-/* Copyright (C) 1999,2000,2001 Free Software Foundation, Inc.
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; either version 2, or (at your option)
- * any later version.
+/* Copyright (C) 1999,2000,2001, 2003, 2005, 2006 Free Software Foundation, Inc.
+ * 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 2.1 of the License, or (at your option) any later version.
*
- * This program is distributed in the hope that it will be useful,
+ * 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 General Public License for more details.
+ * 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 General Public License
- * along with this software; see the file COPYING. If not, write to
- * the Free Software Foundation, Inc., 59 Temple Place, Suite 330,
- * Boston, MA 02111-1307 USA
- *
- * As a special exception, the Free Software Foundation gives permission
- * for additional uses of the text contained in its release of GUILE.
- *
- * The exception is that, if you link the GUILE library with other files
- * to produce an executable, this does not by itself cause the
- * resulting executable to be covered by the GNU General Public License.
- * Your use of that executable is in no way restricted on account of
- * linking the GUILE library code into it.
- *
- * This exception does not however invalidate any other reasons why
- * the executable file might be covered by the GNU General Public License.
- *
- * This exception applies only to the code released by the
- * Free Software Foundation under the name GUILE. If you copy
- * code from other Free Software Foundation releases into a copy of
- * GUILE, as the General Public License permits, the exception does
- * not apply to the code that you add in this way. To avoid misleading
- * anyone as to the status of such modified files, you must delete
- * this exception notice from them.
- *
- * If you write modifications of your own for GUILE, it is your choice
- * whether to permit this exception to apply to your modifications.
- * If you do not wish that, delete this exception notice. */
+ * You should have received a copy of the GNU Lesser General Public
+ * License along with this library; if not, write to the Free Software
+ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
+ */
-/* Software engineering face-lift by Greg J. Badros, 11-Dec-1999,
- gjb@cs.washington.edu, http://www.cs.washington.edu/homes/gjb */
/* Author: Mikael Djurfeldt <djurfeldt@nada.kth.se> */
+#ifdef HAVE_CONFIG_H
+# include <config.h>
+#endif
+
#include "libguile/_scm.h"
+#include <gmp.h>
#include <stdio.h>
#include <math.h>
#include <string.h>
#include "libguile/feature.h"
#include "libguile/strings.h"
#include "libguile/unif.h"
+#include "libguile/srfi-4.h"
#include "libguile/vectors.h"
#include "libguile/validate.h"
* scm_init_random().
*/
-scm_rng scm_the_rng;
+scm_t_rng scm_the_rng;
\f
/*
#define A 2131995753UL
-#if SIZEOF_LONG > 4
-#if SIZEOF_INT > 4
-#define LONG32 unsigned short
-#else
-#define LONG32 unsigned int
-#endif
-#define LONG64 unsigned long
-#else
-#define LONG32 unsigned long
-#define LONG64 unsigned long long
+#ifndef M_PI
+#define M_PI 3.14159265359
#endif
-#if SIZEOF_LONG > 4 || defined (HAVE_LONG_LONGS)
+#if SCM_HAVE_T_UINT64
unsigned long
-scm_i_uniform32 (scm_i_rstate *state)
+scm_i_uniform32 (scm_t_i_rstate *state)
