41 JModule::const_iterator pmt_a = module_a.begin();
42 JModule::const_iterator pmt_b = module_b.begin();
44 for ( ; pmt_a != module_a.end() && pmt_b != module_b.end(); ++pmt_a, ++pmt_b) {
45 Q.
put(pmt_a->getT0() - pmt_b->getT0());
59 inline Double_t getBin(
const std::set<int>& buffer,
const int value)
73 int main(
int argc,
char **argv)
84 int scal = 0xFFFFFFFF;
87 string detectorFile_a;
88 string detectorFile_b;
96 properties[
TCAL] = precision.tcal;
97 properties[
PCAL] = precision.pcal;
98 properties[
RCAL] = precision.rcal;
99 properties[
ACAL] = precision.acal;
100 properties[
CCAL] = precision.ccal;
101 properties[
SCAL] = precision.scal;
103 JParser<> zap(
"Auxiliary program to find differences between two detector files.");
113 catch(
const exception &error) {
114 FATAL(error.what() << endl);
122 load(detectorFile_a, detector_a);
129 load(detectorFile_b, detector_b);
135 size_t numberOfPMTs = 0;
137 bool is_equal =
true;
142 setFormat<JPosition3D> (
JFormat_t(15, 9, std::ios::fixed | std::ios::showpos));
146 if (detector_a.getID() != detector_b.getID()) {
148 DEBUG(
"* Different detector identifiers "
149 << setw(5) << detector_a.getID() <<
" (A) and " << endl
150 << setw(5) << detector_b.getID() <<
" (B)." << endl
158 if (
getDistance(detector_a.getPosition(), detector_b.getPosition()) > precision.pcal) {
160 DEBUG(
" * different UTM position: "
161 << detector_a.getPosition() <<
" (A), "
162 << detector_b.getPosition() <<
" (B)"
163 <<
", B - A " <<
JPosition3D(detector_b.getPosition() - detector_a.getPosition()) << endl);
169 for (JDetector::iterator module = detector_a.begin(); module != detector_a.end(); ++module) {
170 if (module->size() > numberOfPMTs) {
171 numberOfPMTs = module->size();
177 for (JDetector::iterator module = detector_a.begin(); module != detector_a.end(); ++module) {
179 if (!module_router_b.
hasModule(module->getID())) {
181 DEBUG(
"* Module " << setw(10) << module->getID() <<
" is in A " <<
getLabel(*module) <<
" but not in B" << endl);
187 for (JDetector::iterator module = detector_b.begin(); module != detector_b.end(); ++module) {
189 if (!module_router_a.
hasModule(module->getID())) {
191 DEBUG(
"* Module " << setw(10) << module->getID() <<
" is in B " <<
getLabel(*module) <<
" but not in A" << endl);
201 DEBUG(
"Comparing module by module." << endl);
203 for (JDetector::iterator module_a = detector_a.begin(); module_a != detector_a.end(); ++module_a) {
214 DEBUG(
" Module " << setw(10) << module_a->
getID());
225 DEBUG(
" * different location: "
227 <<
getLabel(*module_b) <<
" (B)" << endl);
234 if (fabs(module_a->
getT0() - module_b->
getT0()) > precision.acal) {
236 DEBUG(
" * different T0: "
237 <<
FIXED(12,3) << module_a->
getT0() <<
" (A), "
238 <<
FIXED(12,3) << module_b->
getT0() <<
" (B) "
239 <<
", B - A " << module_b->
getT0() - module_a->
getT0() << endl);
250 DEBUG(
" * different quaternion calibration: "
262 DEBUG(
" * different position: "
272 if (module_a->size() != module_b->size()) {
274 DEBUG(
" * different number of PMTs: "
275 << module_a->size() <<
" (A), "
276 << module_b->size() <<
" (B)" << endl);
283 if (!module_a->empty() &&
284 !module_b->empty()) {
286 const JQuantile q = getQuantile(*module_a, *module_b);
288 if (fabs(q.
