third_party/llvm-project/libcxx/utils/google-benchmark/src/statistics.cc - cobalt - Git at Google

 // Copyright 2016 Ismael Jimenez Martinez. All rights reserved.
 // Copyright 2017 Roman Lebedev. All rights reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #include "benchmark/benchmark.h"

 #include <algorithm>
 #include <cmath>
 #include <numeric>
 #include <string>
 #include <vector>
 #include "check.h"
 #include "statistics.h"

 namespace benchmark {

 auto StatisticsSum = [](const std::vector<double>& v) {
   return std::accumulate(v.begin(), v.end(), 0.0);
 };

 double StatisticsMean(const std::vector<double>& v) {
   if (v.empty()) return 0.0;
   return StatisticsSum(v) * (1.0 / v.size());
 }

 double StatisticsMedian(const std::vector<double>& v) {
   if (v.size() < 3) return StatisticsMean(v);
   std::vector<double> copy(v);

   auto center = copy.begin() + v.size() / 2;
   std::nth_element(copy.begin(), center, copy.end());

   // did we have an odd number of samples?
   // if yes, then center is the median
   // it no, then we are looking for the average between center and the value
   // before
   if (v.size() % 2 == 1) return *center;
   auto center2 = copy.begin() + v.size() / 2 - 1;
   std::nth_element(copy.begin(), center2, copy.end());
   return (*center + *center2) / 2.0;
 }

 // Return the sum of the squares of this sample set
 auto SumSquares = [](const std::vector<double>& v) {
   return std::inner_product(v.begin(), v.end(), v.begin(), 0.0);
 };

 auto Sqr = [](const double dat) { return dat * dat; };
 auto Sqrt = [](const double dat) {
   // Avoid NaN due to imprecision in the calculations
   if (dat < 0.0) return 0.0;
   return std::sqrt(dat);
 };

 double StatisticsStdDev(const std::vector<double>& v) {
   const auto mean = StatisticsMean(v);
   if (v.empty()) return mean;

   // Sample standard deviation is undefined for n = 1
   if (v.size() == 1) return 0.0;

   const double avg_squares = SumSquares(v) * (1.0 / v.size());
   return Sqrt(v.size() / (v.size() - 1.0) * (avg_squares - Sqr(mean)));
 }

 std::vector<BenchmarkReporter::Run> ComputeStats(
     const std::vector<BenchmarkReporter::Run>& reports) {
   typedef BenchmarkReporter::Run Run;
   std::vector<Run> results;

   auto error_count =
       std::count_if(reports.begin(), reports.end(),
                     [](Run const& run) { return run.error_occurred; });

   if (reports.size() - error_count < 2) {
     // We don't report aggregated data if there was a single run.
     return results;
   }

   // Accumulators.
   std::vector<double> real_accumulated_time_stat;
   std::vector<double> cpu_accumulated_time_stat;
   std::vector<double> bytes_per_second_stat;
   std::vector<double> items_per_second_stat;

   real_accumulated_time_stat.reserve(reports.size());
   cpu_accumulated_time_stat.reserve(reports.size());
   bytes_per_second_stat.reserve(reports.size());
   items_per_second_stat.reserve(reports.size());

   // All repetitions should be run with the same number of iterations so we
   // can take this information from the first benchmark.
   int64_t const run_iterations = reports.front().iterations;
   // create stats for user counters
   struct CounterStat {
     Counter c;
     std::vector<double> s;
   };
   std::map<std::string, CounterStat> counter_stats;
   for (Run const& r : reports) {
     for (auto const& cnt : r.counters) {
       auto it = counter_stats.find(cnt.first);
       if (it == counter_stats.end()) {
         counter_stats.insert({cnt.first, {cnt.second, std::vector<double>{}}});
         it = counter_stats.find(cnt.first);
         it->second.s.reserve(reports.size());
       } else {
         CHECK_EQ(counter_stats[cnt.first].c.flags, cnt.second.flags);
       }
     }
   }

