Belle II Software development
InvariantMassAlgorithm Class Reference

Class implementing InvariantMass calibration algorithm. More...

#include <InvariantMassAlgorithm.h>

Inheritance diagram for InvariantMassAlgorithm:
CalibrationAlgorithm

Public Types

enum  EResult {
  c_OK ,
  c_Iterate ,
  c_NotEnoughData ,
  c_Failure ,
  c_Undefined
}
 The result of calibration. More...
 

Public Member Functions

 InvariantMassAlgorithm ()
 Constructor set the prefix to BoostVectorCollector.
 
virtual ~InvariantMassAlgorithm ()
 Destructor.
 
void setOuterLoss (const std::string &loss)
 Set outer loss function (for calibration intervals)
 
void setInnerLoss (const std::string &loss)
 Set inner loss function (for calibration subintervals)
 
void includeHadBcalib (bool state=true)
 Include calibration based on Hadronic B decays.
 
void setMuMuEcmsSpread (double spread)
 set the spread
 
void setMuMuEcmsOffset (double shift)
 set the energy offset
 
std::vector< InvariantMassMuMuCalib::EventgetDataMuMu (const std::vector< std::string > &files, bool is4S)
 Load the mumu data from files.
 
std::vector< InvariantMassBhadCalib::EventgetDataHadB (const std::vector< std::string > &files)
 Load the hadB data from files.
 
const std::string & getPrefix () const
 Get the prefix used for getting calibration data.
 
const std::string & getCollectorName () const
 Alias for prefix.
 
void setPrefix (const std::string &prefix)
 Set the prefix used to identify datastore objects.
 
void setInputFileNames (PyObject *inputFileNames)
 Set the input file names used for this algorithm from a Python list.
 
PyObject * getInputFileNames ()
 Get the input file names used for this algorithm and pass them out as a Python list of unicode strings.
 
std::vector< Calibration::ExpRun > getRunListFromAllData () const
 Get the complete list of runs from inspection of collected data.
 
RunRange getRunRangeFromAllData () const
 Get the complete RunRange from inspection of collected data.
 
IntervalOfValidity getIovFromAllData () const
 Get the complete IoV from inspection of collected data.
 
void fillRunToInputFilesMap ()
 Fill the mapping of ExpRun -> Files.
 
const std::string & getGranularity () const
 Get the granularity of collected data.
 
EResult execute (std::vector< Calibration::ExpRun > runs={}, int iteration=0, IntervalOfValidity iov=IntervalOfValidity())
 Runs calibration over vector of runs for a given iteration.
 
EResult execute (PyObject *runs, int iteration=0, IntervalOfValidity iov=IntervalOfValidity())
 Runs calibration over Python list of runs. Converts to C++ and then calls the other execute() function.
 
std::list< Database::DBImportQuery > & getPayloads ()
 Get constants (in TObjects) for database update from last execution.
 
std::list< Database::DBImportQuerygetPayloadValues () const
 Get constants (in TObjects) for database update from last execution but passed by VALUE.
 
bool commit ()
 Submit constants from last calibration into database.
 
bool commit (std::list< Database::DBImportQuery > payloads)
 Submit constants from a (potentially previous) set of payloads.
 
const std::string & getDescription () const
 Get the description of the algorithm (set by developers in constructor)
 
bool loadInputJson (const std::string &jsonString)
 Load the m_inputJson variable from a string (useful from Python interface). The return bool indicates success or failure.
 
const std::string dumpOutputJson () const
 Dump the JSON string of the output JSON object.
 
const std::vector< Calibration::ExpRun > findPayloadBoundaries (std::vector< Calibration::ExpRun > runs, int iteration=0)
 Used to discover the ExpRun boundaries that you want the Python CAF to execute on. This is optional and only used in some.
 
template<>
std::shared_ptr< TTree > getObjectPtr (const std::string &name, const std::vector< Calibration::ExpRun > &requestedRuns)
 Specialization of getObjectPtr<TTree>.
 

Static Public Member Functions

static bool checkPyExpRun (PyObject *pyObj)
 Checks that a PyObject can be successfully converted to an ExpRun type.
 
static Calibration::ExpRun convertPyExpRun (PyObject *pyObj)
 Performs the conversion of PyObject to ExpRun.
 

Protected Member Functions

virtual EResult calibrate () override
 Run algo on data.
 
void setInputFileNames (const std::vector< std::string > &inputFileNames)
 Set the input file names used for this algorithm.
 
virtual bool isBoundaryRequired (const Calibration::ExpRun &)
 Given the current collector data, make a decision about whether or not this run should be the start of a payload boundary.
 
virtual void boundaryFindingSetup (std::vector< Calibration::ExpRun >, int)
 If you need to make some changes to your algorithm class before 'findPayloadBoundaries' is run, make them in this function.
 
virtual void boundaryFindingTearDown ()
 Put your algorithm back into a state ready for normal execution if you need to.
 
const std::vector< Calibration::ExpRun > & getRunList () const
 Get the list of runs for which calibration is called.
 
int getIteration () const
 Get current iteration.
 
const std::vector< std::string > & getVecInputFileNames () const
 Get the input file names used for this algorithm as a STL vector.
 
template<class T>
std::shared_ptr< T > getObjectPtr (const std::string &name, const std::vector< Calibration::ExpRun > &requestedRuns)
 Get calibration data object by name and list of runs, the Merge function will be called to generate the overall object.
 
template<class T>
std::shared_ptr< T > getObjectPtr (std::string name)
 Get calibration data object (for all runs the calibration is requested for) This function will only work during or after execute() has been called once.
 
template<>
shared_ptr< TTree > getObjectPtr (const string &name, const vector< ExpRun > &requestedRuns)
 We cheekily cast the TChain to TTree for the returned pointer so that the user never knows Hopefully this doesn't cause issues if people do low level stuff to the tree...
 
std::string getGranularityFromData () const
 Get the granularity of collected data.
 
void saveCalibration (TClonesArray *data, const std::string &name)
 Store DBArray payload with given name with default IOV.
 
void saveCalibration (TClonesArray *data, const std::string &name, const IntervalOfValidity &iov)
 Store DBArray with given name and custom IOV.
 
void saveCalibration (TObject *data)
 Store DB payload with default name and default IOV.
 
void saveCalibration (TObject *data, const IntervalOfValidity &iov)
 Store DB payload with default name and custom IOV.
 
void saveCalibration (TObject *data, const std::string &name)
 Store DB payload with given name with default IOV.
 
void saveCalibration (TObject *data, const std::string &name, const IntervalOfValidity &iov)
 Store DB payload with given name and custom IOV.
 
void setDescription (const std::string &description)
 Set algorithm description (in constructor)
 
void clearCalibrationData ()
 Clear calibration data.
 
void resetInputJson ()
 Clears the m_inputJson member variable.
 
void resetOutputJson ()
 Clears the m_outputJson member variable.
 
template<class T>
void setOutputJsonValue (const std::string &key, const T &value)
 Set a key:value pair for the outputJson object, expected to used internally during calibrate()
 
template<class T>
const T getOutputJsonValue (const std::string &key) const
 Get a value using a key from the JSON output object, not sure why you would want to do this.
 
template<class T>
const T getInputJsonValue (const std::string &key) const
 Get an input JSON value using a key. The normal exceptions are raised when the key doesn't exist.
 
const nlohmann::json & getInputJsonObject () const
 Get the entire top level JSON object. We explicitly say this must be of object type so that we might pick.
 
bool inputJsonKeyExists (const std::string &key) const
 Test for a key in the input JSON object.
 

Static Protected Member Functions

static void updateDBObjPtrs (const unsigned int event, const int run, const int experiment)
 Updates any DBObjPtrs by calling update(event) for DBStore.
 
static Calibration::ExpRun getAllGranularityExpRun ()
 Returns the Exp,Run pair that means 'Everything'. Currently unused.
 

Protected Attributes

std::vector< Calibration::ExpRun > m_boundaries
 When using the boundaries functionality from isBoundaryRequired, this is used to store the boundaries. It is cleared when.
 

