eCorr;
ULong64_t ProcessedEntries;
Float_t Frac; ///Progress bar
TStopwatch StpWatch;
bool saveEV2;
FILE * outEV2;
TString outEV2Name;
};
#endif
@ -82,11 +107,23 @@ void Analyzer::Init(TTree *tree)
fChain->SetBranchAddress("evID", &evID, &b_event_ID);
fChain->SetBranchAddress("e", e, &b_energy);
fChain->SetBranchAddress("t", t, &b_time);
fChain->SetBranchAddress("e_t", e_t, &b_time);
fChain->SetBranchAddress("p", p, &b_pileup);
fChain->SetBranchAddress("hit", hit, &b_hit);
fChain->SetBranchAddress("bgo", bgo, &b_bgo);
fChain->SetBranchAddress("bgo_t", bgo_t, &b_bgoTime);
fChain->SetBranchAddress("other", other, &b_other);
fChain->SetBranchAddress("multi", &multi, &b_multiplicity);
fChain->SetBranchAddress("multi", &multi, &b_multi);
if( saveEV2 ){
printf("======================== Create output ev2 : %s\n", outEV2Name.Data());
outEV2 = fopen(outEV2Name.Data(), "w+");
}
printf("======================== Start processing....\n");
StpWatch.Start();
}
Bool_t Analyzer::Notify()

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@ -18,12 +18,12 @@ void newCanvas(int sizeX = 800, int sizeY = 600, int posX = 0, int posY = 0){
cNewCanvas->cd();
}
void rawEvID(bool cal = false){
TCanvas * cRawID = (TCanvas *) gROOT->FindObjectAny("cRawID");
if( cRawID == NULL ) cRawID = new TCanvas("cRawID", "raw ID", 1000, 800);
cRawID->cd(1)->SetGrid();
cal ? heCalVID->Draw("colz") : heVID->Draw("colz");
}
//void rawEvID(bool cal = false){
// TCanvas * cRawID = (TCanvas *) gROOT->FindObjectAny("cRawID");
// if( cRawID == NULL ) cRawID = new TCanvas("cRawID", "raw ID", 1000, 800);
// cRawID->cd(1)->SetGrid();
// cal ? heCalVID->Draw("colz") : heVID->Draw("colz");
//}
void drawE(int CloverID = -1, bool cali = false, bool isLogy = false, double xMin = 0, double xMax = 0){

203
armory/EventBuilder.cpp Normal file
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@ -0,0 +1,203 @@
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <stdbool.h>
#include "TFile.h"
#include "TTree.h"
#include "TMath.h"
#include "TBenchmark.h"
#include "TStopwatch.h"
#include "TTreeIndex.h"
#include "../mapping.h"
Int_t eventID = 0 ;
double e[NCRYSTAL];
ULong64_t e_t[NCRYSTAL];
double bgo[NBGO];
ULong64_t bgo_t[NBGO];
Short_t other[NOTHER];
Short_t multi;
void ClearTreeData(){
for( int i = 0; i < NCRYSTAL; i++){
e[i] = TMath::QuietNaN();
e_t[i] = 0;
//pileup[i] = 0;
//hit[i] = 0;
}
for( int i = 0; i < NBGO; i++) {
bgo[i] = TMath::QuietNaN();
bgo_t[i] = 0 ;
}
for( int i = 0; i < NOTHER; i++) {
other[i] = TMath::QuietNaN();
}
multi = 0;
}
int main(int argn, char **argv){
printf("=====================================\n");
printf("=== Event Builder ===\n");
printf("=====================================\n");
if (argn != 2 && argn != 3 && argn != 4 ) {
printf("Usage :\n");
printf("%s [_raw.root File] <timeWindows> <SaveFileName>\n", argv[0]);
printf(" timeWindows : default = 100 \n");
printf(" SaveFileName : default is *.root \n");
return 1;
}
TString inFileName = argv[1]; // need to check name
int timeWindow = 100;
if( argn >= 3 ) timeWindow = atoi(argv[2]);
printf("======================== Opening input _raw.root \n");
TFile * inFile = new TFile(inFileName, "READ");
if( inFile->IsOpen() == false ) {
printf("!!!! cannot open file %s \n", inFileName.Data());
return 0;
}
TTree * tree = (TTree *) inFile->Get("tree");
Long64_t evID;
UShort_t detID;
UShort_t energy;
ULong64_t energy_t;
TBranch *b_data_ID; //!
TBranch *b_ID; //!
TBranch *b_energy; //!
TBranch *b_energy_timestamp; //!
