catch2/include/internal/benchmark/detail/catch_stats.hpp

/*
 *  Created by Joachim on 16/04/2019.
 *  Adapted from donated nonius code.
 *
 *  Distributed under the Boost Software License, Version 1.0. (See accompanying
 *  file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 */

// Statistical analysis tools

#ifndef TWOBLUECUBES_CATCH_DETAIL_ANALYSIS_HPP_INCLUDED
#define TWOBLUECUBES_CATCH_DETAIL_ANALYSIS_HPP_INCLUDED

#include "../catch_clock.hpp"
#include "../catch_estimate.hpp"
#include "../catch_outlier_classification.hpp"

#include <algorithm>
#include <cassert>
#include <functional>
#include <iterator>
#include <vector>
#include <array>
#include <random>
#include <numeric>
#include <tuple>
#include <cmath>
#include <utility>
#include <cstddef>

#ifdef CATCH_USE_ASYNC
#include <future>
#endif

namespace Catch {
    namespace Benchmark {
        namespace Detail {
            using sample = std::vector<double>;

            template <typename Iterator>
            double weighted_average_quantile(int k, int q, Iterator first, Iterator last) {
                auto count = last - first;
                double idx = (count - 1) * k / static_cast<double>(q);
                int j = static_cast<int>(idx);
                double g = idx - j;
                std::nth_element(first, first + j, last);
                auto xj = first[j];
                if (g == 0) return xj;

                auto xj1 = *std::min_element(first + (j + 1), last);
                return xj + g * (xj1 - xj);
            }

            template <typename Iterator>
            OutlierClassification classify_outliers(Iterator first, Iterator last) {
                std::vector<double> copy(first, last);

                auto q1 = weighted_average_quantile(1, 4, copy.begin(), copy.end());
                auto q3 = weighted_average_quantile(3, 4, copy.begin(), copy.end());
                auto iqr = q3 - q1;
                auto los = q1 - (iqr * 3.);
                auto lom = q1 - (iqr * 1.5);
                auto him = q3 + (iqr * 1.5);
                auto his = q3 + (iqr * 3.);

                OutlierClassification o;
                for (; first != last; ++first) {
                    auto&& t = *first;
                    if (t < los) ++o.low_severe;
                    else if (t < lom) ++o.low_mild;
                    else if (t > his) ++o.high_severe;
                    else if (t > him) ++o.high_mild;
                    ++o.samples_seen;
                }
                return o;
            }

            template <typename Iterator>
            double mean(Iterator first, Iterator last) {
                auto count = last - first;
                double sum = std::accumulate(first, last, 0.);
                return sum / count;
            }

            template <typename Iterator>
            double standard_deviation(Iterator first, Iterator last) {
                auto m = mean(first, last);
                double variance = std::accumulate(first, last, 0., [m](double a, double b) {
                    double diff = b - m;
                    return a + diff * diff;
                }) / (last - first);
                return std::sqrt(variance);
            }

            template <typename URng, typename Iterator, typename Estimator>
            sample resample(URng& rng, int resamples, Iterator first, Iterator last, Estimator& estimator) {
                auto n = last - first;
                std::uniform_int_distribution<decltype(n)> dist(0, n - 1);

                sample out;
                out.reserve(resamples);
                std::generate_n(std::back_inserter(out), resamples, [n, first, &estimator, &dist, &rng] {
                    std::vector<double> resampled;
                    resampled.reserve(n);
                    std::generate_n(std::back_inserter(resampled), n, [first, &dist, &rng] { return first[dist(rng)]; });
                    return estimator(resampled.begin(), resampled.end());
                });
                std::sort(out.begin(), out.end());
                return out;
            }

            template <typename Estimator, typename Iterator>
            sample jackknife(Estimator&& estimator, Iterator first, Iterator last) {
                auto n = last - first;
                auto second = std::next(first);
                sample results;
                results.reserve(n);

                for (auto it = first; it != last; ++it) {
                    std::iter_swap(it, first);
                    results.push_back(estimator(second, last));
                }

