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Please see the license in the file LICENSE and URL above * 16 // * for the full disclaimer and the limitatio 16 // * for the full disclaimer and the limitation of liability. * 17 // * 17 // * * 18 // * This code implementation is the result 18 // * This code implementation is the result of the scientific and * 19 // * technical work of the GEANT4 collaboratio 19 // * technical work of the GEANT4 collaboration. * 20 // * By using, copying, modifying or distri 20 // * By using, copying, modifying or distributing the software (or * 21 // * any work based on the software) you ag 21 // * any work based on the software) you agree to acknowledge its * 22 // * use in resulting scientific publicati 22 // * use in resulting scientific publications, and indicate your * 23 // * acceptance of all terms of the Geant4 Sof 23 // * acceptance of all terms of the Geant4 Software license. * 24 // ******************************************* 24 // ******************************************************************** 25 // 25 // 26 // G4ParticleDefinition 26 // G4ParticleDefinition 27 // 27 // 28 // Class description: 28 // Class description: 29 // 29 // 30 // This class contains all the static data of 30 // This class contains all the static data of a particle. 31 // It uses the process manager in order to col 31 // It uses the process manager in order to collect all the processes 32 // this kind of particle can undertake. 32 // this kind of particle can undertake. 33 33 34 // Authors: G.Cosmo, 2 December 1995 - Design, 34 // Authors: G.Cosmo, 2 December 1995 - Design, based on object model 35 // M.Asai, 29 January 1996 - First im 35 // M.Asai, 29 January 1996 - First implementation 36 // History: 36 // History: 37 // - 1996-2003, H.Kurashige - Revisions 37 // - 1996-2003, H.Kurashige - Revisions 38 // - 11.03.2003, H.Kurashige - Restructuring f 38 // - 11.03.2003, H.Kurashige - Restructuring for Cuts per Region 39 // - 25.01.2013, G.Cosmo, A.Dotti - Introduced 39 // - 25.01.2013, G.Cosmo, A.Dotti - Introduced thread-safety for MT 40 // - 15.06.2017, K.L.Genser - Added support fo 40 // - 15.06.2017, K.L.Genser - Added support for MuonicAtom 41 // ------------------------------------------- 41 // -------------------------------------------------------------------- 42 #ifndef G4ParticleDefinition_hh 42 #ifndef G4ParticleDefinition_hh 43 #define G4ParticleDefinition_hh 1 43 #define G4ParticleDefinition_hh 1 44 44 45 #include "G4PDefManager.hh" << 45 #include <vector> 46 #include "G4ios.hh" << 47 #include "globals.hh" << 48 << 49 #include <CLHEP/Units/PhysicalConstants.h> 46 #include <CLHEP/Units/PhysicalConstants.h> 50 47 51 #include <vector> << 48 #include "globals.hh" >> 49 #include "G4ios.hh" >> 50 #include "G4PDefManager.hh" 52 51 53 class G4ProcessManager; 52 class G4ProcessManager; 54 class G4DecayTable; 53 class G4DecayTable; 55 class G4ParticleTable; 54 class G4ParticleTable; 56 class G4ParticlePropertyTable; 55 class G4ParticlePropertyTable; 57 class G4VTrackingManager; << 58 56 59 using G4ParticleDefinitionSubInstanceManager = 57 using G4ParticleDefinitionSubInstanceManager = G4PDefManager; 60 58 61 class G4ParticleDefinition << 59 class G4ParticleDefinition 62 { 60 { 63 friend class G4ParticlePropertyTable; << 61 friend class G4ParticlePropertyTable; 64 62 65 public: 63 public: >> 64 66 // Only one type of constructor can be use 65 // Only one type of constructor can be used for G4ParticleDefinition. 67 // If you want to create new particle, you << 66 // If you want to create new particle, you must set name of the particle 68 // at construction. Most of members seen a << 67 // at construction. Most of members seen as arguments of the constructor 69 // (except last 3 arguments concerning wit << 68 // (except last 3 arguments concerning with decay ) are "constant" 70 // and can not be changed later. (No "SET" 69 // and can not be changed later. (No "SET" methods are available) 71 // Each type of particle must be construct 70 // Each type of particle must be constructed as a unique object 72 // of special class derived from G4Particl 71 // of special class derived from G4ParticleDefinition. 