glib/glib/grand.c - nest-cam/4320010/glib - Git at Google

 /* GLIB - Library of useful routines for C programming
  * Copyright (C) 1995-1997  Peter Mattis, Spencer Kimball and Josh MacDonald
  *
  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Lesser General Public
  * License as published by the Free Software Foundation; either
  * version 2 of the License, or (at your option) any later version.
  *
  * This library is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  * Lesser General Public License for more details.
  *
  * You should have received a copy of the GNU Lesser General Public
  * License along with this library; if not, see <http://www.gnu.org/licenses/>.
  */

 /* Originally developed and coded by Makoto Matsumoto and Takuji
  * Nishimura.  Please mail <matumoto@math.keio.ac.jp>, if you're using
  * code from this file in your own programs or libraries.
  * Further information on the Mersenne Twister can be found at
  * http://www.math.sci.hiroshima-u.ac.jp/~m-mat/MT/emt.html
  * This code was adapted to glib by Sebastian Wilhelmi.
  */

 /*
  * Modified by the GLib Team and others 1997-2000.  See the AUTHORS
  * file for a list of people on the GLib Team.  See the ChangeLog
  * files for a list of changes.  These files are distributed with
  * GLib at ftp://ftp.gtk.org/pub/gtk/.
  */

 /*
  * MT safe
  */

 #include "config.h"
 #define _CRT_RAND_S

 #include <math.h>
 #include <errno.h>
 #include <stdio.h>
 #include <string.h>
 #include <sys/types.h>
 #include "grand.h"

 #include "genviron.h"
 #include "gmain.h"
 #include "gmem.h"
 #include "gtestutils.h"
 #include "gthread.h"

 #ifdef G_OS_UNIX
 #include <unistd.h>
 #endif

 #ifdef G_OS_WIN32
 #include <stdlib.h>
 #include <process.h> /* For getpid() */
 #endif

 /**
  * SECTION:random_numbers
  * @title: Random Numbers
  * @short_description: pseudo-random number generator
  *
  * The following functions allow you to use a portable, fast and good
  * pseudo-random number generator (PRNG).
  *
  * Do not use this API for cryptographic purposes such as key
  * generation, nonces, salts or one-time pads.
  *
  * This PRNG is suitable for non-cryptographic use such as in games
  * (shuffling a card deck, generating levels), generating data for
  * a test suite, etc. If you need random data for cryptographic
  * purposes, it is recommended to use platform-specific APIs such
  * as `/dev/random` on UNIX, or CryptGenRandom() on Windows.
  *
  * GRand uses the Mersenne Twister PRNG, which was originally
  * developed by Makoto Matsumoto and Takuji Nishimura. Further
  * information can be found at
  * [this page](http://www.math.sci.hiroshima-u.ac.jp/~m-mat/MT/emt.html).
  *
  * If you just need a random number, you simply call the g_random_*
  * functions, which will create a globally used #GRand and use the
  * according g_rand_* functions internally. Whenever you need a
  * stream of reproducible random numbers, you better create a
  * #GRand yourself and use the g_rand_* functions directly, which
  * will also be slightly faster. Initializing a #GRand with a
  * certain seed will produce exactly the same series of random
  * numbers on all platforms. This can thus be used as a seed for
  * e.g. games.
  *
  * The g_rand*_range functions will return high quality equally
  * distributed random numbers, whereas for example the
  * `(g_random_int()%max)` approach often
  * doesn't yield equally distributed numbers.
  *
  * GLib changed the seeding algorithm for the pseudo-random number
  * generator Mersenne Twister, as used by #GRand. This was necessary,
  * because some seeds would yield very bad pseudo-random streams.
  * Also the pseudo-random integers generated by g_rand*_int_range()
  * will have a slightly better equal distribution with the new
  * version of GLib.
  *
  * The original seeding and generation algorithms, as found in
  * GLib 2.0.x, can be used instead of the new ones by setting the
  * environment variable `G_RANDOM_VERSION` to the value of '2.0'.
  * Use the GLib-2.0 algorithms only if you have sequences of numbers
  * generated with Glib-2.0 that you need to reproduce exactly.
  */

 /**
  * GRand:
  *
  * The GRand struct is an opaque data structure. It should only be
  * accessed through the g_rand_* functions.
  **/

 G_LOCK_DEFINE_STATIC (global_random);

 /* Period parameters */
 #define N 624
 #define M 397
 #define MATRIX_A 0x9908b0df   /* constant vector a */
 #define UPPER_MASK 0x80000000 /* most significant w-r bits */
 #define LOWER_MASK 0x7fffffff /* least significant r bits */

 /* Tempering parameters */
 #define TEMPERING_MASK_B 0x9d2c5680
 #define TEMPERING_MASK_C 0xefc60000
 #define TEMPERING_SHIFT_U(y)  (y >> 11)
 #define TEMPERING_SHIFT_S(y)  (y << 7)
 #define TEMPERING_SHIFT_T(y)  (y << 15)
 #define TEMPERING_SHIFT_L(y)  (y >> 18)

 static guint
 get_random_version (void)
 {
   static gsize initialized = FALSE;
   static guint random_version;

   if (g_once_init_enter (&initialized))
     {
       const gchar *version_string = g_getenv ("G_RANDOM_VERSION");
       if (!version_string || version_string[0] == '\000' ||
 	  strcmp (version_string, "2.2") == 0)
 	random_version = 22;
       else if (strcmp (version_string, "2.0") == 0)
 	random_version = 20;
       else
 	{
 	  g_warning ("Unknown G_RANDOM_VERSION \"%s\". Using version 2.2.",
 		     version_string);
 	  random_version = 22;
 	}
       g_once_init_leave (&initialized, TRUE);
     }

   return random_version;
 }

 struct _GRand
 {
   guint32 mt[N]; /* the array for the state vector  */
   guint mti;
 };