   // Populate the accumulators.
   for (Run const& run : reports) {
     CHECK_EQ(reports[0].benchmark_name, run.benchmark_name);
     CHECK_EQ(run_iterations, run.iterations);
     if (run.error_occurred) continue;
     real_accumulated_time_stat.emplace_back(run.real_accumulated_time);
     cpu_accumulated_time_stat.emplace_back(run.cpu_accumulated_time);
     items_per_second_stat.emplace_back(run.items_per_second);
     bytes_per_second_stat.emplace_back(run.bytes_per_second);
     // user counters
     for (auto const& cnt : run.counters) {
       auto it = counter_stats.find(cnt.first);
       CHECK_NE(it, counter_stats.end());
       it->second.s.emplace_back(cnt.second);
     }
   }

   // Only add label if it is same for all runs
   std::string report_label = reports[0].report_label;
   for (std::size_t i = 1; i < reports.size(); i++) {
     if (reports[i].report_label != report_label) {
       report_label = "";
       break;
     }
   }

   for (const auto& Stat : *reports[0].statistics) {
     // Get the data from the accumulator to BenchmarkReporter::Run's.
     Run data;
     data.benchmark_name = reports[0].benchmark_name + "_" + Stat.name_;
     data.report_label = report_label;
     data.iterations = run_iterations;

     data.real_accumulated_time = Stat.compute_(real_accumulated_time_stat);
     data.cpu_accumulated_time = Stat.compute_(cpu_accumulated_time_stat);
     data.bytes_per_second = Stat.compute_(bytes_per_second_stat);
     data.items_per_second = Stat.compute_(items_per_second_stat);

     data.time_unit = reports[0].time_unit;

     // user counters
     for (auto const& kv : counter_stats) {
       const auto uc_stat = Stat.compute_(kv.second.s);
       auto c = Counter(uc_stat, counter_stats[kv.first].c.flags);
       data.counters[kv.first] = c;
     }

     results.push_back(data);
   }

   return results;
 }

 }  // end namespace benchmark
	// Copyright 2016 Ismael Jimenez Martinez. All rights reserved.
	// Copyright 2017 Roman Lebedev. All rights reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#include "benchmark/benchmark.h"

	#include <algorithm>
	#include <cmath>
	#include <numeric>
	#include <string>
	#include <vector>
	#include "check.h"
	#include "statistics.h"

	namespace benchmark {

	auto StatisticsSum = [](const std::vector<double>& v) {
	return std::accumulate(v.begin(), v.end(), 0.0);
	};

	double StatisticsMean(const std::vector<double>& v) {
	if (v.empty()) return 0.0;
	return StatisticsSum(v) * (1.0 / v.size());
	}

	double StatisticsMedian(const std::vector<double>& v) {
	if (v.size() < 3) return StatisticsMean(v);
	std::vector<double> copy(v);

	auto center = copy.begin() + v.size() / 2;
	std::nth_element(copy.begin(), center, copy.end());

	// did we have an odd number of samples?
	// if yes, then center is the median
	// it no, then we are looking for the average between center and the value
	// before
	if (v.size() % 2 == 1) return *center;
	auto center2 = copy.begin() + v.size() / 2 - 1;
	std::nth_element(copy.begin(), center2, copy.end());
	return (center + center2) / 2.0;
	}

	// Return the sum of the squares of this sample set
	auto SumSquares = [](const std::vector<double>& v) {
	return std::inner_product(v.begin(), v.end(), v.begin(), 0.0);
	};

	auto Sqr = [](const double dat) { return dat * dat; };
	auto Sqrt = [](const double dat) {
	// Avoid NaN due to imprecision in the calculations
	if (dat < 0.0) return 0.0;
	return std::sqrt(dat);
	};

	double StatisticsStdDev(const std::vector<double>& v) {
	const auto mean = StatisticsMean(v);
	if (v.empty()) return mean;

