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00001 //--------------------------------------------------------------------------
00002 //THIS IS A BRUTAL COPY OF HEPEVT_Wrapper from HEPMC
00003 //We need it because the EPOS generator needs a largeer version of HEPEVT to store the event
00004 #ifndef EPOS_EntriesAllocation
00005 #define EPOS_EntriesAllocation 99900
00006 #endif  // EPOS_EntriesAllocation
00007 
00008 //--------------------------------------------------------------------------
00009 #ifndef HEPMC_EPOS_COMMON_H
00010 #define HEPMC_EPOS_COMMON_H
00011 
00012 //
00013 //      PARAMETER (NMXHEP=2000) 
00014 //      COMMON/HEPCOM/NEVHEP,NHEP,ISTHEP(NMXHEP),IDHEP(NMXHEP), 
00015 //     &        JMOHEP(2,NMXHEP),JDAHEP(2,NMXHEP),PHEP(5,NMXHEP),VHEP(4,NMXHEP)
00016 /**********************************************************/
00017 /*           D E S C R I P T I O N :                      */
00018 /*--------------------------------------------------------*/
00019 /* NEVHEP          - event number (or some special meaning*/
00020 /*                    (see documentation for details)     */
00021 /* NHEP            - actual number of entries in current  */
00022 /*                    event.                              */
00023 /* ISTHEP[IHEP]    - status code for IHEP'th entry - see  */
00024 /*                    documentation for details           */
00025 /* IDHEP [IHEP]    - IHEP'th particle identifier according*/
00026 /*                    to PDG.                             */
00027 /* JMOHEP[IHEP][0] - pointer to position of 1st mother    */
00028 /* JMOHEP[IHEP][1] - pointer to position of 2nd mother    */
00029 /* JDAHEP[IHEP][0] - pointer to position of 1st daughter  */
00030 /* JDAHEP[IHEP][1] - pointer to position of 2nd daughter  */
00031 /* PHEP  [IHEP][0] - X momentum                           */
00032 /* PHEP  [IHEP][1] - Y momentum                           */
00033 /* PHEP  [IHEP][2] - Z momentum                           */
00034 /* PHEP  [IHEP][3] - Energy                               */
00035 /* PHEP  [IHEP][4] - Mass                                 */
00036 /* VHEP  [IHEP][0] - X vertex                             */
00037 /* VHEP  [IHEP][1] - Y vertex                             */
00038 /* VHEP  [IHEP][2] - Z vertex                             */
00039 /* VHEP  [IHEP][3] - production time                      */
00040 /*========================================================*/
00041 // Remember, array(1) is the first entry in a fortran array, array[0] is the
00042 //           first entry in a C array.
00043 //
00044 // This interface to EPOS common block treats the block as
00045 // an array of bytes --- the precision and number of entries 
00046 // is determined "on the fly" by the wrapper and used to decode
00047 // each entry.
00048 //
00049 // EPOS_EntriesAllocation is the maximum size of the EPOS common block 
00050 //   that can be interfaced.
00051 //   It is NOT the actual size of the EPOS common used in each
00052 //   individual application. The actual size can be changed on
00053 //   the fly using EPOS_Wrapper::set_max_number_entries().
00054 // Thus EPOS_EntriesAllocation should typically be set
00055 // to the maximum possible number of entries --- 10000 is a good choice
00056 // (and is the number used by ATLAS versions of Pythia).
00057 //
00058 // Note: a statement like    *( (int*)&hepcom.data[0] )
00059 //      takes the memory address of the first byte in EPOS,
00060 //      interprets it as an integer pointer, 
00061 //      and dereferences the pointer.
00062 //      i.e. it returns an integer corresponding to nevhep
00063 //
00064 
00065 #include <ctype.h>
00066 
00067     const unsigned int epos_bytes_allocation = 
00068                 sizeof(long int) * ( 2 + 6 * EPOS_EntriesAllocation )
00069                 + sizeof(double) * ( 9 * EPOS_EntriesAllocation );
00070 
00071 
00072 #ifdef _WIN32 // Platform: Windows MS Visual C++
00073 struct HEPCOM_DEF{
00074         char data[epos_bytes_allocation];
00075     };
00076 extern "C" HEPCOM_DEF HEPCOM;
00077 #define hepcom HEPCOM
00078 
00079 #else
00080 extern "C" {
00081     extern struct {
00082         char data[epos_bytes_allocation];
00083     } hepcom_;
00084 }
00085 #define hepcom hepcom_
00086 
00087 #endif // Platform
00088 
00089 #endif  // HEPMC_EPOS_COMMON_H
00090 
00091 //--------------------------------------------------------------------------
00092 #ifndef HEPMC_EPOS_WRAPPER_H
00093 #define HEPMC_EPOS_WRAPPER_H
00094 
00096 // Matt.Dobbs@Cern.CH, April 24, 2000, refer to:
00097 // M. Dobbs and J.B. Hansen, "The HepMC C++ Monte Carlo Event Record for
00098 // High Energy Physics", Computer Physics Communications (to be published).