Private Member Functions

std::vector< std::vector< CalibrationData > > adjustOffResonanceEnergy (std::vector< std::vector< CalibrationData > > CalResultsBlocks, const std::vector< std::vector< InvariantMassMuMuCalib::Event > > &evtsMuMuBlocks)
 Adjust the energy of the off-resonance runs based on the energy offset between mumu and hadB method in the neighboring blocks.
 
std::string getExpRunString (Calibration::ExpRun &expRun) const
 Gets the "exp.run" string repr. of (exp,run)
 
std::string getFullObjectPath (const std::string &name, Calibration::ExpRun expRun) const
 constructs the full TDirectory + Key name of an object in a TFile based on its name and exprun
 

Private Attributes

TString m_lossFunctionOuter = "pow(0.000010e0*rawTime, 2) + 1./nEv"
 Outer loss function (for calibration intervals with constant InvarinatMass spread)
 
TString m_lossFunctionInner = "pow(0.000120e0*rawTime, 2) + 1./nEv"
 Inner loss function (for calibration subintervals with constant InvariantMass)
 
bool m_runHadB = true
 Run the calibration from had-B decays.
 
double m_eCMSmumuSpread = 5.2e-3
 Energy spread for mumu only run (m_runHadB == false)
 
double m_eCMSmumuShift = 10e-3
 Shift between the energy from the mumu events and the real value.
 
std::vector< std::string > m_inputFileNames
 List of input files to the Algorithm, will initially be user defined but then gets the wildcards expanded during execute()
 
std::map< Calibration::ExpRun, std::vector< std::string > > m_runsToInputFiles
 Map of Runs to input files. Gets filled when you call getRunRangeFromAllData, gets cleared when setting input files again.
 
std::string m_granularityOfData
 Granularity of input data. This only changes when the input files change so it isn't specific to an execution.
 
ExecutionData m_data
 Data specific to a SINGLE execution of the algorithm. Gets reset at the beginning of execution.
 
std::string m_description {""}
 Description of the algorithm.
 
std::string m_prefix {""}
 The name of the TDirectory the collector objects are contained within.
 
nlohmann::json m_jsonExecutionInput = nlohmann::json::object()
 Optional input JSON object used to make decisions about how to execute the algorithm code.
 
nlohmann::json m_jsonExecutionOutput = nlohmann::json::object()
 Optional output JSON object that can be set during the execution by the underlying algorithm code.
 

Static Private Attributes

static const Calibration::ExpRun m_allExpRun = make_pair(-1, -1)
 allExpRun
 

Detailed Description

Class implementing InvariantMass calibration algorithm.

Definition at line 24 of file InvariantMassAlgorithm.h.

Member Enumeration Documentation

◆ EResult

enum EResult
inherited

The result of calibration.

Enumerator
c_OK 

Finished successfully =0 in Python.

c_Iterate 

Needs iteration =1 in Python.

c_NotEnoughData 

Needs more data =2 in Python.

c_Failure 

Failed =3 in Python.

c_Undefined 

Not yet known (before execution) =4 in Python.

Definition at line 40 of file CalibrationAlgorithm.h.

40 {
41 c_OK,
42 c_Iterate,
43 c_NotEnoughData,
44 c_Failure,
45 c_Undefined
46 };

Constructor & Destructor Documentation

◆ InvariantMassAlgorithm()

Constructor set the prefix to BoostVectorCollector.

Definition at line 30 of file InvariantMassAlgorithm.cc.

30 : CalibrationAlgorithm("BoostVectorCollector")
31{
32 setDescription("Collision invariant mass calibration algorithm");
33}
void setDescription(const std::string &description)
Set algorithm description (in constructor)
CalibrationAlgorithm(const std::string &collectorModuleName)
Constructor - sets the prefix for collected objects (won't be accesses until execute(....

◆ ~InvariantMassAlgorithm()

virtual ~InvariantMassAlgorithm ( )
inlinevirtual

Destructor.

Definition at line 31 of file InvariantMassAlgorithm.h.

31{}

Member Function Documentation

◆ adjustOffResonanceEnergy()

std::vector< std::vector< CalibrationData > > adjustOffResonanceEnergy ( std::vector< std::vector< CalibrationData > > CalResultsBlocks,
const std::vector< std::vector< InvariantMassMuMuCalib::Event > > & evtsMuMuBlocks )
private

Adjust the energy of the off-resonance runs based on the energy offset between mumu and hadB method in the neighboring blocks.

Definition at line 303 of file InvariantMassAlgorithm.cc.

306{
307 // Adjust the energy in the off-resoncance runs
308 for (int b = 0; b < int(CalResultsBlocks.size()); ++b) {
309 // only deal with off-res runs
310 if (evtsMuMuBlocks[b][0].is4S) continue;
311
312 std::vector<CalibPars> parsEdges;
313 if (b > 0 && evtsMuMuBlocks[b - 1][0].is4S)
314 parsEdges.push_back(CalResultsBlocks[b - 1].back().pars);
315 if (b < int(CalResultsBlocks.size()) - 1 && evtsMuMuBlocks[b + 1][0].is4S)
316 parsEdges.push_back(CalResultsBlocks[b + 1].front().pars);
317 std::vector<double> shifts, shiftsUnc, spreads, spreadsUnc;
318 for (auto p : parsEdges) {
319 shifts.push_back(p.shift);
320 shiftsUnc.push_back(p.shiftUnc);
321 spreads.push_back(p.spreadMat(0, 0));
322 spreadsUnc.push_back(p.spreadUnc);
323 }
324
325 // by default take the offset from the steering
326 double spread = m_eCMSmumuSpread;
327 double spreadUnc = 0.2e-3; // default spread for off-resonance [GeV]
328 double shift = m_eCMSmumuShift;
329 double shiftUnc = 0.3e-3; // default shift unc [GeV]
330
331 // in case of single neighboring 4S block
332 if (shifts.size() == 1) {
333 spread = spreads[0];
334 spreadUnc = spreadsUnc[0];
335 shift = shifts[0];
336 shiftUnc = shiftsUnc[0];
337 }
338 // if neighbors are from both sides take the average
339 else if (shifts.size() == 2) {
340 spread = weightAvg(spreads[0], spreadsUnc[0], spreads[1], spreadsUnc[1]);
341 shift = weightAvg(shifts[0], shiftsUnc[0], shifts[1], shiftsUnc[1]);
342
343 spreadUnc = sqrt(square(spreads[0] - spreads[1]) + (square(spreadsUnc[0]) + square(spreadsUnc[1])) / 2);
344 shiftUnc = sqrt((square(shift - shifts[0]) + square(shift - shifts[1])) / 2 + (square(shiftsUnc[0]) + square(shiftsUnc[1])) / 2);
345 }
346
347 CalResultsBlocks[b] = addSpreadAndOffset(CalResultsBlocks[b], spread, spreadUnc, shift, shiftUnc);
348 }
349 return CalResultsBlocks;
350}
double m_eCMSmumuShift
Shift between the energy from the mumu events and the real value.
double m_eCMSmumuSpread
Energy spread for mumu only run (m_runHadB == false)
constexpr T square(const T &x)
Calculate the square of the input.
Definition MathHelpers.h:21
double sqrt(double a)
sqrt for double
Definition beamHelpers.h:28

◆ boundaryFindingSetup()

virtual void boundaryFindingSetup ( std::vector< Calibration::ExpRun > ,
int  )
inlineprotectedvirtualinherited

If you need to make some changes to your algorithm class before 'findPayloadBoundaries' is run, make them in this function.

Reimplemented in PXDAnalyticGainCalibrationAlgorithm, PXDValidationAlgorithm, SVD3SampleCoGTimeCalibrationAlgorithm, SVD3SampleELSTimeCalibrationAlgorithm, SVDClusterAbsoluteTimeShifterAlgorithm, SVDCoGTimeCalibrationAlgorithm, TestBoundarySettingAlgorithm, and TestCalibrationAlgorithm.

Definition at line 252 of file CalibrationAlgorithm.h.

252{};

◆ boundaryFindingTearDown()

virtual void boundaryFindingTearDown ( )
inlineprotectedvirtualinherited

Put your algorithm back into a state ready for normal execution if you need to.

Definition at line 257 of file CalibrationAlgorithm.h.

