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// Copyright 2019-2020 CERN and copyright holders of ALICE O2.
// See https://alice-o2.web.cern.ch/copyright for details of the copyright holders.
// All rights not expressly granted are reserved.
//
// This software is distributed under the terms of the GNU General Public
// License v3 (GPL Version 3), copied verbatim in the file "COPYING".
//
// In applying this license CERN does not waive the privileges and immunities
// granted to it by virtue of its status as an Intergovernmental Organization
// or submit itself to any jurisdiction.
/// \file HfMlResponseBsToDsPi.h
/// \brief Class to compute the ML response for Bs → Ds∓ π± analysis selections
/// \author Fabio Catalano <fabio.catalano@cern.ch>, CERN
#ifndef PWGHF_CORE_HFMLRESPONSEBSTODSPI_H_
#define PWGHF_CORE_HFMLRESPONSEBSTODSPI_H_
#include "PWGHF/Core/HfMlResponse.h"
#include "PWGHF/D2H/Utils/utilsRedDataFormat.h"
#include "Tools/ML/MlResponse.h"
#include <cstdint>
#include <vector>
// Fill the map of available input features
// the key is the feature's name (std::string)
// the value is the corresponding value in EnumInputFeatures
#define FILL_MAP_BS(FEATURE) \
{ \
#FEATURE, static_cast<uint8_t>(InputFeaturesBsToDsPi::FEATURE) \
}
// Check if the index of mCachedIndices (index associated to a FEATURE)
// matches the entry in EnumInputFeatures associated to this FEATURE
// if so, the inputFeatures vector is filled with the FEATURE's value
// by calling the corresponding GETTER from OBJECT
#define CHECK_AND_FILL_VEC_BS_FULL(OBJECT, FEATURE, GETTER) \
case static_cast<uint8_t>(InputFeaturesBsToDsPi::FEATURE): { \
inputFeatures.emplace_back(OBJECT.GETTER()); \
break; \
}
// Check if the index of mCachedIndices (index associated to a FEATURE)
// matches the entry in EnumInputFeatures associated to this FEATURE
// if so, the inputFeatures vector is filled with the FEATURE's value
// by calling the GETTER function taking OBJECT in argument
#define CHECK_AND_FILL_VEC_BS_FUNC(OBJECT, FEATURE, GETTER) \
case static_cast<uint8_t>(InputFeaturesBsToDsPi::FEATURE): { \
inputFeatures.emplace_back(GETTER(OBJECT)); \
break; \
}
// Specific case of CHECK_AND_FILL_VEC_BS_FULL(OBJECT, FEATURE, GETTER)
// where OBJECT is named candidate and FEATURE = GETTER
#define CHECK_AND_FILL_VEC_BS(GETTER) \
case static_cast<uint8_t>(InputFeaturesBsToDsPi::GETTER): { \
inputFeatures.emplace_back(candidate.GETTER()); \
break; \
}
namespace o2::analysis
{
enum class InputFeaturesBsToDsPi : uint8_t {
ptProng0 = 0,
ptProng1,
impactParameter0,
impactParameter1,
impactParameterProduct,
chi2PCA,
decayLength,
decayLengthXY,
decayLengthNormalised,
decayLengthXYNormalised,
cpa,
cpaXY,
maxNormalisedDeltaIP,
prong0MlScoreBkg,
prong0MlScorePrompt,
prong0MlScoreNonprompt,
tpcNSigmaPi1,
tofNSigmaPi1,
tpcTofNSigmaPi1
};
template <typename TypeOutputScore = float>
class HfMlResponseBsToDsPi : public HfMlResponse<TypeOutputScore>
{
public:
/// Default constructor
HfMlResponseBsToDsPi() = default;
/// Default destructor
virtual ~HfMlResponseBsToDsPi() = default;