                return results;
            }

            inline double normal_cdf(double x) {
                return std::erfc(-x / std::sqrt(2.0)) / 2.0;
            }

            inline double erf_inv(double x) {
                // Code accompanying the article "Approximating the erfinv function" in GPU Computing Gems, Volume 2
                double w, p;

                w = -log((1.0 - x)*(1.0 + x));

                if (w < 6.250000) {
                    w = w - 3.125000;
                    p = -3.6444120640178196996e-21;
                    p = -1.685059138182016589e-19 + p * w;
                    p = 1.2858480715256400167e-18 + p * w;
                    p = 1.115787767802518096e-17 + p * w;
                    p = -1.333171662854620906e-16 + p * w;
                    p = 2.0972767875968561637e-17 + p * w;
                    p = 6.6376381343583238325e-15 + p * w;
                    p = -4.0545662729752068639e-14 + p * w;
                    p = -8.1519341976054721522e-14 + p * w;
                    p = 2.6335093153082322977e-12 + p * w;
                    p = -1.2975133253453532498e-11 + p * w;
                    p = -5.4154120542946279317e-11 + p * w;
                    p = 1.051212273321532285e-09 + p * w;
                    p = -4.1126339803469836976e-09 + p * w;
                    p = -2.9070369957882005086e-08 + p * w;
                    p = 4.2347877827932403518e-07 + p * w;
                    p = -1.3654692000834678645e-06 + p * w;
                    p = -1.3882523362786468719e-05 + p * w;
                    p = 0.0001867342080340571352 + p * w;
                    p = -0.00074070253416626697512 + p * w;
                    p = -0.0060336708714301490533 + p * w;
                    p = 0.24015818242558961693 + p * w;
                    p = 1.6536545626831027356 + p * w;
                } else if (w < 16.000000) {
                    w = sqrt(w) - 3.250000;
                    p = 2.2137376921775787049e-09;
                    p = 9.0756561938885390979e-08 + p * w;
                    p = -2.7517406297064545428e-07 + p * w;
                    p = 1.8239629214389227755e-08 + p * w;
                    p = 1.5027403968909827627e-06 + p * w;
                    p = -4.013867526981545969e-06 + p * w;
                    p = 2.9234449089955446044e-06 + p * w;
                    p = 1.2475304481671778723e-05 + p * w;
                    p = -4.7318229009055733981e-05 + p * w;
                    p = 6.8284851459573175448e-05 + p * w;
                    p = 2.4031110387097893999e-05 + p * w;
                    p = -0.0003550375203628474796 + p * w;
                    p = 0.00095328937973738049703 + p * w;
                    p = -0.0016882755560235047313 + p * w;
                    p = 0.0024914420961078508066 + p * w;
                    p = -0.0037512085075692412107 + p * w;
                    p = 0.005370914553590063617 + p * w;
                    p = 1.0052589676941592334 + p * w;
                    p = 3.0838856104922207635 + p * w;
                } else {
                    w = sqrt(w) - 5.000000;
                    p = -2.7109920616438573243e-11;
                    p = -2.5556418169965252055e-10 + p * w;
                    p = 1.5076572693500548083e-09 + p * w;
                    p = -3.7894654401267369937e-09 + p * w;
                    p = 7.6157012080783393804e-09 + p * w;
                    p = -1.4960026627149240478e-08 + p * w;
                    p = 2.9147953450901080826e-08 + p * w;
                    p = -6.7711997758452339498e-08 + p * w;
                    p = 2.2900482228026654717e-07 + p * w;
                    p = -9.9298272942317002539e-07 + p * w;
                    p = 4.5260625972231537039e-06 + p * w;
                    p = -1.9681778105531670567e-05 + p * w;
                    p = 7.5995277030017761139e-05 + p * w;
                    p = -0.00021503011930044477347 + p * w;
                    p = -0.00013871931833623122026 + p * w;
                    p = 1.0103004648645343977 + p * w;
                    p = 4.8499064014085844221 + p * w;
                }
                return p * x;
            }

            inline double erfc_inv(double x) {
                return erf_inv(1.0 - x);
            }