73 // See G4ParticleTypes for detail 72 // See G4ParticleTypes for detail 74 // clang-format off << 73 75 G4ParticleDefinition(const G4String& aName << 74 G4ParticleDefinition(const G4String& aName, 76 G4int iSpin, G4int iP << 75 G4double mass, 77 G4int iIsospinZ, G4in << 76 G4double width, 78 G4int baryon, G4int e << 77 G4double charge, 79 G4DecayTable* decayta << 78 G4int iSpin, 80 const G4String& subTy << 79 G4int iParity, 81 G4double magneticMome << 80 G4int iConjugation, 82 // clang-format on << 81 G4int iIsospin, >> 82 G4int iIsospinZ, >> 83 G4int gParity, >> 84 const G4String& pType, >> 85 G4int lepton, >> 86 G4int baryon, >> 87 G4int encoding, >> 88 G4bool stable, >> 89 G4double lifetime, >> 90 G4DecayTable* decaytable, >> 91 G4bool shortlived = false, >> 92 const G4String& subType = "", >> 93 G4int anti_encoding = 0, >> 94 G4double magneticMoment = 0.0); 83 95 84 virtual ~G4ParticleDefinition(); 96 virtual ~G4ParticleDefinition(); 85 << 97 86 // Can not use "copy constructor", equalit << 87 G4ParticleDefinition(const G4ParticleDefin 98 G4ParticleDefinition(const G4ParticleDefinition&) = delete; 88 G4ParticleDefinition& operator=(const G4Pa << 99 G4ParticleDefinition& operator=(const G4ParticleDefinition &) = delete; >> 100 // Can not use "copy constructor", equality nor "default constructor"! 89 101 90 G4bool operator==(const G4ParticleDefiniti 102 G4bool operator==(const G4ParticleDefinition& right) const; 91 G4bool operator!=(const G4ParticleDefiniti 103 G4bool operator!=(const G4ParticleDefinition& right) const; 92 104 93 // With the following Getxxxx methods, one << 105 // With the following Getxxxx methods, one can get values 94 // for members which can not be changed 106 // for members which can not be changed 95 << 107 96 const G4String& GetParticleName() const { 108 const G4String& GetParticleName() const { return theParticleName; } 97 109 98 G4double GetPDGMass() const { return thePD 110 G4double GetPDGMass() const { return thePDGMass; } 99 G4double GetPDGWidth() const { return theP << 111 G4double GetPDGWidth() const { return thePDGWidth; } 100 G4double GetPDGCharge() const { return the 112 G4double GetPDGCharge() const { return thePDGCharge; } 101 113 102 G4double GetPDGSpin() const { return thePD 114 G4double GetPDGSpin() const { return thePDGSpin; } 103 G4int GetPDGiSpin() const { return thePDGi << 115 G4int GetPDGiSpin() const { return thePDGiSpin; } 104 G4int GetPDGiParity() const { return thePD << 116 G4int GetPDGiParity() const { return thePDGiParity; } 105 G4int GetPDGiConjugation() const { return << 117 G4int GetPDGiConjugation() const { return thePDGiConjugation; } 106 G4double GetPDGIsospin() const { return th 118 G4double GetPDGIsospin() const { return thePDGIsospin; } 107 G4double GetPDGIsospin3() const { return t 119 G4double GetPDGIsospin3() const { return thePDGIsospin3; } 108 G4int GetPDGiIsospin() const { return theP << 120 G4int GetPDGiIsospin() const { return thePDGiIsospin; } 109 G4int GetPDGiIsospin3() const { return the << 121 G4int GetPDGiIsospin3() const { return thePDGiIsospin3; } 110 G4int GetPDGiGParity() const { return theP << 122 G4int GetPDGiGParity() const { return thePDGiGParity; } 111 << 123 112 G4double GetPDGMagneticMoment() const { re 124 G4double GetPDGMagneticMoment() const { return thePDGMagneticMoment; } 113 inline void SetPDGMagneticMoment(G4double << 125 inline void SetPDGMagneticMoment(G4double mageticMoment); 114 << 126 G4double CalculateAnomaly() const; 115 // Gives the anomaly of magnetic moment fo << 127 // Gives the anomaly of magnetic moment