//===----------------------------------------------------------------------===// // // 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. // //===----------------------------------------------------------------------===// // // REQUIRES: long_tests // // template // class poisson_distribution // template result_type operator()(_URNG& g); #include #include #include #include template inline T sqr(T x) { return x * x; } void test_bad_ranges() { // Test cases where the mean is around the largest representable integer for // `result_type`. These cases don't generate valid poisson distributions, but // at least they don't blow up. std::mt19937 eng; { std::poisson_distribution distribution(32710.9); for (int i=0; i < 1000; ++i) { volatile std::int16_t res = distribution(eng); ((void)res); } } { std::poisson_distribution distribution(std::numeric_limits::max()); for (int i=0; i < 1000; ++i) { volatile std::int16_t res = distribution(eng); ((void)res); } } { std::poisson_distribution distribution( static_cast(std::numeric_limits::max()) + 10); for (int i=0; i < 1000; ++i) { volatile std::int16_t res = distribution(eng); ((void)res); } } { std::poisson_distribution distribution( static_cast(std::numeric_limits::max()) * 2); for (int i=0; i < 1000; ++i) { volatile std::int16_t res = distribution(eng); ((void)res); } } { // We convert `INF` to `DBL_MAX` otherwise the distribution will hang. std::poisson_distribution distribution(std::numeric_limits::infinity()); for (int i=0; i < 1000; ++i) { volatile std::int16_t res = distribution(eng); ((void)res); } } { std::poisson_distribution distribution(0); for (int i=0; i < 1000; ++i) { volatile std::int16_t res = distribution(eng); ((void)res); } } { // We convert `INF` to `DBL_MAX` otherwise the distribution will hang. std::poisson_distribution distribution(-100); for (int i=0; i < 1000; ++i) { volatile std::int16_t res = distribution(eng); ((void)res); } } } int main() { { typedef std::poisson_distribution<> D; typedef std::minstd_rand G; G g; D d(2); const int N = 100000; std::vector u; for (int i = 0; i < N; ++i) { D::result_type v = d(g); assert(d.min() <= v && v <= d.max()); u.push_back(v); } double mean = std::accumulate(u.begin(), u.end(), 0.0) / u.size(); double var = 0; double skew = 0; double kurtosis = 0; for (unsigned i = 0; i < u.size(); ++i) { double dbl = (u[i] - mean); double d2 = sqr(dbl); var += d2; skew += dbl * d2; kurtosis += d2 * d2; } var /= u.size(); double dev = std::sqrt(var); skew /= u.size() * dev * var; kurtosis /= u.size() * var * var; kurtosis -= 3; double x_mean = d.mean(); double x_var = d.mean(); double x_skew = 1 / std::sqrt(x_var); double x_kurtosis = 1 / x_var; 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) / x_skew) < 0.01); assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.03); } { typedef std::poisson_distribution<> D; typedef std::minstd_rand G; G g; D d(0.75); const int N = 100000; std::vector u; for (int i = 0; i < N; ++i) { D::result_type v = d(g); assert(d.min() <= v && v <= d.max()); u.push_back(v); } double mean = std::accumulate(u.begin(), u.end(), 0.0) / u.size(); double var = 0; double skew = 0; double kurtosis = 0; for (unsigned i = 0; i < u.size(); ++i) { double dbl = (u[i] - mean); double d2 = sqr(dbl); var += d2; skew += dbl * d2; kurtosis += d2 * d2; } var /= u.size(); double dev = std::sqrt(var); skew /= u.size() * dev * var; kurtosis /= u.size() * var * var; kurtosis -= 3; double x_mean = d.mean(); double x_var = d.mean(); double x_skew = 1 / std::sqrt(x_var); double x_kurtosis = 1 / x_var; 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) / x_skew) < 0.01); assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.04); } { typedef std::poisson_distribution<> D; typedef std::mt19937 G; G g; D d(20); const int N = 1000000; std::vector u; for (int i = 0; i < N; ++i) { D::result_type v = d(g); assert(d.min() <= v && v <= d.max()); u.push_back(v); } double mean = std::accumulate(u.begin(), u.end(), 0.0) / u.size(); double var = 0; double skew = 0; double kurtosis = 0; for (unsigned i = 0; i < u.size(); ++i) { double dbl = (u[i] - mean); double d2 = sqr(dbl); var += d2; skew += dbl * d2; kurtosis += d2 * d2; } var /= u.size(); double dev = std::sqrt(var); skew /= u.size() * dev * var; kurtosis /= u.size() * var * var; kurtosis -= 3; double x_mean = d.mean(); double x_var = d.mean(); double x_skew = 1 / std::sqrt(x_var); double x_kurtosis = 1 / x_var; 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) / x_skew) < 0.01); assert(std::abs((kurtosis - x_kurtosis) / x_kurtosis) < 0.01); } test_bad_ranges(); }