            inline double normal_quantile(double p) {
                static const double ROOT_TWO = std::sqrt(2.0);

                double result = 0.0;
                assert(p >= 0 && p <= 1);
                if (p < 0 || p > 1) {
                    return result;
                }

                result = -erfc_inv(2.0 * p);
                // result *= normal distribution standard deviation (1.0) * sqrt(2)
                result *= /*sd * */ ROOT_TWO;
                // result += normal disttribution mean (0)
                return result;
            }

            template <typename Iterator, typename Estimator>
            Estimate<double> bootstrap(double confidence_level, Iterator first, Iterator last, sample const& resample, Estimator&& estimator) {
                auto n_samples = last - first;

                double point = estimator(first, last);
                // Degenerate case with a single sample
                if (n_samples == 1) return { point, point, point, confidence_level };

                sample jack = jackknife(estimator, first, last);
                double jack_mean = mean(jack.begin(), jack.end());
                double sum_squares, sum_cubes;
                std::tie(sum_squares, sum_cubes) = std::accumulate(jack.begin(), jack.end(), std::make_pair(0., 0.), [jack_mean](std::pair<double, double> sqcb, double x) -> std::pair<double, double> {
                    auto d = jack_mean - x;
                    auto d2 = d * d;
                    auto d3 = d2 * d;
                    return { sqcb.first + d2, sqcb.second + d3 };
                });

                double accel = sum_cubes / (6 * std::pow(sum_squares, 1.5));
                int n = static_cast<int>(resample.size());
                double prob_n = std::count_if(resample.begin(), resample.end(), [point](double x) { return x < point; }) / (double)n;
                // degenerate case with uniform samples
                if (prob_n == 0) return { point, point, point, confidence_level };

                double bias = normal_quantile(prob_n);
                double z1 = normal_quantile((1. - confidence_level) / 2.);

                auto cumn = [n](double x) -> int {
                    return std::lround(normal_cdf(x) * n); };
                auto a = [bias, accel](double b) { return bias + b / (1. - accel * b); };
                double b1 = bias + z1;
                double b2 = bias - z1;
                double a1 = a(b1);
                double a2 = a(b2);
                auto lo = std::max(cumn(a1), 0);
                auto hi = std::min(cumn(a2), n - 1);

                return { point, resample[lo], resample[hi], confidence_level };
            }

            inline double outlier_variance(Estimate<double> mean, Estimate<double> stddev, int n) {
                double sb = stddev.point;
                double mn = mean.point / n;
                double mg_min = mn / 2.;
                double sg = std::min(mg_min / 4., sb / std::sqrt(n));
                double sg2 = sg * sg;
                double sb2 = sb * sb;

                auto c_max = [n, mn, sb2, sg2](double x) -> double {
                    double k = mn - x;
                    double d = k * k;
                    double nd = n * d;
                    double k0 = -n * nd;
                    double k1 = sb2 - n * sg2 + nd;
                    double det = k1 * k1 - 4 * sg2 * k0;
                    return (int)(-2. * k0 / (k1 + std::sqrt(det)));
                };

                auto var_out = [n, sb2, sg2](double c) {
                    double nc = n - c;
                    return (nc / n) * (sb2 - nc * sg2);
                };

                return std::min(var_out(1), var_out(std::min(c_max(0.), c_max(mg_min)))) / sb2;
            }

            struct bootstrap_analysis {
                Estimate<double> mean;
                Estimate<double> standard_deviation;
                double outlier_variance;
            };

            template <typename Iterator>
            bootstrap_analysis analyse_samples(double confidence_level, int n_resamples, Iterator first, Iterator last) {
                static std::random_device entropy;

                auto n = static_cast<int>(last - first); // seriously, one can't use integral types without hell in C++

                auto mean = &Detail::mean<Iterator>;
                auto stddev = &Detail::standard_deviation<Iterator>;

