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Geant4/externals/clhep/src/flatToGaussian.cc

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Diff markup

Differences between /externals/clhep/src/flatToGaussian.cc (Version 11.3.0) and /externals/clhep/src/flatToGaussian.cc (Version 11.2.2)


  1 // -*- C++ -*-                                      1 // -*- C++ -*-
  2 //                                                  2 //
  3 // -------------------------------------------      3 // -----------------------------------------------------------------------
  4 //                             HEP Random           4 //                             HEP Random
  5 //                          --- flatToGaussian      5 //                          --- flatToGaussian ---
  6 //                      class implementation f      6 //                      class implementation file
  7 // -------------------------------------------      7 // -----------------------------------------------------------------------
  8                                                     8 
  9 // Contains the methods that depend on the 30K      9 // Contains the methods that depend on the 30K-footpring gaussTables.cdat.
 10 //                                                 10 //
 11 // flatToGaussian (double x)                       11 // flatToGaussian (double x)
 12 // inverseErf     (double x)                       12 // inverseErf     (double x)
 13 // erf      (double x)                             13 // erf      (double x)
 14                                                    14 
 15 // ===========================================     15 // =======================================================================
 16 // M Fischler   - Created 1/25/00.                 16 // M Fischler   - Created 1/25/00.
 17 //                                                 17 //
 18 // ===========================================     18 // =======================================================================
 19                                                    19 
 20 #include "CLHEP/Random/Stat.h"                     20 #include "CLHEP/Random/Stat.h"
 21 #include "CLHEP/Units/PhysicalConstants.h"         21 #include "CLHEP/Units/PhysicalConstants.h"
 22 #include <iostream>                                22 #include <iostream>
 23 #include <cmath>                                   23 #include <cmath>
 24                                                    24 
 25 namespace CLHEP {                                  25 namespace CLHEP {
 26                                                    26 
 27 double transformSmall (double r);                  27 double transformSmall (double r);
 28                                                    28 
 29 //                                                 29 //
 30 // Table of errInts, for use with transform(r)     30 // Table of errInts, for use with transform(r) and quickTransform(r)
 31 //                                                 31 //
 32                                                    32 
 33 #ifdef Traces                                      33 #ifdef Traces
 34 #define Trace1                                     34 #define Trace1
 35 #define Trace2                                     35 #define Trace2
 36 #define Trace3                                     36 #define Trace3
 37 #endif                                             37 #endif
 38                                                    38 
 39 // Since all these are this is static to this      39 // Since all these are this is static to this compilation unit only, the 
 40 // info is establised a priori and not at each     40 // info is establised a priori and not at each invocation.
 41                                                    41 
 42 // The main data is of course the gaussTables      42 // The main data is of course the gaussTables table; the rest is all 
 43 // bookkeeping to know what the tables mean.       43 // bookkeeping to know what the tables mean.
 44                                                    44 
 45 #define Table0size   200                           45 #define Table0size   200
 46 #define Table1size   250                           46 #define Table1size   250
 47 #define Table2size   200                           47 #define Table2size   200
 48 #define Table3size   250                           48 #define Table3size   250
 49 #define Table4size  1000                           49 #define Table4size  1000
 50 #define TableSize   (Table0size+Table1size+Tab     50 #define TableSize   (Table0size+Table1size+Table2size+Table3size+Table4size)
 51                                                    51 
 52 static const int Tsizes[5] =   { Table0size,       52 static const int Tsizes[5] =   { Table0size,
 53          Table1size,                               53          Table1size,
 54          Table2size,                               54          Table2size,
 55          Table3size,                               55          Table3size,
 56          Table4size };                             56          Table4size };
 57                                                    57 
 58 #define Table0step  (2.0E-13)                      58 #define Table0step  (2.0E-13)
 59 #define Table1step  (4.0E-11)                      59 #define Table1step  (4.0E-11)  
 60 #define Table2step  (1.0E-8)                       60 #define Table2step  (1.0E-8) 
 61 #define Table3step  (2.0E-6)                       61 #define Table3step  (2.0E-6) 
 62 #define Table4step  (5.0E-4)                       62 #define Table4step  (5.0E-4)
 63                                                    63 
 64 static const double Tsteps[5] = { Table0step,      64 static const double Tsteps[5] = { Table0step,
 65          Table1step,                               65          Table1step,
 66          Table2step,                               66          Table2step,
 67          Table3step,                               67          Table3step,
 68          Table4step };                             68          Table4step };
 69                                                    69 
 70 #define Table0offset 0                             70 #define Table0offset 0
 71 #define Table1offset (2*(Table0size))              71 #define Table1offset (2*(Table0size))