{
- LONG64 x = (LONG64) A * state->w + state->c;
- LONG32 w = x & 0xffffffffUL;
+ scm_t_uint64 x = (scm_t_uint64) A * state->w + state->c;
+ scm_t_uint32 w = x & 0xffffffffUL;
state->w = w;
state->c = x >> 32L;
return w;
#define H(x) ((x) >> 16)
unsigned long
-scm_i_uniform32 (scm_i_rstate *state)
+scm_i_uniform32 (scm_t_i_rstate *state)
{
- LONG32 x1 = L (A) * L (state->w);
- LONG32 x2 = L (A) * H (state->w);
- LONG32 x3 = H (A) * L (state->w);
- LONG32 w = L (x1) + L (state->c);
- LONG32 m = H (x1) + L (x2) + L (x3) + H (state->c) + H (w);
- LONG32 x4 = H (A) * H (state->w);
+ scm_t_uint32 x1 = L (A) * L (state->w);
+ scm_t_uint32 x2 = L (A) * H (state->w);
+ scm_t_uint32 x3 = H (A) * L (state->w);
+ scm_t_uint32 w = L (x1) + L (state->c);
+ scm_t_uint32 m = H (x1) + L (x2) + L (x3) + H (state->c) + H (w);
+ scm_t_uint32 x4 = H (A) * H (state->w);
state->w = w = (L (m) << 16) + L (w);
state->c = H (x2) + H (x3) + x4 + H (m);
return w;
#endif
void
-scm_i_init_rstate (scm_i_rstate *state, char *seed, int n)
+scm_i_init_rstate (scm_t_i_rstate *state, const char *seed, int n)
{
- LONG32 w = 0L;
- LONG32 c = 0L;
+ scm_t_uint32 w = 0L;
+ scm_t_uint32 c = 0L;
int i, m;
for (i = 0; i < n; ++i)
{
else
c += seed[i] << (8 * (m - 4));
}
- if ((w == 0 && c == 0) || (w == 0xffffffffUL && c == A - 1))
+ if ((w == 0 && c == 0) || (w == -1 && c == A - 1))
++c;
state->w = w;
state->c = c;
}
-scm_i_rstate *
-scm_i_copy_rstate (scm_i_rstate *state)
+scm_t_i_rstate *
+scm_i_copy_rstate (scm_t_i_rstate *state)
{
- scm_rstate *new_state = malloc (scm_the_rng.rstate_size);
- if (new_state == 0)
- scm_memory_error ("rstate");
+ scm_t_rstate *new_state = scm_malloc (scm_the_rng.rstate_size);
return memcpy (new_state, state, scm_the_rng.rstate_size);
}
* Random number library functions
*/
-scm_rstate *
-scm_c_make_rstate (char *seed, int n)
+scm_t_rstate *
+scm_c_make_rstate (const char *seed, int n)
{
- scm_rstate *state = malloc (scm_the_rng.rstate_size);
- if (state == 0)
- scm_memory_error ("rstate");
+ scm_t_rstate *state = scm_malloc (scm_the_rng.rstate_size);
state->reserved0 = 0;
scm_the_rng.init_rstate (state, seed, n);
return state;
}
-scm_rstate *
+scm_t_rstate *
scm_c_default_rstate ()
#define FUNC_NAME "scm_c_default_rstate"
{
- SCM state = SCM_CDR (scm_var_random_state);
+ SCM state = SCM_VARIABLE_REF (scm_var_random_state);
if (!SCM_RSTATEP (state))
SCM_MISC_ERROR ("*random-state* contains bogus random state", SCM_EOL);
return SCM_RSTATE (state);
inline double
-scm_c_uniform01 (scm_rstate *state)
+scm_c_uniform01 (scm_t_rstate *state)
{
double x = (double) scm_the_rng.random_bits (state) / (double) 0xffffffffUL;
return ((x + (double) scm_the_rng.random_bits (state))
}
double
-scm_c_normal01 (scm_rstate *state)
+scm_c_normal01 (scm_t_rstate *state)
{
if (state->reserved0)
{
}
double
-scm_c_exp1 (scm_rstate *state)
+scm_c_exp1 (scm_t_rstate *state)
{
return - log (scm_c_uniform01 (state));
}
unsigned char scm_masktab[256];
unsigned long
-scm_c_random (scm_rstate *state, unsigned long m)
+scm_c_random (scm_t_rstate *state, unsigned long m)
{
unsigned int r, mask;
mask = (m < 0x100
return r;
}
+/*
+ SCM scm_c_random_bignum (scm_t_rstate *state, SCM m)
+
+ Takes a random state (source of random bits) and a bignum m.
+ Returns a bignum b, 0 <= b < m.