00099 //
00100 // Generic Wrapper for the fortran EPOS common block
00101 // This class is intended for static use only - it makes no sense to 
00102 // instantiate it.
00103 // Updated: June 30, 2000 (static initialization moved to separate .cxx file)
00105 //
00106 // The index refers to the fortran style index: 
00107 // i.e. index=1 refers to the first entry in the EPOS common block.
00108 // all indices must be >0
00109 // number_entries --> integer between 0 and max_number_entries() giving total
00110 //                    number of sequential particle indices
00111 // first_parent/child --> index of first mother/child if there is one, 
00112 //                        zero otherwise
00113 // last_parent/child --> if number children is >1, address of last parent/child
00114 //                       if number of children is 1, same as first_parent/child
00115 //                       if there are no children, returns zero.
00116 // is_double_precision --> T or F depending if floating point variables 
00117 //                         are 8 or 4 bytes
00118 //
00119 
00120 #include <iostream>
00121 #include <cstdio>       // needed for formatted output using sprintf 
00122 
00123 namespace EPOS {
00124 
00126     
00131     class EPOS_Wrapper {
00132     public:
00133 
00135         static void print_hepcom( std::ostream& ostr = std::cout );
00137         static void print_hepcom_particle( int index, 
00138                                            std::ostream& ostr = std::cout );
00140         static void zero_everything();
00141 
00143         // Access Methods //
00145         static int    event_number();             
00146         static int    number_entries();           
00147         static int    status( int index );        
00148         static int    id( int index );            
00149         static int    first_parent( int index );  
00150         static int    last_parent( int index );   
00151         static int    number_parents( int index ); 
00152         static int    first_child( int index );   
00153         static int    last_child( int index );    
00154         static int    number_children( int index ); 
00155         static double px( int index );            
00156         static double py( int index );            
00157         static double pz( int index );            
00158         static double e( int index );             
00159         static double m( int index );             
00160         static double x( int index );             
00161         static double y( int index );             
00162         static double z( int index );             
00163         static double t( int index );             
00164 
00166         // Set Methods    //
00168 
00170         static void set_event_number( int evtno );
00172         static void set_number_entries( int noentries );
00174         static void set_status( int index, int status );
00176         static void set_id( int index, int id );
00178         static void set_parents( int index, int firstparent, int lastparent );
00180         static void set_children( int index, int firstchild, int lastchild );
00182         static void set_momentum( int index, double px, double py,
00183                                   double pz, double e );
00185         static void set_mass( int index, double mass );
00187         static void set_position( int index, double x, double y, double z, 
00188                                   double t );
00190         // EPOS Floorplan //
00192         static unsigned int sizeof_int();  
00193         static unsigned int sizeof_real(); 
00194         static int  max_number_entries();  
00195         static void set_sizeof_int(unsigned int);  
00196         static void set_sizeof_real(unsigned int); 
00197         static void set_max_number_entries(unsigned int); 
00198 
00199     protected:
00201         static double byte_num_to_double( unsigned int );
00203         static int    byte_num_to_int( unsigned int );
00205         static void   write_byte_num( double, unsigned int );
00207         static void   write_byte_num( int, unsigned int );
00209         static void   print_legend( std::ostream& ostr = std::cout );
00210 
00211     private:
00212         static unsigned int s_sizeof_int;
00213         static unsigned int s_sizeof_real;
00214         static unsigned int s_max_number_entries;
00215 
00216     }; 
00217 
00219     // EPOS Floorplan Inlines //
00221     inline unsigned int EPOS_Wrapper::sizeof_int(){ return s_sizeof_int; }
00222 
00223     inline unsigned int EPOS_Wrapper::sizeof_real(){ return s_sizeof_real; }
00224 
00225     inline int EPOS_Wrapper::max_number_entries() 
00226     { return (int)s_max_number_entries; }
00227 
00228     inline void EPOS_Wrapper::set_sizeof_int( unsigned int size ) 
00229     {
00230         if ( size != sizeof(short int) && size != sizeof(long int) && size != sizeof(int) ) {
00231             std::cerr << "HepMC is not able to handle integers "
00232                       << " of size other than 2 or 4."