for spin 1/2 particles 116 G4double CalculateAnomaly() const; << 117 128 118 const G4String& GetParticleType() const { 129 const G4String& GetParticleType() const { return theParticleType; } 119 const G4String& GetParticleSubType() const 130 const G4String& GetParticleSubType() const { return theParticleSubType; } 120 G4int GetLeptonNumber() const { return the 131 G4int GetLeptonNumber() const { return theLeptonNumber; } 121 G4int GetBaryonNumber() const { return the 132 G4int GetBaryonNumber() const { return theBaryonNumber; } 122 133 123 G4int GetPDGEncoding() const { return theP 134 G4int GetPDGEncoding() const { return thePDGEncoding; } 124 G4int GetAntiPDGEncoding() const { return 135 G4int GetAntiPDGEncoding() const { return theAntiPDGEncoding; } 125 inline void SetAntiPDGEncoding(G4int aEnco 136 inline void SetAntiPDGEncoding(G4int aEncoding); 126 137 127 // Returns the number of quark with flavor << 128 // The value of flavor is assigned as foll << 129 // 1:d, 2:u, 3:s, 4:c, 5:b, 6:t << 130 inline G4int GetQuarkContent(G4int flavor) 138 inline G4int GetQuarkContent(G4int flavor) const; 131 inline G4int GetAntiQuarkContent(G4int fla 139 inline G4int GetAntiQuarkContent(G4int flavor) const; 132 << 140 // Returns the number of quark with flavor contained in this particle. >> 141 // The value of flavor is assigned as follows >> 142 // 1:d, 2:u, 3:s, 4:c, 5:b, 6:t >> 143 133 G4bool IsShortLived() const { return fShor 144 G4bool IsShortLived() const { return fShortLivedFlag; } 134 145 135 inline G4bool GetPDGStable() const; << 146 inline G4bool GetPDGStable() const; 136 void SetPDGStable(const G4bool aFlag) { th << 147 void SetPDGStable(const G4bool aFlag) { thePDGStable=aFlag; } 137 148 138 inline G4double GetPDGLifeTime() const; 149 inline G4double GetPDGLifeTime() const; 139 void SetPDGLifeTime(G4double aLifeTime) { << 150 void SetPDGLifeTime(G4double aLifeTime) { thePDGLifeTime=aLifeTime; } 140 151 141 // Get life time of a generic ion through << 142 inline G4double GetIonLifeTime() const; 152 inline G4double GetIonLifeTime() const; >> 153 // Get life time of a generic ion through G4NuclideTable. 143 154 144 // Set/Get Decay Table << 145 // !! Decay Table can be modified !! << 146 inline G4DecayTable* GetDecayTable() const 155 inline G4DecayTable* GetDecayTable() const; 147 inline void SetDecayTable(G4DecayTable* aD << 156 inline void SetDecayTable(G4DecayTable* aDecayTable); 148 << 157 // Set/Get Decay Table 149 // Set/Get Process Manager << 158 // !! Decay Table can be modified !! 150 // !! Process Manager can be modified !! << 159 151 G4ProcessManager* GetProcessManager() cons << 160 G4ProcessManager* GetProcessManager() const; 152 void SetProcessManager(G4ProcessManager* a << 161 void SetProcessManager(G4ProcessManager* aProcessManager); 153 << 162 // Set/Get Process Manager 154 // Set/Get Tracking Manager; nullptr means << 163 // !! Process Manager can be modified !! 155 // !! Tracking Manager can be modified ! << 156 G4VTrackingManager* GetTrackingManager() c << 157 void SetTrackingManager(G4VTrackingManager << 158 164 159 // Get pointer to the particle table << 160 inline G4ParticleTable* GetParticleTable() 165 inline G4ParticleTable* GetParticleTable() const; >> 166 // Get pointer to the particle table 161 167 162 // Get AtomicNumber and AtomicMass << 163 // These properties are defined for nucleu << 164 inline G4int GetAtomicNumber() const; 168 inline G4int GetAtomicNumber() const; 165 inline G4int GetAtomicMass() const; 169 inline G4int GetAtomicMass() const; >> 170 // Get AtomicNumber and AtomicMass >> 171 // These properties are defined for nucleus 166 172 167 // Prints information of data members. << 168 void DumpTable() const; 173 void DumpTable() const; >> 174 // Prints information of data members. 