+
+ It does this by allocating a bignum b with as many base 65536 digits
+ as m, filling b with random bits (in 32 bit chunks) up to the most
+ significant 1 in m, and, finally checking if the resultant b is too
+ large (>= m). If too large, we simply repeat the process again. (It
+ is important to throw away all generated random bits if b >= m,
+ otherwise we'll end up with a distorted distribution.)
+
+*/
+
SCM
-scm_c_random_bignum (scm_rstate *state, SCM m)
+scm_c_random_bignum (scm_t_rstate *state, SCM m)
{
- SCM b;
- int i, nd;
- LONG32 *bits, mask, w;
- nd = SCM_NUMDIGS (m);
- /* calculate mask for most significant digit */
-#if SIZEOF_INT == 4
- /* 16 bit digits */
- if (nd & 1)
- {
- /* fix most significant 16 bits */
- unsigned short s = SCM_BDIGITS (m)[nd - 1];
- mask = s < 0x100 ? scm_masktab[s] : scm_masktab[s >> 8] << 8 | 0xff;
- }
- else
-#endif
- {
- /* fix most significant 32 bits */
-#if SIZEOF_INT == 4
- w = SCM_BDIGITS (m)[nd - 1] << 16 | SCM_BDIGITS (m)[nd - 2];
-#else
- w = SCM_BDIGITS (m)[nd - 1];
-#endif
- mask = (w < 0x10000
- ? (w < 0x100
- ? scm_masktab[w]
- : scm_masktab[w >> 8] << 8 | 0xff)
- : (w < 0x1000000
- ? scm_masktab[w >> 16] << 16 | 0xffff
- : scm_masktab[w >> 24] << 24 | 0xffffff));
- }
- b = scm_mkbig (nd, 0);
- bits = (LONG32 *) SCM_BDIGITS (b);
+ SCM result = scm_i_mkbig ();
+ const size_t m_bits = mpz_sizeinbase (SCM_I_BIG_MPZ (m), 2);
+ /* how many bits would only partially fill the last unsigned long? */
+ const size_t end_bits = m_bits % (sizeof (unsigned long) * SCM_CHAR_BIT);
+ unsigned long *random_chunks = NULL;
+ const unsigned long num_full_chunks =
+ m_bits / (sizeof (unsigned long) * SCM_CHAR_BIT);
+ const unsigned long num_chunks = num_full_chunks + ((end_bits) ? 1 : 0);
+
+ /* we know the result will be this big */
+ mpz_realloc2 (SCM_I_BIG_MPZ (result), m_bits);
+
+ random_chunks =
+ (unsigned long *) scm_gc_calloc (num_chunks * sizeof (unsigned long),
+ "random bignum chunks");
+
do
{
- i = nd;
- /* treat most significant digit specially */
-#if SIZEOF_INT == 4
- /* 16 bit digits */
- if (i & 1)
- {
- ((SCM_BIGDIG*) bits)[i - 1] = scm_the_rng.random_bits (state) & mask;
- i /= 2;
- }
- else
-#endif
- {
- /* fix most significant 32 bits */
-#if SIZEOF_INT == 4
- w = scm_the_rng.random_bits (state) & mask;
- ((SCM_BIGDIG*) bits)[i - 2] = w & 0xffff;
- ((SCM_BIGDIG*) bits)[i - 1] = w >> 16;
- i = i / 2 - 1;
-#else
- i /= 2;
- bits[--i] = scm_the_rng.random_bits (state) & mask;
-#endif
- }
- /* now fill up the rest of the bignum */
- while (i)
- bits[--i] = scm_the_rng.random_bits (state);
- b = scm_normbig (b);
- if (SCM_INUMP (b))
- return b;
- } while (scm_bigcomp (b, m) <= 0);
- return b;
+ unsigned long *current_chunk = random_chunks + (num_chunks - 1);
+ unsigned long chunks_left = num_chunks;
+
+ mpz_set_ui (SCM_I_BIG_MPZ (result), 0);
+
+ if (end_bits)
+ {
+ /* generate a mask with ones in the end_bits position, i.e. if
+ end_bits is 3, then we'd have a mask of ...0000000111 */
+ const unsigned long rndbits = scm_the_rng.random_bits (state);
+ int rshift = (sizeof (unsigned long) * SCM_CHAR_BIT) - end_bits;
+ unsigned long mask = ((unsigned long) ULONG_MAX) >> rshift;
+ unsigned long highest_bits = rndbits & mask;
