Jpp/v19.1.0/JBuildL2_8hh_source.html

 #ifndef __JTRIGGER__JBUILDL2__

 #define __JTRIGGER__JBUILDL2__


 #include <vector>

 #include <iterator>


 #include "JTrigger/JHitToolkit.hh"

 #include "JTrigger/JSuperFrame1D.hh"

 #include "JTrigger/JSuperFrame2D.hh"

 #include "JTrigger/JSuperFrameClone2D.hh"

 #include "JTrigger/JHit.hh"

 #include "JTrigger/JHitL0.hh"

 #include "JTrigger/JHitL2.hh"

 #include "JTrigger/JHitR2.hh"

 #include "JTrigger/JBuildHelper.hh"

 #include "JTrigger/JBuildL1.hh"

 #include "JTrigger/JTriggerParameters.hh"

 #include "km3net-dataformat/online/JDAQSuperFrame.hh"

 #include "JDetector/JModule.hh"

 #include "JMath/JMathToolkit.hh"


 /**

  * \author mdejong

  */


 namespace JTRIGGER {}

 namespace JPP { using namespace JTRIGGER; }


 namespace JTRIGGER {


   using KM3NETDAQ::JDAQSuperFrame;

   using JDETECTOR::JModule;


   /**

    * Template L2 builder.

    *

    * An L2 hit is a local coincidence between two or more hits from different PMTs

    * within the same optical module satisfying:

    *   - minimal number of hits requirement;

    *   - maximal time difference between hits; and

    *   - maximal space angle requirement between the PMT axes.

    */

   template<class JHit_t>

   class JBuildL2 :

     public JL2Parameters,

     public JBuildL1<JHit_t>,

     public JBuildHelper< JBuildL2<JHit_t> >

   {

   public:


     using JBuildHelper< JBuildL2<JHit_t> >::operator();


     typedef JHit_t   value_type;


     /**

      * Constructor.

      *

      * \param  parameters        L2 parameters

      */

     JBuildL2(const JL2Parameters& parameters) :

       JL2Parameters   (parameters),

       JBuildL1<JHit_t>(parameters)

     {}


     /**

      * Build hits from calibrated data.

      *

      * Only the input hits that satisfy the predefined requirements are copied from input to output.\n

      * The requirements are checked using the calibrated data of each PMT inside the same module.

      * The input data should be time sorted.

      * The output data are time sorted.

      *

      * \param  inputL0           input  L0 data

      * \param  inputL1           input  L1 data

      * \param  out               output L2 data

      */

     template<class JOutput_t>

     void operator()(const JSuperFrame2D<JHit_t>& inputL0,

                     const std::vector  <JHit_t>& inputL1,

                     JOutput_t                    out) const

     {

       const JSuperFrameClone2D<JHit_t> clone(inputL0);


       for (typename std::vector<JHit_t>::const_iterator p = inputL1.begin(); p != inputL1.end(); ++p) {


         clone.fast_forward(*p);


         if (isL2(clone,*p)) {

           *out = *p;

           ++out;

         }

       }

     }


     /**

      * Build hits from calibrated data.

      *

      * Only the input hits that satisfy the predefined requirements are copied from input to output.\n

      * The requirements are checked using the calibrated data of each PMT inside the same module.

      * The input data should be time sorted.

      * The output data are time sorted.

      *

      * \param  __begin           begin  L0 data

      * \param  __end             end    L0 data

      * \param  inputL1           input  L1 data

      * \param  out               output L2 data

      */

     template<class T, class JOutput_t>

     void operator()(T __begin,

                     T __end,

                     const std::vector  <JHit_t>& inputL1,

                     JOutput_t                    out) const

     {

       const JSuperFrameClone2D<JHit_t> clone(__begin, __end);


       for (typename std::vector<JHit_t>::const_iterator p = inputL1.begin(); p != inputL1.end(); ++p) {


         clone.fast_forward(*p);


         if (isL2(clone,*p)) {

           *out = *p;

           ++out;

         }

       }

     }


     /**

      * Build hits from calibrated data.

      *

      * The calibrated data of each PMT inside the optical module are used to build L2 coincidences.

      * The predefined requirements are then checked using the same calibrated data of each PMT.

      * The output data are time sorted.

      *

      * \param  inputL0           input  L0 data

      * \param  out               output L2 data

      */

     template<class JOutput_t>

     void operator()(const JSuperFrame2D<JHit_t>& inputL0, JOutput_t out) const

     {

       bufferL1.clear();


       static_cast<const JBuildL1<JHit_t>&>(*this)(inputL0, std::back_inserter(bufferL1));


       (*this)(inputL0, bufferL1, out);

     }


     /**

      * Build hits from DAQ data.