 72 #define Table2offset (2*(Table0size + Table1si     72 #define Table2offset (2*(Table0size + Table1size))
 73 #define Table3offset (2*(Table0size + Table1si     73 #define Table3offset (2*(Table0size + Table1size + Table2size))
 74 #define Table4offset (2*(Table0size + Table1si     74 #define Table4offset (2*(Table0size + Table1size + Table2size + Table3size))
 75                                                    75 
 76 static const int Toffsets[5] = { Table0offset,     76 static const int Toffsets[5] = { Table0offset,
 77          Table1offset,                             77          Table1offset,
 78          Table2offset,                             78          Table2offset,
 79          Table3offset,                             79          Table3offset,
 80          Table4offset };                           80          Table4offset };
 81                                                    81 
 82   // Here comes the big (30K bytes) table, kep     82   // Here comes the big (30K bytes) table, kept in a file ---
 83                                                    83 
 84 static const double gaussTables [2*TableSize]      84 static const double gaussTables [2*TableSize] = {
 85 #include "CLHEP/Random/gaussTables.cdat"           85 #include "CLHEP/Random/gaussTables.cdat"
 86 };                                                 86 };
 87                                                    87 
 88 double HepStat::flatToGaussian (double r) {        88 double HepStat::flatToGaussian (double r) {
 89                                                    89 
 90   double sign = +1.0; // We always compute a n     90   double sign = +1.0; // We always compute a negative number of 
 91         // sigmas.  For r > 0 we will multiply     91         // sigmas.  For r > 0 we will multiply by
 92         // sign = -1 to return a positive numb     92         // sign = -1 to return a positive number.
 93 #ifdef Trace1                                      93 #ifdef Trace1
 94 std::cout << "r = " << r << "\n";                  94 std::cout << "r = " << r << "\n";
 95 #endif                                             95 #endif
 96                                                    96 
 97   if ( r > .5 ) {                                  97   if ( r > .5 ) {
 98     r = 1-r;                                       98     r = 1-r;
 99     sign = -1.0;                                   99     sign = -1.0;
100 #ifdef Trace1                                     100 #ifdef Trace1
101 std::cout << "r = " << r << "sign negative \n"    101 std::cout << "r = " << r << "sign negative \n";
102 #endif                                            102 #endif
103   } else if ( r == .5 ) {                         103   } else if ( r == .5 ) {
104     return 0.0;                                   104     return 0.0;
105   }                                               105   }  
106                                                   106 
107   // Find a pointer to the proper table entrie    107   // Find a pointer to the proper table entries, along with the fraction 
108   // of the way in the relevant bin dx and the    108   // of the way in the relevant bin dx and the bin size h.
109                                                   109   
110   // Optimize for the case of table 4 by testi    110   // Optimize for the case of table 4 by testing for that first.  
111   // By removing that case from the for loop b    111   // By removing that case from the for loop below, we save not only
112   // several table lookups, but also several i    112   // several table lookups, but also several index calculations that
113   // now become (compile-time) constants.         113   // now become (compile-time) constants.
114   //                                              114   //
115   // Past the case of table 4, we need not be     115   // Past the case of table 4, we need not be as concerned about speed since
116   // this will happen only .1% of the time.       116   // this will happen only .1% of the time.
117                                                   117 
118   const double* tptr = 0;                         118   const double* tptr = 0;
119   double  dx = 0;                                 119   double  dx = 0;
120   double  h = 0;                                  120   double  h = 0;
121                                                   121 
122   // The following big if block will locate tp    122   // The following big if block will locate tptr, h, and dx from whichever
123   // table is applicable:                         123   // table is applicable:
124                                                   124 
125   int index;                                      125   int index;
126                                                   126 
127   if ( r >= Table4step ) {                        127   if ( r >= Table4step ) {
128                                                   128 
129     index = int((Table4size<<1) * r); // 1 to     129     index = int((Table4size<<1) * r); // 1 to Table4size-1 
130     if (index <= 0) index = 1;      // in case    130     if (index <= 0) index = 1;      // in case of rounding problem
131     if (index >= Table4size) index = Table4siz    131     if (index >= Table4size) index = Table4size-1;
132     dx = (Table4size<<1) * r - index;     // f    132     dx = (Table4size<<1) * r - index;     // fraction of way to next bin
133     h = Table4step;                               133     h = Table4step;
134 #ifdef Trace2                                     134 #ifdef Trace2 
135 std::cout << "index = " << index << " dx = " <    135 std::cout << "index = " << index << " dx = " << dx << " h = " << h << "\n";
136 #endif                                            136 #endif
137     index = (index<<1) + (Table4offset-2);        137     index = (index<<1) + (Table4offset-2);  
138   // at r = table4step+eps, index refers to th    138   // at r = table4step+eps, index refers to the start of table 4 
139   // and at r = .5 - eps, index refers to the     139   // and at r = .5 - eps, index refers to the next-to-last entry:
140   // remember, the table has two numbers per a    140   // remember, the table has two numbers per actual entry.