 /**
  * g_rand_new_with_seed:
  * @seed: a value to initialize the random number generator
  *
  * Creates a new random number generator initialized with @seed.
  *
  * Returns: the new #GRand
  **/
 GRand*
 g_rand_new_with_seed (guint32 seed)
 {
   GRand *rand = g_new0 (GRand, 1);
   g_rand_set_seed (rand, seed);
   return rand;
 }

 /**
  * g_rand_new_with_seed_array:
  * @seed: an array of seeds to initialize the random number generator
  * @seed_length: an array of seeds to initialize the random number
  *     generator
  *
  * Creates a new random number generator initialized with @seed.
  *
  * Returns: the new #GRand
  *
  * Since: 2.4
  */
 GRand*
 g_rand_new_with_seed_array (const guint32 *seed,
                             guint          seed_length)
 {
   GRand *rand = g_new0 (GRand, 1);
   g_rand_set_seed_array (rand, seed, seed_length);
   return rand;
 }

 /**
  * g_rand_new:
  *
  * Creates a new random number generator initialized with a seed taken
  * either from `/dev/urandom` (if existing) or from the current time
  * (as a fallback).
  *
  * On Windows, the seed is taken from rand_s().
  *
  * Returns: the new #GRand
  */
 GRand*
 g_rand_new (void)
 {
   guint32 seed[4];
 #ifdef G_OS_UNIX
   static gboolean dev_urandom_exists = TRUE;
   GTimeVal now;

   if (dev_urandom_exists)
     {
       FILE* dev_urandom;

       do
 	{
 	  dev_urandom = fopen("/dev/urandom", "rb");
 	}
       while G_UNLIKELY (dev_urandom == NULL && errno == EINTR);

       if (dev_urandom)
 	{
 	  int r;

 	  setvbuf (dev_urandom, NULL, _IONBF, 0);
 	  do
 	    {
 	      errno = 0;
 	      r = fread (seed, sizeof (seed), 1, dev_urandom);
 	    }
 	  while G_UNLIKELY (errno == EINTR);

 	  if (r != 1)
 	    dev_urandom_exists = FALSE;

 	  fclose (dev_urandom);
 	}
       else
 	dev_urandom_exists = FALSE;
     }

   if (!dev_urandom_exists)
     {
       g_get_current_time (&now);
       seed[0] = now.tv_sec;
       seed[1] = now.tv_usec;
       seed[2] = getpid ();
       seed[3] = getppid ();
     }
 #else /* G_OS_WIN32 */
   /* rand_s() is only available since Visual Studio 2005 and
    * MinGW-w64 has a wrapper that will emulate rand_s() if it's not in msvcrt
    */
 #if (defined(_MSC_VER) && _MSC_VER >= 1400) || defined(__MINGW64_VERSION_MAJOR)
   gint i;

   for (i = 0; i < G_N_ELEMENTS (seed); i++)
     rand_s (&seed[i]);
 #else
 #warning Using insecure seed for random number generation because of missing rand_s() in Windows XP
   GTimeVal now;

   g_get_current_time (&now);
   seed[0] = now.tv_sec;
   seed[1] = now.tv_usec;
   seed[2] = getpid ();
   seed[3] = 0;
 #endif

 #endif

   return g_rand_new_with_seed_array (seed, 4);
 }

 /**
  * g_rand_free:
  * @rand_: a #GRand
  *
  * Frees the memory allocated for the #GRand.
  */
 void
 g_rand_free (GRand *rand)
 {
   g_return_if_fail (rand != NULL);

   g_free (rand);
 }

 /**
  * g_rand_copy:
  * @rand_: a #GRand
  *
  * Copies a #GRand into a new one with the same exact state as before.
  * This way you can take a snapshot of the random number generator for
  * replaying later.
  *
  * Returns: the new #GRand
  *
  * Since: 2.4
  */
 GRand*
 g_rand_copy (GRand *rand)
 {
   GRand* new_rand;

   g_return_val_if_fail (rand != NULL, NULL);

   new_rand = g_new0 (GRand, 1);
   memcpy (new_rand, rand, sizeof (GRand));

   return new_rand;
 }

 /**
  * g_rand_set_seed:
  * @rand_: a #GRand
  * @seed: a value to reinitialize the random number generator
  *
  * Sets the seed for the random number generator #GRand to @seed.
  */
 void
 g_rand_set_seed (GRand   *rand,
                  guint32  seed)
 {
   g_return_if_fail (rand != NULL);

   switch (get_random_version ())
     {
     case 20:
       /* setting initial seeds to mt[N] using         */
       /* the generator Line 25 of Table 1 in          */
       /* [KNUTH 1981, The Art of Computer Programming */
       /*    Vol. 2 (2nd Ed.), pp102]                  */

       if (seed == 0) /* This would make the PRNG produce only zeros */
 	seed = 0x6b842128; /* Just set it to another number */

       rand->mt[0]= seed;
       for (rand->mti=1; rand->mti<N; rand->mti++)
 	rand->mt[rand->mti] = (69069 * rand->mt[rand->mti-1]);

       break;
     case 22:
       /* See Knuth TAOCP Vol2. 3rd Ed. P.106 for multiplier. */
       /* In the previous version (see above), MSBs of the    */
       /* seed affect only MSBs of the array mt[].            */

       rand->mt[0]= seed;
       for (rand->mti=1; rand->mti<N; rand->mti++)
 	rand->mt[rand->mti] = 1812433253UL *
 	  (rand->mt[rand->mti-1] ^ (rand->mt[rand->mti-1] >> 30)) + rand->mti;
       break;
     default:
       g_assert_not_reached ();
     }
 }