      *

      * The time calibration is applied and the requirements are applied to the calibrated data.

      * The output data are time sorted.

      *

      * \param  input             DAQ super frame

      * \param  module            module

      * \param  out               output L2 data

      */

     template<class JOutput_t>

     void operator()(const JDAQSuperFrame& input,

                     const JModule&        module,

                     JOutput_t             out) const

     {

       if (!input.empty()) {

         (*this)(this->demultiplex(input, module), out);

       }

     }


   protected:

     /**

      * Test if requirements for given hit are satisfied.\n

      * The internal iterators of the cloned L0 data should be set before this test operation.

      *

      * \param  clone             L0 data

      * \param  hit               L1 hit

      * \return                   true is L2 condition is satisfied; else false

      */

     bool isL2(const JSuperFrameClone2D<JHit_t>& clone, const JHit_t& hit) const

     {

       using namespace JPP;


       if (numberOfHits < 2) {

         return true;

       }


       for (typename JSuperFrameClone2D<JHit_t>::const_iterator i = clone.begin(); i != clone.end(); ++i) {


         if (this->getTimeDifference(hit,*(i->get())) <= TMaxLocal_ns) {


           int n = 1;


           for (typename JSuperFrameClone2D<JHit_t>::const_iterator j = clone.begin(); j != clone.end(); ++j) {


             if (i != j) {


               if (this->getTimeDifference(hit,*(j->get())) <= TMaxLocal_ns) {


                 if (getDot(i->getDirection(), j->getDirection()) >= ctMin) {


                   if (++n >= numberOfHits) {

                     return true;

                   }

                 }

               }

             }

           }

         }

       }


       return false;

     }


     mutable std::vector<JHit_t> bufferL1;

   };


   /**

    * Template specialisation of L2 builder for JHitL2 data type.

    */

   template<>

   class JBuildL2<JHitL2> :

     public JBuildL2<JHit>,

     public JBuildHelper< JBuildL2<JHitL2> >

   {

   public:


     using JBuildHelper< JBuildL2<JHitL2> >::operator();


     typedef JHitL2       value_type;


     /**

      * Constructor.

      *

      * \param  parameters        L2 parameters

      */

     JBuildL2(const JL2Parameters& parameters) :

       JBuildL2<JHit>(parameters)

     {}


     /**

      * Build hits from calibrated data.

      *

      * Only the input hits that satify the predefined requirements are copied from input to output.

      * The requirements are checked using the calibrated data of each PMT inside the same module.

      * The input data should be time sorted.

      * The output data are time sorted.

      *

      * \param  inputL0           input  L0 data

      * \param  inputL2           input  L2 data

      * \param  out               output L2 data

      */

     template<class JOutput_t>

     void operator()(const JSuperFrame2D<JHit>& inputL0,

                     const std::vector  <JHit>& inputL2,

                     JOutput_t                  out) const

     {

       const JSuperFrameClone2D<JHit> clone(inputL0);


       for (typename std::vector<JHit>::const_iterator p = inputL2.begin(); p != inputL2.end(); ++p) {


         JHitL2 hit(inputL0.getModuleID());


         for (typename JSuperFrameClone2D<JHit>::const_iterator i = clone.begin(); i != clone.end(); ++i) {


           for (typename JSuperFrameClone2D<JHit>::value_type::const_iterator q = i->fast_forward(*p); this->getTimeDifference(*p,*q) <= TMaxLocal_ns; ++q) {


             hit.push_back(JHitL0(i->getPMTIdentifier(),

                                  i->getAxis(),

                                  *q));

           }

         }


         *out = hit.sort();

         ++out;

       }

     }


     /**

      * Build hits from calibrated data.

      *

      * The calibrated data of each PMT inside the optical module are used to build L2 coincidences.

      * The predefined requirements are then checked using the same calibrated data of each PMT.

      * The output data are time sorted.

      *

      * \param  inputL0           input  L0 data

      * \param  out               output L2 data

      */

     template<class JOutput_t>

     void operator()(const JSuperFrame2D<JHit>& inputL0, JOutput_t out) const

     {

       bufferL2.clear();


       static_cast<const JBuildL2<JHit>&>(*this)(inputL0, std::back_inserter(bufferL2));


       (*this)(inputL0, bufferL2, out);

     }


     /**

      * Build hits from DAQ data.

