Geant4 Cross Reference |
1 /* gamma.c 1 /* gamma.c 2 * 2 * 3 * Gamma function 3 * Gamma function 4 * 4 * 5 * DESCRIPTION: 5 * DESCRIPTION: 6 * 6 * 7 * Returns gamma function of the argument. Th 7 * Returns gamma function of the argument. The result is 8 * correctly signed, and the sign (+1 or -1) i 8 * correctly signed, and the sign (+1 or -1) is also 9 * returned in a global (extern) variable name 9 * returned in a global (extern) variable named sgngam. 10 * This variable is also filled in by the loga 10 * This variable is also filled in by the logarithmic gamma 11 * function lgam(). 11 * function lgam(). 12 * 12 * 13 * Arguments |x| <= 34 are reduced by recurren 13 * Arguments |x| <= 34 are reduced by recurrence and the function 14 * approximated by a rational function of degr 14 * approximated by a rational function of degree 6/7 in the 15 * interval (2,3). Large arguments are handle 15 * interval (2,3). Large arguments are handled by Stirling's 16 * formula. Large negative arguments are made 16 * formula. Large negative arguments are made positive using 17 * a reflection formula. 17 * a reflection formula. 18 * 18 * 19 * 19 * 20 * ACCURACY: 20 * ACCURACY: 21 * 21 * 22 * Relative error: 22 * Relative error: 23 * arithmetic domain # trials peak 23 * arithmetic domain # trials peak rms 24 * IEEE -170,-33 20000 2.3e-1 24 * IEEE -170,-33 20000 2.3e-15 3.3e-16 25 * IEEE -33, 33 20000 9.4e-1 25 * IEEE -33, 33 20000 9.4e-16 2.2e-16 26 * IEEE 33, 171.6 20000 2.3e-1 26 * IEEE 33, 171.6 20000 2.3e-15 3.2e-16 27 * 27 * 28 * Error for arguments outside the test range 28 * Error for arguments outside the test range will be larger 29 * owing to error amplification by the exponen 29 * owing to error amplification by the exponential function. 30 * 30 * 31 */ 31 */ 32 /* lgam() 32 /* lgam() 33 * 33 * 34 * Natural logarithm of gamma function 34 * Natural logarithm of gamma function 35 * 35 * 36 * 36 * 37 * DESCRIPTION: 37 * DESCRIPTION: 38 * 38 * 39 * Returns the base e (2.718...) logarithm of 39 * Returns the base e (2.718...) logarithm of the absolute 40 * value of the gamma function of the argument 40 * value of the gamma function of the argument. 41 * The sign (+1 or -1) of the gamma function i 41 * The sign (+1 or -1) of the gamma function is returned in a 42 * global (extern) variable named sgngam. 42 * global (extern) variable named sgngam. 43 * 43 * 44 * For arguments greater than 13, the logarith 44 * For arguments greater than 13, the logarithm of the gamma 45 * function is approximated by the logarithmic 45 * function is approximated by the logarithmic version of 46 * Stirling's formula using a polynomial appro 46 * Stirling's formula using a polynomial approximation of 47 * degree 4. Arguments between -33 and +33 are 47 * degree 4. Arguments between -33 and +33 are reduced by 48 * recurrence to the interval [2,3] of a ratio 48 * recurrence to the interval [2,3] of a rational approximation. 49 * The cosecant reflection formula is employed 49 * The cosecant reflection formula is employed for arguments 50 * less than -33. 