169 175 170 // Control flag for output message << 171 // 0: Silent << 172 // 1: Warning message << 173 // 2: More << 174 inline void SetVerboseLevel(G4int value); 176 inline void SetVerboseLevel(G4int value); 175 inline G4int GetVerboseLevel() const; 177 inline G4int GetVerboseLevel() const; >> 178 // Control flag for output message >> 179 // 0: Silent >> 180 // 1: Warning message >> 181 // 2: More 176 182 177 void SetApplyCutsFlag(G4bool); 183 void SetApplyCutsFlag(G4bool); 178 inline G4bool GetApplyCutsFlag() const; 184 inline G4bool GetApplyCutsFlag() const; 179 185 180 // True only if the particle is G4Ions << 181 // (it means that theProcessManager is sam << 182 inline G4bool IsGeneralIon() const; 186 inline G4bool IsGeneralIon() const; >> 187 // True only if the particle is G4Ions >> 188 // (it means that theProcessManager is same as one for G4GenricIon) 183 189 184 // True only if the particle is a G4Muonic << 185 // (it means that theProcessManager is sam << 186 inline G4bool IsMuonicAtom() const; 190 inline G4bool IsMuonicAtom() const; >> 191 // True only if the particle is a G4MuonicAtom >> 192 // (it means that theProcessManager is same as the one for G4MuonicAtom) 187 193 188 // Returns the process manager master poin << 189 inline G4ProcessManager* GetMasterProcessM 194 inline G4ProcessManager* GetMasterProcessManager() const; 190 << 195 // Returns the process manager master pointer. 191 // Sets the shadow master pointer (not to << 192 inline void SetMasterProcessManager(G4Proc 196 inline void SetMasterProcessManager(G4ProcessManager* aNewPM); >> 197 // Sets the shadow master pointer (not to be used by user) 193 198 194 // Returns the instance ID << 195 inline G4int GetInstanceID() const; 199 inline G4int GetInstanceID() const; >> 200 // Returns the instance ID 196 201 197 // Returns the private data instance manag << 198 static const G4PDefManager& GetSubInstance 202 static const G4PDefManager& GetSubInstanceManager(); >> 203 // Returns the private data instance manager 199 204 200 // Clear memory allocated by sub-instance << 201 static void Clean(); 205 static void Clean(); >> 206 // Clear memory allocated by sub-instance manager 202 207 203 void SetParticleDefinitionID(G4int id = -1 << 208 void SetParticleDefinitionID(G4int id=-1); 204 inline G4int GetParticleDefinitionID() con 209 inline G4int GetParticleDefinitionID() const; 205 210 206 // The first two methods return "false" an << 207 // if the particle is not an hypernucleus; << 208 // "true" and the number of Lambdas bound << 209 // Similarly, the last two methods return << 210 // respectively, if the particle is not an << 211 // else, they return "true" and the number << 212 // bound in the anti-nucleus. << 213 // Notice that, for the time being, we are << 214 // (anti-)Lambda is the only type of (anti << 215 // in all (anti-)hypernuclei. << 216 inline G4bool IsHypernucleus() const; << 217 inline G4int GetNumberOfLambdasInHypernucl << 218 inline G4bool IsAntiHypernucleus() const; << 219 inline G4int GetNumberOfAntiLambdasInAntiH << 220 << 221 protected: 211 protected: 222 // Cannot be used << 212 223 G4ParticleDefinition(); 213 G4ParticleDefinition(); >> 214 // Cannot be used 224 215 225 // Calculates quark and anti-quark content << 226 // return value is the PDG encoding for th << 227 // It means error if the return value is d << 228 // this->thePDGEncoding. << 229 G4int FillQuarkContents(); 216 G4int FillQuarkContents(); >> 217 // Calculates quark and anti-quark contents >> 218 // return value is the PDG encoding for this particle. >> 219 // It means error if the return value is different from >> 220 // this->thePDGEncoding. 