source: branches/Mars_IncreaseNsb/mmc/MMcRunHeader.cxx@ 19963

Last change on this file since 19963 was 17386, checked in by tbretz, 11 years ago
Removed svn:executable property, these are no executables.
File size: 7.5 KB
Line 
1/* ======================================================================== *\
2!
3! *
4! * This file is part of MARS, the MAGIC Analysis and Reconstruction
5! * Software. It is distributed to you in the hope that it can be a useful
6! * and timesaving tool in analysing Data of imaging Cerenkov telescopes.
7! * It is distributed WITHOUT ANY WARRANTY.
8! *
9! * Permission to use, copy, modify and distribute this software and its
10! * documentation for any purpose is hereby granted without fee,
11! * provided that the above copyright notice appear in all copies and
12! * that both that copyright notice and this permission notice appear
13! * in supporting documentation. It is provided "as is" without express
14! * or implied warranty.
15! *
16!
17!
18! Author(s): Thomas Bretz 12/2000 (tbretz@uni-sw.gwdg.de)
19!
20! Copyright: MAGIC Software Development, 2000-2001
21!
22!
23\* ======================================================================== */
24
25/////////////////////////////////////////////////////////////////////////////
26//
27// MMcRunHeader
28//
29// Root storage container for the RUN MONTE CARLO HEADER information
30//
31// This the second version of this output class. Old root files, which have
32// a previous version of this class, are still compatibles and can be used.
33// But of course, you can no try to get infromatino in these old files about
34// the new data members.
35//
36// The following data member have been introduced in this second version
37// and they do not exist in the previous one:
38//
39// Float_t fMcRunNumber; Run Number
40// UInt_t fProductionSite; code to know where the run was generated
41// Float_t fDateRunMMCs; Date of the MMCs production
42// Float_t fDateRunCamera; Date, when the Camera program is run.
43// Byte_t fRawEvt; RawEvt[Data,Hedaer] stored or not
44// Byte_t fElecNoise; Electronic Noise simulated or not
45// Byte_t fStarFieldRotate; Is the starfield rotation switched on (1) or
46// off (0)
47// Float_t fCWaveLower; Wavelength limits for the Cerenkov photons
48// Float_t fCWaveUpper;
49// UInt_t fNumObsLev; Observation levels
50// Float_t fHeightLev[10];
51// Float_t fSlopeSpec; Spectral index
52//
53// Third version:
54//
55// Byte_t fOpticLinksNoise; Flag to state if the optic noise is simualted
56// or not
57//
58//
59// Note: All the azimuth Phi angles in this and other MC classes follow
60// the convention in the Corsika program (see Corsika manual). There, phi
61// is the azimuth of the momentum vector of particles, and is measured
62// from the north direction, anticlockwise (i.e, west is phi=90 degrees).
63//
64//
65// Class Version 5:
66// ----------------
67// removed members fSourceOffsetTheta, fSourceOffsetPhi (were no longer used) //
68//
69// Class Version 6:
70// ----------------
71// removed members fTelesTheta, fTelesPhi (were no longer used) //
72//
73// Class Version 7:
74// ----------------
75// + Float_t fRandomPointingConeSemiAngle;
76//
77////////////////////////////////////////////////////////////////////////////
78#include "MMcRunHeader.hxx"
79
80#include <fstream>
81#include <iomanip>
82
83#include "MLog.h"
84
85ClassImp(MMcRunHeader);
86
87using namespace std;
88
89// --------------------------------------------------------------------------
90//
91// Default constructor.