+ *current_chunk-- = highest_bits;
+ chunks_left--;
+ }
+
+ while (chunks_left)
+ {
+ /* now fill in the remaining unsigned long sized chunks */
+ *current_chunk-- = scm_the_rng.random_bits (state);
+ chunks_left--;
+ }
+ mpz_import (SCM_I_BIG_MPZ (result),
+ num_chunks,
+ -1,
+ sizeof (unsigned long),
+ 0,
+ 0,
+ random_chunks);
+ /* if result >= m, regenerate it (it is important to regenerate
+ all bits in order not to get a distorted distribution) */
+ } while (mpz_cmp (SCM_I_BIG_MPZ (result), SCM_I_BIG_MPZ (m)) >= 0);
+ scm_gc_free (random_chunks,
+ num_chunks * sizeof (unsigned long),
+ "random bignum chunks");
+ return scm_i_normbig (result);
}
/*
* Scheme level representation of random states.
*/
-scm_bits_t scm_tc16_rstate;
+scm_t_bits scm_tc16_rstate;
static SCM
-make_rstate (scm_rstate *state)
+make_rstate (scm_t_rstate *state)
{
SCM_RETURN_NEWSMOB (scm_tc16_rstate, state);
}
-static scm_sizet
+static size_t
rstate_free (SCM rstate)
{
free (SCM_RSTATE (rstate));
- return scm_the_rng.rstate_size;
+ return 0;
}
/*
* Scheme level interface.
*/
-SCM_GLOBAL_VCELL_INIT (scm_var_random_state, "*random-state*", scm_seed_to_random_state (scm_makfrom0str ("URL:http://stat.fsu.edu/~geo/diehard.html")));
+SCM_GLOBAL_VARIABLE_INIT (scm_var_random_state, "*random-state*", scm_seed_to_random_state (scm_from_locale_string ("URL:http://stat.fsu.edu/~geo/diehard.html")));
SCM_DEFINE (scm_random, "random", 1, 1, 0,
(SCM n, SCM state),
- "Return a number in [0,N).\n"
+ "Return a number in [0, N).\n"
"\n"
- "Accepts a positive integer or real n and returns a \n"
- "number of the same type between zero (inclusive) and \n"
- "N (exclusive). The values returned have a uniform \n"
+ "Accepts a positive integer or real n and returns a\n"
+ "number of the same type between zero (inclusive) and\n"
+ "N (exclusive). The values returned have a uniform\n"
"distribution.\n"
"\n"
"The optional argument @var{state} must be of the type produced\n"
#define FUNC_NAME s_scm_random
{
if (SCM_UNBNDP (state))
- state = SCM_CDR (scm_var_random_state);
- SCM_VALIDATE_RSTATE (2,state);
- if (SCM_INUMP (n))
+ state = SCM_VARIABLE_REF (scm_var_random_state);
+ SCM_VALIDATE_RSTATE (2, state);
+ if (SCM_I_INUMP (n))
{
- unsigned long m = SCM_INUM (n);
- SCM_ASSERT_RANGE (1,n,m > 0);
- return SCM_MAKINUM (scm_c_random (SCM_RSTATE (state), m));
+ unsigned long m = SCM_I_INUM (n);
+ SCM_ASSERT_RANGE (1, n, m > 0);
+ return scm_from_ulong (scm_c_random (SCM_RSTATE (state), m));
}
- SCM_VALIDATE_NIM (1,n);
+ SCM_VALIDATE_NIM (1, n);
if (SCM_REALP (n))
- return scm_make_real (SCM_REAL_VALUE (n)
- * scm_c_uniform01 (SCM_RSTATE (state)));
- SCM_VALIDATE_SMOB (1, n, big);
+ return scm_from_double (SCM_REAL_VALUE (n)
+ * scm_c_uniform01 (SCM_RSTATE (state)));
+
+ if (!SCM_BIGP (n))
+ SCM_WRONG_TYPE_ARG (1, n);
return scm_c_random_bignum (SCM_RSTATE (state), n);
}
#undef FUNC_NAME
#define FUNC_NAME s_scm_copy_random_state
{
if (SCM_UNBNDP (state))
- state = SCM_CDR (scm_var_random_state);
- SCM_VALIDATE_RSTATE (1,state);
+ state = SCM_VARIABLE_REF (scm_var_random_state);
+ SCM_VALIDATE_RSTATE (1, state);
return make_rstate (scm_the_rng.copy_rstate (SCM_RSTATE (state)));
}
#undef FUNC_NAME
"Return a new random state using @var{seed}.")