230 221 231 inline void SetParticleSubType(const G4Str 222 inline void SetParticleSubType(const G4String& subtype); 232 223 233 inline void SetAtomicNumber(G4int); 224 inline void SetAtomicNumber(G4int); 234 inline void SetAtomicMass(G4int); 225 inline void SetAtomicMass(G4int); 235 226 236 enum << 227 enum { NumberOfQuarkFlavor = 6 }; 237 { << 228 238 NumberOfQuarkFlavor = 6 << 229 G4int theQuarkContent[NumberOfQuarkFlavor]; 239 }; << 230 G4int theAntiQuarkContent[NumberOfQuarkFlavor]; 240 << 231 // the number of quark (minus Sign means anti-quark) contents 241 // the number of quark (minus Sign means << 232 // The value of flavor is assigned as follows 242 // The value of flavor is assigned as fol << 233 // 0:d, 1:u, 2:s, 3:c, 4:b, 5:t 243 // 0:d, 1:u, 2:s, 3:c, 4:b, 5:t << 234 244 G4int theQuarkContent[NumberOfQuarkFlavor] << 235 protected: 245 G4int theAntiQuarkContent[NumberOfQuarkFla << 246 236 247 G4bool isGeneralIon = false; 237 G4bool isGeneralIon = false; 248 G4bool isMuonicAtom = false; 238 G4bool isMuonicAtom = false; 249 239 250 private: 240 private: >> 241 251 // --- Shadow of master pointers 242 // --- Shadow of master pointers 252 243 253 // Each worker thread can access this fiel << 254 // through this pointer. << 255 G4ProcessManager* theProcessManagerShadow 244 G4ProcessManager* theProcessManagerShadow = nullptr; >> 245 // Each worker thread can access this field from the master thread >> 246 // through this pointer. 256 247 257 // This field is used as instance ID. << 258 G4int g4particleDefinitionInstanceID = 0; 248 G4int g4particleDefinitionInstanceID = 0; >> 249 // This field is used as instance ID. 259 250 260 // This field helps to use the class G4PDe << 261 G4PART_DLL static G4PDefManager subInstanc 251 G4PART_DLL static G4PDefManager subInstanceManager; >> 252 // This field helps to use the class G4PDefManager introduced above. 262 253 263 // --- Following values can not be change 254 // --- Following values can not be changed 264 // --- i.e. No Setxxxx Methods for them << 255 // --- i.e. No Setxxxx Methods for them 265 256 266 // The name of the particle. << 267 // Each object must have its specific name << 268 G4String theParticleName = ""; 257 G4String theParticleName = ""; >> 258 // The name of the particle. >> 259 // Each object must have its specific name!! 269 260 270 // --- Following member values must be de 261 // --- Following member values must be defined with Units 271 262 272 // The mass of the particle, in units of e << 273 G4double thePDGMass = 0.0; 263 G4double thePDGMass = 0.0; >> 264 // The mass of the particle, in units of equivalent energy. 274 265 275 // The decay width of the particle, usuall << 276 // Breit-Wigner function, assuming that yo << 277 // mass center anyway. (in units of equiva << 278 G4double thePDGWidth = 0.0; 266 G4double thePDGWidth = 0.0; >> 267 // The decay width of the particle, usually the width of a >> 268 // Breit-Wigner function, assuming that you are near the >> 269 // mass center anyway. (in units of equivalent energy) 279 270 280 // The charge of the particle.(in units of << 281 G4double thePDGCharge = 0.0; 271 G4double thePDGCharge = 0.0; >> 272 // The charge of the particle.(in units of Coulomb) 282 273 283 // --- Following members are quantum num 274 // --- Following members are quantum number 284 // i.e. discrete numbers can be allo 275 // i.e. discrete numbers can be allowed 285 // So, you can define them only by u << 276 // So, you can define them only by using integer in constructor 286 277 287 // The total spin of the particle, also of << 288 // capital J, in units of 1/2. << 289 G4int thePDGiSpin = 0; 278 G4int thePDGiSpin = 0; 290 << 279 // The total spin of the particle, also often denoted as 291 // The total spin of the particle, in unit << 280 // capital J, in units of 1/2. 292 G4double thePDGSpin = 0.0; 281 G4double thePDGSpin = 0.0; >> 282 // The total spin of the particle, in units of 1. 293 283 294 // The parity quantum number, in units of << 295 // is not defined for this particle, we wi << 296 G4int thePDGiParity = 0; 284 G4int thePDGiParity = 0; >> 285 // The parity quantum number, in units of 1. If the parity >> 286 // is not defined for this particle, we will set this to 0. 