257{};

◆ calibrate()

CalibrationAlgorithm::EResult calibrate ( )
overrideprotectedvirtual

Run algo on data.

Implements CalibrationAlgorithm.

Definition at line 360 of file InvariantMassAlgorithm.cc.

361{
362 std::vector<std::string> files = getVecInputFileNames();
363
364 std::vector<std::string> filesHad4S, filesMuMu4S, filesMuMuOff;
365 for (auto f : files) {
366 if (f.find("/dimuon_4S/") != std::string::npos)
367 filesMuMu4S.push_back(f);
368 else if (f.find("/dimuon_Off/") != std::string::npos)
369 filesMuMuOff.push_back(f);
370 else if (f.find("/hadB_4S/") != std::string::npos)
371 filesHad4S.push_back(f);
372 else {
373 B2FATAL("Unrecognised data type");
374 }
375 }
376
377
378 for (auto r : filesMuMu4S)
379 B2INFO("MuMu4SFile name " << r);
380 for (auto r : filesMuMuOff) {
381 B2INFO("MuMuOffFile name " << r);
382 }
383 for (auto r : filesHad4S)
384 B2INFO("Had4SFile name " << r);
385
386
387
388 // load the mumu data
389 const auto evtsMuMuOff = readMuMuFiles(filesMuMuOff, false /*is4S*/);
390 const auto evtsMuMu4S = readMuMuFiles(filesMuMu4S, true /*is4S*/);
391
392 if (evtsMuMuOff.size() + evtsMuMu4S.size() < 50) {
393 B2WARNING("Not enough data, there are only " << evtsMuMuOff.size() + evtsMuMu4S.size() << " mumu events");
395 }
396
397
398 // load hadB data
399 const auto evtsHad = readBhadFiles(filesHad4S);
400
401 // merge mumu data
402 std::vector<InvariantMassMuMuCalib::Event> evtsMuMuTemp = evtsMuMu4S;
403 evtsMuMuTemp.insert(evtsMuMuTemp.end(), evtsMuMuOff.begin(), evtsMuMuOff.end());
404
405 if (evtsMuMuTemp.size() < 50) {
406 B2WARNING("Not enough mumu data, there are only " << evtsMuMuTemp.size() << " mumu events");
408 }
409
410
411 // sort by time
412 std::sort(evtsMuMuTemp.begin(), evtsMuMuTemp.end(), [](const InvariantMassMuMuCalib::Event & evt1,
413 const InvariantMassMuMuCalib::Event & evt2) { return evt1.t < evt2.t; });
414
415 //split the mumu events into the blocks with identical run type
416 std::vector<std::vector<InvariantMassMuMuCalib::Event>> evtsMuMuBlocks;
417 bool is4Sold = evtsMuMuTemp[0].is4S;
418 evtsMuMuBlocks.push_back({}); // empty vec to start
419 for (const auto& ev : evtsMuMuTemp) {
420 if (is4Sold != ev.is4S) {
421 evtsMuMuBlocks.push_back({}); // adding new entry
422 is4Sold = ev.is4S;
423 }
424 evtsMuMuBlocks.back().push_back(ev);
425 }
426 B2INFO("Number of mumu 4S events " << evtsMuMu4S.size());
427 B2INFO("Number of mumu off-res events " << evtsMuMuOff.size());
428 B2INFO("Total number of mumu events " << evtsMuMuTemp.size());
429 B2INFO("Number of hadronic B events " << evtsHad.size());
430
431 B2INFO("Number of main calibration blocks " << evtsMuMuBlocks.size());
432
433 std::ofstream BonlyOut("BonlyEcmsCalib.txt");
434 BonlyOut << "t1 t2 exp1 run1 exp2 run2 Ecms EcmsUnc spread spreadUnc" << std::endl;
435
436 std::vector<std::vector<CalibrationData>> CalResultsBlocks;
437 //calibrate each run-type block separately
438 for (const auto& evtsMuMu : evtsMuMuBlocks) {
439
440 // Run the mumuCalibration
441 const std::vector<CalibrationData> mumuCalResults = runMuMuCalibration(evtsMuMu,
442 InvariantMassMuMuCalib::runMuMuInvariantMassAnalysis,
444
445
446 //if off-res block or hadB is turned off
447 if (!m_runHadB || evtsMuMu[0].is4S == false) {
448 CalResultsBlocks.push_back(mumuCalResults);
449 continue;
450 }
451
452
453 // If its 4S type and hadB allowed, run the combined Calib
454 auto combCalResults = mumuCalResults;
455 //Update the calibration with Bhad data
456 for (unsigned i = 0; i < mumuCalResults.size(); ++i) {
457 const auto& calibMuMu = mumuCalResults[i];
458 auto& calibComb = combCalResults[i];
459
460 std::vector<std::pair<double, double>> limits, mumuVals;
461
462 for (unsigned j = 0; j < calibMuMu.subIntervals.size(); ++j) {
463 double s = calibMuMu.subIntervals[j].begin()->second.first;
464 double e = calibMuMu.subIntervals[j].rbegin()->second.second;
465 limits.push_back({s, e});
466
467 double val = calibMuMu.pars.cnt[j](0);
468 double unc = calibMuMu.pars.cntUnc[j](0, 0);
469 mumuVals.push_back({val, unc});
470 }
471
472
474 // run B mesons stand-alone calibration
476 auto resB = InvariantMassBhadCalib::doBhadOnlyFit(evtsHad, limits);
477
478 // store it to file
479 double s = calibMuMu.subIntervals.front().begin()->second.first; // start time in hours
480 double e = calibMuMu.subIntervals.back().rbegin()->second.second;// end time in hours
481
482 double exp1 = calibMuMu.subIntervals.front().begin()->first.exp;
483 double exp2 = calibMuMu.subIntervals.back().rbegin()->first.exp;
484 double run1 = calibMuMu.subIntervals.front().begin()->first.run;
485 double run2 = calibMuMu.subIntervals.back().rbegin()->first.run;
486
487 BonlyOut << std::setprecision(8) << s << " " << e << " " << exp1 << " " << run1 << " " << exp2 << " " << run2 << " " <<
488 1e3 * resB[0] << " " << 1e3 * resB[1] << " " << 1e3 * resB[2] << " " << 1e3 * resB[3] << std::endl;
489
490
491
493 //run the combined calibration
495 auto res = InvariantMassBhadCalib::doBhadFit(evtsHad, limits, mumuVals, resB);
496
497 // update calibration data
498 for (unsigned j = 0; j < calibMuMu.subIntervals.size(); ++j) {
499 calibComb.pars.cnt[j](0) = res[j][0];
500 calibComb.pars.cntUnc[j](0, 0) = res[j][1];
501 calibComb.pars.spreadMat(0, 0) = res[j][2];
502
503 calibComb.pars.spreadUnc = res[j][3];
504 calibComb.pars.shift = res[j][4];
505 calibComb.pars.shiftUnc = res[j][5];
506 calibComb.pars.pulls[j] = res[j][6];
507 }
508
509
510 }
511
512 CalResultsBlocks.push_back(combCalResults);
513
514 }
515
516 assert(CalResultsBlocks.size() == evtsMuMuBlocks.size());
517
518 CalResultsBlocks = adjustOffResonanceEnergy(CalResultsBlocks, evtsMuMuBlocks);
519
520
521 std::vector<CalibrationData> CalResults;
522 for (auto cb : CalResultsBlocks)
523 for (auto c : cb)
524 CalResults.push_back(c);
525
526 //Store info to the text file
527 printToFile(CalResults, "finalEcmsCalib.txt");
528
529
530 storePayloadsNoIntraRun(CalResults, "CollisionInvariantMass", getInvariantMassObj);
531
532
534}
@ c_OK
Finished successfully =0 in Python.
@ c_NotEnoughData
Needs more data =2 in Python.
const std::vector< std::string > & getVecInputFileNames() const
Get the input file names used for this algorithm as a STL vector.
bool m_runHadB
Run the calibration from had-B decays.
TString m_lossFunctionOuter
Outer loss function (for calibration intervals with constant InvarinatMass spread)
std::vector< std::vector< CalibrationData > > adjustOffResonanceEnergy(std::vector< std::vector< CalibrationData > > CalResultsBlocks, const std::vector< std::vector< InvariantMassMuMuCalib::Event > > &evtsMuMuBlocks)
Adjust the energy of the off-resonance runs based on the energy offset between mumu and hadB method i...
TString m_lossFunctionInner
Inner loss function (for calibration subintervals with constant InvariantMass)
void storePayloadsNoIntraRun(const std::vector< CalibrationData > &calVecConst, std::string objName, std::function< TObject *(Eigen::VectorXd, Eigen::MatrixXd, Eigen::MatrixXd) > getCalibObj)
Store payloads to files, where calib data have no intra-run dependence.
Definition calibTools.h:290

◆ checkPyExpRun()

bool checkPyExpRun ( PyObject * pyObj)
staticinherited

Checks that a PyObject can be successfully converted to an ExpRun type.