tree->SetBranchAddress("evID", &evID, &b_data_ID);
tree->SetBranchAddress("id", &detID, &b_ID);
tree->SetBranchAddress("e", &energy, &b_energy);
tree->SetBranchAddress("e_t", &energy_t, &b_energy_timestamp);
Long64_t totnumEntry = tree->GetEntries();
printf( "total Entry : %lld \n", totnumEntry);
printf("======================== Buidling Index using the timestamp\n");
tree->BuildIndex("e_t");
TTreeIndex *in = (TTreeIndex*) tree->GetTreeIndex();
Long64_t * index = in->GetIndex();
ULong64_t time0; //time-0 for each event
int timeDiff;
printf("======================== Create output tree\n");
TString outFileName = inFileName;
outFileName.Remove(inFileName.First('.'));
outFileName.Append(".root");
if( argn >=4 ) outFileName = argv[3];
TFile * saveFile = new TFile(outFileName, "recreate");
saveFile->cd();
TTree * newtree = new TTree("tree", "tree");
newtree->Branch("evID", &eventID, "event_ID/l");
newtree->Branch("e", e, Form("e[%d]/D", NCRYSTAL));
newtree->Branch("e_t", e_t, Form("e_timestamp[%d]/l", NCRYSTAL));
//newtree->Branch("p", pileup, Form("pile_up_flag[%d]/s", NCRYSTAL));
//newtree->Branch("hit", hit, Form("hit[%d]/s", NCRYSTAL));
newtree->Branch("bgo", bgo, Form("BGO_e[%d]/D", NBGO));
newtree->Branch("bgo_t", bgo_t, Form("BGO_timestamp[%d]/l", NBGO));
newtree->Branch("other", other, Form("other_e[%d]/D", NOTHER));
newtree->Branch("multi", &multi, "multiplicity_crystal/I");
ClearTreeData();
printf("======================== Start processing....\n");
Float_t Frac = 0.1; ///Progress bar
TStopwatch StpWatch;
StpWatch.Start();
eventID = 0;
for( Long64_t entry = 0; entry < totnumEntry; entry++){
/*********** Progress Bar ******************************************/
if (entry>totnumEntry*Frac-1) {
TString msg; msg.Form("%llu", totnumEntry/1000);
int len = msg.Sizeof();
printf(" %3.0f%% (%*llu/%llu k) processed in %6.1f sec | expect %6.1f sec\n",
Frac*100, len, entry/1000,totnumEntry/1000,StpWatch.RealTime(), StpWatch.RealTime()/Frac);
StpWatch.Start(kFALSE);
Frac+=0.1;
}
entry = index[entry];
b_ID->GetEntry(entry);
b_energy->GetEntry(entry);
b_energy_timestamp->GetEntry(entry);
if( time0 == 0) time0 = energy_t;
timeDiff = (int) (energy_t - time0);
if( timeDiff < timeWindow ) {
if ( detID < NCRYSTAL ){
e[detID] = energy;
e_t[detID] = energy_t;
multi++;
}
if ( 100 <= detID && detID < 100 + NBGO ){
bgo[detID-100] = energy;
bgo_t[detID-100] = energy_t;
}
if ( 200 <= detID && detID < 200 + NOTHER){
other[detID-200] = energy;
}
//printf("%d | %3d %6d %10llu, %3d\n", multi, detID, energy, energy_t, timeDiff);
}else{
//---- end of event
eventID ++;
saveFile->cd();
newtree->Fill();
ClearTreeData();
/// fill 1st data of an event
time0 = energy_t;
timeDiff = 0;
if ( detID < NCRYSTAL ){
e[detID] = energy;
e_t[detID] = energy_t;
multi = 1;
}
if ( 100 <= detID && detID < 100 + NBGO ){
bgo[detID-100] = energy;
bgo_t[detID-100] = energy_t;
}
if ( 200 <= detID && detID < 200 + NOTHER){
other[detID-200] = energy;
}
}
}
printf("============================== finished.\n");
saveFile->cd();
newtree->Write();
saveFile->Close();
printf(" total number of event Built : %d \n", eventID);
}

81
armory/ev22txt.cpp Normal file
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@ -0,0 +1,81 @@
#include <stdio.h>
#include <stdlib.h>
#include <iostream>
#include <string.h>
using namespace std;
int main(int argc, char **argv){
printf("=====================================\n");
printf("=== ev2 --> txt ===\n");
printf("=====================================\n");
if ( argc != 2 && argc != 3 ){
printf("Usage: \n");
printf("%10s [ev2 file] [max number of event]\n", argv[0]);
}
string inFileName = argv[1];
string outFileName = argv[1];
int found = outFileName.find('.');
int len = outFileName.length();
outFileName.erase(found, len-found);
outFileName.append(".txt");
long long maxNumEvent = 0; // if maxNumEvent <= 0, all event
if( argc >= 3 ) maxNumEvent = atoi(argv[2]);
//open list-mode data file from PXI digitizer
FILE *inFile = fopen(argv[1], "r");
long int inFileSize,inFilepos;
if ( inFile == NULL) {
printf("Error, cannot open input file %s\n", argv[1]);
return 1;
}
//get file size
fseek(inFile, 0L, SEEK_END);
inFileSize = ftell(inFile);
rewind(inFile);
long int inFilePos = 0;
printf(" in file : %s | file size : %f MB\n", inFileName.c_str(), inFileSize/1024./1024.);
//printf(" out file : %s \n", outFileName.c_str());
if( maxNumEvent <= 0 ){
printf(" max number of event : ALL \n");
}else{
printf(" max number of event : %lld \n", maxNumEvent);
}
printf("-------------------------------------\n");
long long nEvent = 0;
short * multi = new short[1];
short * id = new short[1];
short * energy = new short[1] ;
while ( inFilePos < inFileSize || feof(inFile) ) {
printf("------------------- %lld\n", nEvent);
fread(multi, 1, 1, inFile);
printf(" number of det : %d \n", multi[0]);
for( int i = 0; i < multi[0] ; i++){
fread(id, 1, 1, inFile);
fread(energy, 2, 1, inFile);
printf("%2d| %3d, %8d \n", i, id[0], energy[0]);
}
fread(multi, 1, 1, inFile);
nEvent++;
if( maxNumEvent > 0 && nEvent > maxNumEvent ) break;
}
}

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@ -15,6 +15,7 @@
#define MAX_CHANNELS_PER_BOARD 16
#define BOARD_START 2
#include "../mapping.h"
class measurment{
@ -106,8 +107,8 @@ int main(int argn, char **argv) {