      *

      * The time calibration is applied and the requirements are applied to the calibrated data.

      * The output data are time sorted.

      *

      * \param  input             DAQ super frame

      * \param  module            module

      * \param  out               output L2 data

      */

     template<class JOutput_t>

     void operator()(const JDAQSuperFrame& input,

                     const JModule&        module,

                     JOutput_t             out) const

     {

       if (!input.empty()) {


         const JSuperFrame2D<JHit>& bufferL0 = this->demultiplex(input, module);


         (*this)(bufferL0, out);

       }

     }


   protected:

     mutable std::vector<JHit> bufferL2;

   };


   /**

    * Template specialisation of L2 builder for JHitR2 data type.

    */

   template<>

   class JBuildL2<JHitR2> :

     public JBuildL2<JHit>,

     public JBuildHelper< JBuildL2<JHitR2> >

   {

   public:


     using JBuildHelper< JBuildL2<JHitR2> >::operator();


     typedef JHitR2       value_type;


     /**

      * Constructor.

      *

      * \param  parameters        L2 parameters

      */

     JBuildL2(const JL2Parameters& parameters) :

       JBuildL2<JHit>(parameters)

     {}


     /**

      * Build hits from calibrated data.

      *

      * Only the input hits that satify the predefined requirements are copied from input to output.

      * The requirements are checked using the calibrated data of each PMT inside the same module.

      * The input data should be time sorted.

      * The output data are time sorted.

      *

      * \param  inputL0           input  L0 data

      * \param  inputL2           input  L2 data

      * \param  out               output L2 data

      */

     template<class JOutput_t>

     void operator()(const JSuperFrame2D<JHit>& inputL0,

                     const std::vector  <JHit>& inputL2,

                     JOutput_t                  out) const

     {

       const JSuperFrameClone2D<JHit> clone(inputL0);


       for (typename std::vector<JHit>::const_iterator p = inputL2.begin(); p != inputL2.end(); ++p) {


         JHitR2 hit(inputL0.getModuleID(),

                    inputL0.getPosition());


         clone.fast_forward(*p);


         for (typename JSuperFrameClone2D<JHit>::const_iterator i = clone.begin(); i != clone.end(); ++i) {


           if (i->getTimeDifference(*p) <= TMaxLocal_ns) {


             if (hit.getN() == 0)

               hit.set(i->getJHit());

             else

               hit.add(i->getJHit());


             if (i->getT() < hit.getT()) {

               hit.setPosition(i->getPosition());

             }

           }

         }


         *out = hit;

         ++out;

       }

     }


     /**

      * Build hits from calibrated data.

      *

      * The calibrated data of each PMT inside the optical module are used to build L2 coincidences.

      * The predefined requirements are then checked using the same calibrated data of each PMT.

      * The output data are time sorted.

      *

      * \param  inputL0           input  L0 data

      * \param  out               output L2 data

      */

     template<class JOutput_t>

     void operator()(const JSuperFrame2D<JHit>& inputL0, JOutput_t out) const

     {

       bufferL2.clear();


       static_cast<const JBuildL2<JHit>&>(*this)(inputL0, std::back_inserter(bufferL2));


       (*this)(inputL0, bufferL2, out);

     }


     /**

      * Build hits from DAQ data.

      *

      * The time calibration is applied and the requirements are applied to the calibrated data.

      * The output data are time sorted.

      *

      * \param  input             DAQ super frame

      * \param  module            module

      * \param  out               output L2 data

      */

     template<class JOutput_t>

     void operator()(const JDAQSuperFrame& input,

                     const JModule&        module,

                     JOutput_t             out) const

     {

       if (!input.empty()) {


         const JSuperFrame2D<JHit>& bufferL0 = this->demultiplex(input, module);


         (*this)(bufferL0, out);

       }

     }


   private:

     mutable std::vector<JHit> bufferL2;

   };

 }


 #endif

JBuildHelper.hh

JBuildL1.hh

JDAQSuperFrame.hh

JHitL0.hh
Basic data structure for L0 hit.

JHitL2.hh
Basic data structure for L2 hit.

JHitR2.hh
Basic data structure for R2 hit.

JHitToolkit.hh
Tools for handling different hit types.

JMathToolkit.hh
Auxiliary methods for geometrical methods.

JModule.hh
Data structure for optical module.

JSuperFrame1D.hh

JSuperFrame2D.hh

JSuperFrameClone2D.hh

JHit.hh
Basic data structure for time and time over threshold information of hit.