141 #ifdef Trace2                                     141 #ifdef Trace2 
142 std::cout << "offset index = " << index << "\n    142 std::cout << "offset index = " << index << "\n";
143 #endif                                            143 #endif
144                                                   144 
145     tptr = &gaussTables [index];                  145     tptr = &gaussTables [index];
146                                                   146     
147   } else if (r < Tsteps[0])  {                    147   } else if (r < Tsteps[0])  {
148                                                   148 
149     // If r is so small none of the tables app    149     // If r is so small none of the tables apply, use the asymptotic formula.
150     return (sign * transformSmall (r));           150     return (sign * transformSmall (r));
151                                                   151 
152   } else {                                        152   } else {
153                                                   153     
154     for ( int tableN = 3; tableN >= 0; tableN-    154     for ( int tableN = 3; tableN >= 0; tableN-- ) {
155       if ( r < Tsteps[tableN] ) {continue;}       155       if ( r < Tsteps[tableN] ) {continue;}   // can't happen when tableN==0
156 #ifdef Trace2                                     156 #ifdef Trace2 
157 std::cout << "Using table " << tableN << "\n";    157 std::cout << "Using table " << tableN << "\n";
158 #endif                                            158 #endif
159       double step = Tsteps[tableN];               159       double step = Tsteps[tableN];
160       index = int(r/step);      // 1 to TableN    160       index = int(r/step);      // 1 to TableNsize-1 
161         // The following two tests should prob    161         // The following two tests should probably never be true, but
162         // roundoff might cause index to be ou    162         // roundoff might cause index to be outside its proper range.
163         // In such a case, the interpolation s    163         // In such a case, the interpolation still makes sense, but we
164         // need to take care that tptr points     164         // need to take care that tptr points to valid data in the right table.
165       if (index == 0) index = 1;                  165       if (index == 0) index = 1;      
166       if (index >= Tsizes[tableN]) index = Tsi    166       if (index >= Tsizes[tableN]) index = Tsizes[tableN] - 1;
167       dx =  r/step - index;       // fraction     167       dx =  r/step - index;       // fraction of way to next bin
168       h  =  step;                                 168       h  =  step;
169 #ifdef Trace2                                     169 #ifdef Trace2 
170 std::cout << "index = " << index << " dx = " <    170 std::cout << "index = " << index << " dx = " << dx << " h = " << h << "\n";
171 #endif                                            171 #endif
172       index = (index<<1) + Toffsets[tableN] -     172       index = (index<<1) + Toffsets[tableN] - 2;
173       tptr = &gaussTables [index];                173       tptr = &gaussTables [index];
174       break;                                      174       break;
175     } // end of the for loop which finds tptr,    175     } // end of the for loop which finds tptr, dx and h in one of the tables
176                                                   176 
177     // The code can only get to here by a brea    177     // The code can only get to here by a break statement, having set dx etc.
178     // It not get to here without going throug    178     // It not get to here without going through one of the breaks,
179     // because before the for loop we test for    179     // because before the for loop we test for the case of r < Tsteps[0].
180                                                   180 
181   } // End of the big if block.                   181   } // End of the big if block.
182                                                   182 
183   // At the end of this if block, we have tptr    183   // At the end of this if block, we have tptr, dx and h -- and if r is less 
184   // than the smallest step, we have already r    184   // than the smallest step, we have already returned the proper answer.  