getMean()) > precision.tcal) {
290 DEBUG(
" * different average t0: "
302 DEBUG(
" * different status module " << module_a->
getID() <<
": "
314 for (
unsigned int pmt = 0; pmt != module_a->size() && pmt != module_b->size(); ++pmt) {
321 DEBUG(
" * different identifier PMT " << setw(2) << pmt <<
": "
322 << setw(8) << pmt_a.
getID() <<
" (A" <<
FILL(2,
'0') << pmt <<
"), " <<
FILL()
323 << setw(8) << pmt_b.
getID() <<
" (B" <<
FILL(2,
'0') << pmt <<
")" <<
FILL()
324 <<
", B - A " << pmt_b.
getID() - pmt_a.
getID()
333 for (
unsigned int pmt = 0; pmt != module_a->size() && pmt != module_b->size(); ++pmt) {
338 if (fabs(pmt_a.
getT0() - pmt_b.
getT0()) > precision.tcal) {
340 DEBUG(
" * different T0 PMT " << setw(2) << pmt <<
": "
343 <<
", B - A " << pmt_b.
getT0() - pmt_a.
getT0()
352 for (
unsigned int pmt = 0; pmt != module_a->size() && pmt != module_b->size(); ++pmt) {
361 DEBUG(
" * different PMT position: "
372 for (
unsigned int pmt = 0; pmt != module_a->size() && pmt != module_b->size(); ++pmt) {
381 if ((1.0 - dot) > precision.rcal) {
383 DEBUG(
" * different PMT direction: "
394 for (
unsigned int pmt = 0; pmt != module_a->size() && pmt != module_b->size(); ++pmt) {
401 DEBUG(
" * different status PMT " << setw(2) << pmt <<
": "
418 for (JDetector::iterator module = detector_a.begin(); module != detector_a.end(); ++module) {
419 string.insert(module->getString());
420 floor .insert(module->getFloor ());
423 for (JDetector::iterator module = detector_b.begin(); module != detector_b.end(); ++module) {
424 string.insert(module->getString());
425 floor .insert(module->getFloor ());
431 string.size(), -0.5,
string.size() - 0.5,
432 floor .size(), -0.5, floor .size() - 0.5);
442 TH2D* X2 = (TH2D*) M2.Clone(
"X2" );
443 TH2D* Y2 = (TH2D*) M2.Clone(
"Y2" );
444 TH2D* Z2 = (TH2D*) M2.Clone(
"Z2" );
445 TH2D* T2 = (TH2D*) M2.Clone(
"T2" );
446 TH2D* RMS = (TH2D*) M2.Clone(
"RMS");
447 TH2D* R2 = (TH2D*) M2.Clone(
"R2" );
448 TH2D* QA = (TH2D*) M2.Clone(
"QA" );
449 TH2D* QB = (TH2D*) M2.Clone(
"QB" );
450 TH2D* QC = (TH2D*) M2.Clone(
"QC" );
451 TH2D* QD = (TH2D*) M2.Clone(
"QD" );
452 TH2D* Q2 = (TH2D*) M2.Clone(
"Q2" );
454 for (JDetector::iterator module = detector_a.begin(); module != detector_a.end(); ++module) {
455 if (!module_router_b.
hasModule(module->getID()) ) {
456 M2.Fill(module->getString(), module->getFloor(), -1.0);
460 for (JDetector::iterator module = detector_b.begin(); module != detector_b.end(); ++module) {
461 if (!module_router_a.