#define FUNC_NAME s_scm_seed_to_random_state
{
+ SCM res;
if (SCM_NUMBERP (seed))
seed = scm_number_to_string (seed, SCM_UNDEFINED);
- SCM_VALIDATE_STRING (1,seed);
- return make_rstate (scm_c_make_rstate (SCM_STRING_CHARS (seed),
- SCM_STRING_LENGTH (seed)));
+ SCM_VALIDATE_STRING (1, seed);
+ res = make_rstate (scm_c_make_rstate (scm_i_string_chars (seed),
+ scm_i_string_length (seed)));
+ scm_remember_upto_here_1 (seed);
+ return res;
+
}
#undef FUNC_NAME
#define FUNC_NAME s_scm_random_uniform
{
if (SCM_UNBNDP (state))
- state = SCM_CDR (scm_var_random_state);
- SCM_VALIDATE_RSTATE (1,state);
- return scm_make_real (scm_c_uniform01 (SCM_RSTATE (state)));
+ state = SCM_VARIABLE_REF (scm_var_random_state);
+ SCM_VALIDATE_RSTATE (1, state);
+ return scm_from_double (scm_c_uniform01 (SCM_RSTATE (state)));
}
#undef FUNC_NAME
#define FUNC_NAME s_scm_random_normal
{
if (SCM_UNBNDP (state))
- state = SCM_CDR (scm_var_random_state);
- SCM_VALIDATE_RSTATE (1,state);
- return scm_make_real (scm_c_normal01 (SCM_RSTATE (state)));
+ state = SCM_VARIABLE_REF (scm_var_random_state);
+ SCM_VALIDATE_RSTATE (1, state);
+ return scm_from_double (scm_c_normal01 (SCM_RSTATE (state)));
}
#undef FUNC_NAME
-#ifdef HAVE_ARRAYS
-
static void
-vector_scale (SCM v, double c)
+vector_scale_x (SCM v, double c)
{
- int n = SCM_INUM (scm_uniform_vector_length (v));
- if (SCM_VECTORP (v))
- while (--n >= 0)
- SCM_REAL_VALUE (SCM_VELTS (v)[n]) *= c;
+ size_t n;
+ if (scm_is_simple_vector (v))
+ {
+ n = SCM_SIMPLE_VECTOR_LENGTH (v);
+ while (n-- > 0)
+ SCM_REAL_VALUE (SCM_SIMPLE_VECTOR_REF (v, n)) *= c;
+ }
else
- while (--n >= 0)
- ((double *) SCM_VELTS (v))[n] *= c;
+ {
+ /* must be a f64vector. */
+ scm_t_array_handle handle;
+ size_t i, len;
+ ssize_t inc;
+ double *elts;
+
+ elts = scm_f64vector_writable_elements (v, &handle, &len, &inc);
+
+ for (i = 0; i < len; i++, elts += inc)
+ *elts *= c;
+
+ scm_array_handle_release (&handle);
+ }
}
static double
vector_sum_squares (SCM v)
{
double x, sum = 0.0;
- int n = SCM_INUM (scm_uniform_vector_length (v));
- if (SCM_VECTORP (v))
- while (--n >= 0)
- {
- x = SCM_REAL_VALUE (SCM_VELTS (v)[n]);
- sum += x * x;
- }
+ size_t n;
+ if (scm_is_simple_vector (v))
+ {
+ n = SCM_SIMPLE_VECTOR_LENGTH (v);
+ while (n-- > 0)
+ {
+ x = SCM_REAL_VALUE (SCM_SIMPLE_VECTOR_REF (v, n));
+ sum += x * x;
+ }
+ }
else
- while (--n >= 0)
- {
- x = ((double *) SCM_VELTS (v))[n];
- sum += x * x;
- }
+ {
+ /* must be a f64vector. */
+ scm_t_array_handle handle;
+ size_t i, len;
+ ssize_t inc;