tree->Branch("evID", &measureID, "data_ID/L");
tree->Branch("id", &data.id, "ID/s");
tree->Branch("e", &data.energy, "energy/s");
tree->Branch("t", &data.time, "timestamp/l");
tree->Branch("e", &data.energy, "crystal_energy/s");
tree->Branch("e_t", &data.time, "crystal_timestamp/l");
//tree->Branch("tdiff", &data.timeDiff, "time_Diff/L");
@ -125,7 +126,7 @@ int main(int argn, char **argv) {
measureID ++;
/// see the Pixie-16 user manual, Table4-2
data.ch = header[0] & 0xF ;
data.ch = header[0] & 0xF ;
data.slot = (header[0] >> 4) & 0xF;
data.crate = (header[0] >> 8) & 0xF;
data.headerLength = (header[0] >> 12) & 0x1F;
@ -139,23 +140,11 @@ int main(int argn, char **argv) {
data.id = data.crate*MAX_BOARDS_PER_CRATE*MAX_CHANNELS_PER_BOARD + (data.slot-BOARD_START)*MAX_CHANNELS_PER_BOARD + data.ch;
data.id = mapping[data.id];
data.energy = data.energy / 2. ; // factor 2 is the rawe_rebin_factor;
nWords += data.eventLength;
//if( measureID == 0 ) {
// data.timeDiff = 0;
//}else{
// data.timeDiff = (Long64_t) data.time - timeLast;
//}
//timeLast = data.time;
//if( data.timeDiff == false ){
// printf("----------------------nWords: %llu, inFilePos: %lu\n", nWords, inFilePos);
// for(int i = 0; i < 4; i++){
// printf(" %x\n", header[i]);
// }
// data.Print();
//}
//=== jump to next measurement
if( data.eventLength > 4 ){
fseek(inFile, sizeof(int) * (data.eventLength-4), SEEK_CUR);

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@ -1,454 +0,0 @@
/**********************************************************/
/* */
/* Modified by Ryan From */
/* */
/* PXI SCAN CODE -- J.M. Allmond (ORNL) -- July 2016 */
/* */
/**********************************************************/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <stdbool.h>
#include "TFile.h"
#include "TTree.h"
#include "TMath.h"
#include "TBenchmark.h"
#define RAND ((float) rand() / ((unsigned int) RAND_MAX + 1)) // random number in interval (0,1)
#define MAX_CRATES 2
#define MAX_BOARDS_PER_CRATE 13
#define MAX_CHANNELS_PER_BOARD 16
#define BOARD_START 2
#define MAX_ID MAX_CRATES*MAX_BOARDS_PER_CRATE*MAX_CHANNELS_PER_BOARD
#define HEADER_LENGTH 4 //unit = words with 4 bytes per word
#define MAX_SUB_LENGTH 2016 //unit = words with 4 bytes per word ; 2004 --> 40 micro-second trace + 4 word header
#define RAWE_REBIN_FACTOR 2.0 // Rebin 32k pixie16 spectra to something smaller to fit better into 8k.
#include "../mapping.h"
/////////////////////
// RAW EVENT TYPES //
/////////////////////
struct subevent
{
int chn;
int sln;
int crn;
int id;
int hlen;
int elen;
int trlen; //number of samples
int trwlen; //number of words (two samples per word)
int fcode; //pileup flag
long long int time;
int ctime;
int ctimef;
int energy;
int extra;
short tr[4096];
int esum[4];
int qsum[8];
};
struct subevent subevt[MAX_ID]={0};
int sevtmult=0;
unsigned long long int sevtcount=0;
unsigned long long int pileupcount=0;
unsigned long long int evtcount=0;
int mult[1][4096]={0};
int tdifid[MAX_ID][8192]={0};
/****
int overwrite = 1;
///////////////////////
// Write 2-byte data //
///////////////////////
void write_data2(char *filename, short *data, int xdim, int ydim, int overwrite) { //2byte per channel Write / Add to previous
FILE *FP;
int i;
short *previous;
if(!overwrite) {
//allocate memory for 1d-array for reading in rows of 2d Radware matrix
if ( ( previous = (short *)malloc(xdim * ydim * sizeof(short)) ) == NULL ) {
printf("\nError, memory not allocated.\n");
exit(1);
}
//open previous spectra file
if( (FP=fopen(filename, "r")) != NULL ){
fread(previous, sizeof(short)*xdim*ydim, 1, FP);
fclose(FP);
//update spectra
for (i=0; i<xdim*ydim; i++) {
if(previous[i] < (powf(2,sizeof(short)*8.0)-2))
data[i] = data[i] + previous[i];
}
}
else{
printf("%s did not previously exist, creating ...\n", filename);
}
//Deallocate previous data
free(previous);
}
FP=fopen(filename, "w");
fwrite(data, sizeof(short)*xdim, ydim, FP);
fclose(FP);
}
///////////////////////
// Write 4-byte data //
///////////////////////
void write_data4(char *filename, int *data, int xdim, int ydim, int overwrite) { //4byte per channel Write / Add to previous
FILE *FP;
int i;
int *previous;
if(!overwrite) {
//allocate memory for 1d-array for reading in rows of 2d Radware matrix
if ( ( previous = (int *)malloc(xdim * ydim * sizeof(int)) ) == NULL ) {
printf("\nError, memory not allocated.\n");
exit(1);
}
//open previous spectra file
if( (FP=fopen(filename, "r")) != NULL ){
fread(previous, sizeof(int)*xdim*ydim, 1, FP);
fclose(FP);
//update spectra
for (i=0; i<xdim*ydim; i++) {
if(previous[i] < (powf(2,sizeof(int)*8.0)-2))
data[i] = data[i] + previous[i];
}
}
else{
printf("%s did not previously exist, creating ...\n", filename);
}
//Deallocate previous data
free(previous);
}
FP=fopen(filename, "w");
fwrite(data, sizeof(int)*xdim, ydim, FP);
fclose(FP);
}
******/
///////////////////////////////////
// START OF MAIN FUNCTION //
///////////////////////////////////
int main(int argc, char **argv) {
int i=0, j=0, k=0;
float tempf=0;
div_t e_div;
lldiv_t lle_div;
//temp buffer for each sub event
unsigned int sub[MAX_SUB_LENGTH];
memset(sub, 0, sizeof(sub));
//Reference time and difference for event building
long long int etime, tdif, idtime[MAX_ID]={0}, temptime;
// Check that the corrent number of arguments were provided.