 /**
  * g_rand_set_seed_array:
  * @rand_: a #GRand
  * @seed: array to initialize with
  * @seed_length: length of array
  *
  * Initializes the random number generator by an array of longs.
  * Array can be of arbitrary size, though only the first 624 values
  * are taken.  This function is useful if you have many low entropy
  * seeds, or if you require more then 32 bits of actual entropy for
  * your application.
  *
  * Since: 2.4
  */
 void
 g_rand_set_seed_array (GRand         *rand,
                        const guint32 *seed,
                        guint          seed_length)
 {
   int i, j, k;

   g_return_if_fail (rand != NULL);
   g_return_if_fail (seed_length >= 1);

   g_rand_set_seed (rand, 19650218UL);

   i=1; j=0;
   k = (N>seed_length ? N : seed_length);
   for (; k; k--)
     {
       rand->mt[i] = (rand->mt[i] ^
 		     ((rand->mt[i-1] ^ (rand->mt[i-1] >> 30)) * 1664525UL))
 	      + seed[j] + j; /* non linear */
       rand->mt[i] &= 0xffffffffUL; /* for WORDSIZE > 32 machines */
       i++; j++;
       if (i>=N)
         {
 	  rand->mt[0] = rand->mt[N-1];
 	  i=1;
 	}
       if (j>=seed_length)
 	j=0;
     }
   for (k=N-1; k; k--)
     {
       rand->mt[i] = (rand->mt[i] ^
 		     ((rand->mt[i-1] ^ (rand->mt[i-1] >> 30)) * 1566083941UL))
 	      - i; /* non linear */
       rand->mt[i] &= 0xffffffffUL; /* for WORDSIZE > 32 machines */
       i++;
       if (i>=N)
         {
 	  rand->mt[0] = rand->mt[N-1];
 	  i=1;
 	}
     }

   rand->mt[0] = 0x80000000UL; /* MSB is 1; assuring non-zero initial array */
 }

 /**
  * g_rand_boolean:
  * @rand_: a #GRand
  *
  * Returns a random #gboolean from @rand_.
  * This corresponds to a unbiased coin toss.
  *
  * Returns: a random #gboolean
  */
 /**
  * g_rand_int:
  * @rand_: a #GRand
  *
  * Returns the next random #guint32 from @rand_ equally distributed over
  * the range [0..2^32-1].
  *
  * Returns: a random number
  */
 guint32
 g_rand_int (GRand *rand)
 {
   guint32 y;
   static const guint32 mag01[2]={0x0, MATRIX_A};
   /* mag01[x] = x * MATRIX_A  for x=0,1 */

   g_return_val_if_fail (rand != NULL, 0);

   if (rand->mti >= N) { /* generate N words at one time */
     int kk;

     for (kk = 0; kk < N - M; kk++) {
       y = (rand->mt[kk]&UPPER_MASK)|(rand->mt[kk+1]&LOWER_MASK);
       rand->mt[kk] = rand->mt[kk+M] ^ (y >> 1) ^ mag01[y & 0x1];
     }
     for (; kk < N - 1; kk++) {
       y = (rand->mt[kk]&UPPER_MASK)|(rand->mt[kk+1]&LOWER_MASK);
       rand->mt[kk] = rand->mt[kk+(M-N)] ^ (y >> 1) ^ mag01[y & 0x1];
     }
     y = (rand->mt[N-1]&UPPER_MASK)|(rand->mt[0]&LOWER_MASK);
     rand->mt[N-1] = rand->mt[M-1] ^ (y >> 1) ^ mag01[y & 0x1];

     rand->mti = 0;
   }

   y = rand->mt[rand->mti++];
   y ^= TEMPERING_SHIFT_U(y);
   y ^= TEMPERING_SHIFT_S(y) & TEMPERING_MASK_B;
   y ^= TEMPERING_SHIFT_T(y) & TEMPERING_MASK_C;
   y ^= TEMPERING_SHIFT_L(y);

   return y;
 }

 /* transform [0..2^32] -> [0..1] */
 #define G_RAND_DOUBLE_TRANSFORM 2.3283064365386962890625e-10