#ifdef CATCH_USE_ASYNC
                auto Estimate = [=](double(*f)(Iterator, Iterator)) {
                    auto seed = entropy();
                    return std::async(std::launch::async, [=] {
                        std::mt19937 rng(seed);
                        auto resampled = resample(rng, n_resamples, first, last, f);
                        return bootstrap(confidence_level, first, last, resampled, f);
                    });
                };

                auto mean_future = Estimate(mean);
                auto stddev_future = Estimate(stddev);

                auto mean_estimate = mean_future.get();
                auto stddev_estimate = stddev_future.get();
#else
                auto Estimate = [=](double(*f)(Iterator, Iterator)) {
                    auto seed = entropy();
                    std::mt19937 rng(seed);
                    auto resampled = resample(rng, n_resamples, first, last, f);
                    return bootstrap(confidence_level, first, last, resampled, f);
                };

                auto mean_estimate = Estimate(mean);
                auto stddev_estimate = Estimate(stddev);
#endif // CATCH_USE_ASYNC

                double outlier_variance = Detail::outlier_variance(mean_estimate, stddev_estimate, n);

                return { mean_estimate, stddev_estimate, outlier_variance };
            }
        } // namespace Detail
    } // namespace Benchmark
} // namespace Catch

#endif // TWOBLUECUBES_CATCH_DETAIL_ANALYSIS_HPP_INCLUDED
Integrate Nonius benchmark into Catch2 Changes done to Nonius: * Moved things into "Catch::Benchmark" namespace * Benchmarks were integrated with `TEST_CASE`/`SECTION`/`GENERATE` macros * Removed Nonius's parameters for benchmarks, Generators should be used instead * Added relevant methods to the reporter interface (default-implemented, to avoid breaking existing 3rd party reporters) * Async processing is guarded with `_REENTRANT` macro for GCC/Clang, used by default on MSVC * Added a macro `CATCH_CONFIG_DISABLE_BENCHMARKING` that removes all traces of benchmarking from Catch 2019-04-23 23:41:13 +02:00			`/*`
			`* Created by Joachim on 16/04/2019.`
			`* Adapted from donated nonius code.`
			`*`
			`* Distributed under the Boost Software License, Version 1.0. (See accompanying`
			`* file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)`
			`*/`

			`// Statistical analysis tools`

			`#ifndef TWOBLUECUBES_CATCH_DETAIL_ANALYSIS_HPP_INCLUDED`
			`#define TWOBLUECUBES_CATCH_DETAIL_ANALYSIS_HPP_INCLUDED`

			`#include "../catch_clock.hpp"`
			`#include "../catch_estimate.hpp"`
			`#include "../catch_outlier_classification.hpp"`

			`#include <algorithm>`
			`#include <cassert>`
			`#include <functional>`
			`#include <iterator>`
			`#include <vector>`
			`#include <array>`
			`#include <random>`
			`#include <numeric>`
			`#include <tuple>`
			`#include <cmath>`
			`#include <utility>`
			`#include <cstddef>`

			`#ifdef CATCH_USE_ASYNC`
			`#include <future>`
			`#endif`

			`namespace Catch {`
			`namespace Benchmark {`
			`namespace Detail {`
			`using sample = std::vector<double>;`

			`template <typename Iterator>`
			`double weighted_average_quantile(int k, int q, Iterator first, Iterator last) {`
			`auto count = last - first;`
			`double idx = (count - 1) * k / static_cast<double>(q);`
			`int j = static_cast<int>(idx);`
			`double g = idx - j;`
			`std::nth_element(first, first + j, last);`
			`auto xj = first[j];`
			`if (g == 0) return xj;`

			`auto xj1 = *std::min_element(first + (j + 1), last);`
			`return xj + g * (xj1 - xj);`
			`}`

			`template <typename Iterator>`
			`OutlierClassification classify_outliers(Iterator first, Iterator last) {`
			`std::vector<double> copy(first, last);`

			`auto q1 = weighted_average_quantile(1, 4, copy.begin(), copy.end());`
			`auto q3 = weighted_average_quantile(3, 4, copy.begin(), copy.end());`
			`auto iqr = q3 - q1;`
			`auto los = q1 - (iqr * 3.);`
			`auto lom = q1 - (iqr * 1.5);`
			`auto him = q3 + (iqr * 1.5);`
			`auto his = q3 + (iqr * 3.);`