if (argc != 2 && argc != 3 ) {
printf("Incorrect number of arguments:\n");
printf("%s [*.to File] [timeWindow] \n", argv[0]);
printf(" timeWindow : number of tick, 1 tick = 10 ns. default = 100 \n");
return 1;
}
printf("=====================================\n");
printf("=== evt --> root ===\n");
printf("=====================================\n");
//CERN ROOT things
TString inFileName = argv[1];
TString outFileName = inFileName;
int EVENT_BUILD_TIME = 100;
if( argc >= 3 ){
EVENT_BUILD_TIME = atoi(argv[2]);
}
outFileName.Remove(inFileName.First('.'));
outFileName.Append(".root");
printf(" in file : %s \n", inFileName.Data());
printf(" our file : %s \n", outFileName.Data());
printf(" number of detector channal: %d \n", MAX_ID);
printf("------------------------ Event building time window : %d tics = %d nsec \n", EVENT_BUILD_TIME, EVENT_BUILD_TIME*10);
TFile * outRootFile = new TFile(outFileName, "recreate");
outRootFile->cd();
TTree * tree = new TTree("tree", "tree");
unsigned long long evID = -1;
double energy[NCRYSTAL];
unsigned long long etimestamp[NCRYSTAL];
double bgo[NBGO];
double other[NOTHER];
unsigned short pileup[NCRYSTAL];
//const int maxMulti = 40;
//double energy[maxMulti];
//unsigned timestamp[maxMulti];
//short detID[maxMulti];
int multi;
tree->Branch("evID", &evID, "event_ID/l");
///tree->Branch("detID", detID, Form("det ID[%d]/B", NCRYSTAL));
tree->Branch("e", energy, Form("energy[%d]/D", NCRYSTAL));
tree->Branch("t", etimestamp, Form("energy_time_stamp[%d]/l", NCRYSTAL));
tree->Branch("p", pileup, Form("pile_up_flag[%d]/s", NCRYSTAL));
tree->Branch("bgo", bgo, Form("BGO_energy[%d]/D", NBGO));
tree->Branch("other", other, Form("other_energy[%d]/D", NOTHER));
tree->Branch("multi", &multi, "multiplicity/I");
//open list-mode data file from PXI digitizer
FILE *fpr;
long int fprsize,fprpos;
if ((fpr = fopen(argv[1], "r")) == NULL) {
fprintf(stderr, "Error, cannot open input file %s\n", argv[2]);
return 1;
}
//get file size
fseek(fpr, 0L, SEEK_END);
fprsize = ftell(fpr);
rewind(fpr);
TBenchmark gClock;
gClock.Reset();
gClock.Start("timer");
/////////////////////
// MAIN WHILE LOOP //
/////////////////////
while (1) { //main while loop
/////////////////////////////////
// UNPACK DATA AND EVENT BUILD //
/////////////////////////////////
//CERN data clear
for( int haha = 0; haha < NCRYSTAL; haha++){
energy[haha] = TMath::QuietNaN();
etimestamp[haha] = 0;
pileup[haha] = 0;
}
for( int haha = 0; haha < NBGO; haha++) bgo[haha] = TMath::QuietNaN();
for( int haha = 0; haha < NOTHER; haha++) other[haha] = TMath::QuietNaN();
multi = 0;
evID++;
etime=-1; tdif=-1; sevtmult=0;
//memset(&subevt, 0, sizeof(subevt)); //not needed since everything is redefined (except maybe trace on pileup evts)
while (1) { //get subevents and event build for one "event"
// memset(&subevt[sevtmult], 0, sizeof(subevt[sevtmult])); //not needed since everything is redefined (except maybe trace on pileup evts)
//read 4-byte header
if (fread(sub, sizeof(int)*HEADER_LENGTH, 1, fpr) != 1) break;
subevt[sevtmult].chn = sub[0] & 0xF; /// channel in digitizer
subevt[sevtmult].sln = (sub[0] & 0xF0) >> 4; /// digitizer ID
subevt[sevtmult].crn = (sub[0] & 0xF00) >> 8; /// crate
subevt[sevtmult].id = subevt[sevtmult].crn*MAX_BOARDS_PER_CRATE*MAX_CHANNELS_PER_BOARD + (subevt[sevtmult].sln-BOARD_START)*MAX_CHANNELS_PER_BOARD + subevt[sevtmult].chn;
subevt[sevtmult].hlen = (sub[0] & 0x1F000) >> 12;
subevt[sevtmult].elen = (sub[0] & 0x7FFE0000) >> 17;
subevt[sevtmult].fcode = (sub[0] & 0x80000000) >> 31;
subevt[sevtmult].time = ( (long long int)(sub[2] & 0xFFFF) << 32) + sub[1];
subevt[sevtmult].ctime = (sub[2] & 0x7FFF0000) >> 16;
subevt[sevtmult].ctimef = (sub[2] & 0x80000000) >> 31;
subevt[sevtmult].energy = (sub[3] & 0xFFFF);
subevt[sevtmult].trlen = (sub[3] & 0x7FFF0000) >> 16;
subevt[sevtmult].trwlen = subevt[sevtmult].trlen / 2;
subevt[sevtmult].extra = (sub[3] & 0x80000000) >> 31;
//rebin raw trap energy from 32k to ....
tempf = (float)subevt[sevtmult].energy/RAWE_REBIN_FACTOR;// + RAND;
subevt[sevtmult].energy = (int)tempf;
//check lengths (sometimes all of the bits for trace length are turned on ...)