50 * less than -33. 51 * 51 * 52 * Arguments greater than MAXLGM return DBL_MA 52 * Arguments greater than MAXLGM return DBL_MAX and an error 53 * message. MAXLGM = 2.556348e305 for IEEE ar 53 * message. MAXLGM = 2.556348e305 for IEEE arithmetic. 54 * 54 * 55 * 55 * 56 * ACCURACY: 56 * ACCURACY: 57 * 57 * 58 * arithmetic domain # trials 58 * arithmetic domain # trials peak rms 59 * IEEE 0, 3 28000 5 59 * IEEE 0, 3 28000 5.4e-16 1.1e-16 60 * IEEE 2.718, 2.556e305 40000 3 60 * IEEE 2.718, 2.556e305 40000 3.5e-16 8.3e-17 61 * The error criterion was relative when the f 61 * The error criterion was relative when the function magnitude 62 * was greater than one but absolute when it w 62 * was greater than one but absolute when it was less than one. 63 * 63 * 64 * The following test used the relative error 64 * The following test used the relative error criterion, though 65 * at certain points the relative error could 65 * at certain points the relative error could be much higher than 66 * indicated. 66 * indicated. 67 * IEEE -200, -4 10000 4 67 * IEEE -200, -4 10000 4.8e-16 1.3e-16 68 * 68 * 69 */ 69 */ 70 /* gamma.c */ 70 /* gamma.c */ 71 /* gamma function */ 71 /* gamma function */ 72 72 73 /* 73 /* 74 Cephes Math Library Release 2.8: June, 2000 74 Cephes Math Library Release 2.8: June, 2000 75 Copyright 1984, 1987, 1989, 1992, 2000 by Step 75 Copyright 1984, 1987, 1989, 1992, 2000 by Stephen L. Moshier 76 */ 76 */ 77 77 78 #include "nf_specialFunctions.h" 78 #include "nf_specialFunctions.h" 79 79 80 #if defined __cplusplus 80 #if defined __cplusplus 81 #include "G4Exp.hh" 81 #include "G4Exp.hh" 82 #include "G4Log.hh" 82 #include "G4Log.hh" 83 #include "G4Pow.hh" 83 #include "G4Pow.hh" 84 namespace GIDI { 84 namespace GIDI { 85 using namespace GIDI; 85 using namespace GIDI; 86 using namespace std; 86 using namespace std; 87 #endif 87 #endif 88 88 89 static double P[] = { 1.60119522476751861407E- 89 static double P[] = { 1.60119522476751861407E-4, 1.19135147006586384913E-3, 1.04213797561761569935E-2, 4.76367800457137231464E-2, 90 2.07448227648435975150E- 90 2.07448227648435975150E-1, 4.94214826801497100753E-1, 9.99999999999999996796E-1 }; 91 static double Q[] = { -2.31581873324120129819E 91 static double Q[] = { -2.31581873324120129819E-5, 5.39605580493303397842E-4, -4.45641913851797240494E-3, 1.18139785222060435552E-2, 92 3.58236398605498653373E 92 3.58236398605498653373E-2, -2.34591795718243348568E-1, 7.14304917030273074085E-2, 1.00000000000000000320E0 }; 93 #define MAXGAM 171.624376956302725 93 #define MAXGAM 171.624376956302725 94 static double LOGPI = 1.14472988584940017414; 94 static double LOGPI = 1.14472988584940017414; 95 static double SQTPI = 2.50662827463100050242E0 95 static double SQTPI = 2.50662827463100050242E0; 96 96 97 /* Stirling's formula for the gamma function * 97 /* Stirling's formula for the gamma function */ 98 static double STIR[5] = { 7.873113957930936284 98 static double STIR[5] = { 7.873113957930936284e-4, -2.2954996161337812638e-4, -2.6813261780578123283e-3, 3.472222216054586673e-3, 