			`OutlierClassification o;`
			`for (; first != last; ++first) {`
			`auto&& t = *first;`
			`if (t < los) ++o.low_severe;`
			`else if (t < lom) ++o.low_mild;`
			`else if (t > his) ++o.high_severe;`
			`else if (t > him) ++o.high_mild;`
			`++o.samples_seen;`
			`}`
			`return o;`
			`}`

			`template <typename Iterator>`
			`double mean(Iterator first, Iterator last) {`
			`auto count = last - first;`
			`double sum = std::accumulate(first, last, 0.);`
			`return sum / count;`
			`}`

			`template <typename Iterator>`
			`double standard_deviation(Iterator first, Iterator last) {`
			`auto m = mean(first, last);`
			`double variance = std::accumulate(first, last, 0., [m](double a, double b) {`
			`double diff = b - m;`
			`return a + diff * diff;`
			`}) / (last - first);`
			`return std::sqrt(variance);`
			`}`

			`template <typename URng, typename Iterator, typename Estimator>`
			`sample resample(URng& rng, int resamples, Iterator first, Iterator last, Estimator& estimator) {`
			`auto n = last - first;`
			`std::uniform_int_distribution<decltype(n)> dist(0, n - 1);`

			`sample out;`
			`out.reserve(resamples);`
			`std::generate_n(std::back_inserter(out), resamples, [n, first, &estimator, &dist, &rng] {`
			`std::vector<double> resampled;`
			`resampled.reserve(n);`
			`std::generate_n(std::back_inserter(resampled), n, [first, &dist, &rng] { return first[dist(rng)]; });`
			`return estimator(resampled.begin(), resampled.end());`
			`});`
			`std::sort(out.begin(), out.end());`
			`return out;`
			`}`

			`template <typename Estimator, typename Iterator>`
			`sample jackknife(Estimator&& estimator, Iterator first, Iterator last) {`
			`auto n = last - first;`
			`auto second = std::next(first);`
			`sample results;`
			`results.reserve(n);`

			`for (auto it = first; it != last; ++it) {`
			`std::iter_swap(it, first);`
			`results.push_back(estimator(second, last));`
			`}`

			`return results;`
			`}`

			`inline double normal_cdf(double x) {`
			`return std::erfc(-x / std::sqrt(2.0)) / 2.0;`
			`}`

			`inline double erf_inv(double x) {`
			`// Code accompanying the article "Approximating the erfinv function" in GPU Computing Gems, Volume 2`
			`double w, p;`