/* if (subevt[sevtmult].elen - subevt[sevtmult].hlen != subevt[sevtmult].trwlen) {
printf("SEVERE ERROR: event, header, and trace length inconsistencies found\n");
printf("event length = %d\n", subevt[sevtmult].elen);
printf("header length = %d\n", subevt[sevtmult].hlen);
printf("trace length = %d\n", subevt[sevtmult].trwlen);
printf("Extra = %d\n", subevt[sevtmult].extra);
printf("fcode = %d\n", subevt[sevtmult].fcode);
//sleep(1);
//return 0;
} */
//CERN fill tree
///========== need a mapping, can reduce the array size, speed up.
int ch = mapping[subevt[sevtmult].id];
if ( 0 <= ch && ch < NCRYSTAL ){
energy[ch] = subevt[sevtmult].energy;
etimestamp[ch] = subevt[sevtmult].time;
pileup[ch] = subevt[sevtmult].fcode;
multi++;
}
if ( 100 <= ch && ch < 100 + NBGO ){
bgo[ch-100] = subevt[sevtmult].energy;
}
if ( 200 <= ch && ch < 200 + NOTHER){
other[ch-200] = subevt[sevtmult].energy;
}
//Set reference time for event building
if (etime == -1) {
etime = subevt[sevtmult].time;
tdif = 0;
}
else {
tdif = subevt[sevtmult].time - etime;
//if (tdif < 0) {
// printf("SEVERE ERROR: tdiff < 0, file must be time sorted\n");
// printf("etime = %lld, time = %lld, and tdif = %lld\n", etime, subevt[sevtmult].time, tdif);
// return 0;
//}
}
//Check for end of event, rewind, and break out of while loop
if (tdif > EVENT_BUILD_TIME) {
fseek(fpr, -sizeof(int)*HEADER_LENGTH, SEEK_CUR); //fwrite/fread is buffered by system ; storing this in local buffer is no faster!
break;
}
//time between sequential events for a single channel ; useful for determining optimal event building time
temptime = (subevt[sevtmult].time - idtime[subevt[sevtmult].id])/100; //rebin to 1 micro-second
if ( temptime >= 0 && temptime < 8192) {
tdifid[subevt[sevtmult].id][temptime]++;
}
idtime[subevt[sevtmult].id]=subevt[sevtmult].time; //store time for next subevent of channel
// total pileups
if (subevt[sevtmult].fcode==1) {
pileupcount++;
}
//more data than just the header; read entire sub event
fseek(fpr, -sizeof(int)*HEADER_LENGTH, SEEK_CUR);
if (fread(sub, sizeof(int)*subevt[sevtmult].elen, 1, fpr) != 1) break;
/*
//trace
k=0;
for (i = subevt[sevtmult].hlen; i < subevt[sevtmult].elen; i++) {
subevt[sevtmult].tr[i - subevt[sevtmult].hlen + k] = sub[i] & 0x3FFF;
subevt[sevtmult].tr[i - subevt[sevtmult].hlen + k + 1] = (sub[i]>>16) & 0x3FFF;
k=k+1;
}
// if (subevt[sevtmult].id == 4 && subevt[sevtmult].fcode == 1) DB(subevt[sevtmult].tr);
//continue if no esum or qsum
if (subevt[sevtmult].hlen==HEADER_LENGTH) {
sevtmult++;
continue;
}
//esum
if (subevt[sevtmult].hlen==8 || subevt[sevtmult].hlen==16) {
for (i=4; i < 8; i++) {
subevt[sevtmult].esum[i-4] = sub[i];
}
}
//qsum
if (subevt[sevtmult].hlen==12) {
for (i=4; i < 12; i++) {
subevt[sevtmult].qsum[i-4] = sub[i];
}
}
//qsum
if (subevt[sevtmult].hlen==16) {
for (i=8; i < 16; i++) {
subevt[sevtmult].qsum[i-8] = sub[i];
}
}
*/
sevtmult++;
} //end while loop for unpacking sub events and event building for one "event"
if (sevtmult==0) break; //end main WHILE LOOP when out of events
mult[0][sevtmult]++; //Histogram raw sub event multiplicity
sevtcount += sevtmult;
evtcount++; //event-built number
/////////////////////////////////////
// END UNPACK DATA AND EVENT BUILD //
/////////////////////////////////////
//event stats, print status every 10000 events
lle_div=lldiv(evtcount,10000);
if ( lle_div.rem == 0 ) {
fprpos = ftell(fpr);
tempf = (float)fprsize/(1024.*1024.*1024.);
gClock.Stop("timer");
double time = gClock.GetRealTime("timer");
gClock.Start("timer");
printf("Total SubEvents: \x1B[32m%llu \x1B[31m(%d%% pileup)\x1B[0m\nTotal Events: \x1B[32m%llu (%.1f <mult>)\x1B[0m\nPercent Complete: \x1B[32m%ld%% of %.3f GB\x1B[0m\nTime used:%3.0f min %5.2f sec\033[3A\r",
sevtcount, (int)((100*pileupcount)/sevtcount), evtcount, (float)sevtcount/(float)evtcount, (100*fprpos/fprsize), tempf, TMath::Floor(time/60.), time - TMath::Floor(time/60.)*60.);
}
//cern fill tree
outRootFile->cd();
tree->Fill();
} // end main while loop
/////////////////////////
// END MAIN WHILE LOOP //
/////////////////////////
fprpos = ftell(fpr);
tempf = (float)fprsize/(1024.*1024.*1024.);
printf("Total SubEvents: \x1B[32m%llu \x1B[31m(%d%% pileup)\x1B[0m\nTotal Events: \x1B[32m%llu (%.1f <mult>)\x1B[0m\nPercent Complete: \x1B[32m%ld%% of %.3f GB\x1B[0m\n\033[3A\n",
sevtcount, (int)((100*pileupcount)/sevtcount), evtcount, (float)sevtcount/(float)evtcount, (100*fprpos/fprsize), tempf);
//cern save root
outRootFile->cd();
tree->Write();
outRootFile->Close();
fclose(fpr);
gClock.Stop("timer");
double time = gClock.GetRealTime("timer");
printf("\n==================== finished.\r\n");
printf("Total time spend : %3.0f min %5.2f sec\n", TMath::Floor(time/60.), time - TMath::Floor(time/60.)*60.);
return 0;
}

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/**********************************************************/
/* */
/* Modified by Ryan From */
/* */
/* PXI SCAN CODE -- J.M. Allmond (ORNL) -- July 2016 */
/* */
/**********************************************************/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <stdbool.h>
#include "TFile.h"
#include "TTree.h"
#include "TMath.h"
#include "TBenchmark.h"
#define RAND ((float) rand() / ((unsigned int) RAND_MAX + 1)) // random number in interval (0,1)
#define MAX_CRATES 2
#define MAX_BOARDS_PER_CRATE 13
#define MAX_CHANNELS_PER_BOARD 16
#define BOARD_START 2
#define MAX_ID MAX_CRATES*MAX_BOARDS_PER_CRATE*MAX_CHANNELS_PER_BOARD
#define HEADER_LENGTH 4 //unit = words with 4 bytes per word
#define MAX_SUB_LENGTH 2016 //unit = words with 4 bytes per word ; 2004 --> 40 micro-second trace + 4 word header
#define RAWE_REBIN_FACTOR 2.0 // Rebin 32k pixie16 spectra to something smaller to fit better into 8k.