185                                                   185 
186   double  y0 = *tptr++;                           186   double  y0 = *tptr++;
187   double  d0 = *tptr++;                           187   double  d0 = *tptr++;
188   double  y1 = *tptr++;                           188   double  y1 = *tptr++;
189   double  d1 = *tptr;                             189   double  d1 = *tptr;
190                                                   190 
191 #ifdef Trace3                                     191 #ifdef Trace3
192 std::cout << "y0: " << y0 << " y1: " << y1 <<     192 std::cout << "y0: " << y0 << " y1: " << y1 << " d0: " << d0 << " d1: " << d1 << "\n";
193 #endif                                            193 #endif
194                                                   194 
195   double  x2 = dx * dx;                           195   double  x2 = dx * dx;
196   double  oneMinusX = 1 - dx;                     196   double  oneMinusX = 1 - dx;
197   double  oneMinusX2 = oneMinusX * oneMinusX;     197   double  oneMinusX2 = oneMinusX * oneMinusX;
198                                                   198 
199   double  f0 = (2. * dx + 1.) * oneMinusX2;       199   double  f0 = (2. * dx + 1.) * oneMinusX2;
200   double  f1 = (3. - 2. * dx) * x2;               200   double  f1 = (3. - 2. * dx) * x2;
201   double  g0 =  h * dx * oneMinusX2;              201   double  g0 =  h * dx * oneMinusX2;
202   double  g1 =  - h * oneMinusX * x2;             202   double  g1 =  - h * oneMinusX * x2;
203                                                   203 
204 #ifdef Trace3                                     204 #ifdef Trace3
205 std::cout << "f0: " << f0 << " f1: " << f1 <<     205 std::cout << "f0: " << f0 << " f1: " << f1 << " g0: " << g0 << " g1: " << g1 << "\n";
206 #endif                                            206 #endif
207                                                   207 
208   double answer = f0 * y0 + f1 * y1 + g0 * d0     208   double answer = f0 * y0 + f1 * y1 + g0 * d0 + g1 * d1;
209                                                   209 
210 #ifdef Trace1                                     210 #ifdef Trace1
211 std::cout << "variate is: " << sign*answer <<     211 std::cout << "variate is: " << sign*answer << "\n";
212 #endif                                            212 #endif
213                                                   213 
214   return sign * answer;                           214   return sign * answer;
215                                                   215 
216 } // flatToGaussian                               216 } // flatToGaussian
217                                                   217 
218 double transformSmall (double r) {                218 double transformSmall (double r) {
219                                                   219 
220   // Solve for -v in the asymtotic formula        220   // Solve for -v in the asymtotic formula 
221   //                                              221   //
222   // errInt (-v) =  exp(-v*v/2)         1         222   // errInt (-v) =  exp(-v*v/2)         1     1*3    1*3*5
223   //       ------------ * (1 - ---- + ---- - -    223   //       ------------ * (1 - ---- + ---- - ----- + ... )
224   //       v*sqrt(2*pi)        v**2   v**4   v    224   //       v*sqrt(2*pi)        v**2   v**4   v**6
225                                                   225 
226   // The value of r (=errInt(-v)) supplied is     226   // The value of r (=errInt(-v)) supplied is going to less than 2.0E-13,
227   // which is such that v < -7.25.  Since the     227   // which is such that v < -7.25.  Since the value of r is meaningful only
228   // to an absolute error of 1E-16 (double pre    228   // to an absolute error of 1E-16 (double precision accuracy for a number 
229   // which on the high side could be of the fo    229   // which on the high side could be of the form 1-epsilon), computing
230   // v to more than 3-4 digits of accuracy is     230   // v to more than 3-4 digits of accuracy is suspect; however, to ensure 
231   // smoothness with the table generator (whic    231   // smoothness with the table generator (which uses quite a few terms) we
232   // also use terms up to 1*3*5* ... *13/v**14    232   // also use terms up to 1*3*5* ... *13/v**14, and insist on accuracy of
233   // solution at the level of 1.0e-7.             233   // solution at the level of 1.0e-7.
234                                                   234 
235   // This routine is called less than one time    235   // This routine is called less than one time in a trillion firings, so
236   // speed is of no concern.  As a matter of t    236   // speed is of no concern.  As a matter of technique, we terminate the
237   // iterations in case they would be infinite    237   // iterations in case they would be infinite, but this should not happen.
