/* naurng.c * This is thread-safe version of rng.c if thread-local support * is available. * This file contains the code for a high-quality random number generator written by Don Knuth. The auxilliary routine ran_arr_cycle() has been modified slightly, and ran_init() is new. To use it: 0. #include "naurng.h" (or "naututil.h" if you are using nauty) 1. Call ran_init(seed), where seed is any long integer. This step is optional, but if you don't use it you will always get the same sequence of random numbers. 2. For each random number, use the NEXTRAN macro. It will give a random value in the range 0..2^30-1. Alternatively, KRAN(k) will have a random value in the range 0..k-1. KRAN(k) actually gives you NEXTRAN mod k, so it is not totally uniform if k is very large. In that case, you can use the slightly slower GETKRAN(k,var) to set the variable var to a better random number from 0..k-1. Brendan McKay, July 2002. Fixed Nov 2002 on advice of DEK. */ /* This program by D E Knuth is in the public domain and freely copyable * AS LONG AS YOU MAKE ABSOLUTELY NO CHANGES! * It is explained in Seminumerical Algorithms, 3rd edition, Section 3.6 * (or in the errata to the 2nd edition --- see * http://www-cs-faculty.stanford.edu/~knuth/taocp.html * in the changes to Volume 2 on pages 171 and following). */ /* N.B. The MODIFICATIONS introduced in the 9th printing (2002) are included here; there's no backwards compatibility with the original. */ /* If you find any bugs, please report them immediately to * taocp@cs.stanford.edu * (and you will be rewarded if the bug is genuine). Thanks! */ /************ see the book for explanations and caveats! *******************/ /************ in particular, you need two's complement arithmetic **********/ #include "naurng.h" #define KK 100 /* the long lag */ #define LL 37 /* the short lag */ #define MM (1L<<30) /* the modulus */ #define mod_diff(x,y) (((x)-(y))&(MM-1)) /* subtraction mod MM */ static TLS_ATTR long ran_x[KK]; /* the generator state */ static void ran_array(long aa[],int n) { int i,j; for (j=0;j=MM) ss-=MM-2; /* cyclic shift 29 bits */ } x[1]++; /* make x[1] (and only x[1]) odd */ for (ss=seed&(MM-1),t=TT-1; t; ) { for (j=KK-1;j>0;j--) x[j+j]=x[j], x[j+j-1]=0; /* "square" */ for (j=KK+KK-2;j>=KK;j--) x[j-(KK-LL)]=mod_diff(x[j-(KK-LL)],x[j]), x[j-KK]=mod_diff(x[j-KK],x[j]); if (is_odd(ss)) { /* "multiply by z" */ for (j=KK;j>0;j--) x[j]=x[j-1]; x[0]=x[KK]; /* shift the buffer cyclically */ x[LL]=mod_diff(x[LL],x[KK]); } if (ss) ss>>=1; else t--; } for (j=0;j=0 ? *ran_arr_ptr++ : ran_arr_cycle()); }