#include "../mapping.h"
/////////////////////
// RAW EVENT TYPES //
/////////////////////
struct measurement
{
int chn;
int sln;
int crn;
int id;
int hlen;
int elen;
int trlen; //number of samples
int trwlen; //number of words (two samples per word)
int fcode; //pileup flag
long long int time;
int ctime;
int ctimef;
int e;
int extra;
short tr[4096];
int esum[4];
int qsum[8];
};
struct measurement data = {0};
int sevtmult=0;
unsigned long long int dataCount=0;
unsigned long long int pileUpCount=0;
unsigned long long int evtCount=0;
///////////////////////////////////
// START OF MAIN FUNCTION //
///////////////////////////////////
int main(int argc, char **argv) {
float tempf=0;
//temp buffer for each sub event
unsigned int sub[MAX_SUB_LENGTH];
memset(sub, 0, sizeof(sub));
printf("=====================================\n");
printf("=== evt.to --> root ===\n");
printf("=====================================\n");
// Check that the corrent number of arguments were provided.
if (argc != 2 && argc != 3 ) {
printf("Incorrect number of arguments:\n");
printf("%s [*.to File] [timeWindow] \n", argv[0]);
printf(" timeWindow : number of tick, 1 tick = 10 ns. default = 100 \n");
return 1;
}
//CERN ROOT things
TString inFileName = argv[1];
TString outFileName = inFileName;
int timeWindow = 100;
if( argc >= 3 ) timeWindow = atoi(argv[2]);
outFileName.Remove(inFileName.First('.'));
outFileName.Append(".root");
printf(" in file : %s \n", inFileName.Data());
printf(" our file : %s \n", outFileName.Data());
printf(" max number of detector channal: %d \n", MAX_ID);
printf("------------------------ Event building time window : %d tics = %d nsec \n", timeWindow, timeWindow*10);
TFile * outRootFile = new TFile(outFileName, "recreate");
outRootFile->cd();
TTree * tree = new TTree("tree", "tree");
unsigned long long evID = -1;
double e[NCRYSTAL];
unsigned long long e_t[NCRYSTAL];
unsigned short pileup[NCRYSTAL];
unsigned short hit[NCRYSTAL]; // number of hit in an event
double bgo[NBGO];
unsigned long long bgo_t[NBGO];
double other[NOTHER];
int multi; //sum of all crystal hit in an event
tree->Branch("evID", &evID, "event_ID/l");
//TODO: use TCloneArray to save measurement struc, that can save space and possibly time.
///tree->Branch("detID", detID, Form("det ID[%d]/B", NCRYSTAL));
tree->Branch("e", e, Form("e[%d]/D", NCRYSTAL));
tree->Branch("e_t", e_t, Form("e_timestamp[%d]/l", NCRYSTAL));
tree->Branch("p", pileup, Form("pile_up_flag[%d]/s", NCRYSTAL));
tree->Branch("hit", hit, Form("hit[%d]/s", NCRYSTAL));
tree->Branch("bgo", bgo, Form("BGO_e[%d]/D", NBGO));
tree->Branch("bgo_t", bgo_t, Form("BGO_timestamp[%d]/l", NBGO));
tree->Branch("other", other, Form("other_e[%d]/D", NOTHER));
tree->Branch("multi", &multi, "multiplicity_crystal/I");
//open list-mode data file from PXI digitizer
FILE *fpr = fopen(argv[1], "r");
long int fprsize,fprpos;
if ( fpr == NULL) {
fprintf(stderr, "Error, cannot open input file %s\n", argv[2]);
return 1;
}
//get file size
fseek(fpr, 0L, SEEK_END);
fprsize = ftell(fpr);
rewind(fpr);
TBenchmark gClock;
gClock.Reset();
gClock.Start("timer");
int hitcrystal[NCRYSTAL] = {0};
/////////////////////
// MAIN WHILE LOOP //
/////////////////////
while (1) { //main while loop
/////////////////////////////////
// UNPACK DATA AND EVENT BUILD //
/////////////////////////////////
//data clear
for( int i = 0; i < NCRYSTAL; i++){
e[i] = TMath::QuietNaN();
e_t[i] = 0;
pileup[i] = 0;
hit[i] = 0;
}
for( int i = 0; i < NBGO; i++) {
bgo[i] = TMath::QuietNaN();
bgo_t[i] = 0 ;
}
for( int i = 0; i < NOTHER; i++) {
other[i] = TMath::QuietNaN();
}
multi = 0;
evID++;
long long int etime=-1;
long long int tdif=-1;
int sevtmult=0;
while (1) { //get subevents and event build for one "event"
if (fread(sub, sizeof(int)*HEADER_LENGTH, 1, fpr) != 1) break;
data.chn = sub[0] & 0xF; /// channel in digitizer
data.sln = (sub[0] & 0xF0) >> 4; /// digitizer ID
data.crn = (sub[0] & 0xF00) >> 8; /// crate
data.id = data.crn*MAX_BOARDS_PER_CRATE*MAX_CHANNELS_PER_BOARD + (data.sln-BOARD_START)*MAX_CHANNELS_PER_BOARD + data.chn;
data.hlen = (sub[0] & 0x1F000) >> 12;
data.elen = (sub[0] & 0x7FFE0000) >> 17;
data.fcode = (sub[0] & 0x80000000) >> 31;
data.time = ( (long long int)(sub[2] & 0xFFFF) << 32) + sub[1];
data.ctime = (sub[2] & 0x7FFF0000) >> 16;
data.ctimef = (sub[2] & 0x80000000) >> 31;
data.e = (sub[3] & 0xFFFF);
data.trlen = (sub[3] & 0x7FFF0000) >> 16;
data.trwlen = data.trlen / 2;
data.extra = (sub[3] & 0x80000000) >> 31;
tempf = (float)data.e/RAWE_REBIN_FACTOR;// + RAND;
data.e = (int)tempf;
//check lengths (sometimes all of the bits for trace length are turned on ...)