238                                                   238 
239   double eps = 1.0e-7;                            239   double eps = 1.0e-7;
240   double guess = 7.5;                             240   double guess = 7.5;
241   double v;                                       241   double v;
242                                                   242   
243   for ( int i = 1; i < 50; i++ ) {                243   for ( int i = 1; i < 50; i++ ) {
244     double vn2 = 1.0/(guess*guess);               244     double vn2 = 1.0/(guess*guess);
245     double s1 = -13*11*9*7*5*3 * vn2*vn2*vn2*v    245     double s1 = -13*11*9*7*5*3 * vn2*vn2*vn2*vn2*vn2*vn2*vn2;
246             s1 +=    11*9*7*5*3 * vn2*vn2*vn2*    246             s1 +=    11*9*7*5*3 * vn2*vn2*vn2*vn2*vn2*vn2;
247             s1 +=      -9*7*5*3 * vn2*vn2*vn2*    247             s1 +=      -9*7*5*3 * vn2*vn2*vn2*vn2*vn2;
248             s1 +=         7*5*3 * vn2*vn2*vn2*    248             s1 +=         7*5*3 * vn2*vn2*vn2*vn2;
249             s1 +=          -5*3 * vn2*vn2*vn2;    249             s1 +=          -5*3 * vn2*vn2*vn2;
250             s1 +=            3 * vn2*vn2    -     250             s1 +=            3 * vn2*vn2    - vn2  +    1.0;
251     v = std::sqrt ( 2.0 * std::log ( s1 / (r*g    251     v = std::sqrt ( 2.0 * std::log ( s1 / (r*guess*std::sqrt(CLHEP::twopi)) ) );
252     if ( std::abs(v-guess) < eps ) break;         252     if ( std::abs(v-guess) < eps ) break;
253     guess = v;                                    253     guess = v;
254   }                                               254   }
255                                                   255  
256   return -v;                                      256   return -v;
257                                                   257 
258 } // transformSmall()                             258 } // transformSmall()
259                                                   259 
260 double HepStat::inverseErf (double t) {           260 double HepStat::inverseErf (double t) {
261                                                   261 
262   // This uses erf(x) = 2*gaussCDF(sqrt(2)*x)     262   // This uses erf(x) = 2*gaussCDF(sqrt(2)*x) - 1
263                                                   263 
264   return std::sqrt(0.5) * flatToGaussian(.5*(t    264   return std::sqrt(0.5) * flatToGaussian(.5*(t+1));
265                                                   265 
266 }                                                 266 }
267                                                   267 
268 double HepStat::erf (double x) {                  268 double HepStat::erf (double x) {
269                                                   269 
270 // Math:                                          270 // Math:
271 //                                                271 //
272 // For any given x we can "quickly" find t0 =     272 // For any given x we can "quickly" find t0 = erfQ (x) = erf(x) + epsilon.
273 //                                                273 //
274 // Then we can find x1 = inverseErf (t0) = inv    274 // Then we can find x1 = inverseErf (t0) = inverseErf (erf(x)+epsilon)
275 //                                                275 //
276 // Expanding in the small epsion,                 276 // Expanding in the small epsion, 
277 //                                                277 // 
278 //  x1 = x + epsilon * [deriv(inverseErf(u),u)    278 //  x1 = x + epsilon * [deriv(inverseErf(u),u) at u = t0] + O(epsilon**2)
279 //                                                279 //
280 // so epsilon is (x1-x) / [deriv(inverseErf(u)    280 // so epsilon is (x1-x) / [deriv(inverseErf(u),u) at u = t0] + O(epsilon**2)
281 //                                                281 //
282 // But the derivative of an inverse function i    282 // But the derivative of an inverse function is one over the derivative of the
283 // function, so                                   283 // function, so 
284 // epsilon  = (x1-x) * [deriv(erf(v),v) at v =    284 // epsilon  = (x1-x) * [deriv(erf(v),v) at v = x] + O(epsilon**2)
285 //                                                285 //
286 // And the definition of the erf integral make    286 // And the definition of the erf integral makes that derivative trivial.
287 // Ultimately,                                    287 // Ultimately,
288 //                                                288 //
289 // erf(x) = erfQ(x) - (inverseErf(erfQ(x))-x)     289 // erf(x) = erfQ(x) - (inverseErf(erfQ(x))-x) * exp(-x**2) * 2/sqrt(CLHEP::pi)
290 //                                                290 //
291                                                   291 
292   double t0 = erfQ(x);                            292   double t0 = erfQ(x);
293   double deriv = std::exp(-x*x) * (2.0 / std::    293   double deriv = std::exp(-x*x) * (2.0 / std::sqrt(CLHEP::pi));
294                                                   294 
295   return t0 - (inverseErf (t0) - x) * deriv;      295   return t0 - (inverseErf (t0) - x) * deriv;
296                                                   296 
297 }                                                 297 }
298                                                   298 
299                                                   299 
300 }  // namespace CLHEP                             300 }  // namespace CLHEP
301                                                   301 
302                                                   302