Checks if the PyObject can be converted to ExpRun.

Definition at line 28 of file CalibrationAlgorithm.cc.

29{
30 // Is it a sequence?
31 if (PySequence_Check(pyObj)) {
32 Py_ssize_t nObj = PySequence_Length(pyObj);
33 // Does it have 2 objects in it?
34 if (nObj != 2) {
35 B2DEBUG(29, "ExpRun was a Python sequence which didn't have exactly 2 entries!");
36 return false;
37 }
38 PyObject* item1, *item2;
39 item1 = PySequence_GetItem(pyObj, 0);
40 item2 = PySequence_GetItem(pyObj, 1);
41 // Did the GetItem work?
42 if ((item1 == NULL) || (item2 == NULL)) {
43 B2DEBUG(29, "A PyObject pointer was NULL in the sequence");
44 return false;
45 }
46 // Are they longs?
47 if (PyLong_Check(item1) && PyLong_Check(item2)) {
48 long value1, value2;
49 value1 = PyLong_AsLong(item1);
50 value2 = PyLong_AsLong(item2);
51 if (((value1 == -1) || (value2 == -1)) && PyErr_Occurred()) {
52 B2DEBUG(29, "An error occurred while converting the PyLong to long");
53 return false;
54 }
55 } else {
56 B2DEBUG(29, "One or more of the PyObjects in the ExpRun wasn't a long");
57 return false;
58 }
59 // Make sure to kill off the reference GetItem gave us responsibility for
60 Py_DECREF(item1);
61 Py_DECREF(item2);
62 } else {
63 B2DEBUG(29, "ExpRun was not a Python sequence.");
64 return false;
65 }
66 return true;
67}

◆ clearCalibrationData()

void clearCalibrationData ( )
inlineprotectedinherited

Clear calibration data.

Definition at line 324 of file CalibrationAlgorithm.h.

324{m_data.clearCalibrationData();}

◆ commit() [1/2]

bool commit ( )
inherited

Submit constants from last calibration into database.

Definition at line 302 of file CalibrationAlgorithm.cc.

303{
304 if (getPayloads().empty())
305 return false;
306 list<Database::DBImportQuery> payloads = getPayloads();
307 B2INFO("Committing " << payloads.size() << " payloads to database.");
308 return Database::Instance().storeData(payloads);
309}
std::list< Database::DBImportQuery > & getPayloads()
Get constants (in TObjects) for database update from last execution.
static Database & Instance()
Instance of a singleton Database.
Definition Database.cc:42
bool storeData(const std::string &name, TObject *object, const IntervalOfValidity &iov)
Store an object in the database.
Definition Database.cc:141

◆ commit() [2/2]

bool commit ( std::list< Database::DBImportQuery > payloads)
inherited

Submit constants from a (potentially previous) set of payloads.

Definition at line 312 of file CalibrationAlgorithm.cc.

313{
314 if (payloads.empty())
315 return false;
316 return Database::Instance().storeData(payloads);
317}

◆ convertPyExpRun()

ExpRun convertPyExpRun ( PyObject * pyObj)
staticinherited

Performs the conversion of PyObject to ExpRun.

Converts the PyObject to an ExpRun. We've preoviously checked the object so this assumes a lot about the PyObject.

Definition at line 70 of file CalibrationAlgorithm.cc.

71{
72 ExpRun expRun;
73 PyObject* itemExp, *itemRun;
74 itemExp = PySequence_GetItem(pyObj, 0);
75 itemRun = PySequence_GetItem(pyObj, 1);
76 expRun.first = PyLong_AsLong(itemExp);
77 Py_DECREF(itemExp);
78 expRun.second = PyLong_AsLong(itemRun);
79 Py_DECREF(itemRun);
80 return expRun;
81}

◆ dumpOutputJson()

const std::string dumpOutputJson ( ) const
inlineinherited

Dump the JSON string of the output JSON object.

Definition at line 223 of file CalibrationAlgorithm.h.

223{return m_jsonExecutionOutput.dump();}

◆ execute() [1/2]

CalibrationAlgorithm::EResult execute ( PyObject * runs,
int iteration = 0,
IntervalOfValidity iov = IntervalOfValidity() )
inherited

Runs calibration over Python list of runs. Converts to C++ and then calls the other execute() function.

Definition at line 83 of file CalibrationAlgorithm.cc.

84{
85 B2DEBUG(29, "Running execute() using Python Object as input argument");
86 // Reset the execution specific data in case the algorithm was previously called
87 m_data.reset();
88 m_data.setIteration(iteration);
89 vector<ExpRun> vecRuns;
90 // Is it a list?
91 if (PySequence_Check(runs)) {
92 boost::python::handle<> handle(boost::python::borrowed(runs));
93 boost::python::list listRuns(handle);
94
95 int nList = boost::python::len(listRuns);
96 for (int iList = 0; iList < nList; ++iList) {
97 boost::python::object pyExpRun(listRuns[iList]);
98 if (!checkPyExpRun(pyExpRun.ptr())) {
99 B2ERROR("Received Python ExpRuns couldn't be converted to C++");
100 m_data.setResult(c_Failure);
101 return c_Failure;
102 } else {
103 vecRuns.push_back(convertPyExpRun(pyExpRun.ptr()));
104 }
105 }
106 } else {
107 B2ERROR("Tried to set the input runs but we didn't receive a Python sequence object (list,tuple).");
108 m_data.setResult(c_Failure);
109 return c_Failure;
110 }
111 return execute(vecRuns, iteration, iov);
112}
static bool checkPyExpRun(PyObject *pyObj)
Checks that a PyObject can be successfully converted to an ExpRun type.
EResult execute(std::vector< Calibration::ExpRun > runs={}, int iteration=0, IntervalOfValidity iov=IntervalOfValidity())
Runs calibration over vector of runs for a given iteration.
static Calibration::ExpRun convertPyExpRun(PyObject *pyObj)
Performs the conversion of PyObject to ExpRun.
ExecutionData m_data
Data specific to a SINGLE execution of the algorithm. Gets reset at the beginning of execution.

◆ execute() [2/2]

CalibrationAlgorithm::EResult execute ( std::vector< Calibration::ExpRun > runs = {},
int iteration = 0,
IntervalOfValidity iov = IntervalOfValidity() )
inherited

Runs calibration over vector of runs for a given iteration.

You can also specify the IoV to save the database payload as. By default the Algorithm will create an IoV from your requested ExpRuns, or from the overall ExpRuns of the input data if you haven't specified ExpRuns in this function.

No checks are performed to make sure that a IoV you specify matches the data you ran over, it simply labels the IoV to commit to the database later.

Definition at line 114 of file CalibrationAlgorithm.cc.