/**if (dataBlock[sevtmult].elen - dataBlock[sevtmult].hlen != dataBlock[sevtmult].trwlen) {
printf("SEVERE ERROR: event, header, and trace length inconsistencies found\n");
printf("event length = %d\n", dataBlock[sevtmult].elen);
printf("header length = %d\n", dataBlock[sevtmult].hlen);
printf("trace length = %d\n", dataBlock[sevtmult].trwlen);
printf("Extra = %d\n", dataBlock[sevtmult].extra);
printf("fcode = %d\n", dataBlock[sevtmult].fcode);
//sleep(1);
//return 0;
} */
//Set reference time for event building
if (etime == -1) {
etime = data.time;
tdif = 0;
}
else {
tdif = data.time - etime;
}
//Check for end of event, rewind, and break out of while loop
if (tdif > timeWindow) {
fseek(fpr, -sizeof(int)*HEADER_LENGTH, SEEK_CUR); //fwrite/fread is buffered by system ; storing this in local buffer is no faster!
break;
}else{
//if within time window, fill array;
int detID = mapping[data.id];
if ( 0 <= detID && detID < NCRYSTAL ){
e[detID] = data.e;
e_t[detID] = data.time;
pileup[detID] = data.fcode;
hit[detID] ++;
multi++;
}
if ( 100 <= detID && detID < 100 + NBGO ){
bgo[detID-100] = data.e;
bgo_t[detID-100] = data.time;
}
if ( 200 <= detID && detID < 200 + NOTHER){
other[detID-200] = data.e;
}
}
// total pileups
if (data.fcode==1) {
pileUpCount++;
}
//more data than just the header; read entire sub event, first rewind, then read data.elen
fseek(fpr, -sizeof(int)*HEADER_LENGTH, SEEK_CUR);
//if (fread(sub, sizeof(int)*dataBlock[sevtmult].elen, 1, fpr) != 1) break;
if (fread(sub, sizeof(int)*data.elen, 1, fpr) != 1) break;
/**
//trace
k=0;
for (i = dataBlock[sevtmult].hlen; i < dataBlock[sevtmult].elen; i++) {
dataBlock[sevtmult].tr[i - dataBlock[sevtmult].hlen + k] = sub[i] & 0x3FFF;
dataBlock[sevtmult].tr[i - dataBlock[sevtmult].hlen + k + 1] = (sub[i]>>16) & 0x3FFF;
k=k+1;
}
// if (dataBlock[sevtmult].id == 4 && dataBlock[sevtmult].fcode == 1) DB(dataBlock[sevtmult].tr);
//continue if no esum or qsum
if (dataBlock[sevtmult].hlen==HEADER_LENGTH) {
sevtmult++;
continue;
}
//esum
if (dataBlock[sevtmult].hlen==8 || dataBlock[sevtmult].hlen==16) {
for (i=4; i < 8; i++) {
dataBlock[sevtmult].esum[i-4] = sub[i];
}
}
//qsum
if (dataBlock[sevtmult].hlen==12) {
for (i=4; i < 12; i++) {
dataBlock[sevtmult].qsum[i-4] = sub[i];
}
}
//qsum
if (dataBlock[sevtmult].hlen==16) {
for (i=8; i < 16; i++) {
dataBlock[sevtmult].qsum[i-8] = sub[i];
}
}
*/
sevtmult++;
} //end while loop for unpacking sub events and event building for one "event"
if (sevtmult==0) break; //end main WHILE LOOP when out of events
dataCount += sevtmult;
evtCount++; //event-built number
int hit_add = 0;
for ( int i = 0; i < NCRYSTAL; i++){
if( hit[i] > 1 ) {
hit_add = 1;
hitcrystal[i] ++;
}
}
///if( hit_add == 1 ){
/// for ( int i = 0; i < NCRYSTAL; i++){ printf("%d", hit[i]); }
/// printf("------------%d\n", hitcrystal);
///}
///if( evtCount < 40 ) {
/// printf("------------------------------------- %lld \n", evtCount);
/// for( int i = 0; i < NCRYSTAL; i++){
/// if(e[i] > 0 )printf("%2d %6.0f %10llu\n", i, e[i], e_t[i]);
/// }
///
///}
/////////////////////////////////////
// END UNPACK DATA AND EVENT BUILD //
/////////////////////////////////////
//event stats, print status every 10000 events
if ( evtCount % 10000 == 0 ) {
fprpos = ftell(fpr);
tempf = (float)fprsize/(1024.*1024.*1024.);
gClock.Stop("timer");
double time = gClock.GetRealTime("timer");
gClock.Start("timer");
printf("Total dataBlock: \x1B[32m%llu \x1B[31m(%d%% pileup)\x1B[0m\nTotal Events: \x1B[32m%llu (%.1f <mult>)\x1B[0m\nPercent Complete: \x1B[32m%ld%% of %.3f GB\x1B[0m\nTime used:%3.0f min %5.2f sec\033[3A\r",