00233                       << " You requested: " << size << std::endl;
00234         }
00235         s_sizeof_int = size;
00236     }
00237 
00238     inline void EPOS_Wrapper::set_sizeof_real( unsigned int size ) {
00239         if ( size != sizeof(float) && size != sizeof(double) ) {
00240             std::cerr << "HepMC is not able to handle floating point numbers"
00241                       << " of size other than 4 or 8."
00242                       << " You requested: " << size << std::endl;
00243         }
00244         s_sizeof_real = size;
00245     }
00246 
00247     inline void EPOS_Wrapper::set_max_number_entries( unsigned int size ) {
00248         s_max_number_entries = size;
00249     }
00250 
00251     inline double EPOS_Wrapper::byte_num_to_double( unsigned int b ) {
00252         if ( b >= epos_bytes_allocation ) std::cerr 
00253                   << "EPOS_Wrapper: requested hepcom data exceeds allocation"
00254                   << std::endl;
00255         if ( s_sizeof_real == sizeof(float) ) {
00256             float* myfloat = (float*)&hepcom.data[b];
00257             return (double)(*myfloat);
00258         } else if ( s_sizeof_real == sizeof(double) ) {
00259             double* mydouble = (double*)&hepcom.data[b];
00260             return (*mydouble);
00261         } else {
00262             std::cerr 
00263                 << "EPOS_Wrapper: illegal floating point number length." 
00264                 << s_sizeof_real << std::endl;
00265         }
00266         return 0;
00267     }
00268 
00269     inline int EPOS_Wrapper::byte_num_to_int( unsigned int b ) {
00270         if ( b >= epos_bytes_allocation ) std::cerr 
00271                   << "EPOS_Wrapper: requested hepcom data exceeds allocation"
00272                   << std::endl;
00273         if ( s_sizeof_int == sizeof(short int) ) {
00274             short int* myshortint = (short int*)&hepcom.data[b];
00275             return (int)(*myshortint);
00276         } else if ( s_sizeof_int == sizeof(long int) ) {
00277             long int* mylongint = (long int*)&hepcom.data[b];
00278             return (*mylongint);
00279        // on some 64 bit machines, int, short, and long are all different
00280         } else if ( s_sizeof_int == sizeof(int) ) {
00281             int* myint = (int*)&hepcom.data[b];
00282             return (*myint);
00283         } else {
00284             std::cerr 
00285                 << "EPOS_Wrapper: illegal integer number length." 
00286                 << s_sizeof_int << std::endl;
00287         }
00288         return 0;
00289     }
00290 
00291     inline void EPOS_Wrapper::write_byte_num( double in, unsigned int b ) {
00292         if ( b >= epos_bytes_allocation ) std::cerr 
00293                   << "EPOS_Wrapper: requested hepcom data exceeds allocation"
00294                   << std::endl;
00295         if ( s_sizeof_real == sizeof(float) ) {
00296             float* myfloat = (float*)&hepcom.data[b];
00297             (*myfloat) = (float)in;
00298         } else if ( s_sizeof_real == sizeof(double) ) {
00299             double* mydouble = (double*)&hepcom.data[b];
00300             (*mydouble) = (double)in;
00301         } else {
00302             std::cerr 
00303                 << "EPOS_Wrapper: illegal floating point number length." 
00304                 << s_sizeof_real << std::endl;
00305         }
00306     }
00307 
00308     inline void EPOS_Wrapper::write_byte_num( int in, unsigned int b ) {
00309         if ( b >= epos_bytes_allocation ) std::cerr 
00310                   << "EPOS_Wrapper: requested hepcom data exceeds allocation"
00311                   << std::endl;
00312         if ( s_sizeof_int == sizeof(short int) ) {
00313             short int* myshortint = (short int*)&hepcom.data[b];
00314             (*myshortint) = (short int)in;
00315         } else if ( s_sizeof_int == sizeof(long int) ) {
00316             long int* mylongint = (long int*)&hepcom.data[b];
00317             (*mylongint) = (int)in;
00318        // on some 64 bit machines, int, short, and long are all different
00319         } else if ( s_sizeof_int == sizeof(int) ) {
00320             int* myint = (int*)&hepcom.data[b];
00321             (*myint) = (int)in;
00322         } else {
00323             std::cerr 
00324                 << "EPOS_Wrapper: illegal integer number length." 
