-/* Copyright (c) 2019. The SimGrid Team. All rights reserved. */
+/* Copyright (c) 2019-2021. The SimGrid Team. All rights reserved. */
/* This program is free software; you can redistribute it and/or modify it
* under the terms of the license (GNU LGPL) which comes with this package. */
-#include "xbt/random.hpp"
#include "xbt/asserts.h"
+#include <fstream>
+#include <iostream>
#include <limits>
-#include <random>
+#include <memory>
+#include <string>
+#include <xbt/log.hpp>
+#include <xbt/random.hpp>
+
+XBT_LOG_EXTERNAL_CATEGORY(xbt);
+XBT_LOG_NEW_DEFAULT_SUBCATEGORY(xbt_random, xbt, "Random");
namespace simgrid {
namespace xbt {
namespace random {
-std::mt19937 mt19937_gen;
-xbt_random_method current_rng = XBT_RNG_xbt;
-void use_xbt()
+bool Random::read_state(const std::string& filename)
{
- current_rng = XBT_RNG_xbt;
+ std::ifstream file(filename);
+ file >> mt19937_gen;
+ file.close();
+ if (file.fail())
+ XBT_WARN("Could not save the RNG state to file %s.", filename.c_str());
+ return not file.fail();
}
-void use_std()
+
+bool Random::write_state(const std::string& filename) const
{
- current_rng = XBT_RNG_std;
+ std::ofstream file(filename);
+ file << mt19937_gen;
+ file.close();
+ if (file.fail())
+ XBT_WARN("Could not read the RNG state from file %s.", filename.c_str());
+ return not file.fail();
}
-int uniform_int(int min, int max)
+int StdRandom::uniform_int(int min, int max)
{
- switch (current_rng) {
- case XBT_RNG_xbt:
- return xbt_uniform_int(min, max);
- case XBT_RNG_std: {
- std::uniform_int_distribution<> dist(min, max);
- return dist(mt19937_gen);
- }
- default:
- xbt_assert(false, "The uniform integer distribution is not yet supported for the current RNG.");
- }
-}
-
-int xbt_uniform_int(int min, int max)
-{
- unsigned long gmin = mt19937_gen.min();
- unsigned long gmax = mt19937_gen.max();
- unsigned long grange = gmax - gmin + 1;
- unsigned long range = max - min + 1;
- xbt_assert(
- min <= max,
- "The maximum value for the uniform integer distribution must be greater than or equal to the minimum value");
- xbt_assert(range <= grange, "The current implementation of the uniform integer distribution does not allow range to "
- "be higher than mt19937's range");
- unsigned long mult = grange / range;
- unsigned long maxallowed = gmin + (mult + 1) * range - 1;
- while (true) {
- unsigned long value = mt19937_gen();
- if (value > maxallowed) {
- } else {
- return value % range + min;
- }
- }
+ std::uniform_int_distribution<> dist(min, max);
+ return dist(mt19937_gen);
}
-double uniform_real(double min, double max)
+double StdRandom::uniform_real(double min, double max)
{
- switch (current_rng) {
- case XBT_RNG_xbt:
- return xbt_uniform_real(min, max);
- case XBT_RNG_std: {
- std::uniform_real_distribution<> dist(min, max);
- return dist(mt19937_gen);
- }
- default:
- xbt_assert(false, "The uniform real distribution is not yet supported for the current RNG.");
- }
+ std::uniform_real_distribution<> dist(min, max);
+ return dist(mt19937_gen);
}
-double xbt_uniform_real(double min, double max)
+double StdRandom::exponential(double lambda)
{
- // This reuses Boost's uniform real distribution ideas
- unsigned long numerator = mt19937_gen() - mt19937_gen.min();
- unsigned long divisor = mt19937_gen.max() - mt19937_gen.min();
- return min + (max - min) * numerator / divisor;
+ std::exponential_distribution<> dist(lambda);
+ return dist(mt19937_gen);
}
-double exponential(double lambda)
+double StdRandom::normal(double mean, double sd)
{
- switch (current_rng) {
- case XBT_RNG_xbt:
- return xbt_exponential(lambda);
- case XBT_RNG_std: {
- std::exponential_distribution<> dist(lambda);
- return dist(mt19937_gen);
- }
- default:
- xbt_assert(false, "The exponential distribution is not yet supported for the current RNG.");
- }
+ std::normal_distribution<> dist(mean, sd);
+ return dist(mt19937_gen);
}
-double xbt_exponential(double lambda)
+int XbtRandom::uniform_int(int min, int max)
{
- return -1 / lambda * log(uniform_real(0, 1));
+ // The casts to unsigned are here to ensure that the value of range is correctly calculated, even when greater than
+ // INT_MAX. See the corresponding unit tests for examples.