115{
116 // Check if we are calling this function directly and need to reset, or through Python where it was already done.
117 if (m_data.getResult() != c_Undefined) {
118 m_data.reset();
119 m_data.setIteration(iteration);
120 }
121
122 if (m_inputFileNames.empty()) {
123 B2ERROR("There aren't any input files set. Please use CalibrationAlgorithm::setInputFiles()");
124 m_data.setResult(c_Failure);
125 return c_Failure;
126 }
127
128 // Did we receive runs to execute over explicitly?
129 if (!(runs.empty())) {
130 for (auto expRun : runs) {
131 B2DEBUG(29, "ExpRun requested = (" << expRun.first << ", " << expRun.second << ")");
132 }
133 // We've asked explicitly for certain runs, but we should check if the data granularity is 'run'
134 if (strcmp(getGranularity().c_str(), "all") == 0) {
135 B2ERROR(("The data is collected with granularity=all (exp=-1,run=-1), but you seem to request calibration for specific runs."
136 " We'll continue but using ALL the input data given instead of the specific runs requested."));
137 }
138 } else {
139 // If no runs are provided, infer the runs from all collected data
140 runs = getRunListFromAllData();
141 // Let's check that we have some now
142 if (runs.empty()) {
143 B2ERROR("No collected data in input files.");
144 m_data.setResult(c_Failure);
145 return c_Failure;
146 }
147 for (auto expRun : runs) {
148 B2DEBUG(29, "ExpRun requested = (" << expRun.first << ", " << expRun.second << ")");
149 }
150 }
151
152 m_data.setRequestedRuns(runs);
153 if (iov.empty()) {
154 // If no user specified IoV we use the IoV from the executed run list
155 iov = IntervalOfValidity(runs[0].first, runs[0].second, runs[runs.size() - 1].first, runs[runs.size() - 1].second);
156 }
157 m_data.setRequestedIov(iov);
158 // After here, the getObject<...>(...) helpers start to work
159
161 m_data.setResult(result);
162 return result;
163}
std::vector< Calibration::ExpRun > getRunListFromAllData() const
Get the complete list of runs from inspection of collected data.
std::vector< std::string > m_inputFileNames
List of input files to the Algorithm, will initially be user defined but then gets the wildcards expa...
EResult
The result of calibration.
@ c_Undefined
Not yet known (before execution) =4 in Python.
const std::string & getGranularity() const
Get the granularity of collected data.
virtual EResult calibrate()=0
Run algo on data - pure virtual: needs to be implemented.

◆ fillRunToInputFilesMap()

void fillRunToInputFilesMap ( )
inherited

Fill the mapping of ExpRun -> Files.

Definition at line 331 of file CalibrationAlgorithm.cc.

332{
333 m_runsToInputFiles.clear();
334 // Save TDirectory to change back at the end
335 TDirectory* dir = gDirectory;
336 RunRange* runRange;
337 // Construct the TDirectory name where we expect our objects to be
338 string runRangeObjName(getPrefix() + "/" + RUN_RANGE_OBJ_NAME);
339 for (const auto& fileName : m_inputFileNames) {
340 //Open TFile to get the objects
341 unique_ptr<TFile> f;
342 f.reset(TFile::Open(fileName.c_str(), "READ"));
343 runRange = dynamic_cast<RunRange*>(f->Get(runRangeObjName.c_str()));
344 if (runRange) {
345 // Insert or extend the run -> file mapping for this ExpRun
346 auto expRuns = runRange->getExpRunSet();
347 for (const auto& expRun : expRuns) {
348 auto runFiles = m_runsToInputFiles.find(expRun);
349 if (runFiles != m_runsToInputFiles.end()) {
350 (runFiles->second).push_back(fileName);
351 } else {
352 m_runsToInputFiles.insert(std::make_pair(expRun, std::vector<std::string> {fileName}));
353 }
354 }
355 } else {
356 B2WARNING("Missing a RunRange object for file: " << fileName);
357 }
358 }
359 dir->cd();
360}
const std::string & getPrefix() const
Get the prefix used for getting calibration data.
std::map< Calibration::ExpRun, std::vector< std::string > > m_runsToInputFiles
Map of Runs to input files. Gets filled when you call getRunRangeFromAllData, gets cleared when setti...
const std::set< Calibration::ExpRun > & getExpRunSet()
Get access to the stored set.
Definition RunRange.h:64

◆ findPayloadBoundaries()

const std::vector< ExpRun > findPayloadBoundaries ( std::vector< Calibration::ExpRun > runs,
int iteration = 0 )
inherited

Used to discover the ExpRun boundaries that you want the Python CAF to execute on. This is optional and only used in some.

Definition at line 521 of file CalibrationAlgorithm.cc.

522{
523 m_boundaries.clear();
524 if (m_inputFileNames.empty()) {
525 B2ERROR("There aren't any input files set. Please use CalibrationAlgorithm::setInputFiles()");
526 return m_boundaries;
527 }
528 // Reset the internal execution data just in case something is hanging around
529 m_data.reset();
530 if (runs.empty()) {
531 // Want to loop over all runs we could possibly know about
532 runs = getRunListFromAllData();
533 }
534 // Let's check that we have some now
535 if (runs.empty()) {
536 B2ERROR("No collected data in input files.");
537 return m_boundaries;
538 }
539 // In order to find run boundaries we must have collected with data granularity == 'run'
540 if (strcmp(getGranularity().c_str(), "all") == 0) {
541 B2ERROR("The data is collected with granularity='all' (exp=-1,run=-1), and we can't use that to find run boundaries.");
542 return m_boundaries;
543 }
544 m_data.setIteration(iteration);
545 // User defined setup function
546 boundaryFindingSetup(runs, iteration);
547 std::vector<ExpRun> runList;
548 // Loop over run list and call derived class "isBoundaryRequired" member function
549 for (auto currentRun : runs) {
550 runList.push_back(currentRun);
551 m_data.setRequestedRuns(runList);
552 // After here, the getObject<...>(...) helpers start to work
553 if (isBoundaryRequired(currentRun)) {
554 m_boundaries.push_back(currentRun);
555 }
556 // Only want run-by-run
557 runList.clear();
558 // Don't want memory hanging around
559 m_data.clearCalibrationData();
560 }
561 m_data.reset();
563 return m_boundaries;
564}
std::vector< Calibration::ExpRun > m_boundaries
When using the boundaries functionality from isBoundaryRequired, this is used to store the boundaries...
virtual void boundaryFindingTearDown()
Put your algorithm back into a state ready for normal execution if you need to.
virtual void boundaryFindingSetup(std::vector< Calibration::ExpRun >, int)
If you need to make some changes to your algorithm class before 'findPayloadBoundaries' is run,...
virtual bool isBoundaryRequired(const Calibration::ExpRun &)
Given the current collector data, make a decision about whether or not this run should be the start o...

◆ getAllGranularityExpRun()

static Calibration::ExpRun getAllGranularityExpRun ( )
inlinestaticprotectedinherited

Returns the Exp,Run pair that means 'Everything'. Currently unused.

Definition at line 327 of file CalibrationAlgorithm.h.

327{return m_allExpRun;}

◆ getCollectorName()

const std::string & getCollectorName ( ) const
inlineinherited

Alias for prefix.

For convenience and less writing, we say developers to set this to default collector module name in constructor of base class. One can however use the dublets of collector+algorithm multiple times with different settings. To bind these together correctly, the prefix has to be set the same for algo and collector. So we call the setter setPrefix rather than setModuleName or whatever. This getter will work out of the box for default cases -> return the name of module you have to add to your path to collect data for this algorithm.

Definition at line 164 of file CalibrationAlgorithm.h.

164{return getPrefix();}

◆ getDataHadB()

std::vector< InvariantMassBhadCalib::Event > getDataHadB ( const std::vector< std::string > & files)

Load the hadB data from files.

Definition at line 221 of file InvariantMassAlgorithm.cc.

222{
223 if (files.size() == 0)
224 return {};
225
227 setPrefix("EcmsCollector");
228
229 setInputFileNames(files);
231 TTree* eventsTr = getObjectPtr<TTree>("events").get();
232
233 // Check that there are at least some mumu data
234 if (!eventsTr || eventsTr->GetEntries() < 15) {
235 if (eventsTr)
236 B2WARNING("Too few data, only " << eventsTr->GetEntries() << " events found in hadronic B decay sample");
237 else
238 B2WARNING("Pointer to the \"events\" object not defined for hadronic B decay sample");
239
240 return {};
241 }
242 B2INFO("Number of mumu events: " << eventsTr->GetEntries());
243
244
245 return InvariantMassBhadCalib::getEvents(eventsTr);
246
247}
void setInputFileNames(PyObject *inputFileNames)
Set the input file names used for this algorithm from a Python list.
void setPrefix(const std::string &prefix)
Set the prefix used to identify datastore objects.
void fillRunToInputFilesMap()
Fill the mapping of ExpRun -> Files.
void clearCalibrationData()
Clear calibration data.
std::shared_ptr< T > getObjectPtr(const std::string &name, const std::vector< Calibration::ExpRun > &requestedRuns)
Get calibration data object by name and list of runs, the Merge function will be called to generate t...