00325                 << s_sizeof_int << std::endl;
00326         }
00327     }
00328 
00330     // INLINES  //
00332 
00333     inline int EPOS_Wrapper::event_number()
00334     { return byte_num_to_int(0); }
00335 
00336     inline int EPOS_Wrapper::number_entries() 
00337     { 
00338         int nhep = byte_num_to_int( 1*sizeof_int() );
00339         return ( nhep <= max_number_entries() ?
00340                  nhep : max_number_entries() );
00341     }
00342 
00343     inline int EPOS_Wrapper::status( int index )   
00344     { return byte_num_to_int( (2+index-1) * sizeof_int() ); }
00345 
00346     inline int EPOS_Wrapper::id( int index )
00347     { 
00348         return byte_num_to_int( (2+max_number_entries()+index-1) 
00349                                 * sizeof_int() ); 
00350     }
00351 
00352     inline int EPOS_Wrapper::first_parent( int index )
00353     { 
00354         int parent = byte_num_to_int( (2+2*max_number_entries()+2*(index-1)) 
00355                                       * sizeof_int() ); 
00356         return ( parent > 0 && parent <= number_entries() ) ?
00357                                          parent : 0; 
00358     }
00359 
00360     inline int EPOS_Wrapper::last_parent( int index )
00361     { 
00362         // Returns the Index of the LAST parent in the EPOS record
00363         // for particle with Index index.
00364         // If there is only one parent, the last parent is forced to 
00365         // be the same as the first parent.
00366         // If there are no parents for this particle, both the first_parent
00367         // and the last_parent with return 0.
00368         // Error checking is done to ensure the parent is always
00369         // within range ( 0 <= parent <= nhep )
00370         //
00371         int firstparent = first_parent(index);
00372         int parent = byte_num_to_int( (2+2*max_number_entries()+2*(index-1)+1) 
00373                                       * sizeof_int() ); 
00374         return ( parent > firstparent && parent <= number_entries() ) 
00375                                                    ? parent : firstparent; 
00376     }
00377 
00378     inline int EPOS_Wrapper::number_parents( int index ) {
00379         int firstparent = first_parent(index);
00380         return ( firstparent>0 ) ? 
00381             ( 1+last_parent(index)-firstparent ) : 0;
00382     }
00383 
00384     inline int EPOS_Wrapper::first_child( int index )
00385     { 
00386         int child = byte_num_to_int( (2+4*max_number_entries()+2*(index-1)) 
00387                                      * sizeof_int() ); 
00388         return ( child > 0 && child <= number_entries() ) ?
00389                                        child : 0; 
00390     }
00391 
00392     inline int EPOS_Wrapper::last_child( int index )
00393     { 
00394         // Returns the Index of the LAST child in the EPOS record
00395         // for particle with Index index.
00396         // If there is only one child, the last child is forced to 
00397         // be the same as the first child.
00398         // If there are no children for this particle, both the first_child
00399         // and the last_child with return 0.
00400         // Error checking is done to ensure the child is always
00401         // within range ( 0 <= parent <= nhep )
00402         //
00403         int firstchild = first_child(index);
00404         int child = byte_num_to_int( (2+4*max_number_entries()+2*(index-1)+1) 
00405                                      * sizeof_int() ); 
00406         return ( child > firstchild && child <= number_entries() ) 
00407                                                 ? child : firstchild;
00408     }
00409 
00410     inline int EPOS_Wrapper::number_children( int index ) 
00411     {
00412         int firstchild = first_child(index);
00413         return ( firstchild>0 ) ? 