 /**
  * g_rand_int_range:
  * @rand_: a #GRand
  * @begin: lower closed bound of the interval
  * @end: upper open bound of the interval
  *
  * Returns the next random #gint32 from @rand_ equally distributed over
  * the range [@begin..@end-1].
  *
  * Returns: a random number
  */
 gint32
 g_rand_int_range (GRand  *rand,
                   gint32  begin,
                   gint32  end)
 {
   guint32 dist = end - begin;
   guint32 random;

   g_return_val_if_fail (rand != NULL, begin);
   g_return_val_if_fail (end > begin, begin);

   switch (get_random_version ())
     {
     case 20:
       if (dist <= 0x10000L) /* 2^16 */
 	{
 	  /* This method, which only calls g_rand_int once is only good
 	   * for (end - begin) <= 2^16, because we only have 32 bits set
 	   * from the one call to g_rand_int ().
 	   *
 	   * We are using (trans + trans * trans), because g_rand_int only
 	   * covers [0..2^32-1] and thus g_rand_int * trans only covers
 	   * [0..1-2^-32], but the biggest double < 1 is 1-2^-52.
 	   */

 	  gdouble double_rand = g_rand_int (rand) *
 	    (G_RAND_DOUBLE_TRANSFORM +
 	     G_RAND_DOUBLE_TRANSFORM * G_RAND_DOUBLE_TRANSFORM);

 	  random = (gint32) (double_rand * dist);
 	}
       else
 	{
 	  /* Now we use g_rand_double_range (), which will set 52 bits
 	   * for us, so that it is safe to round and still get a decent
 	   * distribution
            */
 	  random = (gint32) g_rand_double_range (rand, 0, dist);
 	}
       break;
     case 22:
       if (dist == 0)
 	random = 0;
       else
 	{
 	  /* maxvalue is set to the predecessor of the greatest
 	   * multiple of dist less or equal 2^32.
 	   */
 	  guint32 maxvalue;
 	  if (dist <= 0x80000000u) /* 2^31 */
 	    {
 	      /* maxvalue = 2^32 - 1 - (2^32 % dist) */
 	      guint32 leftover = (0x80000000u % dist) * 2;
 	      if (leftover >= dist) leftover -= dist;
 	      maxvalue = 0xffffffffu - leftover;
 	    }
 	  else
 	    maxvalue = dist - 1;

 	  do
 	    random = g_rand_int (rand);
 	  while (random > maxvalue);

 	  random %= dist;
 	}
       break;
     default:
       random = 0;		/* Quiet GCC */
       g_assert_not_reached ();
     }

   return begin + random;
 }

 /**
  * g_rand_double:
  * @rand_: a #GRand
  *
  * Returns the next random #gdouble from @rand_ equally distributed over
  * the range [0..1).
  *
  * Returns: a random number
  */
 gdouble
 g_rand_double (GRand *rand)
 {
   /* We set all 52 bits after the point for this, not only the first
      32. Thats why we need two calls to g_rand_int */
   gdouble retval = g_rand_int (rand) * G_RAND_DOUBLE_TRANSFORM;
   retval = (retval + g_rand_int (rand)) * G_RAND_DOUBLE_TRANSFORM;

   /* The following might happen due to very bad rounding luck, but
    * actually this should be more than rare, we just try again then */
   if (retval >= 1.0)
     return g_rand_double (rand);

   return retval;
 }

 /**
  * g_rand_double_range:
  * @rand_: a #GRand
  * @begin: lower closed bound of the interval
  * @end: upper open bound of the interval
  *
  * Returns the next random #gdouble from @rand_ equally distributed over
  * the range [@begin..@end).
  *
  * Returns: a random number
  */
 gdouble
 g_rand_double_range (GRand   *rand,
                      gdouble  begin,
                      gdouble  end)
 {
   gdouble r;

   r = g_rand_double (rand);

   return r * end - (r - 1) * begin;
 }

 static GRand *
 get_global_random (void)
 {
   static GRand *global_random;

   /* called while locked */
   if (!global_random)
     global_random = g_rand_new ();

   return global_random;
 }

 /**
  * g_random_boolean:
  *
  * Returns a random #gboolean.
  * This corresponds to a unbiased coin toss.
  *
  * Returns: a random #gboolean
  */
 /**
  * g_random_int:
  *
  * Return a random #guint32 equally distributed over the range
  * [0..2^32-1].
  *
  * Returns: a random number
  */
 guint32
 g_random_int (void)
 {
   guint32 result;
   G_LOCK (global_random);
   result = g_rand_int (get_global_random ());
   G_UNLOCK (global_random);
   return result;
 }

 /**
  * g_random_int_range:
  * @begin: lower closed bound of the interval
  * @end: upper open bound of the interval
  *
  * Returns a random #gint32 equally distributed over the range
  * [@begin..@end-1].
  *
  * Returns: a random number
  */
 gint32
 g_random_int_range (gint32 begin,
                     gint32 end)
 {
   gint32 result;
   G_LOCK (global_random);
   result = g_rand_int_range (get_global_random (), begin, end);
   G_UNLOCK (global_random);
   return result;
 }

 /**
  * g_random_double:
  *
  * Returns a random #gdouble equally distributed over the range [0..1).
  *
  * Returns: a random number
  */
 gdouble
 g_random_double (void)
 {
   double result;
   G_LOCK (global_random);
   result = g_rand_double (get_global_random ());
   G_UNLOCK (global_random);
   return result;
 }

 /**
  * g_random_double_range:
  * @begin: lower closed bound of the interval
  * @end: upper open bound of the interval
  *
  * Returns a random #gdouble equally distributed over the range
  * [@begin..@end).
  *
  * Returns: a random number
  */
 gdouble
 g_random_double_range (gdouble begin,
                        gdouble end)
 {
   double result;
   G_LOCK (global_random);
   result = g_rand_double_range (get_global_random (), begin, end);
   G_UNLOCK (global_random);
   return result;
 }