hasModule(module->getID()) ) {
462 M2.Fill(module->getString(), module->getFloor(), +1.0);
467 for (JDetector::iterator module_a = detector_a.begin(); module_a != detector_a.end(); ++module_a) {
475 for (
size_t i = 0;
i != numberOfPMTs; ++
i) {
482 X2 ->Fill(getBin(
string, module_a->
getString()), getBin(floor, module_a->
getFloor()), module_a->
getX() - module_b->
getX() + numeric_limits<double>::min());
483 Y2 ->Fill(getBin(
string, module_a->
getString()), getBin(floor, module_a->
getFloor()), module_a->
getY() - module_b->
getY() + numeric_limits<double>::min());
484 Z2 ->Fill(getBin(
string, module_a->
getString()), getBin(floor, module_a->
getFloor()), module_a->
getZ() - module_b->
getZ() + numeric_limits<double>::min());
490 const JQuantile q = getQuantile(*module_a, *module_b);
496 R2 ->Fill(getBin(
string, module_a->
getString()), getBin(floor, module_a->
getFloor()), phi);
510 for (TH2D* h2 : { &M2, X2, Y2, Z2, T2, RMS, R2, QA, QB, QC, QD, Q2 }) {
Utility class to parse command line options.
double getAngle(const JQuaternion3D &first, const JQuaternion3D &second)
Get space angle between quanternions.
Q(UTCMax_s-UTCMin_s)-livetime_s
int main(int argc, char *argv[])
double getB() const
Get b value.
int getFloor() const
Get floor number.
const JModule & getModule(const JObjectID &id) const
Get module parameters.
Data structure for a composite optical module.
static const std::string ACAL
acoustic time offsets (piezo sensor or hydrophone)
std::vector< T >::difference_type distance(typename std::vector< T >::const_iterator first, typename PhysicsEvent::const_iterator< T > second)
Specialisation of STL distance.
std::string getLabel(const JLocation &location)
Get module label for monitoring and other applications.
static const std::string CCAL
compass alignment (a.k.a. quaternion calibration)
const JDirection3D & getDirection() const
Get direction.
Router for direct addressing of module data in detector data structure.
Utility class to parse parameter values.
static JRotation getRotation
Function object to get rotation matrix to go from first to second module.
#define MAKE_CSTRING(A)
Make C-string.
Empty structure for specification of parser element that is initialised (i.e. does not require input)...
Dynamic ROOT object management.
Auxiliary data structure for floating point format specification.
double getDistance(const JVector3D &pos) const
Get distance to point.
Data structure for detector geometry and calibration.
double getDot(const JAngle3D &angle) const
Get dot product.
Utility class to parse parameter values.
double getDistance(const JFirst_t &first, const JSecond_t &second)
Get distance between objects.
const JQuaternion3D & getQuaternion() const
Get quaternion.
static const std::string TCAL
PMT time offsets.
int getStatus() const
Get status.
Auxiliary class to manage set of compatible ROOT objects (e.g. histograms) using unique keys...
#define ASSERT(A,...)
Assert macro.
JQuaternion3D twist
rotation around parallel axis
const JLocation & getLocation() const
Get location.
#define make_field(A,...)
macro to convert parameter to JParserTemplateElement object
int getID() const
Get identifier.
Data structure for PMT geometry, calibration and status.
void Write(TDirectory &out, const bool wm=false)
Write objects to file.
double getY() const
Get y position.
const JPosition3D & getPosition() const
Get position.
static const std::string RCAL
optical module orientations
const JPMT & getPMT(const int index) const
Get PMT.
General purpose messaging.
Auxiliary data structure for sequence of same character.
double getD() const
Get d value.
Data structure for unit quaternion in three dimensions.
Direct access to module in detector data structure.
double getAngle() const
Get rotation angle.
int getString() const
Get string number.
void load(const std::string &file_name, JDetector &detector)
Load detector from input file.
Auxiliary class to define a range between two values.
Utility class to parse command line options.
static const std::string SCAL
(module|PMT) status
static const JVector3D JVector3Z_t(0, 0, 1)
unit z-vector
bool hasModule(const JObjectID &id) const
Has module.
double getC() const
Get c value.
double getX() const
Get x position.
double getA() const
Get a value.
double getDot(const JVector3D &vector) const
Get dot product.
Data structure for position in three dimensions.
static const std::string PCAL
(optical|base) module positions
Auxiliary data structure for decomposition of quaternion in twist and swing quaternions.
double getZ() const
Get z position.
#define DEBUG(A)
Message macros.
double getT0() const
Get time offset.