00414             ( 1+last_child(index)-firstchild ) : 0;
00415     }
00416 
00417     inline double EPOS_Wrapper::px( int index )
00418     { 
00419         return byte_num_to_double( (2+6*max_number_entries())*sizeof_int()
00420                                  + (5*(index-1)+0) *sizeof_real() );
00421     }
00422 
00423     inline double EPOS_Wrapper::py( int index )
00424     { 
00425         return byte_num_to_double( (2+6*max_number_entries())*sizeof_int()
00426                                  + (5*(index-1)+1) *sizeof_real() );
00427     }
00428 
00429 
00430     inline double EPOS_Wrapper::pz( int index )
00431     { 
00432         return byte_num_to_double( (2+6*max_number_entries())*sizeof_int()
00433                                  + (5*(index-1)+2) *sizeof_real() );
00434     }
00435 
00436     inline double EPOS_Wrapper::e( int index )
00437     { 
00438         return byte_num_to_double( (2+6*max_number_entries())*sizeof_int()
00439                                  + (5*(index-1)+3) *sizeof_real() );
00440     }
00441 
00442     inline double EPOS_Wrapper::m( int index )
00443     { 
00444         return byte_num_to_double( (2+6*max_number_entries())*sizeof_int()
00445                                  + (5*(index-1)+4) *sizeof_real() );
00446     }
00447 
00448     inline double EPOS_Wrapper::x( int index )
00449     { 
00450         return byte_num_to_double( (2+6*max_number_entries())*sizeof_int()
00451                                    + ( 5*max_number_entries()
00452                                        + (4*(index-1)+0) ) *sizeof_real() );
00453     }
00454 
00455     inline double EPOS_Wrapper::y( int index )
00456     { 
00457         return byte_num_to_double( (2+6*max_number_entries())*sizeof_int()
00458                                    + ( 5*max_number_entries()
00459                                        + (4*(index-1)+1) ) *sizeof_real() );
00460     }
00461 
00462     inline double EPOS_Wrapper::z( int index )
00463     { 
00464         return byte_num_to_double( (2+6*max_number_entries())*sizeof_int()
00465                                    + ( 5*max_number_entries()
00466                                        + (4*(index-1)+2) ) *sizeof_real() );
00467     }
00468 
00469     inline double EPOS_Wrapper::t( int index )
00470     { 
00471         return byte_num_to_double( (2+6*max_number_entries())*sizeof_int()
00472                                    + ( 5*max_number_entries()
00473                                        + (4*(index-1)+3) ) *sizeof_real() );
00474     }
00475 
00476     inline void EPOS_Wrapper::set_event_number( int evtno ) 
00477     { write_byte_num( evtno, 0 ); }
00478 
00479     inline void EPOS_Wrapper::set_number_entries( int noentries ) 
00480     { write_byte_num( noentries, 1*sizeof_int() ); }
00481 
00482     inline void EPOS_Wrapper::set_status( int index, int status ) 
00483     {
00484         if ( index <= 0 || index > max_number_entries() ) return;
00485         write_byte_num( status, (2+index-1) * sizeof_int() );
00486     }
00487 
00488     inline void EPOS_Wrapper::set_id( int index, int id ) 
00489     {
00490         if ( index <= 0 || index > max_number_entries() ) return;
00491         write_byte_num( id, (2+max_number_entries()+index-1) *sizeof_int() );
00492     }
00493 
00494     inline void EPOS_Wrapper::set_parents( int index, int firstparent, 
00495                                              int lastparent ) 
00496     {
00497         if ( index <= 0 || index > max_number_entries() ) return;
00498         write_byte_num( firstparent, (2+2*max_number_entries()+2*(index-1)) 
00499                                      *sizeof_int() );
00500         write_byte_num( lastparent, (2+2*max_number_entries()+2*(index-1)+1) 
00501                                     * sizeof_int() );
00502     }
00503     
00504     inline void EPOS_Wrapper::set_children( int index, int firstchild, 
00505                                               int lastchild ) 
00506     {
00507         if ( index <= 0 || index > max_number_entries() ) return;
00508         write_byte_num( firstchild, (2+4*max_number_entries()+2*(index-1)) 
00509                                      *sizeof_int() );
00510         write_byte_num( lastchild, (2+4*max_number_entries()+2*(index-1)+1) 
00511                                     *sizeof_int() );
00512     }
00513 
00514     inline void EPOS_Wrapper::set_momentum( int index, double px, 
00515                                               double py, double pz, double e ) 
00516     {
00517         if ( index <= 0 || index > max_number_entries() ) return;
00518         write_byte_num( px, (2+6*max_number_entries()) *sizeof_int()
00519                             + (5*(index-1)+0) *sizeof_real() );
00520         write_byte_num( py, (2+6*max_number_entries())*sizeof_int()
00521                             + (5*(index-1)+1) *sizeof_real() );
