cxx/test/numerics/rand/rand.dis/rand.dist.uni/rand.dist.uni.real/eval.pass.cpp
Howard Hinnant b64f8b07c1 license change
git-svn-id: https://llvm.org/svn/llvm-project/libcxx/trunk@119395 91177308-0d34-0410-b5e6-96231b3b80d8
2010-11-16 22:09:02 +00:00

473 lines
16 KiB
C++

//===----------------------------------------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is dual licensed under the MIT and the University of Illinois Open
// Source Licenses. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
// <random>
// template<class RealType = double>
// class uniform_real_distribution
// template<class _URNG> result_type operator()(_URNG& g);
#include <random>
#include <cassert>
#include <vector>
#include <numeric>
template <class T>
inline
T
sqr(T x)
{
return x * x;
}
int main()
{
{
typedef std::uniform_real_distribution<> D;
typedef std::minstd_rand0 G;
G g;
D d;
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::minstd_rand G;
G g;
D d;
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::mt19937 G;
G g;
D d;
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::mt19937_64 G;
G g;
D d;
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::ranlux24_base G;
G g;
D d;
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.02);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::ranlux48_base G;
G g;
D d;
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::ranlux24 G;
G g;
D d;
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::ranlux48 G;
G g;
D d;
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::knuth_b G;
G g;
D d;
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::minstd_rand G;
G g;
D d(-1, 1);
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs(mean - x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
{
typedef std::uniform_real_distribution<> D;
typedef std::minstd_rand G;
G g;
D d(5.5, 25);
const int N = 100000;
std::vector<D::result_type> u;
for (int i = 0; i < N; ++i)
{
D::result_type v = d(g);
assert(d.a() <= v && v < d.b());
u.push_back(v);
}
D::result_type mean = std::accumulate(u.begin(), u.end(),
D::result_type(0)) / u.size();
D::result_type var = 0;
D::result_type skew = 0;
D::result_type kurtosis = 0;
for (int i = 0; i < u.size(); ++i)
{
D::result_type d = (u[i] - mean);
D::result_type d2 = sqr(d);
var += d2;
skew += d * d2;
kurtosis += d2 * d2;
}
var /= u.size();
D::result_type dev = std::sqrt(var);
skew /= u.size() * dev * var;
kurtosis /= u.size() * var * var;
kurtosis -= 3;
D::result_type x_mean = (d.a() + d.b()) / 2;
D::result_type x_var = sqr(d.b() - d.a()) / 12;
D::result_type x_skew = 0;
D::result_type x_kurtosis = -6./5;
assert(std::abs((mean - x_mean) / x_mean) < 0.01);
assert(std::abs((var - x_var) / x_var) < 0.01);
assert(std::abs(skew - x_skew) < 0.01);
assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01);
}
}