 /**
  * g_random_set_seed:
  * @seed: a value to reinitialize the global random number generator
  *
  * Sets the seed for the global random number generator, which is used
  * by the g_random_* functions, to @seed.
  */
 void
 g_random_set_seed (guint32 seed)
 {
   G_LOCK (global_random);
   g_rand_set_seed (get_global_random (), seed);
   G_UNLOCK (global_random);
 }
	/* GLIB - Library of useful routines for C programming
	* Copyright (C) 1995-1997 Peter Mattis, Spencer Kimball and Josh MacDonald
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Lesser General Public
	* License as published by the Free Software Foundation; either
	* version 2 of the License, or (at your option) any later version.
	*
	* This library is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this library; if not, see <http://www.gnu.org/licenses/>.
	*/

	/* Originally developed and coded by Makoto Matsumoto and Takuji
	* Nishimura. Please mail <matumoto@math.keio.ac.jp>, if you're using
	* code from this file in your own programs or libraries.
	* Further information on the Mersenne Twister can be found at
	* http://www.math.sci.hiroshima-u.ac.jp/~m-mat/MT/emt.html
	* This code was adapted to glib by Sebastian Wilhelmi.
	*/

	/*
	* Modified by the GLib Team and others 1997-2000. See the AUTHORS
	* file for a list of people on the GLib Team. See the ChangeLog
	* files for a list of changes. These files are distributed with
	* GLib at ftp://ftp.gtk.org/pub/gtk/.
	*/

	/*
	* MT safe
	*/

	#include "config.h"
	#define _CRT_RAND_S

	#include <math.h>
	#include <errno.h>
	#include <stdio.h>
	#include <string.h>
	#include <sys/types.h>
	#include "grand.h"

	#include "genviron.h"
	#include "gmain.h"
	#include "gmem.h"
	#include "gtestutils.h"
	#include "gthread.h"

	#ifdef G_OS_UNIX
	#include <unistd.h>
	#endif

	#ifdef G_OS_WIN32
	#include <stdlib.h>
	#include <process.h> /* For getpid() */
	#endif

	/**
	* SECTION:random_numbers
	* @title: Random Numbers
	* @short_description: pseudo-random number generator
	*
	* The following functions allow you to use a portable, fast and good
	* pseudo-random number generator (PRNG).
	*
	* Do not use this API for cryptographic purposes such as key
	* generation, nonces, salts or one-time pads.
	*
	* This PRNG is suitable for non-cryptographic use such as in games
	* (shuffling a card deck, generating levels), generating data for
	* a test suite, etc. If you need random data for cryptographic
	* purposes, it is recommended to use platform-specific APIs such
	* as `/dev/random` on UNIX, or CryptGenRandom() on Windows.
	*
	* GRand uses the Mersenne Twister PRNG, which was originally
	* developed by Makoto Matsumoto and Takuji Nishimura. Further
	* information can be found at
	* [this page](http://www.math.sci.hiroshima-u.ac.jp/~m-mat/MT/emt.html).
	*
	* If you just need a random number, you simply call the g_random_*
	* functions, which will create a globally used #GRand and use the
	* according g_rand_* functions internally. Whenever you need a
	* stream of reproducible random numbers, you better create a
	* #GRand yourself and use the g_rand_* functions directly, which
	* will also be slightly faster. Initializing a #GRand with a
	* certain seed will produce exactly the same series of random
	* numbers on all platforms. This can thus be used as a seed for
	* e.g. games.
	*
	* The g_rand*_range functions will return high quality equally
	* distributed random numbers, whereas for example the
	* `(g_random_int()%max)` approach often
	* doesn't yield equally distributed numbers.
	*
	* GLib changed the seeding algorithm for the pseudo-random number
	* generator Mersenne Twister, as used by #GRand. This was necessary,
	* because some seeds would yield very bad pseudo-random streams.
	* Also the pseudo-random integers generated by g_rand*_int_range()
	* will have a slightly better equal distribution with the new
	* version of GLib.
	*
	* The original seeding and generation algorithms, as found in
	* GLib 2.0.x, can be used instead of the new ones by setting the
	* environment variable `G_RANDOM_VERSION` to the value of '2.0'.
	* Use the GLib-2.0 algorithms only if you have sequences of numbers
	* generated with Glib-2.0 that you need to reproduce exactly.
	*/

	/**
	* GRand:
	*
	* The GRand struct is an opaque data structure. It should only be
	* accessed through the g_rand_* functions.
	**/

	G_LOCK_DEFINE_STATIC (global_random);

	/* Period parameters */
	#define N 624
	#define M 397
	#define MATRIX_A 0x9908b0df /* constant vector a */
	#define UPPER_MASK 0x80000000 /* most significant w-r bits */
	#define LOWER_MASK 0x7fffffff /* least significant r bits */

	/* Tempering parameters */
	#define TEMPERING_MASK_B 0x9d2c5680
	#define TEMPERING_MASK_C 0xefc60000
	#define TEMPERING_SHIFT_U(y) (y >> 11)
	#define TEMPERING_SHIFT_S(y) (y << 7)
	#define TEMPERING_SHIFT_T(y) (y << 15)
	#define TEMPERING_SHIFT_L(y) (y >> 18)

	static guint
	get_random_version (void)
	{
	static gsize initialized = FALSE;
	static guint random_version;

	if (g_once_init_enter (&initialized))
	{
	const gchar *version_string = g_getenv ("G_RANDOM_VERSION");
	if (!version_string \|\| version_string[0] == '\000' \|\|
	strcmp (version_string, "2.2") == 0)
	random_version = 22;
	else if (strcmp (version_string, "2.0") == 0)
	random_version = 20;
	else
	{
	g_warning ("Unknown G_RANDOM_VERSION \"%s\". Using version 2.2.",
	version_string);
	random_version = 22;
	}
	g_once_init_leave (&initialized, TRUE);
	}

	return random_version;
	}

	struct _GRand
	{
	guint32 mt[N]; /* the array for the state vector */
	guint mti;
	};