dataCount, (int)((100*pileUpCount)/dataCount), evtCount, (float)dataCount/(float)evtCount, (100*fprpos/fprsize), tempf, TMath::Floor(time/60.), time - TMath::Floor(time/60.)*60.);
}
outRootFile->cd();
tree->Fill();
} // end main while loop
/////////////////////////
// END MAIN WHILE LOOP //
/////////////////////////
fprpos = ftell(fpr);
tempf = (float)fprsize/(1024.*1024.*1024.);
printf("Total SubEvents: \x1B[32m%llu \x1B[31m(%d%% pileup)\x1B[0m\nTotal Events: \x1B[32m%llu (%.1f <mult>)\x1B[0m\nPercent Complete: \x1B[32m%ld%% of %.3f GB\x1B[0m\n\033[3A\n",
dataCount, (int)((100*pileUpCount)/dataCount), evtCount, (float)dataCount/(float)evtCount, (100*fprpos/fprsize), tempf);
outRootFile->cd();
tree->Write();
outRootFile->Close();
fclose(fpr);
gClock.Stop("timer");
double time = gClock.GetRealTime("timer");
printf("\n\n==================== finished.\r\n");
printf("Total time spend : %3.0f min %5.2f sec\n", TMath::Floor(time/60.), time - TMath::Floor(time/60.)*60.);
printf("number of hit per crystal per event:\n");
for( int i = 0; i < NCRYSTAL ; i++){
printf("%2d -- %d \n", i, hitcrystal[i]);
}
return 0;
}

View File

@ -2,7 +2,7 @@ CC=g++
#all: xia2root xia2ev2_nopart pixie2root scan pxi-time-order
#all: xia2root xia2ev2_nopart pixie2root scan evt2root evt2hist
all: xia2root pixie2root evt2root evt2hist pxi-time-order
all: xia2root to2root evt2root evt2hist pxi-time-order ev22txt EventBuilder
#this is FSU evt to root
xia2root: armory/xia2root.cpp
@ -12,8 +12,8 @@ xia2root: armory/xia2root.cpp
# $(CC) armory/xia2ev2_nopart.cpp -o xia2ev2_nopart
#this is for eventbuild
pixie2root: armory/pixie2root.cpp
$(CC) armory/pixie2root.cpp -o pixie2root `root-config --cflags --glibs`
to2root: armory/to2root.cpp
$(CC) armory/to2root.cpp -o to2root `root-config --cflags --glibs`
#this is for online root
evt2root: armory/evt2root.cpp
@ -25,3 +25,9 @@ evt2hist: armory/evt2hist.cpp
pxi-time-order: armory/pxi-time-order.c
$(CC) armory/pxi-time-order.c -o pxi-time-order
ev22txt: armory/ev22txt.cpp
$(CC) armory/ev22txt.cpp -o ev22txt
EventBuilder: armory/EventBuilder.cpp
$(CC) armory/EventBuilder.cpp -o EventBuilder `root-config --cflags --glibs`

View File

@ -11,18 +11,18 @@ Other : 200 - 299
#define NBGO 9
#define NOTHER 52
// 0 1 2 3 4 5 6 7 8 9
int mapping[130] = { 0, 1, 2, 3, 100, 4, 5, 6, 7, 101, // 0
8, 9, 10, 11, 102, -1, 12, 13, 14, 15, // 10
103, 16, 17, 18, 19, 104, -1, -1, -1, -1, // 20
-1, -1, 20, 21, 22, 23, 105, 24, 25, 26, // 30
27, 106, 28, 29, 30, 31, 107, -1, -1, -1, // 40
-1, -1, -1, 32, 33, 34, 35, 108, -1, -1, // 50
200, 201, 202, 203, 204, 205, 206, 207, 208, 209, // 60
210, 211, 212, 213, 214, 215, 216, 217, 218, 219, // 70
220, 221, 222, 223, 224, 225, 226, 227, 228, 229, // 80
230, 231, 232, 233, 234, 235, 236, 237, 238, 239, // 90
240, 241, 242, 243, 244, 245, 246, 247, 248, 249, // 100
250, 251, -1, -1, -1, -1, -1, -1, -1, -1, // 110
-1, -1, -1, -1, -1, -1, -1, -1, -1, -1}; // 120
// 0 1 2 3 4 5 6 7 8 9
int mapping[130] ={ 0, 1, 2, 3, 100, 4, 5, 6, 7, 101, // 0
8, 9, 10, 11, 102, -1, 12, 13, 14, 15, // 10
103, 16, 17, 18, 19, 104, -1, -1, -1, -1, // 20
-1, -1, 20, 21, 22, 23, 105, 24, 25, 26, // 30
27, 106, 28, 29, 30, 31, 107, -1, -1, -1, // 40
-1, -1, -1, 32, 33, 34, 35, 108, -1, -1, // 50
200, 201, 202, 203, 204, 205, 206, 207, 208, 209, // 60
210, 211, 212, 213, 214, 215, 216, 217, 218, 219, // 70
220, 221, 222, 223, 224, 225, 226, 227, 228, 229, // 80
230, 231, 232, 233, 234, 235, 236, 237, 238, 239, // 90
240, 241, 242, 243, 244, 245, 246, 247, 248, 249, // 100
250, 251, -1, -1, -1, -1, -1, -1, -1, -1, // 110
-1, -1, -1, -1, -1, -1, -1, -1, -1, -1}; // 120