JTriggerParameters.hh

JDETECTOR::JModule
Data structure for a composite optical module.
Definition: JModule.hh:75

JGEOMETRY3D::JPosition3D::setPosition
void setPosition(const JVector3D &pos)
Set position.
Definition: JPosition3D.hh:152

JGEOMETRY3D::JPosition3D::getPosition
const JPosition3D & getPosition() const
Get position.
Definition: JPosition3D.hh:130

JTRIGGER::JBuildL1
Template L1 hit builder.
Definition: JBuildL1.hh:90

JTRIGGER::JBuildL2< JHitL2 >::bufferL2
std::vector< JHit > bufferL2
Definition: JBuildL2.hh:331

JTRIGGER::JBuildL2< JHitL2 >::operator()
void operator()(const JSuperFrame2D< JHit > &inputL0, JOutput_t out) const
Build hits from calibrated data.
Definition: JBuildL2.hh:297

JTRIGGER::JBuildL2< JHitL2 >::operator()
void operator()(const JDAQSuperFrame &input, const JModule &module, JOutput_t out) const
Build hits from DAQ data.
Definition: JBuildL2.hh:318

JTRIGGER::JBuildL2< JHitL2 >::JBuildL2
JBuildL2(const JL2Parameters &parameters)
Constructor.
Definition: JBuildL2.hh:242

JTRIGGER::JBuildL2< JHitL2 >::operator()
void operator()(const JSuperFrame2D< JHit > &inputL0, const std::vector< JHit > &inputL2, JOutput_t out) const
Build hits from calibrated data.
Definition: JBuildL2.hh:260

JTRIGGER::JBuildL2< JHitL2 >::value_type
JHitL2 value_type
Definition: JBuildL2.hh:234

JTRIGGER::JBuildL2< JHitR2 >::operator()
void operator()(const JSuperFrame2D< JHit > &inputL0, JOutput_t out) const
Build hits from calibrated data.
Definition: JBuildL2.hh:418

JTRIGGER::JBuildL2< JHitR2 >::value_type
JHitR2 value_type
Definition: JBuildL2.hh:347

JTRIGGER::JBuildL2< JHitR2 >::operator()
void operator()(const JDAQSuperFrame &input, const JModule &module, JOutput_t out) const
Build hits from DAQ data.
Definition: JBuildL2.hh:439

JTRIGGER::JBuildL2< JHitR2 >::operator()
void operator()(const JSuperFrame2D< JHit > &inputL0, const std::vector< JHit > &inputL2, JOutput_t out) const
Build hits from calibrated data.
Definition: JBuildL2.hh:373

JTRIGGER::JBuildL2< JHitR2 >::JBuildL2
JBuildL2(const JL2Parameters &parameters)
Constructor.
Definition: JBuildL2.hh:355

JTRIGGER::JBuildL2< JHitR2 >::bufferL2
std::vector< JHit > bufferL2
Definition: JBuildL2.hh:452

JTRIGGER::JBuildL2
Template L2 builder.
Definition: JBuildL2.hh:49

JTRIGGER::JBuildL2::operator()
void operator()(const JSuperFrame2D< JHit_t > &inputL0, const std::vector< JHit_t > &inputL1, JOutput_t out) const
Build hits from calibrated data.
Definition: JBuildL2.hh:81

JTRIGGER::JBuildL2::value_type
JHit_t value_type
Definition: JBuildL2.hh:54

JTRIGGER::JBuildL2::JBuildL2
JBuildL2(const JL2Parameters &parameters)
Constructor.
Definition: JBuildL2.hh:62

JTRIGGER::JBuildL2::operator()
void operator()(T __begin, T __end, const std::vector< JHit_t > &inputL1, JOutput_t out) const
Build hits from calibrated data.
Definition: JBuildL2.hh:113

JTRIGGER::JBuildL2::bufferL1
std::vector< JHit_t > bufferL1
Definition: JBuildL2.hh:218

JTRIGGER::JBuildL2::operator()
void operator()(const JDAQSuperFrame &input, const JModule &module, JOutput_t out) const
Build hits from DAQ data.
Definition: JBuildL2.hh:164

JTRIGGER::JBuildL2::isL2
bool isL2(const JSuperFrameClone2D< JHit_t > &clone, const JHit_t &hit) const
Test if requirements for given hit are satisfied.
Definition: JBuildL2.hh:182