	/**
	* g_rand_new_with_seed:
	* @seed: a value to initialize the random number generator
	*
	* Creates a new random number generator initialized with @seed.
	*
	* Returns: the new #GRand
	**/
	GRand*
	g_rand_new_with_seed (guint32 seed)
	{
	GRand *rand = g_new0 (GRand, 1);
	g_rand_set_seed (rand, seed);
	return rand;
	}

	/**
	* g_rand_new_with_seed_array:
	* @seed: an array of seeds to initialize the random number generator
	* @seed_length: an array of seeds to initialize the random number
	* generator
	*
	* Creates a new random number generator initialized with @seed.
	*
	* Returns: the new #GRand
	*
	* Since: 2.4
	*/
	GRand*
	g_rand_new_with_seed_array (const guint32 *seed,
	guint seed_length)
	{
	GRand *rand = g_new0 (GRand, 1);
	g_rand_set_seed_array (rand, seed, seed_length);
	return rand;
	}

	/**
	* g_rand_new:
	*
	* Creates a new random number generator initialized with a seed taken
	* either from `/dev/urandom` (if existing) or from the current time
	* (as a fallback).
	*
	* On Windows, the seed is taken from rand_s().
	*
	* Returns: the new #GRand
	*/
	GRand*
	g_rand_new (void)
	{
	guint32 seed[4];
	#ifdef G_OS_UNIX
	static gboolean dev_urandom_exists = TRUE;
	GTimeVal now;

	if (dev_urandom_exists)
	{
	FILE* dev_urandom;

	do
	{
	dev_urandom = fopen("/dev/urandom", "rb");
	}
	while G_UNLIKELY (dev_urandom == NULL && errno == EINTR);

	if (dev_urandom)
	{
	int r;

	setvbuf (dev_urandom, NULL, _IONBF, 0);
	do
	{
	errno = 0;
	r = fread (seed, sizeof (seed), 1, dev_urandom);
	}
	while G_UNLIKELY (errno == EINTR);

	if (r != 1)
	dev_urandom_exists = FALSE;

	fclose (dev_urandom);
	}
	else
	dev_urandom_exists = FALSE;
	}

	if (!dev_urandom_exists)
	{
	g_get_current_time (&now);
	seed[0] = now.tv_sec;
	seed[1] = now.tv_usec;
	seed[2] = getpid ();
	seed[3] = getppid ();
	}
	#else /* G_OS_WIN32 */
	/* rand_s() is only available since Visual Studio 2005 and
	* MinGW-w64 has a wrapper that will emulate rand_s() if it's not in msvcrt
	*/
	#if (defined(_MSC_VER) && _MSC_VER >= 1400) \|\| defined(__MINGW64_VERSION_MAJOR)
	gint i;

	for (i = 0; i < G_N_ELEMENTS (seed); i++)
	rand_s (&seed[i]);
	#else
	#warning Using insecure seed for random number generation because of missing rand_s() in Windows XP
	GTimeVal now;

	g_get_current_time (&now);
	seed[0] = now.tv_sec;
	seed[1] = now.tv_usec;
	seed[2] = getpid ();
	seed[3] = 0;
	#endif

	#endif

	return g_rand_new_with_seed_array (seed, 4);
	}

	/**
	* g_rand_free:
	* @rand_: a #GRand
	*
	* Frees the memory allocated for the #GRand.
	*/
	void
	g_rand_free (GRand *rand)
	{
	g_return_if_fail (rand != NULL);

	g_free (rand);
	}

	/**
	* g_rand_copy:
	* @rand_: a #GRand
	*
	* Copies a #GRand into a new one with the same exact state as before.
	* This way you can take a snapshot of the random number generator for
	* replaying later.
	*
	* Returns: the new #GRand
	*
	* Since: 2.4
	*/
	GRand*
	g_rand_copy (GRand *rand)
	{
	GRand* new_rand;

	g_return_val_if_fail (rand != NULL, NULL);

	new_rand = g_new0 (GRand, 1);
	memcpy (new_rand, rand, sizeof (GRand));

	return new_rand;
	}

	/**
	* g_rand_set_seed:
	* @rand_: a #GRand
	* @seed: a value to reinitialize the random number generator
	*
	* Sets the seed for the random number generator #GRand to @seed.
	*/
	void
	g_rand_set_seed (GRand *rand,
	guint32 seed)
	{
	g_return_if_fail (rand != NULL);

	switch (get_random_version ())
	{
	case 20:
	/* setting initial seeds to mt[N] using */
	/* the generator Line 25 of Table 1 in */
	/* [KNUTH 1981, The Art of Computer Programming */
	/* Vol. 2 (2nd Ed.), pp102] */

	if (seed == 0) /* This would make the PRNG produce only zeros */
	seed = 0x6b842128; /* Just set it to another number */

	rand->mt[0]= seed;
	for (rand->mti=1; rand->mti<N; rand->mti++)
	rand->mt[rand->mti] = (69069 * rand->mt[rand->mti-1]);

	break;
	case 22:
	/* See Knuth TAOCP Vol2. 3rd Ed. P.106 for multiplier. */
	/* In the previous version (see above), MSBs of the */
	/* seed affect only MSBs of the array mt[]. */

	rand->mt[0]= seed;
	for (rand->mti=1; rand->mti<N; rand->mti++)
	rand->mt[rand->mti] = 1812433253UL *
	(rand->mt[rand->mti-1] ^ (rand->mt[rand->mti-1] >> 30)) + rand->mti;
	break;
	default:
	g_assert_not_reached ();
	}
	}