◆ getDataMuMu()

std::vector< InvariantMassMuMuCalib::Event > getDataMuMu ( const std::vector< std::string > & files,
bool is4S )

Load the mumu data from files.

Definition at line 189 of file InvariantMassAlgorithm.cc.

190{
191 if (files.size() == 0)
192 return {};
193
195 setPrefix("BoostVectorCollector");
196
197 setInputFileNames(files);
199
200 TTree* eventsTr = getObjectPtr<TTree>("events").get();
201
202 // Check that there are at least some mumu data
203 if (!eventsTr || eventsTr->GetEntries() < 15) {
204 if (eventsTr) {
205 if (is4S)
206 B2WARNING("Small number of events in the 4S mumu sample, only " << eventsTr->GetEntries());
207 else
208 B2WARNING("Small number of events in the off-resonance mumu sample, only " << eventsTr->GetEntries());
209 } else
210 B2WARNING("Pointer to the \"events\" object not defined for the mumu sample");
211
212 return {};
213 }
214 B2INFO("Number of mumu events: " << eventsTr->GetEntries());
215
216
217 return InvariantMassMuMuCalib::getEvents(eventsTr, is4S);
218
219}

◆ getDescription()

const std::string & getDescription ( ) const
inlineinherited

Get the description of the algorithm (set by developers in constructor)

Definition at line 216 of file CalibrationAlgorithm.h.

216{return m_description;}

◆ getExpRunString()

string getExpRunString ( Calibration::ExpRun & expRun) const
privateinherited

Gets the "exp.run" string repr. of (exp,run)

Definition at line 254 of file CalibrationAlgorithm.cc.

255{
256 string expRunString;
257 expRunString += to_string(expRun.first);
258 expRunString += ".";
259 expRunString += to_string(expRun.second);
260 return expRunString;
261}

◆ getFullObjectPath()

string getFullObjectPath ( const std::string & name,
Calibration::ExpRun expRun ) const
privateinherited

constructs the full TDirectory + Key name of an object in a TFile based on its name and exprun

Definition at line 263 of file CalibrationAlgorithm.cc.

264{
265 string dirName = getPrefix() + "/" + name;
266 string objName = name + "_" + getExpRunString(expRun);
267 return dirName + "/" + objName;
268}
std::string getExpRunString(Calibration::ExpRun &expRun) const
Gets the "exp.run" string repr. of (exp,run)

◆ getGranularity()

const std::string & getGranularity ( ) const
inlineinherited

Get the granularity of collected data.

Definition at line 188 of file CalibrationAlgorithm.h.

188{return m_granularityOfData;};

◆ getGranularityFromData()

string getGranularityFromData ( ) const
protectedinherited

Get the granularity of collected data.

Definition at line 384 of file CalibrationAlgorithm.cc.

385{
386 // Save TDirectory to change back at the end
387 TDirectory* dir = gDirectory;
388 const RunRange* runRange;
389 string runRangeObjName(getPrefix() + "/" + RUN_RANGE_OBJ_NAME);
390 // We only check the first file
391 string fileName = m_inputFileNames[0];
392 unique_ptr<TFile> f;
393 f.reset(TFile::Open(fileName.c_str(), "READ"));
394 runRange = dynamic_cast<RunRange*>(f->Get(runRangeObjName.c_str()));
395 if (!runRange) {
396 B2FATAL("The input file " << fileName << " does not contain a RunRange object at "
397 << runRangeObjName << ". Please set your input files to exclude it.");
398 return "";
399 }
400 string granularity = runRange->getGranularity();
401 dir->cd();
402 return granularity;
403}
const std::string & getGranularity() const
Gets the m_granularity.
Definition RunRange.h:110

◆ getInputFileNames()

PyObject * getInputFileNames ( )
inherited

Get the input file names used for this algorithm and pass them out as a Python list of unicode strings.

Definition at line 245 of file CalibrationAlgorithm.cc.

246{
247 PyObject* objInputFileNames = PyList_New(m_inputFileNames.size());
248 for (size_t i = 0; i < m_inputFileNames.size(); ++i) {
249 PyList_SetItem(objInputFileNames, i, Py_BuildValue("s", m_inputFileNames[i].c_str()));
250 }
251 return objInputFileNames;
252}

◆ getInputJsonObject()

const nlohmann::json & getInputJsonObject ( ) const
inlineprotectedinherited

Get the entire top level JSON object. We explicitly say this must be of object type so that we might pick.

Definition at line 357 of file CalibrationAlgorithm.h.

357{return m_jsonExecutionInput;}

◆ getInputJsonValue()

template<class T>
const T getInputJsonValue ( const std::string & key) const
inlineprotectedinherited

Get an input JSON value using a key. The normal exceptions are raised when the key doesn't exist.

Definition at line 350 of file CalibrationAlgorithm.h.

351 {
352 return m_jsonExecutionInput.at(key);
353 }

◆ getIovFromAllData()

IntervalOfValidity getIovFromAllData ( ) const
inherited

Get the complete IoV from inspection of collected data.

Definition at line 326 of file CalibrationAlgorithm.cc.

327{
329}
RunRange getRunRangeFromAllData() const
Get the complete RunRange from inspection of collected data.
IntervalOfValidity getIntervalOfValidity()
Make IntervalOfValidity from the set, spanning all runs. Works because sets are sorted by default.
Definition RunRange.h:70

◆ getIteration()

int getIteration ( ) const
inlineprotectedinherited

Get current iteration.

Definition at line 269 of file CalibrationAlgorithm.h.

269{ return m_data.getIteration(); }

◆ getObjectPtr()

template<class T>
std::shared_ptr< T > getObjectPtr ( std::string name)
inlineprotectedinherited

Get calibration data object (for all runs the calibration is requested for) This function will only work during or after execute() has been called once.

Definition at line 285 of file CalibrationAlgorithm.h.

286 {
287 if (m_runsToInputFiles.size() == 0)
288 fillRunToInputFilesMap();
289 return getObjectPtr<T>(name, m_data.getRequestedRuns());
290 }

◆ getOutputJsonValue()

template<class T>
const T getOutputJsonValue ( const std::string & key) const
inlineprotectedinherited

Get a value using a key from the JSON output object, not sure why you would want to do this.

Definition at line 342 of file CalibrationAlgorithm.h.

343 {
344 return m_jsonExecutionOutput.at(key);
345 }

◆ getPayloads()

std::list< Database::DBImportQuery > & getPayloads ( )
inlineinherited

Get constants (in TObjects) for database update from last execution.

Definition at line 204 of file CalibrationAlgorithm.h.

204{return m_data.getPayloads();}

◆ getPayloadValues()

std::list< Database::DBImportQuery > getPayloadValues ( ) const
inlineinherited

Get constants (in TObjects) for database update from last execution but passed by VALUE.

Definition at line 207 of file CalibrationAlgorithm.h.

207{return m_data.getPayloadValues();}

◆ getPrefix()

const std::string & getPrefix ( ) const
inlineinherited

Get the prefix used for getting calibration data.

Definition at line 146 of file CalibrationAlgorithm.h.

146{return m_prefix;}

◆ getRunList()

const std::vector< Calibration::ExpRun > & getRunList ( ) const
inlineprotectedinherited

Get the list of runs for which calibration is called.

Definition at line 266 of file CalibrationAlgorithm.h.

266{return m_data.getRequestedRuns();}

◆ getRunListFromAllData()

vector< ExpRun > getRunListFromAllData ( ) const
inherited

Get the complete list of runs from inspection of collected data.

Definition at line 319 of file CalibrationAlgorithm.cc.

320{
321 RunRange runRange = getRunRangeFromAllData();
322 set<ExpRun> expRunSet = runRange.getExpRunSet();
323 return vector<ExpRun>(expRunSet.begin(), expRunSet.end());
324}

◆ getRunRangeFromAllData()

RunRange getRunRangeFromAllData ( ) const
inherited

Get the complete RunRange from inspection of collected data.