			`w = -log((1.0 - x)*(1.0 + x));`

			`if (w < 6.250000) {`
			`w = w - 3.125000;`
			`p = -3.6444120640178196996e-21;`
			`p = -1.685059138182016589e-19 + p * w;`
			`p = 1.2858480715256400167e-18 + p * w;`
			`p = 1.115787767802518096e-17 + p * w;`
			`p = -1.333171662854620906e-16 + p * w;`
			`p = 2.0972767875968561637e-17 + p * w;`
			`p = 6.6376381343583238325e-15 + p * w;`
			`p = -4.0545662729752068639e-14 + p * w;`
			`p = -8.1519341976054721522e-14 + p * w;`
			`p = 2.6335093153082322977e-12 + p * w;`
			`p = -1.2975133253453532498e-11 + p * w;`
			`p = -5.4154120542946279317e-11 + p * w;`
			`p = 1.051212273321532285e-09 + p * w;`
			`p = -4.1126339803469836976e-09 + p * w;`
			`p = -2.9070369957882005086e-08 + p * w;`
			`p = 4.2347877827932403518e-07 + p * w;`
			`p = -1.3654692000834678645e-06 + p * w;`
			`p = -1.3882523362786468719e-05 + p * w;`
			`p = 0.0001867342080340571352 + p * w;`
			`p = -0.00074070253416626697512 + p * w;`
			`p = -0.0060336708714301490533 + p * w;`
			`p = 0.24015818242558961693 + p * w;`
			`p = 1.6536545626831027356 + p * w;`
			`} else if (w < 16.000000) {`
			`w = sqrt(w) - 3.250000;`
			`p = 2.2137376921775787049e-09;`
			`p = 9.0756561938885390979e-08 + p * w;`
			`p = -2.7517406297064545428e-07 + p * w;`
			`p = 1.8239629214389227755e-08 + p * w;`
			`p = 1.5027403968909827627e-06 + p * w;`
			`p = -4.013867526981545969e-06 + p * w;`
			`p = 2.9234449089955446044e-06 + p * w;`
			`p = 1.2475304481671778723e-05 + p * w;`
			`p = -4.7318229009055733981e-05 + p * w;`
			`p = 6.8284851459573175448e-05 + p * w;`
			`p = 2.4031110387097893999e-05 + p * w;`
			`p = -0.0003550375203628474796 + p * w;`
			`p = 0.00095328937973738049703 + p * w;`
			`p = -0.0016882755560235047313 + p * w;`
			`p = 0.0024914420961078508066 + p * w;`
			`p = -0.0037512085075692412107 + p * w;`
			`p = 0.005370914553590063617 + p * w;`
			`p = 1.0052589676941592334 + p * w;`
			`p = 3.0838856104922207635 + p * w;`
			`} else {`
			`w = sqrt(w) - 5.000000;`
			`p = -2.7109920616438573243e-11;`
			`p = -2.5556418169965252055e-10 + p * w;`
			`p = 1.5076572693500548083e-09 + p * w;`
			`p = -3.7894654401267369937e-09 + p * w;`
			`p = 7.6157012080783393804e-09 + p * w;`
			`p = -1.4960026627149240478e-08 + p * w;`
			`p = 2.9147953450901080826e-08 + p * w;`
			`p = -6.7711997758452339498e-08 + p * w;`
			`p = 2.2900482228026654717e-07 + p * w;`
			`p = -9.9298272942317002539e-07 + p * w;`
			`p = 4.5260625972231537039e-06 + p * w;`
			`p = -1.9681778105531670567e-05 + p * w;`
			`p = 7.5995277030017761139e-05 + p * w;`
			`p = -0.00021503011930044477347 + p * w;`
			`p = -0.00013871931833623122026 + p * w;`
			`p = 1.0103004648645343977 + p * w;`
			`p = 4.8499064014085844221 + p * w;`
			`}`
			`return p * x;`
			`}`

			`inline double erfc_inv(double x) {`
			`return erf_inv(1.0 - x);`
			`}`

			`inline double normal_quantile(double p) {`
			`static const double ROOT_TWO = std::sqrt(2.0);`

			`double result = 0.0;`
			`assert(p >= 0 && p <= 1);`
			`if (p < 0 \|\| p > 1) {`
			`return result;`
			`}`

			`result = -erfc_inv(2.0 * p);`
			`// result = normal distribution standard deviation (1.0) sqrt(2)`
			`result = /sd * */ ROOT_TWO;`
			`// result += normal disttribution mean (0)`
			`return result;`
			`}`

			`template <typename Iterator, typename Estimator>`
			`Estimate<double> bootstrap(double confidence_level, Iterator first, Iterator last, sample const& resample, Estimator&& estimator) {`
			`auto n_samples = last - first;`

			`double point = estimator(first, last);`
			`// Degenerate case with a single sample`
			`if (n_samples == 1) return { point, point, point, confidence_level };`

			`sample jack = jackknife(estimator, first, last);`
			`double jack_mean = mean(jack.begin(), jack.end());`
			`double sum_squares, sum_cubes;`
			`std::tie(sum_squares, sum_cubes) = std::accumulate(jack.begin(), jack.end(), std::make_pair(0., 0.), [jack_mean](std::pair<double, double> sqcb, double x) -> std::pair<double, double> {`
			`auto d = jack_mean - x;`
			`auto d2 = d * d;`
			`auto d3 = d2 * d;`
			`return { sqcb.first + d2, sqcb.second + d3 };`
			`});`