+ unsigned long range = static_cast<unsigned>(max) - static_cast<unsigned>(min);
+ xbt_assert(min <= max,
+ "The minimum value for the uniform integer distribution must not be greater than the maximum value");
+ xbt_assert(range <= decltype(mt19937_gen)::max(),
+ "Overflow in the uniform integer distribution, please use a smaller range.");
+ if (range == decltype(mt19937_gen)::max())
+ return static_cast<int>(mt19937_gen() + min);
+
+ ++range;
+ unsigned long limit = decltype(mt19937_gen)::max() - decltype(mt19937_gen)::max() % range;
+ unsigned long value;
+ do {
+ value = mt19937_gen();
+ } while (value >= limit);
+ return static_cast<int>(value % range + min);
}
-double normal(double mean, double sd)
+double XbtRandom::uniform_real(double min, double max)
+{
+ // This reuses Boost's uniform real distribution ideas
+ constexpr unsigned long divisor = decltype(mt19937_gen)::max() - decltype(mt19937_gen)::min();
+ unsigned long numerator;
+ do {
+ numerator = mt19937_gen() - decltype(mt19937_gen)::min();
+ } while (numerator == divisor);
+ return min + (max - min) * static_cast<double>(numerator) / divisor;
+}
+
+double XbtRandom::exponential(double lambda)
+{
+ return -1.0 / lambda * log(uniform_real(0.0, 1.0));
+}
+
+double XbtRandom::normal(double mean, double sd)
{
- switch (current_rng) {
- case XBT_RNG_xbt:
- return xbt_normal(mean, sd);
- case XBT_RNG_std: {
- std::normal_distribution<> dist(mean, sd);
- return dist(mt19937_gen);
- }
- default:
- xbt_assert(false, "The normal distribution is not yet supported for the curent RNG.");
- }
-}
-
-double xbt_normal(double mean, double sd)
-{
- double u1 = 0;
- while (u1 < std::numeric_limits<double>::min()) {
- u1 = uniform_real(0, 1);
- }
- double u2 = uniform_real(0, 1);
- double z0 = sqrt(-2.0 * log(u1)) * cos(2 * M_PI * u2);
+ double u1;
+ do {
+ u1 = uniform_real(0.0, 1.0);
+ } while (u1 < std::numeric_limits<double>::min());
+ double u2 = uniform_real(0.0, 1.0);
+ double z0 = sqrt(-2.0 * log(u1)) * cos(2.0 * M_PI * u2);
return z0 * sd + mean;
}
+static std::unique_ptr<Random> default_random = std::make_unique<XbtRandom>();
+
+void set_implem_xbt()
+{
+ default_random = std::make_unique<XbtRandom>();
+}
+void set_implem_std()
+{
+ default_random = std::make_unique<StdRandom>();
+}
+
void set_mersenne_seed(int seed)
{
- mt19937_gen.seed(seed);
+ default_random->set_seed(seed);
+}
+
+bool read_mersenne_state(const std::string& filename)
+{
+ return default_random->read_state(filename);
+}
+
+bool write_mersenne_state(const std::string& filename)
+{
+ return default_random->write_state(filename);
+}
+
+int uniform_int(int min, int max)
+{
+ return default_random->uniform_int(min, max);
+}
+
+double uniform_real(double min, double max)
+{
+ return default_random->uniform_real(min, max);
+}
+
+double exponential(double lambda)
+{
+ return default_random->exponential(lambda);
+}
+
+double normal(double mean, double sd)
+{
+ return default_random->normal(mean, sd);
}
} // namespace random