297 287 298 // This charge conjugation quantum number << 299 G4int thePDGiConjugation = 0; 288 G4int thePDGiConjugation = 0; >> 289 // This charge conjugation quantum number in units of 1. 300 290 301 // The value of the G-parity quantum numbe << 302 G4int thePDGiGParity = 0; 291 G4int thePDGiGParity = 0; >> 292 // The value of the G-parity quantum number. 303 293 304 // The isospin and its 3rd-component in un << 305 G4int thePDGiIsospin = 0; 294 G4int thePDGiIsospin = 0; 306 G4int thePDGiIsospin3 = 0; 295 G4int thePDGiIsospin3 = 0; 307 << 296 // The isospin and its 3rd-component in units of 1/2. 308 // The isospin quantum number in units of << 309 G4double thePDGIsospin = 0.0; 297 G4double thePDGIsospin = 0.0; 310 G4double thePDGIsospin3 = 0.0; 298 G4double thePDGIsospin3 = 0.0; 311 << 299 // The isospin quantum number in units of 1. 312 // The magnetic moment. << 300 313 G4double thePDGMagneticMoment = 0.0; 301 G4double thePDGMagneticMoment = 0.0; >> 302 // The magnetic moment. 314 303 315 // The lepton quantum number. << 316 G4int theLeptonNumber = 0; 304 G4int theLeptonNumber = 0; >> 305 // The lepton quantum number. 317 306 318 // The baryon quantum number. << 319 G4int theBaryonNumber = 0; 307 G4int theBaryonNumber = 0; >> 308 // The baryon quantum number. 320 309 321 // More general textual type description o << 322 G4String theParticleType = ""; 310 G4String theParticleType = ""; >> 311 // More general textual type description of the particle. 323 312 324 // Textual type description of the particl << 325 // eg. pion, lamda etc. << 326 G4String theParticleSubType = ""; 313 G4String theParticleSubType = ""; >> 314 // Textual type description of the particle >> 315 // eg. pion, lamda etc. 327 316 328 // The Particle Data Group integer identif << 329 G4int thePDGEncoding = 0; 317 G4int thePDGEncoding = 0; 330 << 318 // The Particle Data Group integer identifier of this particle 331 // The Particle Data Group integer identif << 319 332 G4int theAntiPDGEncoding = 0; 320 G4int theAntiPDGEncoding = 0; >> 321 // The Particle Data Group integer identifier of the anti-particle 333 322 334 // --- Following members can be changed af 323 // --- Following members can be changed after construction 335 324 336 // Particles which have true value of this << 337 // will not be tracked by TrackingManager << 338 G4bool fShortLivedFlag = false; 325 G4bool fShortLivedFlag = false; >> 326 // Particles which have true value of this flag >> 327 // will not be tracked by TrackingManager 339 328 340 // Is an indicator that this particle is s << 341 // not decay. If the user tries to assign << 342 // object to it, it will refuse to take it << 343 G4bool thePDGStable = false; 329 G4bool thePDGStable = false; >> 330 // Is an indicator that this particle is stable. It must >> 331 // not decay. If the user tries to assign a kind of decay >> 332 // object to it, it will refuse to take it. 344 333 345 // Is related to the decay width of the pa << 346 // life time is given in seconds. << 347 G4double thePDGLifeTime = 0.0; 334 G4double thePDGLifeTime = 0.0; >> 335 // Is related to the decay width of the particle. The mean >> 336 // life time is given in seconds. 348 337 349 // Points DecayTable << 350 G4DecayTable* theDecayTable = nullptr; 338 G4DecayTable* theDecayTable = nullptr; >> 339 // Points DecayTable 351 340 352 G4ParticleTable* theParticleTable = nullpt 341 G4ParticleTable* theParticleTable = nullptr; 353 342 354 G4int theAtomicNumber = 0; 343 G4int theAtomicNumber = 0; 355 G4int theAtomicMass = 0; 344 G4int theAtomicMass = 0; 356 << 345 357 G4int verboseLevel = 1; 346 G4int verboseLevel = 1; 358 G4bool fApplyCutsFlag = false; 347 G4bool fApplyCutsFlag = false; 359 }; 348 }; 360 349 361 #include "G4ParticleDefinition.icc" 350 #include "G4ParticleDefinition.icc" 362 351 363 #endif 352 #endif 364 353