	/**
	* g_rand_set_seed_array:
	* @rand_: a #GRand
	* @seed: array to initialize with
	* @seed_length: length of array
	*
	* Initializes the random number generator by an array of longs.
	* Array can be of arbitrary size, though only the first 624 values
	* are taken. This function is useful if you have many low entropy
	* seeds, or if you require more then 32 bits of actual entropy for
	* your application.
	*
	* Since: 2.4
	*/
	void
	g_rand_set_seed_array (GRand *rand,
	const guint32 *seed,
	guint seed_length)
	{
	int i, j, k;

	g_return_if_fail (rand != NULL);
	g_return_if_fail (seed_length >= 1);

	g_rand_set_seed (rand, 19650218UL);

	i=1; j=0;
	k = (N>seed_length ? N : seed_length);
	for (; k; k--)
	{
	rand->mt[i] = (rand->mt[i] ^
	((rand->mt[i-1] ^ (rand->mt[i-1] >> 30)) * 1664525UL))
	+ seed[j] + j; /* non linear */
	rand->mt[i] &= 0xffffffffUL; /* for WORDSIZE > 32 machines */
	i++; j++;
	if (i>=N)
	{
	rand->mt[0] = rand->mt[N-1];
	i=1;
	}
	if (j>=seed_length)
	j=0;
	}
	for (k=N-1; k; k--)
	{
	rand->mt[i] = (rand->mt[i] ^
	((rand->mt[i-1] ^ (rand->mt[i-1] >> 30)) * 1566083941UL))
	- i; /* non linear */
	rand->mt[i] &= 0xffffffffUL; /* for WORDSIZE > 32 machines */
	i++;
	if (i>=N)
	{
	rand->mt[0] = rand->mt[N-1];
	i=1;
	}
	}

	rand->mt[0] = 0x80000000UL; /* MSB is 1; assuring non-zero initial array */
	}

	/**
	* g_rand_boolean:
	* @rand_: a #GRand
	*
	* Returns a random #gboolean from @rand_.
	* This corresponds to a unbiased coin toss.
	*
	* Returns: a random #gboolean
	*/
	/**
	* g_rand_int:
	* @rand_: a #GRand
	*
	* Returns the next random #guint32 from @rand_ equally distributed over
	* the range [0..2^32-1].
	*
	* Returns: a random number
	*/
	guint32
	g_rand_int (GRand *rand)
	{
	guint32 y;
	static const guint32 mag01[2]={0x0, MATRIX_A};
	/* mag01[x] = x * MATRIX_A for x=0,1 */

	g_return_val_if_fail (rand != NULL, 0);

	if (rand->mti >= N) { /* generate N words at one time */
	int kk;

	for (kk = 0; kk < N - M; kk++) {
	y = (rand->mt[kk]&UPPER_MASK)\|(rand->mt[kk+1]&LOWER_MASK);
	rand->mt[kk] = rand->mt[kk+M] ^ (y >> 1) ^ mag01[y & 0x1];
	}
	for (; kk < N - 1; kk++) {
	y = (rand->mt[kk]&UPPER_MASK)\|(rand->mt[kk+1]&LOWER_MASK);
	rand->mt[kk] = rand->mt[kk+(M-N)] ^ (y >> 1) ^ mag01[y & 0x1];
	}
	y = (rand->mt[N-1]&UPPER_MASK)\|(rand->mt[0]&LOWER_MASK);
	rand->mt[N-1] = rand->mt[M-1] ^ (y >> 1) ^ mag01[y & 0x1];

	rand->mti = 0;
	}

	y = rand->mt[rand->mti++];
	y ^= TEMPERING_SHIFT_U(y);
	y ^= TEMPERING_SHIFT_S(y) & TEMPERING_MASK_B;
	y ^= TEMPERING_SHIFT_T(y) & TEMPERING_MASK_C;
	y ^= TEMPERING_SHIFT_L(y);

	return y;
	}

	/* transform [0..2^32] -> [0..1] */
	#define G_RAND_DOUBLE_TRANSFORM 2.3283064365386962890625e-10