8.3333333333348225713e-2 }; 99 #define MAXSTIR 143.01608 99 #define MAXSTIR 143.01608 100 100 101 static double stirf( double x, nfu_status *sta 101 static double stirf( double x, nfu_status *status ); 102 static double lgam( double x, int *sgngam, nfu 102 static double lgam( double x, int *sgngam, nfu_status *status ); 103 /* 103 /* 104 ********************************************** 104 ************************************************************ 105 */ 105 */ 106 static double stirf( double x, nfu_status * /* 106 static double stirf( double x, nfu_status * /*status*/ ) { 107 /* Gamma function computed by Stirling's formu 107 /* Gamma function computed by Stirling's formula. The polynomial STIR is valid for 33 <= x <= 172. */ 108 108 109 double y, w, v; 109 double y, w, v; 110 110 111 w = 1.0 / x; 111 w = 1.0 / x; 112 w = 1.0 + w * nf_polevl( w, STIR, 4 ); 112 w = 1.0 + w * nf_polevl( w, STIR, 4 ); 113 y = G4Exp( x ); 113 y = G4Exp( x ); 114 if( x > MAXSTIR ) { /* 114 if( x > MAXSTIR ) { /* Avoid overflow in pow() */ 115 v = G4Pow::GetInstance()->powA( x, 0.5 115 v = G4Pow::GetInstance()->powA( x, 0.5 * x - 0.25 ); 116 y = v * (v / y); } 116 y = v * (v / y); } 117 else { 117 else { 118 y = G4Pow::GetInstance()->powA( x, x - 118 y = G4Pow::GetInstance()->powA( x, x - 0.5 ) / y; 119 } 119 } 120 y = SQTPI * y * w; 120 y = SQTPI * y * w; 121 return( y ); 121 return( y ); 122 } 122 } 123 /* 123 /* 124 ********************************************** 124 ************************************************************ 125 */ 125 */ 126 double nf_gammaFunction( double x, nfu_status 126 double nf_gammaFunction( double x, nfu_status *status ) { 127 127 128 double p, q, z; 128 double p, q, z; 129 int i, sgngam = 1; 129 int i, sgngam = 1; 130 130 131 *status = nfu_badInput; 131 *status = nfu_badInput; 132 if( !isfinite( x ) ) return( x ); 132 if( !isfinite( x ) ) return( x ); 133 *status = nfu_Okay; 133 *status = nfu_Okay; 134 134 135 q = fabs( x ); 135 q = fabs( x ); 136 136 137 if( q > 33.0 ) { 137 if( q > 33.0 ) { 138 if( x < 0.0 ) { 138 if( x < 0.0 ) { 139 p = floor( q ); 139 p = floor( q ); 140 if( p == q ) goto goverf; 140 if( p == q ) goto goverf; 141 i = (int) p; 141 i = (int) p; 142 if( ( i & 1 ) == 0 ) sgngam = -1; 142 if( ( i & 1 ) == 0 ) sgngam = -1; 143 z = q - p; 143 z = q - p; 144 if( z > 0.5 ) { 144 if( z > 0.5 ) { 145 p += 1.0; 145 p += 1.0; 146 z = q - p; 146 z = q - p; 147 } 147 } 148 z = q * sin( M_PI * z ); 148 z = q * sin( M_PI * z ); 149 if( z == 0.0 ) goto goverf; 149 if( z == 0.0 ) goto goverf; 150 z = M_PI / ( fabs( z ) * stirf( q, 150 z = M_PI / ( fabs( z ) * stirf( q, status ) ); 151 } 151 } 152 else { 152 else { 153 z = stirf( x, status ); 153 z = stirf( x, status ); 154 } 154 } 155 return( sgngam * z ); 155 return( sgngam * z ); 156 } 156 } 157 157 158 z = 1.0; 158 z = 1.0; 159 while( x >= 3.0 ) { 159 while( x >= 3.0 ) { 160 x -= 1.0; 160 x -= 1.0; 161 z *= x; 161 z *= x; 162 } // Loop checking, 11.06.2015, T. Koi 162 } // Loop checking, 11.06.2015, T. Koi 163 163 164 while( x < 0.0 ) { 164 while( x < 0.0 ) { 165 if( x > -1.E-9 ) goto small; 165 if( x > -1.E-9 ) goto small; 166 z /= x; 166 z /= x; 167 x += 1.0; 167 x += 1.0; 168 } // Loop checking, 11.06.2015, T. Koi 168 } // Loop checking, 11.06.2015, T. Koi 169 169 170 while( x < 2.0 ) { 170 while( x < 2.0 ) { 171 if( x < 1.e-9 ) goto small; 171 if( x < 1.e-9 ) goto small; 172 z /= x; 172 z /= x; 173 x += 1.0; 173 x += 1.0; 174 } // Loop checking, 11.06.2015, T. Koi 174 } // Loop checking, 11.06.2015, T. Koi 175 175 176 if( x == 2.0 ) return( z ); 176 if( x == 2.0 ) return( z ); 177 177 178 x -= 2.0; 178 x -= 2.0; 179 p = nf_polevl( x, P, 6 ); 179 p = nf_polevl( x, P, 6 ); 180 q = nf_polevl( x, Q, 7 ); 180 q = nf_polevl( x, Q, 7 ); 181 return( z * p / q ); 181 return( z * p / q ); 182 182 183 small: 183 small: 184 if( x == 0.0 ) goto goverf; 184 if( x == 0.0 ) goto goverf; 185 return( z / ( ( 1.0 + 0.5772156649015329 * 185 return( z / ( ( 1.0 + 0.5772156649015329 * x ) * x ) ); 186 186 187 goverf: 187 goverf: 188 return( sgngam * DBL_MAX ); 188 return( sgngam * DBL_MAX ); 189 } 189 } 190 190 191 /* A[]: Stirling's formula expansion of log ga 191 /* A[]: Stirling's formula expansion of log gamma 192 * B[], C[]: log gamma function between 2 and 192 * B[], C[]: log gamma function between 2 and 3 193 */ 193 */ 194 static double A[] = { 8.11614167470508450300E- 194 static double A[] = { 8.11614167470508450300E-4, -5.95061904284301438324E-4, 7.93650340457716943945E-4, 195 -2.77777777730099687205E- 195 -2.77777777730099687205E-3, 8.33333333333331927722E-2 }; 196 static double B[] = { -1.37825152569120859100E 196 static double B[] = { -1.37825152569120859100E3, -3.88016315134637840924E4, -3.31612992738871184744E5, 197 -1.16237097492762307383E 197 -1.16237097492762307383E6, -1.72173700820839662146E6, -8.53555664245765465627E5 }; 198 static double C[] = { -3.51815701436523470549E 198 static double C[] = { -3.51815701436523470549E2, -1.70642106651881159223E4, -2.20528590553854454839E5, 199 -1.13933444367982507207E 199 -1.13933444367982507207E6, -2.53252307177582951285E6, -2.01889141433532773231E6 }; 200 static double LS2PI = 0.91893853320467274178 200 static double LS2PI = 0.91893853320467274178; /* log( sqrt( 2*pi ) ) */ 201 #define MAXLGM 2.556348e305 201 #define MAXLGM 2.556348e305 202 202 203 /* 203 /* 204 ********************************************** 204 ************************************************************ 205 */ 205 */ 206 double nf_logGammaFunction( double x, nfu_stat 206 double nf_logGammaFunction( double x, nfu_status *status ) { 207 /* Logarithm of gamma function */ 207 /* Logarithm of gamma function */ 208 208 209 int sgngam; 209 int sgngam; 210 210 211 *status = nfu_badInput; 211 *status = nfu_badInput; 212 if( !isfinite( x ) ) return( x ); 212 if( !isfinite( x ) ) return( x ); 213 *status = nfu_Okay; 213 *status = nfu_Okay; 214 return( lgam( x, &sgngam, status ) ); 214 return( lgam( x, &sgngam, status ) ); 215 } 215 } 216 /* 216 /* 217 ********************************************** 217 ************************************************************ 