+#include "simgrid_config.h" /*_XBT_WIN32*/
+
+#ifdef _XBT_WIN32
+
+static unsigned int _seed = 2147483647;
+
+#ifdef __VISUALC__
+typedef unsigned __int64 uint64_t;
+typedef unsigned int uint32_t;
+#endif
+
+struct drand48_data {
+ unsigned short int __x[3]; /* Current state. */
+ unsigned short int __old_x[3]; /* Old state. */
+ unsigned short int __c; /* Additive const. in congruential formula. */
+ unsigned short int __init; /* Flag for initializing. */
+ unsigned long long int __a; /* Factor in congruential formula. */
+};
+
+static struct drand48_data __libc_drand48_data = { 0 };
+
+union ieee754_double {
+ double d;
+
+ /* This is the IEEE 754 double-precision format. */
+ struct {
+ /* Together these comprise the mantissa. */
+ unsigned int mantissa1:32;
+ unsigned int mantissa0:20;
+ unsigned int exponent:11;
+ unsigned int negative:1;
+ /* Little endian. */
+ } ieee;
+
+ /* This format makes it easier to see if a NaN is a signalling NaN. */
+ struct {
+ /* Together these comprise the mantissa. */
+ unsigned int mantissa1:32;
+ unsigned int mantissa0:19;
+ unsigned int quiet_nan:1;
+ unsigned int exponent:11;
+ unsigned int negative:1;
+
+ } ieee_nan;
+};
+
+#define IEEE754_DOUBLE_BIAS 0x3ff /* Added to exponent. */
+
+double drand48(void);
+
+int
+_drand48_iterate(unsigned short int xsubi[3], struct drand48_data *buffer);
+
+int
+_erand48_r(unsigned short int xsubi[3], struct drand48_data *buffer,
+ double *result);
+
+
+int
+_erand48_r(unsigned short int xsubi[3], struct drand48_data *buffer,
+ double *result)
+{
+ union ieee754_double temp;
+
+ /* Compute next state. */
+ if (_drand48_iterate(xsubi, buffer) < 0)
+ return -1;
+
+ /* Construct a positive double with the 48 random bits distributed over
+ its fractional part so the resulting FP number is [0.0,1.0). */
+
+ temp.ieee.negative = 0;
+ temp.ieee.exponent = IEEE754_DOUBLE_BIAS;
+ temp.ieee.mantissa0 = (xsubi[2] << 4) | (xsubi[1] >> 12);
+ temp.ieee.mantissa1 = ((xsubi[1] & 0xfff) << 20) | (xsubi[0] << 4);
+
+ /* Please note the lower 4 bits of mantissa1 are always 0. */
+ *result = temp.d - 1.0;
+
+ return 0;
+}
+
+int _drand48_iterate(unsigned short int xsubi[3],
+ struct drand48_data *buffer)
+{
+ uint64_t X;
+ uint64_t result;
+
+ /* Initialize buffer, if not yet done. */
+
+ if (buffer->__init == 0) {
+ buffer->__a = 0x5deece66dull;
+ buffer->__c = 0xb;
+ buffer->__init = 1;
+ }
+
+ /* Do the real work. We choose a data type which contains at least
+ 48 bits. Because we compute the modulus it does not care how
+ many bits really are computed. */
+
+ X = (uint64_t) xsubi[2] << 32 | (uint32_t) xsubi[1] << 16 | xsubi[0];
+
+ result = X * buffer->__a + buffer->__c;
+
+
+ xsubi[0] = result & 0xffff;
+ xsubi[1] = (result >> 16) & 0xffff;
+ xsubi[2] = (result >> 32) & 0xffff;
+
+ return 0;
+}
+
+
+double _drand48(void)
+{
+ double result;
+
+ (void) _erand48_r(__libc_drand48_data.__x, &__libc_drand48_data,
+ &result);
+
+ return result;
+}
+
+void _srand(unsigned int seed)
+{
+ _seed = seed;
+}
+
+int _rand(void)
+{
+ const long a = 16807;
+ const long m = 2147483647;
+ const long q = 127773; /* (m/a) */
+ const long r = 2836; /* (m%a) */
+
+ long lo, k, s;
+
+ s = (long) _seed;
+
+ k = (long) (s / q);
+
+ lo = (s - q * k);