	/**
	* g_rand_int_range:
	* @rand_: a #GRand
	* @begin: lower closed bound of the interval
	* @end: upper open bound of the interval
	*
	* Returns the next random #gint32 from @rand_ equally distributed over
	* the range [@begin..@end-1].
	*
	* Returns: a random number
	*/
	gint32
	g_rand_int_range (GRand *rand,
	gint32 begin,
	gint32 end)
	{
	guint32 dist = end - begin;
	guint32 random;

	g_return_val_if_fail (rand != NULL, begin);
	g_return_val_if_fail (end > begin, begin);

	switch (get_random_version ())
	{
	case 20:
	if (dist <= 0x10000L) /* 2^16 */
	{
	/* This method, which only calls g_rand_int once is only good
	* for (end - begin) <= 2^16, because we only have 32 bits set
	* from the one call to g_rand_int ().
	*
	* We are using (trans + trans * trans), because g_rand_int only
	* covers [0..2^32-1] and thus g_rand_int * trans only covers
	* [0..1-2^-32], but the biggest double < 1 is 1-2^-52.
	*/

	gdouble double_rand = g_rand_int (rand) *
	(G_RAND_DOUBLE_TRANSFORM +
	G_RAND_DOUBLE_TRANSFORM * G_RAND_DOUBLE_TRANSFORM);

	random = (gint32) (double_rand * dist);
	}
	else
	{
	/* Now we use g_rand_double_range (), which will set 52 bits
	* for us, so that it is safe to round and still get a decent
	* distribution
	*/
	random = (gint32) g_rand_double_range (rand, 0, dist);
	}
	break;
	case 22:
	if (dist == 0)
	random = 0;
	else
	{
	/* maxvalue is set to the predecessor of the greatest
	* multiple of dist less or equal 2^32.
	*/
	guint32 maxvalue;
	if (dist <= 0x80000000u) /* 2^31 */
	{
	/* maxvalue = 2^32 - 1 - (2^32 % dist) */
	guint32 leftover = (0x80000000u % dist) * 2;
	if (leftover >= dist) leftover -= dist;
	maxvalue = 0xffffffffu - leftover;
	}
	else
	maxvalue = dist - 1;

	do
	random = g_rand_int (rand);
	while (random > maxvalue);

	random %= dist;
	}
	break;
	default:
	random = 0; /* Quiet GCC */
	g_assert_not_reached ();
	}

	return begin + random;
	}

	/**
	* g_rand_double:
	* @rand_: a #GRand
	*
	* Returns the next random #gdouble from @rand_ equally distributed over
	* the range [0..1).
	*
	* Returns: a random number
	*/
	gdouble
	g_rand_double (GRand *rand)
	{
	/* We set all 52 bits after the point for this, not only the first
	32. Thats why we need two calls to g_rand_int */
	gdouble retval = g_rand_int (rand) * G_RAND_DOUBLE_TRANSFORM;
	retval = (retval + g_rand_int (rand)) * G_RAND_DOUBLE_TRANSFORM;

	/* The following might happen due to very bad rounding luck, but
	* actually this should be more than rare, we just try again then */
	if (retval >= 1.0)
	return g_rand_double (rand);

	return retval;
	}

	/**
	* g_rand_double_range:
	* @rand_: a #GRand
	* @begin: lower closed bound of the interval
	* @end: upper open bound of the interval
	*
	* Returns the next random #gdouble from @rand_ equally distributed over
	* the range [@begin..@end).
	*
	* Returns: a random number
	*/
	gdouble
	g_rand_double_range (GRand *rand,
	gdouble begin,
	gdouble end)
	{
	gdouble r;

	r = g_rand_double (rand);

	return r * end - (r - 1) * begin;
	}

	static GRand *
	get_global_random (void)
	{
	static GRand *global_random;

	/* called while locked */
	if (!global_random)
	global_random = g_rand_new ();

	return global_random;
	}

	/**
	* g_random_boolean:
	*
	* Returns a random #gboolean.
	* This corresponds to a unbiased coin toss.
	*
	* Returns: a random #gboolean
	*/
	/**
	* g_random_int:
	*
	* Return a random #guint32 equally distributed over the range
	* [0..2^32-1].
	*
	* Returns: a random number
	*/
	guint32
	g_random_int (void)
	{
	guint32 result;
	G_LOCK (global_random);
	result = g_rand_int (get_global_random ());
	G_UNLOCK (global_random);
	return result;
	}

	/**
	* g_random_int_range:
	* @begin: lower closed bound of the interval
	* @end: upper open bound of the interval
	*
	* Returns a random #gint32 equally distributed over the range
	* [@begin..@end-1].
	*
	* Returns: a random number
	*/
	gint32
	g_random_int_range (gint32 begin,
	gint32 end)
	{
	gint32 result;
	G_LOCK (global_random);
	result = g_rand_int_range (get_global_random (), begin, end);
	G_UNLOCK (global_random);
	return result;
	}

	/**
	* g_random_double:
	*
	* Returns a random #gdouble equally distributed over the range [0..1).
	*
	* Returns: a random number
	*/
	gdouble
	g_random_double (void)
	{
	double result;
	G_LOCK (global_random);
	result = g_rand_double (get_global_random ());
	G_UNLOCK (global_random);
	return result;
	}

	/**
	* g_random_double_range:
	* @begin: lower closed bound of the interval
	* @end: upper open bound of the interval
	*
	* Returns a random #gdouble equally distributed over the range
	* [@begin..@end).
	*
	* Returns: a random number
	*/
	gdouble
	g_random_double_range (gdouble begin,
	gdouble end)
	{
	double result;
	G_LOCK (global_random);
	result = g_rand_double_range (get_global_random (), begin, end);
	G_UNLOCK (global_random);
	return result;
	}

	/**
	* g_random_set_seed:
	* @seed: a value to reinitialize the global random number generator
	*
	* Sets the seed for the global random number generator, which is used
	* by the g_random_* functions, to @seed.
	*/
	void
	g_random_set_seed (guint32 seed)
	{
	G_LOCK (global_random);
	g_rand_set_seed (get_global_random (), seed);
	G_UNLOCK (global_random);
	}