218 */ 218 */ 219 static double lgam( double x, int *sgngam, nfu 219 static double lgam( double x, int *sgngam, nfu_status *status ) { 220 220 221 double p, q, u, w, z; 221 double p, q, u, w, z; 222 int i; 222 int i; 223 223 224 *sgngam = 1; 224 *sgngam = 1; 225 225 226 if( x < -34.0 ) { 226 if( x < -34.0 ) { 227 q = -x; 227 q = -x; 228 w = lgam( q, sgngam, status ); 228 w = lgam( q, sgngam, status ); /* note this modifies *sgngam! */ 229 p = floor( q ); 229 p = floor( q ); 230 if( p == q ) goto lgsing; 230 if( p == q ) goto lgsing; 231 i = (int) p; 231 i = (int) p; 232 if( ( i & 1 ) == 0 ) { 232 if( ( i & 1 ) == 0 ) { 233 *sgngam = -1; } 233 *sgngam = -1; } 234 else { 234 else { 235 *sgngam = 1; 235 *sgngam = 1; 236 } 236 } 237 z = q - p; 237 z = q - p; 238 if( z > 0.5 ) { 238 if( z > 0.5 ) { 239 p += 1.0; 239 p += 1.0; 240 z = p - q; 240 z = p - q; 241 } 241 } 242 z = q * sin( M_PI * z ); 242 z = q * sin( M_PI * z ); 243 if( z == 0.0 ) goto lgsing; 243 if( z == 0.0 ) goto lgsing; 244 z = LOGPI - G4Log( z ) - w; 244 z = LOGPI - G4Log( z ) - w; 245 return( z ); 245 return( z ); 246 } 246 } 247 247 248 if( x < 13.0 ) { 248 if( x < 13.0 ) { 249 z = 1.0; 249 z = 1.0; 250 p = 0.0; 250 p = 0.0; 251 u = x; 251 u = x; 252 while( u >= 3.0 ) { 252 while( u >= 3.0 ) { 253 p -= 1.0; 253 p -= 1.0; 254 u = x + p; 254 u = x + p; 255 z *= u; 255 z *= u; 256 } // Loop checking, 11.06.2015, T. Koi 256 } // Loop checking, 11.06.2015, T. Koi 257 while( u < 2.0 ) { 257 while( u < 2.0 ) { 258 if( u == 0.0 ) goto lgsing; 258 if( u == 0.0 ) goto lgsing; 259 z /= u; 259 z /= u; 260 p += 1.0; 260 p += 1.0; 261 u = x + p; 261 u = x + p; 262 } // Loop checking, 11.06.2015, T. Koi 262 } // Loop checking, 11.06.2015, T. Koi 263 if( z < 0.0 ) { 263 if( z < 0.0 ) { 264 *sgngam = -1; 264 *sgngam = -1; 265 z = -z; } 265 z = -z; } 266 else { 266 else { 267 *sgngam = 1; 267 *sgngam = 1; 268 } 268 } 269 if( u == 2.0 ) return( G4Log( z ) ); 269 if( u == 2.0 ) return( G4Log( z ) ); 270 p -= 2.0; 270 p -= 2.0; 271 x = x + p; 271 x = x + p; 272 p = x * nf_polevl( x, B, 5 ) / nf_p1ev 272 p = x * nf_polevl( x, B, 5 ) / nf_p1evl( x, C, 6); 273 return( G4Log( z ) + p ); 273 return( G4Log( z ) + p ); 274 } 274 } 275 275 276 if( x > MAXLGM ) goto lgsing; 276 if( x > MAXLGM ) goto lgsing; 277 q = ( x - 0.5 ) * G4Log( x ) - x + LS2PI; 277 q = ( x - 0.5 ) * G4Log( x ) - x + LS2PI; 278 if( x > 1.0e8 ) return( q ); 278 if( x > 1.0e8 ) return( q ); 279 279 280 p = 1.0 / ( x * x ); 280 p = 1.0 / ( x * x ); 281 if( x >= 1000.0 ) { 281 if( x >= 1000.0 ) { 282 q += ( ( 7.9365079365079365079365e-4 * 282 q += ( ( 7.9365079365079365079365e-4 * p - 2.7777777777777777777778e-3 ) * p + 0.0833333333333333333333 ) / x; } 283 else { 283 else { 284 q += nf_polevl( p, A, 4 ) / x; 284 q += nf_polevl( p, A, 4 ) / x; 285 } 285 } 286 return( q ); 286 return( q ); 287 287 288 lgsing: 288 lgsing: 289 return( *sgngam * DBL_MAX ); 289 return( *sgngam * DBL_MAX ); 290 } 290 } 291 291 292 #if defined __cplusplus 292 #if defined __cplusplus 293 } 293 } 294 #endif 294 #endif 295 295