92//
93//
94MMcRunHeader::MMcRunHeader(const char *name, const char *title)
95{
96 fName = name ? name : "MMcRunHeader";
97 fTitle = title ? title : "Raw Run Header Information";
98
99 fMcRunNumber =0;
100 fProductionSite = 0;
101 fDateRunMMCs = 0;
102 fDateRunCamera = 0;
103 fNumTrigCond = 0;
104 fAllEvtsTriggered = 0 ;
105 fMcEvt = 0;
106 fMcTrig = 0;
107 fMcFadc = 0;
108 fRawEvt = 0;
109 fElecNoise = 0;
110 fStarFieldRotate = 0;
111 fNumAnalisedPixels = 0;
112 fNumSimulatedShowers = 0;
113 fNumStoredShowers = 0;
114 fNumEvents = 0;
115
116 fStarFieldRaH = 0;
117 fStarFieldRaM = 0;
118 fStarFieldRaS = 0;
119 fStarFieldDeD = 0;
120 fStarFieldDeM = 0;
121 fStarFieldDeS = 0;
122
123 fNumPheFromDNSB = 0.0;
124 fShowerThetaMax = 0.0;
125 fShowerThetaMin = 0.0;
126 fShowerPhiMax = 0.0;
127 fShowerPhiMin = 0.0;
128
129 fImpactMax = -1;
130
131 fCWaveLower = 0.0;
132 fCWaveUpper = 0.0;
133
134 fNumObsLev = 0;
135 for (int i=0; i<10; i++){
136 fHeightLev[i]=0.0;
137 }
138 fSlopeSpec = 0.0;
139
140 fCorsikaVersion = UShort_t(-1);
141 fReflVersion = UShort_t(-1);
142 fCamVersion = UShort_t(-1);
143
144 fOpticLinksNoise= 0;
145
146 fRandomPointingConeSemiAngle=0;
147}
148
149// -------------------------------------------------------------------------
150//
151// Fill. Put data in the container
152//
153void MMcRunHeader::Fill(const Float_t runnumber,
154 const UInt_t productionsite,
155 const Float_t daterunMMCs,
156 const Float_t daterunCamera,
157 const UInt_t numtrigcond,
158 const Byte_t allevts,
159 const Byte_t mcevt,
160 const Byte_t mctrig,
161 const Byte_t mcfadc,
162 const Byte_t rawevt,
163 const Byte_t elecnoise,
164 const Int_t numanalpixels,
165 const UInt_t numsim,
166 const UInt_t numsto,
167 const Byte_t starfieldrotate,
168 const Int_t sfRaH,
169 const Int_t sfRaM,
170 const Int_t sfRaS,
171 const Int_t sfDeD,
172 const Int_t sfDeM,
173 const Int_t sfDeS,
174 const Float_t numdnsb,
175 const Float_t shthetamax,
176 const Float_t shthetamin,
177 const Float_t shphimax,
178 const Float_t shphimin,
179 const Float_t impactmax,
180 const Float_t cwavelower,
181 const Float_t cwaveupper,
182 const Float_t slopespec,
183 const UInt_t numObslev,
184 const Float_t heightlev[10],
185 const UInt_t corsika,
186 const UInt_t refl,
187 const UInt_t cam,
188 const Byte_t opticnoise,
189 const Float_t conesmiangle)
190{
191 fMcRunNumber =runnumber;
192 fProductionSite = productionsite;
193 fDateRunMMCs = daterunMMCs;
194 fDateRunCamera = daterunCamera;
195 fNumTrigCond = numtrigcond;
196 fAllEvtsTriggered = allevts;
197 fMcEvt = mcevt;
198 fMcTrig = mctrig;
199 fMcFadc = mcfadc;
200 fRawEvt = rawevt;
201 fElecNoise = elecnoise;
202 fStarFieldRotate = starfieldrotate;
203 fNumAnalisedPixels = numanalpixels;
204 fNumSimulatedShowers = numsim;
205 fNumStoredShowers = numsto;
206 fNumEvents = numsto;
207
208 fStarFieldRaH = sfRaH;
209 fStarFieldRaM = sfRaM;
210 fStarFieldRaS = sfRaS;
211 fStarFieldDeD = sfDeD;
212 fStarFieldDeM = sfDeM;
213 fStarFieldDeS = sfDeS;
214
215 fNumPheFromDNSB = numdnsb;
216 fShowerThetaMax = shthetamax;
217 fShowerThetaMin = shthetamin;
218 fShowerPhiMax = shphimax;
219 fShowerPhiMin = shphimin;
220
221 fImpactMax=impactmax;
222
223 fCWaveLower = cwavelower;
224 fCWaveUpper = cwaveupper;
225
226 fNumObsLev = numObslev;
227 for (UInt_t i=0; i<numObslev; i++){
228 fHeightLev[i]=heightlev[i];
229 }
230 fSlopeSpec = slopespec;
231
232 fCorsikaVersion = corsika;
233 fReflVersion = refl;
234 fCamVersion = cam;
235 fOpticLinksNoise= opticnoise;
236
237 fRandomPointingConeSemiAngle=conesmiangle;
238}
239
240// -------------------------------------------------------------------------
241//
242// GetStarFieldRa. Get RA coordinates of the starfield
243//
244void MMcRunHeader::GetStarFieldRa(Int_t *hour, Int_t *minute, Int_t *second) const
245{
246 *hour = fStarFieldRaH;
247 *minute = fStarFieldRaM;
248 *second = fStarFieldRaS;
249}
250// -------------------------------------------------------------------------
251//
252// GetStarFieldDec. Get DE coordinates of the starfield
253//
254void MMcRunHeader::GetStarFieldDec(Int_t *degree, Int_t *minute, Int_t *second) const
255{
256 *degree = fStarFieldDeD;
257 *minute = fStarFieldDeM;
258 *second = fStarFieldDeS;
259}
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