/// Method to get the input features vector needed for ML inference
/// \param candidate is the Bs candidate
/// \param prong1 is the candidate's prong1
/// \return inputFeatures vector
template <bool withDmesMl, typename T1, typename T2>
std::vector<float> getInputFeatures(T1 const& candidate,
T2 const& prong1)
{
std::vector<float> inputFeatures;
for (const auto& idx : MlResponse<TypeOutputScore>::mCachedIndices) {
if constexpr (withDmesMl) {
switch (idx) {
CHECK_AND_FILL_VEC_BS(ptProng0);
CHECK_AND_FILL_VEC_BS(ptProng1);
CHECK_AND_FILL_VEC_BS(impactParameter0);
CHECK_AND_FILL_VEC_BS(impactParameter1);
CHECK_AND_FILL_VEC_BS(impactParameterProduct);
CHECK_AND_FILL_VEC_BS(chi2PCA);
CHECK_AND_FILL_VEC_BS(decayLength);
CHECK_AND_FILL_VEC_BS(decayLengthXY);
CHECK_AND_FILL_VEC_BS(decayLengthNormalised);
CHECK_AND_FILL_VEC_BS(decayLengthXYNormalised);
CHECK_AND_FILL_VEC_BS(cpa);
CHECK_AND_FILL_VEC_BS(cpaXY);
CHECK_AND_FILL_VEC_BS(maxNormalisedDeltaIP);
CHECK_AND_FILL_VEC_BS(prong0MlScoreBkg);
CHECK_AND_FILL_VEC_BS(prong0MlScorePrompt);
CHECK_AND_FILL_VEC_BS(prong0MlScoreNonprompt);
// Pion PID variables
CHECK_AND_FILL_VEC_BS_FULL(prong1, tpcNSigmaPi1, tpcNSigmaPi);
CHECK_AND_FILL_VEC_BS_FULL(prong1, tofNSigmaPi1, tofNSigmaPi);
CHECK_AND_FILL_VEC_BS_FUNC(prong1, tpcTofNSigmaPi1, o2::pid_tpc_tof_utils::getTpcTofNSigmaPi1);
}
} else {
switch (idx) {
CHECK_AND_FILL_VEC_BS(ptProng0);
CHECK_AND_FILL_VEC_BS(ptProng1);
CHECK_AND_FILL_VEC_BS(impactParameter0);
CHECK_AND_FILL_VEC_BS(impactParameter1);
CHECK_AND_FILL_VEC_BS(impactParameterProduct);
CHECK_AND_FILL_VEC_BS(chi2PCA);
CHECK_AND_FILL_VEC_BS(decayLength);
CHECK_AND_FILL_VEC_BS(decayLengthXY);
CHECK_AND_FILL_VEC_BS(decayLengthNormalised);
CHECK_AND_FILL_VEC_BS(decayLengthXYNormalised);
CHECK_AND_FILL_VEC_BS(cpa);
CHECK_AND_FILL_VEC_BS(cpaXY);
CHECK_AND_FILL_VEC_BS(maxNormalisedDeltaIP);
// Pion PID variables
CHECK_AND_FILL_VEC_BS_FULL(prong1, tpcNSigmaPi1, tpcNSigmaPi);
CHECK_AND_FILL_VEC_BS_FULL(prong1, tofNSigmaPi1, tofNSigmaPi);
CHECK_AND_FILL_VEC_BS_FUNC(prong1, tpcTofNSigmaPi1, o2::pid_tpc_tof_utils::getTpcTofNSigmaPi1);
}
}
}
return inputFeatures;
}
protected:
/// Method to fill the map of available input features
void setAvailableInputFeatures()
{
MlResponse<TypeOutputScore>::mAvailableInputFeatures = {
FILL_MAP_BS(ptProng0),
FILL_MAP_BS(ptProng1),
FILL_MAP_BS(impactParameter0),
FILL_MAP_BS(impactParameter1),
FILL_MAP_BS(impactParameterProduct),
FILL_MAP_BS(chi2PCA),
FILL_MAP_BS(decayLength),
FILL_MAP_BS(decayLengthXY),
FILL_MAP_BS(decayLengthNormalised),
FILL_MAP_BS(decayLengthXYNormalised),
FILL_MAP_BS(cpa),
FILL_MAP_BS(cpaXY),
FILL_MAP_BS(maxNormalisedDeltaIP),
FILL_MAP_BS(prong0MlScoreBkg),
FILL_MAP_BS(prong0MlScorePrompt),
FILL_MAP_BS(prong0MlScoreNonprompt),
// Pion PID variables
FILL_MAP_BS(tpcNSigmaPi1),
FILL_MAP_BS(tofNSigmaPi1),
FILL_MAP_BS(tpcTofNSigmaPi1)};
}
};
} // namespace o2::analysis
#undef FILL_MAP_BS
#undef CHECK_AND_FILL_VEC_BS_FULL
#undef CHECK_AND_FILL_VEC_BS_FUNC
#undef CHECK_AND_FILL_VEC_BS
#endif // PWGHF_CORE_HFMLRESPONSEBSTODSPI_H_