+ const double *elts;
+
+ elts = scm_f64vector_elements (v, &handle, &len, &inc);
+
+ for (i = 0; i < len; i++, elts += inc)
+ {
+ x = *elts;
+ sum += x * x;
+ }
+
+ scm_array_handle_release (&handle);
+ }
return sum;
}
*/
SCM_DEFINE (scm_random_solid_sphere_x, "random:solid-sphere!", 1, 1, 0,
(SCM v, SCM state),
- "Fills vect with inexact real random numbers\n"
- "the sum of whose squares is less than 1.0.\n"
- "Thinking of vect as coordinates in space of \n"
- "dimension n = (vector-length vect), the coordinates \n"
- "are uniformly distributed within the unit n-shere.\n"
- "The sum of the squares of the numbers is returned.")
+ "Fills @var{vect} with inexact real random numbers the sum of\n"
+ "whose squares is less than 1.0. Thinking of @var{vect} as\n"
+ "coordinates in space of dimension @var{n} @math{=}\n"
+ "@code{(vector-length @var{vect})}, the coordinates are\n"
+ "uniformly distributed within the unit @var{n}-sphere.")
#define FUNC_NAME s_scm_random_solid_sphere_x
{
- SCM_VALIDATE_VECTOR_OR_DVECTOR (1,v);
if (SCM_UNBNDP (state))
- state = SCM_CDR (scm_var_random_state);
- SCM_VALIDATE_RSTATE (2,state);
+ state = SCM_VARIABLE_REF (scm_var_random_state);
+ SCM_VALIDATE_RSTATE (2, state);
scm_random_normal_vector_x (v, state);
- vector_scale (v,
- pow (scm_c_uniform01 (SCM_RSTATE (state)),
- 1.0 / SCM_INUM (scm_uniform_vector_length (v)))
- / sqrt (vector_sum_squares (v)));
+ vector_scale_x (v,
+ pow (scm_c_uniform01 (SCM_RSTATE (state)),
+ 1.0 / scm_c_generalized_vector_length (v))
+ / sqrt (vector_sum_squares (v)));
return SCM_UNSPECIFIED;
}
#undef FUNC_NAME
(SCM v, SCM state),
"Fills vect with inexact real random numbers\n"
"the sum of whose squares is equal to 1.0.\n"
- "Thinking of vect as coordinates in space of \n"
+ "Thinking of vect as coordinates in space of\n"
"dimension n = (vector-length vect), the coordinates\n"
- "are uniformly distributed over the surface of the \n"
- "unit n-shere.")
+ "are uniformly distributed over the surface of the\n"
+ "unit n-sphere.")
#define FUNC_NAME s_scm_random_hollow_sphere_x
{
- SCM_VALIDATE_VECTOR_OR_DVECTOR (1,v);
if (SCM_UNBNDP (state))
- state = SCM_CDR (scm_var_random_state);
- SCM_VALIDATE_RSTATE (2,state);
+ state = SCM_VARIABLE_REF (scm_var_random_state);
+ SCM_VALIDATE_RSTATE (2, state);
scm_random_normal_vector_x (v, state);
- vector_scale (v, 1 / sqrt (vector_sum_squares (v)));
+ vector_scale_x (v, 1 / sqrt (vector_sum_squares (v)));
return SCM_UNSPECIFIED;
}
#undef FUNC_NAME
"(i.e., with mean 0 and variance 1).")