Definition at line 362 of file CalibrationAlgorithm.cc.

363{
364 // Save TDirectory to change back at the end
365 TDirectory* dir = gDirectory;
366 RunRange runRange;
367 // Construct the TDirectory name where we expect our objects to be
368 string runRangeObjName(getPrefix() + "/" + RUN_RANGE_OBJ_NAME);
369 for (const auto& fileName : m_inputFileNames) {
370 //Open TFile to get the objects
371 unique_ptr<TFile> f;
372 f.reset(TFile::Open(fileName.c_str(), "READ"));
373 const RunRange* runRangeOther = dynamic_cast<RunRange*>(f->Get(runRangeObjName.c_str()));
374 if (runRangeOther) {
375 runRange.merge(runRangeOther);
376 } else {
377 B2WARNING("Missing a RunRange object for file: " << fileName);
378 }
379 }
380 dir->cd();
381 return runRange;
382}
virtual void merge(const RunRange *other)
Implementation of merging - other is added to the set (union)
Definition RunRange.h:52

◆ getVecInputFileNames()

const std::vector< std::string > & getVecInputFileNames ( ) const
inlineprotectedinherited

Get the input file names used for this algorithm as a STL vector.

Definition at line 275 of file CalibrationAlgorithm.h.

275{return m_inputFileNames;}

◆ includeHadBcalib()

void includeHadBcalib ( bool state = true)
inline

Include calibration based on Hadronic B decays.

Definition at line 40 of file InvariantMassAlgorithm.h.

40{m_runHadB = state;}

◆ inputJsonKeyExists()

bool inputJsonKeyExists ( const std::string & key) const
inlineprotectedinherited

Test for a key in the input JSON object.

Definition at line 360 of file CalibrationAlgorithm.h.

360{return m_jsonExecutionInput.count(key);}

◆ isBoundaryRequired()

virtual bool isBoundaryRequired ( const Calibration::ExpRun & )
inlineprotectedvirtualinherited

Given the current collector data, make a decision about whether or not this run should be the start of a payload boundary.

Reimplemented in PXDAnalyticGainCalibrationAlgorithm, PXDValidationAlgorithm, SVD3SampleCoGTimeCalibrationAlgorithm, SVD3SampleELSTimeCalibrationAlgorithm, SVDClusterAbsoluteTimeShifterAlgorithm, SVDCoGTimeCalibrationAlgorithm, TestBoundarySettingAlgorithm, and TestCalibrationAlgorithm.

Definition at line 243 of file CalibrationAlgorithm.h.

244 {
245 B2ERROR("You didn't implement a isBoundaryRequired() member function in your CalibrationAlgorithm but you are calling it!");
246 return false;
247 }

◆ loadInputJson()

bool loadInputJson ( const std::string & jsonString)
inherited

Load the m_inputJson variable from a string (useful from Python interface). The return bool indicates success or failure.

Definition at line 503 of file CalibrationAlgorithm.cc.

504{
505 try {
506 auto jsonInput = nlohmann::json::parse(jsonString);
507 // Input string has an object (dict) as the top level object?
508 if (jsonInput.is_object()) {
509 m_jsonExecutionInput = jsonInput;
510 return true;
511 } else {
512 B2ERROR("JSON input string isn't an object type i.e. not a '{}' at the top level.");
513 return false;
514 }
515 } catch (nlohmann::json::parse_error&) {
516 B2ERROR("Parsing of JSON input string failed");
517 return false;
518 }
519}
nlohmann::json m_jsonExecutionInput
Optional input JSON object used to make decisions about how to execute the algorithm code.

◆ resetInputJson()

void resetInputJson ( )
inlineprotectedinherited

Clears the m_inputJson member variable.

Definition at line 330 of file CalibrationAlgorithm.h.

330{m_jsonExecutionInput.clear();}

◆ resetOutputJson()

void resetOutputJson ( )
inlineprotectedinherited

Clears the m_outputJson member variable.

Definition at line 333 of file CalibrationAlgorithm.h.

333{m_jsonExecutionOutput.clear();}

◆ saveCalibration() [1/6]

void saveCalibration ( TClonesArray * data,
const std::string & name )
protectedinherited

Store DBArray payload with given name with default IOV.

Definition at line 297 of file CalibrationAlgorithm.cc.

298{
299 saveCalibration(data, name, m_data.getRequestedIov());
300}
void saveCalibration(TClonesArray *data, const std::string &name)
Store DBArray payload with given name with default IOV.

◆ saveCalibration() [2/6]

void saveCalibration ( TClonesArray * data,
const std::string & name,
const IntervalOfValidity & iov )
protectedinherited

Store DBArray with given name and custom IOV.

Definition at line 276 of file CalibrationAlgorithm.cc.

277{
278 B2DEBUG(29, "Saving calibration TClonesArray '" << name << "' to payloads list.");
279 getPayloads().emplace_back(name, data, iov);
280}

◆ saveCalibration() [3/6]

void saveCalibration ( TObject * data)
protectedinherited

Store DB payload with default name and default IOV.

Definition at line 287 of file CalibrationAlgorithm.cc.

288{
289 saveCalibration(data, DataStore::objectName(data->IsA(), ""));
290}
static std::string objectName(const TClass *t, const std::string &name)
Return the storage name for an object of the given TClass and name.
Definition DataStore.cc:150

◆ saveCalibration() [4/6]

void saveCalibration ( TObject * data,
const IntervalOfValidity & iov )
protectedinherited

Store DB payload with default name and custom IOV.

Definition at line 282 of file CalibrationAlgorithm.cc.

283{
284 saveCalibration(data, DataStore::objectName(data->IsA(), ""), iov);
285}

◆ saveCalibration() [5/6]

void saveCalibration ( TObject * data,
const std::string & name )
protectedinherited

Store DB payload with given name with default IOV.

Definition at line 292 of file CalibrationAlgorithm.cc.

293{
294 saveCalibration(data, name, m_data.getRequestedIov());
295}

◆ saveCalibration() [6/6]

void saveCalibration ( TObject * data,
const std::string & name,
const IntervalOfValidity & iov )
protectedinherited

Store DB payload with given name and custom IOV.

Definition at line 270 of file CalibrationAlgorithm.cc.

271{
272 B2DEBUG(29, "Saving calibration TObject = '" << name << "' to payloads list.");
273 getPayloads().emplace_back(name, data, iov);
274}

◆ setDescription()

void setDescription ( const std::string & description)
inlineprotectedinherited

Set algorithm description (in constructor)

Definition at line 321 of file CalibrationAlgorithm.h.

321{m_description = description;}

◆ setInnerLoss()

void setInnerLoss ( const std::string & loss)
inline

Set inner loss function (for calibration subintervals)

Definition at line 37 of file InvariantMassAlgorithm.h.

37{ m_lossFunctionInner = loss; }

◆ setInputFileNames() [1/2]

void setInputFileNames ( const std::vector< std::string > & inputFileNames)
protectedinherited

Set the input file names used for this algorithm.

Set the input file names used for this algorithm and resolve the wildcards.

Definition at line 194 of file CalibrationAlgorithm.cc.

195{
196 // A lot of code below is tweaked from RootInputModule::initialize,
197 // since we're basically copying the functionality anyway.
198 if (inputFileNames.empty()) {
199 B2WARNING("You have called setInputFileNames() with an empty list. Did you mean to do that?");
200 return;
201 }
202 auto tmpInputFileNames = RootIOUtilities::expandWordExpansions(inputFileNames);
203
204 // We'll use a set to enforce sorted unique file paths as we check them
205 set<string> setInputFileNames;
206 // Check that files exist and convert to absolute paths
207 for (auto path : tmpInputFileNames) {
208 string fullPath = fs::absolute(path).string();
209 if (fs::exists(fullPath)) {
210 setInputFileNames.insert(fs::canonical(fullPath).string());
211 } else {
212 B2WARNING("Couldn't find the file " << path);
213 }
214 }
215
216 if (setInputFileNames.empty()) {
217 B2WARNING("No valid files specified!");
218 return;
219 } else {
220 // Reset the run -> files map as our files are likely different
221 m_runsToInputFiles.clear();
222 }
223
224 // Open TFile to check they can be accessed by ROOT
225 TDirectory* dir = gDirectory;
226 for (const string& fileName : setInputFileNames) {
227 unique_ptr<TFile> f;
228 try {
229 f.reset(TFile::Open(fileName.c_str(), "READ"));
230 } catch (logic_error&) {
231 //this might happen for ~invaliduser/foo.root
232 //actually undefined behaviour per standard, reported as ROOT-8490 in JIRA
233 }
234 if (!f || !f->IsOpen()) {
235 B2FATAL("Couldn't open input file " + fileName);
236 }
237 }
238 dir->cd();
239
240 // Copy the entries of the set to a vector
241 m_inputFileNames = vector<string>(setInputFileNames.begin(), setInputFileNames.end());
243}
std::string m_granularityOfData
Granularity of input data. This only changes when the input files change so it isn't specific to an e...
std::string getGranularityFromData() const
Get the granularity of collected data.
std::vector< std::string > expandWordExpansions(const std::vector< std::string > &filenames)
Performs wildcard expansion using wordexp(), returns matches.