			`double accel = sum_cubes / (6 * std::pow(sum_squares, 1.5));`
			`int n = static_cast<int>(resample.size());`
			`double prob_n = std::count_if(resample.begin(), resample.end(), [point](double x) { return x < point; }) / (double)n;`
			`// degenerate case with uniform samples`
			`if (prob_n == 0) return { point, point, point, confidence_level };`

			`double bias = normal_quantile(prob_n);`
			`double z1 = normal_quantile((1. - confidence_level) / 2.);`

			`auto cumn = [n](double x) -> int {`
			`return std::lround(normal_cdf(x) * n); };`
			`auto a = [bias, accel](double b) { return bias + b / (1. - accel * b); };`
			`double b1 = bias + z1;`
			`double b2 = bias - z1;`
			`double a1 = a(b1);`
			`double a2 = a(b2);`
			`auto lo = std::max(cumn(a1), 0);`
			`auto hi = std::min(cumn(a2), n - 1);`

			`return { point, resample[lo], resample[hi], confidence_level };`
			`}`

			`inline double outlier_variance(Estimate<double> mean, Estimate<double> stddev, int n) {`
			`double sb = stddev.point;`
			`double mn = mean.point / n;`
			`double mg_min = mn / 2.;`
			`double sg = std::min(mg_min / 4., sb / std::sqrt(n));`
			`double sg2 = sg * sg;`
			`double sb2 = sb * sb;`

			`auto c_max = [n, mn, sb2, sg2](double x) -> double {`
			`double k = mn - x;`
			`double d = k * k;`
			`double nd = n * d;`
			`double k0 = -n * nd;`
			`double k1 = sb2 - n * sg2 + nd;`
			`double det = k1 * k1 - 4 * sg2 * k0;`
			`return (int)(-2. * k0 / (k1 + std::sqrt(det)));`
			`};`

			`auto var_out = [n, sb2, sg2](double c) {`
			`double nc = n - c;`
			`return (nc / n) * (sb2 - nc * sg2);`
			`};`

			`return std::min(var_out(1), var_out(std::min(c_max(0.), c_max(mg_min)))) / sb2;`
			`}`

			`struct bootstrap_analysis {`
			`Estimate<double> mean;`
			`Estimate<double> standard_deviation;`
			`double outlier_variance;`
			`};`

			`template <typename Iterator>`
			`bootstrap_analysis analyse_samples(double confidence_level, int n_resamples, Iterator first, Iterator last) {`
			`static std::random_device entropy;`

			`auto n = static_cast<int>(last - first); // seriously, one can't use integral types without hell in C++`

			`auto mean = &Detail::mean<Iterator>;`
			`auto stddev = &Detail::standard_deviation<Iterator>;`

			`#ifdef CATCH_USE_ASYNC`
			`auto Estimate = [=](double(*f)(Iterator, Iterator)) {`
			`auto seed = entropy();`
			`return std::async(std::launch::async, [=] {`
			`std::mt19937 rng(seed);`
			`auto resampled = resample(rng, n_resamples, first, last, f);`
			`return bootstrap(confidence_level, first, last, resampled, f);`
			`});`
			`};`

			`auto mean_future = Estimate(mean);`
			`auto stddev_future = Estimate(stddev);`

			`auto mean_estimate = mean_future.get();`
			`auto stddev_estimate = stddev_future.get();`
			`#else`
			`auto Estimate = [=](double(*f)(Iterator, Iterator)) {`
			`auto seed = entropy();`
			`std::mt19937 rng(seed);`
			`auto resampled = resample(rng, n_resamples, first, last, f);`
			`return bootstrap(confidence_level, first, last, resampled, f);`
			`};`

			`auto mean_estimate = Estimate(mean);`
			`auto stddev_estimate = Estimate(stddev);`
			`#endif // CATCH_USE_ASYNC`

			`double outlier_variance = Detail::outlier_variance(mean_estimate, stddev_estimate, n);`

			`return { mean_estimate, stddev_estimate, outlier_variance };`
			`}`
			`} // namespace Detail`
			`} // namespace Benchmark`
			`} // namespace Catch`

			`#endif // TWOBLUECUBES_CATCH_DETAIL_ANALYSIS_HPP_INCLUDED`