#define FUNC_NAME s_scm_random_normal_vector_x
{
- int n;
- SCM_VALIDATE_VECTOR_OR_DVECTOR (1,v);
+ long i;
+ scm_t_array_handle handle;
+ scm_t_array_dim *dim;
+
if (SCM_UNBNDP (state))
- state = SCM_CDR (scm_var_random_state);
- SCM_VALIDATE_RSTATE (2,state);
- n = SCM_INUM (scm_uniform_vector_length (v));
- if (SCM_VECTORP (v))
- while (--n >= 0)
- SCM_VELTS (v)[n] = scm_make_real (scm_c_normal01 (SCM_RSTATE (state)));
+ state = SCM_VARIABLE_REF (scm_var_random_state);
+ SCM_VALIDATE_RSTATE (2, state);
+
+ scm_generalized_vector_get_handle (v, &handle);
+ dim = scm_array_handle_dims (&handle);
+
+ if (scm_is_vector (v))
+ {
+ SCM *elts = scm_array_handle_writable_elements (&handle);
+ for (i = dim->lbnd; i <= dim->ubnd; i++, elts += dim->inc)
+ *elts = scm_from_double (scm_c_normal01 (SCM_RSTATE (state)));
+ }
else
- while (--n >= 0)
- ((double *) SCM_VELTS (v))[n] = scm_c_normal01 (SCM_RSTATE (state));
+ {
+ /* must be a f64vector. */
+ double *elts = scm_array_handle_f64_writable_elements (&handle);
+ for (i = dim->lbnd; i <= dim->ubnd; i++, elts += dim->inc)
+ *elts = scm_c_normal01 (SCM_RSTATE (state));
+ }
+
+ scm_array_handle_release (&handle);
+
return SCM_UNSPECIFIED;
}
#undef FUNC_NAME
-#endif /* HAVE_ARRAYS */
-
SCM_DEFINE (scm_random_exp, "random:exp", 0, 1, 0,
(SCM state),
"Return an inexact real in an exponential distribution with mean\n"
#define FUNC_NAME s_scm_random_exp
{
if (SCM_UNBNDP (state))
- state = SCM_CDR (scm_var_random_state);
- SCM_VALIDATE_RSTATE (1,state);
- return scm_make_real (scm_c_exp1 (SCM_RSTATE (state)));
+ state = SCM_VARIABLE_REF (scm_var_random_state);
+ SCM_VALIDATE_RSTATE (1, state);
+ return scm_from_double (scm_c_exp1 (SCM_RSTATE (state)));
}
#undef FUNC_NAME
{
int i, m;
/* plug in default RNG */
- scm_rng rng =
+ scm_t_rng rng =
{
- sizeof (scm_i_rstate),
+ sizeof (scm_t_i_rstate),
(unsigned long (*)()) scm_i_uniform32,
(void (*)()) scm_i_init_rstate,
- (scm_rstate *(*)()) scm_i_copy_rstate
+ (scm_t_rstate *(*)()) scm_i_copy_rstate
};
scm_the_rng = rng;
for (i = m >> 1; i < m; ++i)
scm_masktab[i] = m - 1;
-#ifndef SCM_MAGIC_SNARFER
#include "libguile/random.x"
-#endif
- /* Check that the assumptions about bits per bignum digit are correct. */
-#if SIZEOF_INT == 4
- m = 16;
-#else
- m = 32;
-#endif
- if (m != SCM_BITSPERDIG)
- {
- fprintf (stderr, "Internal inconsistency: Confused about bignum digit size in random.c\n");
- exit (1);
- }
-
scm_add_feature ("random");
}