	// Sample standard deviation is undefined for n = 1
	if (v.size() == 1) return 0.0;

	const double avg_squares = SumSquares(v) * (1.0 / v.size());
	return Sqrt(v.size() / (v.size() - 1.0) * (avg_squares - Sqr(mean)));
	}

	std::vector<BenchmarkReporter::Run> ComputeStats(
	const std::vector<BenchmarkReporter::Run>& reports) {
	typedef BenchmarkReporter::Run Run;
	std::vector<Run> results;

	auto error_count =
	std::count_if(reports.begin(), reports.end(),
	[](Run const& run) { return run.error_occurred; });

	if (reports.size() - error_count < 2) {
	// We don't report aggregated data if there was a single run.
	return results;
	}

	// Accumulators.
	std::vector<double> real_accumulated_time_stat;
	std::vector<double> cpu_accumulated_time_stat;
	std::vector<double> bytes_per_second_stat;
	std::vector<double> items_per_second_stat;

	real_accumulated_time_stat.reserve(reports.size());
	cpu_accumulated_time_stat.reserve(reports.size());
	bytes_per_second_stat.reserve(reports.size());
	items_per_second_stat.reserve(reports.size());

	// All repetitions should be run with the same number of iterations so we
	// can take this information from the first benchmark.
	int64_t const run_iterations = reports.front().iterations;
	// create stats for user counters
	struct CounterStat {
	Counter c;
	std::vector<double> s;
	};
	std::map<std::string, CounterStat> counter_stats;
	for (Run const& r : reports) {
	for (auto const& cnt : r.counters) {
	auto it = counter_stats.find(cnt.first);
	if (it == counter_stats.end()) {
	counter_stats.insert({cnt.first, {cnt.second, std::vector<double>{}}});
	it = counter_stats.find(cnt.first);
	it->second.s.reserve(reports.size());
	} else {
	CHECK_EQ(counter_stats[cnt.first].c.flags, cnt.second.flags);
	}
	}
	}

	// Populate the accumulators.
	for (Run const& run : reports) {
	CHECK_EQ(reports[0].benchmark_name, run.benchmark_name);
	CHECK_EQ(run_iterations, run.iterations);
	if (run.error_occurred) continue;
	real_accumulated_time_stat.emplace_back(run.real_accumulated_time);
	cpu_accumulated_time_stat.emplace_back(run.cpu_accumulated_time);
	items_per_second_stat.emplace_back(run.items_per_second);
	bytes_per_second_stat.emplace_back(run.bytes_per_second);
	// user counters
	for (auto const& cnt : run.counters) {
	auto it = counter_stats.find(cnt.first);
	CHECK_NE(it, counter_stats.end());
	it->second.s.emplace_back(cnt.second);
	}
	}

	// Only add label if it is same for all runs
	std::string report_label = reports[0].report_label;
	for (std::size_t i = 1; i < reports.size(); i++) {
	if (reports[i].report_label != report_label) {
	report_label = "";
	break;
	}
	}

	for (const auto& Stat : *reports[0].statistics) {
	// Get the data from the accumulator to BenchmarkReporter::Run's.
	Run data;
	data.benchmark_name = reports[0].benchmark_name + "_" + Stat.name_;
	data.report_label = report_label;
	data.iterations = run_iterations;

	data.real_accumulated_time = Stat.compute_(real_accumulated_time_stat);
	data.cpu_accumulated_time = Stat.compute_(cpu_accumulated_time_stat);
	data.bytes_per_second = Stat.compute_(bytes_per_second_stat);
	data.items_per_second = Stat.compute_(items_per_second_stat);

	data.time_unit = reports[0].time_unit;

	// user counters
	for (auto const& kv : counter_stats) {
	const auto uc_stat = Stat.compute_(kv.second.s);
	auto c = Counter(uc_stat, counter_stats[kv.first].c.flags);
	data.counters[kv.first] = c;
	}

	results.push_back(data);
	}

	return results;
	}

	} // end namespace benchmark