00522         write_byte_num( pz, (2+6*max_number_entries())*sizeof_int()
00523                             + (5*(index-1)+2) *sizeof_real() );
00524         write_byte_num( e,  (2+6*max_number_entries())*sizeof_int()
00525                             + (5*(index-1)+3) *sizeof_real() );
00526     }
00527 
00528     inline void EPOS_Wrapper::set_mass( int index, double mass ) 
00529     {
00530         if ( index <= 0 || index > max_number_entries() ) return;
00531         write_byte_num( mass, (2+6*max_number_entries())*sizeof_int()
00532                               + (5*(index-1)+4) *sizeof_real() );
00533     }
00534 
00535     inline void EPOS_Wrapper::set_position( int index, double x, double y,
00536                                               double z, double t ) 
00537     {
00538         if ( index <= 0 || index > max_number_entries() ) return;
00539         write_byte_num( x, (2+6*max_number_entries())*sizeof_int()
00540                            + ( 5*max_number_entries()
00541                                + (4*(index-1)+0) ) *sizeof_real() );
00542         write_byte_num( y, (2+6*max_number_entries())*sizeof_int()
00543                            + ( 5*max_number_entries()
00544                                + (4*(index-1)+1) ) *sizeof_real() );
00545         write_byte_num( z, (2+6*max_number_entries())*sizeof_int()
00546                            + ( 5*max_number_entries()
00547                                + (4*(index-1)+2) ) *sizeof_real() );
00548         write_byte_num( t, (2+6*max_number_entries())*sizeof_int()
00549                            + ( 5*max_number_entries()
00550                                + (4*(index-1)+3) ) *sizeof_real() );
00551     }
00552 
00553     inline void EPOS_Wrapper::zero_everything()
00554     {
00555         set_event_number( 0 );
00556         set_number_entries( 0 );
00557         for ( int i = 1; i<=max_number_entries(); ++i ) {
00558            set_status( i, 0 );
00559            set_id( i, 0 );
00560            set_parents( i, 0, 0 );
00561            set_children( i, 0, 0 );
00562            set_momentum( i, 0, 0, 0, 0 );
00563            set_mass( i, 0 );
00564            set_position( i, 0, 0, 0, 0 );
00565         }
00566     }
00567 
00568     inline void EPOS_Wrapper::print_hepcom( std::ostream& ostr ) 
00569     {
00570         ostr << "________________________________________"
00571              << "________________________________________" << std::endl;
00572         ostr << "***** HEPEVT Common Event#: " 
00573              << event_number()
00574              << ", " << number_entries() << " particles (max "
00575              << max_number_entries() << ") *****";
00576         ostr << sizeof_int() << "-byte integers, " 
00577              << sizeof_real() << "-byte floating point numbers, "
00578              << max_number_entries() << "-allocated entries." 
00579              << std::endl;
00580         print_legend(ostr);
00581         ostr << "________________________________________"
00582              << "________________________________________" << std::endl;
00583         for ( int i=1; i <= number_entries(); ++i ) {
00584              print_hepcom_particle( i, ostr );
00585         }
00586         ostr << "________________________________________"
00587              << "________________________________________" << std::endl;
00588     } 
00589 
00590     inline void EPOS_Wrapper::print_hepcom_particle( int i, std::ostream& ostr ) 
00591     {
00592         char outline[81];
00593         sprintf( outline,
00594                  "%4d %+4d %4d %4d    (%9.3g, %9.3g, %9.3g, %9.3g, %9.3g)"
00595                 ,i, status(i), first_parent(i), first_child(i),
00596                  px(i), py(i), pz(i), e(i), m(i) );
00597         ostr << outline << "\n";
00598         sprintf( outline,"%+9d %4d %4d    (%9.3g, %9.3g, %9.3g, %9.3g)",
00599               // old version was:" (%+9.2e, %+9.2e, %+9.2e, %+9.2e)"
00600                 id(i), last_parent(i), last_child(i), 
00601                 x(i), y(i), z(i), t(i) );
00602         ostr << outline << std::endl;
00603     } 
00604     
00605     inline void EPOS_Wrapper::print_legend( std::ostream& ostr )
00606     {
00607         char outline[81];
00608         sprintf( outline,"%4s %4s %4s %5s   %10s, %9s, %9s, %9s, %10s",
00609                 "Indx","Stat","Par-","chil-",
00610                 "(  P_x","P_y","P_z","Energy","M ) ");
00611         ostr << outline << std::endl;
00612         sprintf( outline,"%9s %4s %4s    %10s, %9s, %9s, %9s) %9s",
00613                 "ID ","ents","dren",
00614                 "Prod (   X","Y","Z","cT", "[mm]");
00615         ostr << outline << std::endl;
00616     }     
00617 
00618 } // HepMC
00619 
00620 #endif  // HEPMC_EPOS_WRAPPER_H
00621 //--------------------------------------------------------------------------
00622