JTRIGGER::JBuildL2::operator()
void operator()(const JSuperFrame2D< JHit_t > &inputL0, JOutput_t out) const
Build hits from calibrated data.
Definition: JBuildL2.hh:143

JTRIGGER::JClone< JFrame< JElement_t, std::allocator< JElement_t > > >::const_iterator
JContainer_t::const_iterator const_iterator
Definition: JClone.hh:45

JTRIGGER::JHitL0
Data structure for L0 hit.
Definition: JHitL0.hh:31

JTRIGGER::JHitL1
Data structure for L1 hit.
Definition: JHitL1.hh:37

JTRIGGER::JHitL1::sort
const JHitL1 & sort()
Sort L0 hits.
Definition: JHitL1.hh:97

JTRIGGER::JHitR1
Reduced data structure for L1 hit.
Definition: JHitR1.hh:35

JTRIGGER::JHitR1::set
void set(const JHit &hit, const double weight=1.0)
Set hit.
Definition: JHitR1.hh:125

JTRIGGER::JHitR1::getN
int getN() const
Get count.
Definition: JHitR1.hh:183

JTRIGGER::JHitR1::add
JHitR1 & add(const JHit &hit, const double weight=1.0)
Add hit.
Definition: JHitR1.hh:148

JTRIGGER::JHit
Hit data structure.
Definition: JTrigger/JHit.hh:23

JTRIGGER::JHit::getT
double getT() const
Get calibrated time of hit.
Definition: JTrigger/JHit.hh:143

JTRIGGER::JSuperFrame2D
2-dimensional frame with time calibrated data from one optical module.
Definition: JSuperFrame2D.hh:46

JTRIGGER::JSuperFrameClone2D
Clone of JSuperFrame2D.
Definition: JSuperFrameClone2D.hh:30

JTRIGGER::JSuperFrameClone2D::const_iterator
std::vector< value_type >::const_iterator const_iterator
Definition: JSuperFrameClone2D.hh:36

JTRIGGER::JSuperFrameClone2D::fast_forward
void fast_forward(argument_type hit) const
Increment the internal iterators until the lower bounds corresponding to the time of the given hit.
Definition: JSuperFrameClone2D.hh:119

KM3NETDAQ::JDAQFrame::empty
bool empty() const
Definition: JDAQFrame.hh:181

KM3NETDAQ::JDAQModuleIdentifier::getModuleID
int getModuleID() const
Get module identifier.
Definition: JDAQModuleIdentifier.hh:72

KM3NETDAQ::JDAQSuperFrame
Data frame of one optical module.
Definition: JDAQSuperFrame.hh:26

std::vector< JHit_t >

JASTRONOMY::getDot
double getDot(const JNeutrinoDirection &first, const JNeutrinoDirection &second)
Dot product.
Definition: JAstronomy.hh:676

JPP
This name space includes all other name spaces (except KM3NETDAQ, KM3NET and ANTARES).
Definition: JAAnetToolkit.hh:43

JTOOLS::n
const int n
Definition: JPolint.hh:786

JTOOLS::j
int j
Definition: JPolint.hh:792

JTRIGGER
Auxiliary classes and methods for triggering.
Definition: JSupport/JSupport.hh:36

KM3NETDAQ::getTimeDifference
double getTimeDifference(const JDAQChronometer &first, const JDAQChronometer &second)
Get time difference between two chronometers.
Definition: JDAQChronometer.hh:267

JSIRENE::JHit_t
Auxiliary class to set-up Hit.
Definition: JSirene.hh:58

JTRIGGER::JBuildHelper
Auxiliary class to extend hit building functionality to all DAQ data types.
Definition: JBuildHelper.hh:45

JTRIGGER::JBuild::demultiplex
JSuperFrame2D< JHit_t > & demultiplex(const JDAQSuperFrame &input, const JModule &module) const
Demultiplex and pre-process DAQ super frame.
Definition: JBuild.hh:103

JTRIGGER::JL2Parameters
Data structure for L2 parameters.
Definition: JTrigger/JTriggerParameters.hh:35

JTRIGGER::JL2Parameters::ctMin
double ctMin
minimal cosine space angle between PMT axes
Definition: JTrigger/JTriggerParameters.hh:109

JTRIGGER::JL2Parameters::TMaxLocal_ns
double TMaxLocal_ns
maximal time difference [ns]
Definition: JTrigger/JTriggerParameters.hh:108

JTRIGGER::JL2Parameters::numberOfHits
int numberOfHits
minimal number of hits
Definition: JTrigger/JTriggerParameters.hh:107