◆ setInputFileNames() [2/2]

void setInputFileNames ( PyObject * inputFileNames)
inherited

Set the input file names used for this algorithm from a Python list.

Set the input file names used for this algorithm and resolve the wildcards.

Definition at line 166 of file CalibrationAlgorithm.cc.

167{
168 // The reasoning for this very 'manual' approach to extending the Python interface
169 // (instead of using boost::python) is down to my fear of putting off final users with
170 // complexity on their side.
171 //
172 // I didn't want users that inherit from this class to be forced to use boost and
173 // to have to define a new python module just to use the CAF. A derived class from
174 // from a boost exposed class would need to have its own boost python module definition
175 // to allow access from a steering file and to the base class functions (I think).
176 // I also couldn't be bothered to write a full framework to get around the issue in a similar
177 // way to Module()...maybe there's an easy way.
178 //
179 // But this way we can allow people to continue using their ROOT implemented classes and inherit
180 // easily from this one. But add in a few helper functions that work with Python objects
181 // created in their steering file i.e. instead of being forced to use STL objects as input
182 // to the algorithm.
183 if (PyList_Check(inputFileNames)) {
184 boost::python::handle<> handle(boost::python::borrowed(inputFileNames));
185 boost::python::list listInputFileNames(handle);
186 auto vecInputFileNames = PyObjConvUtils::convertPythonObject(listInputFileNames, vector<string>());
187 setInputFileNames(vecInputFileNames);
188 } else {
189 B2ERROR("Tried to set the input files but we didn't receive a Python list.");
190 }
191}
Scalar convertPythonObject(const boost::python::object &pyObject, Scalar)
Convert from Python to given type.

◆ setMuMuEcmsOffset()

void setMuMuEcmsOffset ( double shift)
inline

set the energy offset

Definition at line 46 of file InvariantMassAlgorithm.h.

46{m_eCMSmumuShift = shift;}

◆ setMuMuEcmsSpread()

void setMuMuEcmsSpread ( double spread)
inline

set the spread

Definition at line 43 of file InvariantMassAlgorithm.h.

43{m_eCMSmumuSpread = spread;}

◆ setOuterLoss()

void setOuterLoss ( const std::string & loss)
inline

Set outer loss function (for calibration intervals)

Definition at line 34 of file InvariantMassAlgorithm.h.

34{ m_lossFunctionOuter = loss; }

◆ setOutputJsonValue()

template<class T>
void setOutputJsonValue ( const std::string & key,
const T & value )
inlineprotectedinherited

Set a key:value pair for the outputJson object, expected to used internally during calibrate()

Definition at line 337 of file CalibrationAlgorithm.h.

337{m_jsonExecutionOutput[key] = value;}

◆ setPrefix()

void setPrefix ( const std::string & prefix)
inlineinherited

Set the prefix used to identify datastore objects.

Definition at line 167 of file CalibrationAlgorithm.h.

167{m_prefix = prefix;}

◆ updateDBObjPtrs()

void updateDBObjPtrs ( const unsigned int event,
const int run,
const int experiment )
staticprotectedinherited

Updates any DBObjPtrs by calling update(event) for DBStore.

Definition at line 405 of file CalibrationAlgorithm.cc.

406{
407 // Construct an EventMetaData object but NOT in the Datastore
408 EventMetaData emd(event, run, experiment);
409 // Explicitly update while avoiding registering a Datastore object
411 // Also update the intra-run objects to the event at the same time (maybe unnecessary...)
413}
static DBStore & Instance()
Instance of a singleton DBStore.
Definition DBStore.cc:26
void updateEvent()
Updates all intra-run dependent objects.
Definition DBStore.cc:140
void update()
Updates all objects that are outside their interval of validity.
Definition DBStore.cc:77

Member Data Documentation

◆ m_allExpRun

const ExpRun m_allExpRun = make_pair(-1, -1)
staticprivateinherited

allExpRun

Definition at line 364 of file CalibrationAlgorithm.h.

◆ m_boundaries

std::vector<Calibration::ExpRun> m_boundaries
protectedinherited

When using the boundaries functionality from isBoundaryRequired, this is used to store the boundaries. It is cleared when.

Definition at line 261 of file CalibrationAlgorithm.h.

◆ m_data

ExecutionData m_data
privateinherited

Data specific to a SINGLE execution of the algorithm. Gets reset at the beginning of execution.

Definition at line 382 of file CalibrationAlgorithm.h.

◆ m_description

std::string m_description {""}
privateinherited

Description of the algorithm.

Definition at line 385 of file CalibrationAlgorithm.h.

385{""};

◆ m_eCMSmumuShift

double m_eCMSmumuShift = 10e-3
private

Shift between the energy from the mumu events and the real value.

Definition at line 79 of file InvariantMassAlgorithm.h.

◆ m_eCMSmumuSpread

double m_eCMSmumuSpread = 5.2e-3
private

Energy spread for mumu only run (m_runHadB == false)

Definition at line 76 of file InvariantMassAlgorithm.h.

◆ m_granularityOfData

std::string m_granularityOfData
privateinherited

Granularity of input data. This only changes when the input files change so it isn't specific to an execution.

Definition at line 379 of file CalibrationAlgorithm.h.

◆ m_inputFileNames

std::vector<std::string> m_inputFileNames
privateinherited

List of input files to the Algorithm, will initially be user defined but then gets the wildcards expanded during execute()

Definition at line 373 of file CalibrationAlgorithm.h.

◆ m_jsonExecutionInput

nlohmann::json m_jsonExecutionInput = nlohmann::json::object()
privateinherited

Optional input JSON object used to make decisions about how to execute the algorithm code.

Definition at line 397 of file CalibrationAlgorithm.h.

◆ m_jsonExecutionOutput

nlohmann::json m_jsonExecutionOutput = nlohmann::json::object()
privateinherited

Optional output JSON object that can be set during the execution by the underlying algorithm code.

Definition at line 403 of file CalibrationAlgorithm.h.

◆ m_lossFunctionInner

TString m_lossFunctionInner = "pow(0.000120e0*rawTime, 2) + 1./nEv"
private

Inner loss function (for calibration subintervals with constant InvariantMass)

Definition at line 70 of file InvariantMassAlgorithm.h.

◆ m_lossFunctionOuter

TString m_lossFunctionOuter = "pow(0.000010e0*rawTime, 2) + 1./nEv"
private

Outer loss function (for calibration intervals with constant InvarinatMass spread)

Definition at line 67 of file InvariantMassAlgorithm.h.

◆ m_prefix

std::string m_prefix {""}
privateinherited

The name of the TDirectory the collector objects are contained within.

Definition at line 388 of file CalibrationAlgorithm.h.

388{""};

◆ m_runHadB

bool m_runHadB = true
private

Run the calibration from had-B decays.

Definition at line 73 of file InvariantMassAlgorithm.h.

◆ m_runsToInputFiles

std::map<Calibration::ExpRun, std::vector<std::string> > m_runsToInputFiles
privateinherited

Map of Runs to input files. Gets filled when you call getRunRangeFromAllData, gets cleared when setting input files again.

Definition at line 376 of file CalibrationAlgorithm.h.


The documentation for this class was generated from the following files: