faux-folly/folly/Benchmark.cpp - nest-cam/4320010/faux-folly - Git at Google

 /*
  * Copyright 2015 Facebook, Inc.
  *
  * 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.
  */

 // @author Andrei Alexandrescu (andrei.alexandrescu@fb.com)

 #include <folly/Benchmark.h>
 #include <folly/Foreach.h>
 #include <folly/String.h>

 #include <algorithm>
 #include <boost/regex.hpp>
 #include <cmath>
 #include <iostream>
 #include <limits>
 #include <utility>
 #include <vector>
 #include <cstring>

 using namespace std;

 DEFINE_bool(benchmark, false, "Run benchmarks.");

 DEFINE_string(bm_regex, "",
               "Only benchmarks whose names match this regex will be run.");

 DEFINE_int64(bm_min_usec, 100,
              "Minimum # of microseconds we'll accept for each benchmark.");

 DEFINE_int64(bm_min_iters, 1,
              "Minimum # of iterations we'll try for each benchmark.");

 DEFINE_int32(bm_max_secs, 1,
              "Maximum # of seconds we'll spend on each benchmark.");


 namespace folly {

 BenchmarkSuspender::NanosecondsSpent BenchmarkSuspender::nsSpent;

 typedef function<detail::TimeIterPair(unsigned int)> BenchmarkFun;


 vector<tuple<const char*, const char*, BenchmarkFun>>& benchmarks() {
   static vector<tuple<const char*, const char*, BenchmarkFun>> _benchmarks;
   return _benchmarks;
 }

 #define FB_FOLLY_GLOBAL_BENCHMARK_BASELINE fbFollyGlobalBenchmarkBaseline
 #define FB_STRINGIZE_X2(x) FB_STRINGIZE(x)

 // Add the global baseline
 BENCHMARK(FB_FOLLY_GLOBAL_BENCHMARK_BASELINE) {
 #ifdef _MSC_VER
   _ReadWriteBarrier();
 #else
   asm volatile("");
 #endif
 }

 int getGlobalBenchmarkBaselineIndex() {
   const char *global = FB_STRINGIZE_X2(FB_FOLLY_GLOBAL_BENCHMARK_BASELINE);
   auto it = std::find_if(
     benchmarks().begin(),
     benchmarks().end(),
     [global](const tuple<const char*, const char*, BenchmarkFun> &v) {
       return std::strcmp(get<1>(v), global) == 0;
     }
   );
   CHECK(it != benchmarks().end());
   return it - benchmarks().begin();
 }

 #undef FB_STRINGIZE_X2
 #undef FB_FOLLY_GLOBAL_BENCHMARK_BASELINE

 void detail::addBenchmarkImpl(const char* file, const char* name,
                               BenchmarkFun fun) {
   benchmarks().emplace_back(file, name, std::move(fun));
 }

 /**
  * Given a point, gives density at that point as a number 0.0 < x <=
  * 1.0. The result is 1.0 if all samples are equal to where, and
  * decreases near 0 if all points are far away from it. The density is
  * computed with the help of a radial basis function.
  */
 static double density(const double * begin, const double *const end,
                       const double where, const double bandwidth) {
   assert(begin < end);
   assert(bandwidth > 0.0);
   double sum = 0.0;
   FOR_EACH_RANGE (i, begin, end) {
     auto d = (*i - where) / bandwidth;
     sum += exp(- d * d);
   }
   return sum / (end - begin);
 }

 /**
  * Computes mean and variance for a bunch of data points. Note that
  * mean is currently not being used.
  */
 static pair<double, double>
 meanVariance(const double * begin, const double *const end) {
   assert(begin < end);
   double sum = 0.0, sum2 = 0.0;
   FOR_EACH_RANGE (i, begin, end) {
     sum += *i;
     sum2 += *i * *i;
   }
   auto const n = end - begin;
   return make_pair(sum / n, sqrt((sum2 - sum * sum / n) / n));
 }

 /**
  * Computes the mode of a sample set through brute force. Assumes
  * input is sorted.
  */
 static double mode(const double * begin, const double *const end) {
   assert(begin < end);
   // Lower bound and upper bound for result and their respective
   // densities.
   auto
     result = 0.0,
     bestDensity = 0.0;

   // Get the variance so we pass it down to density()
   auto const sigma = meanVariance(begin, end).second;
   if (!sigma) {
     // No variance means constant signal
     return *begin;
   }

   FOR_EACH_RANGE (i, begin, end) {
     assert(i == begin || *i >= i[-1]);
     auto candidate = density(begin, end, *i, sigma * sqrt(2.0));
     if (candidate > bestDensity) {
       // Found a new best
       bestDensity = candidate;
       result = *i;
     } else {
       // Density is decreasing... we could break here if we definitely
       // knew this is unimodal.
     }
   }

   return result;
 }

 /**
  * Given a bunch of benchmark samples, estimate the actual run time.
  */
 static double estimateTime(double * begin, double * end) {
   assert(begin < end);

   // Current state of the art: get the minimum. After some
   // experimentation, it seems taking the minimum is the best.

   return *min_element(begin, end);

   // What follows after estimates the time as the mode of the
   // distribution.

   // Select the awesomest (i.e. most frequent) result. We do this by
   // sorting and then computing the longest run length.
   sort(begin, end);

   // Eliminate outliers. A time much larger than the minimum time is
   // considered an outlier.
   while (end[-1] > 2.0 * *begin) {
     --end;
     if (begin == end) {
       LOG(INFO) << *begin;
     }
     assert(begin < end);
   }

   double result = 0;

   /* Code used just for comparison purposes */ {
     unsigned bestFrequency = 0;
     unsigned candidateFrequency = 1;
     double candidateValue = *begin;
     for (auto current = begin + 1; ; ++current) {
       if (current == end || *current != candidateValue) {
         // Done with the current run, see if it was best
         if (candidateFrequency > bestFrequency) {
           bestFrequency = candidateFrequency;
           result = candidateValue;
         }
         if (current == end) {
           break;
         }
         // Start a new run
         candidateValue = *current;
         candidateFrequency = 1;
       } else {
         // Cool, inside a run, increase the frequency
         ++candidateFrequency;
       }
     }
   }

   result = mode(begin, end);

   return result;
 }

 static double runBenchmarkGetNSPerIteration(const BenchmarkFun& fun,
                                             const double globalBaseline) {
   // They key here is accuracy; too low numbers means the accuracy was
   // coarse. We up the ante until we get to at least minNanoseconds
   // timings.
   static uint64_t resolutionInNs = 0, coarseResolutionInNs = 0;
   if (!resolutionInNs) {
     timespec ts;
     CHECK_EQ(0, clock_getres(detail::DEFAULT_CLOCK_ID, &ts));
     CHECK_EQ(0, ts.tv_sec) << "Clock sucks.";
     CHECK_LT(0, ts.tv_nsec) << "Clock too fast for its own good.";
     CHECK_EQ(1, ts.tv_nsec) << "Clock too coarse, upgrade your kernel.";
     resolutionInNs = ts.tv_nsec;
   }
   // We choose a minimum minimum (sic) of 100,000 nanoseconds, but if
   // the clock resolution is worse than that, it will be larger. In
   // essence we're aiming at making the quantization noise 0.01%.
   static const auto minNanoseconds =
     max<uint64_t>(FLAGS_bm_min_usec * 1000UL,
         min<uint64_t>(resolutionInNs * 100000, 1000000000ULL));

   // We do measurements in several epochs and take the minimum, to
   // account for jitter.
   static const unsigned int epochs = 1000;
   // We establish a total time budget as we don't want a measurement
   // to take too long. This will curtail the number of actual epochs.
   const uint64_t timeBudgetInNs = FLAGS_bm_max_secs * 1000000000ULL;
   timespec global;
   CHECK_EQ(0, clock_gettime(CLOCK_REALTIME, &global));

   double epochResults[epochs] = { 0 };
   size_t actualEpochs = 0;

   for (; actualEpochs < epochs; ++actualEpochs) {
     for (unsigned int n = FLAGS_bm_min_iters; n < (1UL << 30); n *= 2) {
       auto const nsecsAndIter = fun(n);
       if (nsecsAndIter.first < minNanoseconds) {
         continue;
       }
       // We got an accurate enough timing, done. But only save if
       // smaller than the current result.
       epochResults[actualEpochs] = max(0.0, double(nsecsAndIter.first) /
                                        nsecsAndIter.second - globalBaseline);
       // Done with the current epoch, we got a meaningful timing.
       break;
     }
     timespec now;
     CHECK_EQ(0, clock_gettime(CLOCK_REALTIME, &now));
     if (detail::timespecDiff(now, global) >= timeBudgetInNs) {
       // No more time budget available.
       ++actualEpochs;
       break;
     }
   }

   // If the benchmark was basically drowned in baseline noise, it's
   // possible it became negative.
   return max(0.0, estimateTime(epochResults, epochResults + actualEpochs));
 }

 struct ScaleInfo {
   double boundary;
   const char* suffix;
 };

 static const ScaleInfo kTimeSuffixes[] {
   { 365.25 * 24 * 3600, "years" },
   { 24 * 3600, "days" },
   { 3600, "hr" },
   { 60, "min" },
   { 1, "s" },
   { 1E-3, "ms" },
   { 1E-6, "us" },
   { 1E-9, "ns" },
   { 1E-12, "ps" },
   { 1E-15, "fs" },
   { 0, nullptr },
 };

 static const ScaleInfo kMetricSuffixes[] {
   { 1E24, "Y" },  // yotta
   { 1E21, "Z" },  // zetta
   { 1E18, "X" },  // "exa" written with suffix 'X' so as to not create
                   //   confusion with scientific notation
   { 1E15, "P" },  // peta
   { 1E12, "T" },  // terra
   { 1E9, "G" },   // giga
   { 1E6, "M" },   // mega
   { 1E3, "K" },   // kilo
   { 1, "" },
   { 1E-3, "m" },  // milli
   { 1E-6, "u" },  // micro
   { 1E-9, "n" },  // nano
   { 1E-12, "p" }, // pico
   { 1E-15, "f" }, // femto
   { 1E-18, "a" }, // atto
   { 1E-21, "z" }, // zepto
   { 1E-24, "y" }, // yocto
   { 0, nullptr },
 };

 static string humanReadable(double n, unsigned int decimals,
                             const ScaleInfo* scales) {
   if (std::isinf(n) || std::isnan(n)) {
     return folly::to<string>(n);
   }

   const double absValue = fabs(n);
   const ScaleInfo* scale = scales;
   while (absValue < scale[0].boundary && scale[1].suffix != nullptr) {
     ++scale;
   }

   const double scaledValue = n / scale->boundary;
   return stringPrintf("%.*f%s", decimals, scaledValue, scale->suffix);
 }

 static string readableTime(double n, unsigned int decimals) {
   return humanReadable(n, decimals, kTimeSuffixes);
 }

 static string metricReadable(double n, unsigned int decimals) {
   return humanReadable(n, decimals, kMetricSuffixes);
 }

 static void printBenchmarkResultsAsTable(
   const vector<tuple<const char*, const char*, double> >& data) {
   // Width available
   static const unsigned int columns = 76;

   // Compute the longest benchmark name
   size_t longestName = 0;
   FOR_EACH_RANGE (i, 1, benchmarks().size()) {
     longestName = max(longestName, strlen(get<1>(benchmarks()[i])));
   }

   // Print a horizontal rule
   auto separator = [&](char pad) {
     puts(string(columns, pad).c_str());
   };

   // Print header for a file
   auto header = [&](const char* file) {
     separator('=');
     printf("%-*srelative  time/iter  iters/s\n",
            columns - 28, file);
     separator('=');
   };

   double baselineNsPerIter = numeric_limits<double>::max();
   const char* lastFile = "";

   for (auto& datum : data) {
     auto file = get<0>(datum);
     if (strcmp(file, lastFile)) {
       // New file starting
       header(file);
       lastFile = file;
     }

     string s = get<1>(datum);
     if (s == "-") {
       separator('-');
       continue;
     }
     bool useBaseline /* = void */;
     if (s[0] == '%') {
       s.erase(0, 1);
       useBaseline = true;
     } else {
       baselineNsPerIter = get<2>(datum);
       useBaseline = false;
     }
     s.resize(columns - 29, ' ');
     auto nsPerIter = get<2>(datum);
     auto secPerIter = nsPerIter / 1E9;
     auto itersPerSec = 1 / secPerIter;
     if (!useBaseline) {
       // Print without baseline
       printf("%*s           %9s  %7s\n",
              static_cast<int>(s.size()), s.c_str(),
              readableTime(secPerIter, 2).c_str(),
              metricReadable(itersPerSec, 2).c_str());
     } else {
       // Print with baseline
       auto rel = baselineNsPerIter / nsPerIter * 100.0;
       printf("%*s %7.2f%%  %9s  %7s\n",
              static_cast<int>(s.size()), s.c_str(),
              rel,
              readableTime(secPerIter, 2).c_str(),
              metricReadable(itersPerSec, 2).c_str());
     }
   }
   separator('=');
 }

 static void printBenchmarkResults(
   const vector<tuple<const char*, const char*, double> >& data) {

   printBenchmarkResultsAsTable(data);
 }

 void runBenchmarks() {
   CHECK(!benchmarks().empty());

   vector<tuple<const char*, const char*, double>> results;
   results.reserve(benchmarks().size() - 1);

   std::unique_ptr<boost::regex> bmRegex;
   if (!FLAGS_bm_regex.empty()) {
     bmRegex.reset(new boost::regex(FLAGS_bm_regex));
   }

   // PLEASE KEEP QUIET. MEASUREMENTS IN PROGRESS.

   unsigned int baselineIndex = getGlobalBenchmarkBaselineIndex();

   auto const globalBaseline =
       runBenchmarkGetNSPerIteration(get<2>(benchmarks()[baselineIndex]), 0);
   FOR_EACH_RANGE (i, 0, benchmarks().size()) {
     if (i == baselineIndex) {
       continue;
     }
     double elapsed = 0.0;
     if (strcmp(get<1>(benchmarks()[i]), "-") != 0) { // skip separators
       if (bmRegex && !boost::regex_search(get<1>(benchmarks()[i]), *bmRegex)) {
         continue;
       }
       elapsed = runBenchmarkGetNSPerIteration(get<2>(benchmarks()[i]),
                                               globalBaseline);
     }
     results.emplace_back(get<0>(benchmarks()[i]),
                          get<1>(benchmarks()[i]), elapsed);
   }

   // PLEASE MAKE NOISE. MEASUREMENTS DONE.

   printBenchmarkResults(results);
 }

 } // namespace folly
	/*
	* Copyright 2015 Facebook, Inc.
	*
	* 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.
	*/

	// @author Andrei Alexandrescu (andrei.alexandrescu@fb.com)

	#include <folly/Benchmark.h>
	#include <folly/Foreach.h>
	#include <folly/String.h>

	#include <algorithm>
	#include <boost/regex.hpp>
	#include <cmath>
	#include <iostream>
	#include <limits>
	#include <utility>
	#include <vector>
	#include <cstring>

	using namespace std;

	DEFINE_bool(benchmark, false, "Run benchmarks.");

	DEFINE_string(bm_regex, "",
	"Only benchmarks whose names match this regex will be run.");

	DEFINE_int64(bm_min_usec, 100,
	"Minimum # of microseconds we'll accept for each benchmark.");

	DEFINE_int64(bm_min_iters, 1,
	"Minimum # of iterations we'll try for each benchmark.");

	DEFINE_int32(bm_max_secs, 1,
	"Maximum # of seconds we'll spend on each benchmark.");


	namespace folly {

	BenchmarkSuspender::NanosecondsSpent BenchmarkSuspender::nsSpent;

	typedef function<detail::TimeIterPair(unsigned int)> BenchmarkFun;


	vector<tuple<const char, const char, BenchmarkFun>>& benchmarks() {
	static vector<tuple<const char, const char, BenchmarkFun>> _benchmarks;
	return _benchmarks;
	}

	#define FB_FOLLY_GLOBAL_BENCHMARK_BASELINE fbFollyGlobalBenchmarkBaseline
	#define FB_STRINGIZE_X2(x) FB_STRINGIZE(x)

	// Add the global baseline
	BENCHMARK(FB_FOLLY_GLOBAL_BENCHMARK_BASELINE) {
	#ifdef _MSC_VER
	_ReadWriteBarrier();
	#else
	asm volatile("");
	#endif
	}

	int getGlobalBenchmarkBaselineIndex() {
	const char *global = FB_STRINGIZE_X2(FB_FOLLY_GLOBAL_BENCHMARK_BASELINE);
	auto it = std::find_if(
	benchmarks().begin(),
	benchmarks().end(),
	[global](const tuple<const char, const char, BenchmarkFun> &v) {
	return std::strcmp(get<1>(v), global) == 0;
	}
	);
	CHECK(it != benchmarks().end());
	return it - benchmarks().begin();
	}

	#undef FB_STRINGIZE_X2
	#undef FB_FOLLY_GLOBAL_BENCHMARK_BASELINE

	void detail::addBenchmarkImpl(const char* file, const char* name,
	BenchmarkFun fun) {
	benchmarks().emplace_back(file, name, std::move(fun));
	}

	/**
	* Given a point, gives density at that point as a number 0.0 < x <=
	* 1.0. The result is 1.0 if all samples are equal to where, and
	* decreases near 0 if all points are far away from it. The density is
	* computed with the help of a radial basis function.
	*/
	static double density(const double * begin, const double *const end,
	const double where, const double bandwidth) {
	assert(begin < end);
	assert(bandwidth > 0.0);
	double sum = 0.0;
	FOR_EACH_RANGE (i, begin, end) {
	auto d = (*i - where) / bandwidth;
	sum += exp(- d * d);
	}
	return sum / (end - begin);
	}

	/**
	* Computes mean and variance for a bunch of data points. Note that
	* mean is currently not being used.
	*/
	static pair<double, double>
	meanVariance(const double * begin, const double *const end) {
	assert(begin < end);
	double sum = 0.0, sum2 = 0.0;
	FOR_EACH_RANGE (i, begin, end) {
	sum += *i;
	sum2 += i *i;
	}
	auto const n = end - begin;
	return make_pair(sum / n, sqrt((sum2 - sum * sum / n) / n));
	}

	/**
	* Computes the mode of a sample set through brute force. Assumes
	* input is sorted.
	*/
	static double mode(const double * begin, const double *const end) {
	assert(begin < end);
	// Lower bound and upper bound for result and their respective
	// densities.
	auto
	result = 0.0,
	bestDensity = 0.0;

	// Get the variance so we pass it down to density()
	auto const sigma = meanVariance(begin, end).second;
	if (!sigma) {
	// No variance means constant signal
	return *begin;
	}

	FOR_EACH_RANGE (i, begin, end) {
	assert(i == begin \|\| *i >= i[-1]);
	auto candidate = density(begin, end, i, sigma sqrt(2.0));
	if (candidate > bestDensity) {
	// Found a new best
	bestDensity = candidate;
	result = *i;
	} else {
	// Density is decreasing... we could break here if we definitely
	// knew this is unimodal.
	}
	}

	return result;
	}

	/**
	* Given a bunch of benchmark samples, estimate the actual run time.
	*/
	static double estimateTime(double * begin, double * end) {
	assert(begin < end);

	// Current state of the art: get the minimum. After some
	// experimentation, it seems taking the minimum is the best.

	return *min_element(begin, end);

	// What follows after estimates the time as the mode of the
	// distribution.

	// Select the awesomest (i.e. most frequent) result. We do this by
	// sorting and then computing the longest run length.
	sort(begin, end);

	// Eliminate outliers. A time much larger than the minimum time is
	// considered an outlier.
	while (end[-1] > 2.0 * *begin) {
	--end;
	if (begin == end) {
	LOG(INFO) << *begin;
	}
	assert(begin < end);
	}

	double result = 0;

	/* Code used just for comparison purposes */ {
	unsigned bestFrequency = 0;
	unsigned candidateFrequency = 1;
	double candidateValue = *begin;
	for (auto current = begin + 1; ; ++current) {
	if (current == end \|\| *current != candidateValue) {
	// Done with the current run, see if it was best
	if (candidateFrequency > bestFrequency) {
	bestFrequency = candidateFrequency;
	result = candidateValue;
	}
	if (current == end) {
	break;
	}
	// Start a new run
	candidateValue = *current;
	candidateFrequency = 1;
	} else {
	// Cool, inside a run, increase the frequency
	++candidateFrequency;
	}
	}
	}

	result = mode(begin, end);

	return result;
	}

	static double runBenchmarkGetNSPerIteration(const BenchmarkFun& fun,
	const double globalBaseline) {
	// They key here is accuracy; too low numbers means the accuracy was
	// coarse. We up the ante until we get to at least minNanoseconds
	// timings.
	static uint64_t resolutionInNs = 0, coarseResolutionInNs = 0;
	if (!resolutionInNs) {
	timespec ts;
	CHECK_EQ(0, clock_getres(detail::DEFAULT_CLOCK_ID, &ts));
	CHECK_EQ(0, ts.tv_sec) << "Clock sucks.";
	CHECK_LT(0, ts.tv_nsec) << "Clock too fast for its own good.";
	CHECK_EQ(1, ts.tv_nsec) << "Clock too coarse, upgrade your kernel.";
	resolutionInNs = ts.tv_nsec;
	}
	// We choose a minimum minimum (sic) of 100,000 nanoseconds, but if
	// the clock resolution is worse than that, it will be larger. In
	// essence we're aiming at making the quantization noise 0.01%.
	static const auto minNanoseconds =
	max<uint64_t>(FLAGS_bm_min_usec * 1000UL,
	min<uint64_t>(resolutionInNs * 100000, 1000000000ULL));

	// We do measurements in several epochs and take the minimum, to
	// account for jitter.
	static const unsigned int epochs = 1000;
	// We establish a total time budget as we don't want a measurement
	// to take too long. This will curtail the number of actual epochs.
	const uint64_t timeBudgetInNs = FLAGS_bm_max_secs * 1000000000ULL;
	timespec global;
	CHECK_EQ(0, clock_gettime(CLOCK_REALTIME, &global));

	double epochResults[epochs] = { 0 };
	size_t actualEpochs = 0;

	for (; actualEpochs < epochs; ++actualEpochs) {
	for (unsigned int n = FLAGS_bm_min_iters; n < (1UL << 30); n *= 2) {
	auto const nsecsAndIter = fun(n);
	if (nsecsAndIter.first < minNanoseconds) {
	continue;
	}
	// We got an accurate enough timing, done. But only save if
	// smaller than the current result.
	epochResults[actualEpochs] = max(0.0, double(nsecsAndIter.first) /
	nsecsAndIter.second - globalBaseline);
	// Done with the current epoch, we got a meaningful timing.
	break;
	}
	timespec now;
	CHECK_EQ(0, clock_gettime(CLOCK_REALTIME, &now));
	if (detail::timespecDiff(now, global) >= timeBudgetInNs) {
	// No more time budget available.
	++actualEpochs;
	break;
	}
	}

	// If the benchmark was basically drowned in baseline noise, it's
	// possible it became negative.
	return max(0.0, estimateTime(epochResults, epochResults + actualEpochs));
	}

	struct ScaleInfo {
	double boundary;
	const char* suffix;
	};

	static const ScaleInfo kTimeSuffixes[] {
	{ 365.25 * 24 * 3600, "years" },
	{ 24 * 3600, "days" },
	{ 3600, "hr" },
	{ 60, "min" },
	{ 1, "s" },
	{ 1E-3, "ms" },
	{ 1E-6, "us" },
	{ 1E-9, "ns" },
	{ 1E-12, "ps" },
	{ 1E-15, "fs" },
	{ 0, nullptr },
	};

	static const ScaleInfo kMetricSuffixes[] {
	{ 1E24, "Y" }, // yotta
	{ 1E21, "Z" }, // zetta
	{ 1E18, "X" }, // "exa" written with suffix 'X' so as to not create
	// confusion with scientific notation
	{ 1E15, "P" }, // peta
	{ 1E12, "T" }, // terra
	{ 1E9, "G" }, // giga
	{ 1E6, "M" }, // mega
	{ 1E3, "K" }, // kilo
	{ 1, "" },
	{ 1E-3, "m" }, // milli
	{ 1E-6, "u" }, // micro
	{ 1E-9, "n" }, // nano
	{ 1E-12, "p" }, // pico
	{ 1E-15, "f" }, // femto
	{ 1E-18, "a" }, // atto
	{ 1E-21, "z" }, // zepto
	{ 1E-24, "y" }, // yocto
	{ 0, nullptr },
	};

	static string humanReadable(double n, unsigned int decimals,
	const ScaleInfo* scales) {
	if (std::isinf(n) \|\| std::isnan(n)) {
	return folly::to<string>(n);
	}

	const double absValue = fabs(n);
	const ScaleInfo* scale = scales;
	while (absValue < scale[0].boundary && scale[1].suffix != nullptr) {
	++scale;
	}

	const double scaledValue = n / scale->boundary;
	return stringPrintf("%.*f%s", decimals, scaledValue, scale->suffix);
	}

	static string readableTime(double n, unsigned int decimals) {
	return humanReadable(n, decimals, kTimeSuffixes);
	}

	static string metricReadable(double n, unsigned int decimals) {
	return humanReadable(n, decimals, kMetricSuffixes);
	}

	static void printBenchmarkResultsAsTable(
	const vector<tuple<const char, const char, double> >& data) {
	// Width available
	static const unsigned int columns = 76;

	// Compute the longest benchmark name
	size_t longestName = 0;
	FOR_EACH_RANGE (i, 1, benchmarks().size()) {
	longestName = max(longestName, strlen(get<1>(benchmarks()[i])));
	}

	// Print a horizontal rule
	auto separator = [&](char pad) {
	puts(string(columns, pad).c_str());
	};

	// Print header for a file
	auto header = [&](const char* file) {
	separator('=');
	printf("%-*srelative time/iter iters/s\n",
	columns - 28, file);
	separator('=');
	};

	double baselineNsPerIter = numeric_limits<double>::max();
	const char* lastFile = "";

	for (auto& datum : data) {
	auto file = get<0>(datum);
	if (strcmp(file, lastFile)) {
	// New file starting
	header(file);
	lastFile = file;
	}

	string s = get<1>(datum);
	if (s == "-") {
	separator('-');
	continue;
	}
	bool useBaseline /* = void */;
	if (s[0] == '%') {
	s.erase(0, 1);
	useBaseline = true;
	} else {
	baselineNsPerIter = get<2>(datum);
	useBaseline = false;
	}
	s.resize(columns - 29, ' ');
	auto nsPerIter = get<2>(datum);
	auto secPerIter = nsPerIter / 1E9;
	auto itersPerSec = 1 / secPerIter;
	if (!useBaseline) {
	// Print without baseline
	printf("%*s %9s %7s\n",
	static_cast<int>(s.size()), s.c_str(),
	readableTime(secPerIter, 2).c_str(),
	metricReadable(itersPerSec, 2).c_str());
	} else {
	// Print with baseline
	auto rel = baselineNsPerIter / nsPerIter * 100.0;
	printf("%*s %7.2f%% %9s %7s\n",
	static_cast<int>(s.size()), s.c_str(),
	rel,
	readableTime(secPerIter, 2).c_str(),
	metricReadable(itersPerSec, 2).c_str());
	}
	}
	separator('=');
	}

	static void printBenchmarkResults(
	const vector<tuple<const char, const char, double> >& data) {

	printBenchmarkResultsAsTable(data);
	}

	void runBenchmarks() {
	CHECK(!benchmarks().empty());

	vector<tuple<const char, const char, double>> results;
	results.reserve(benchmarks().size() - 1);

	std::unique_ptr<boost::regex> bmRegex;
	if (!FLAGS_bm_regex.empty()) {
	bmRegex.reset(new boost::regex(FLAGS_bm_regex));
	}

	// PLEASE KEEP QUIET. MEASUREMENTS IN PROGRESS.

	unsigned int baselineIndex = getGlobalBenchmarkBaselineIndex();

	auto const globalBaseline =
	runBenchmarkGetNSPerIteration(get<2>(benchmarks()[baselineIndex]), 0);
	FOR_EACH_RANGE (i, 0, benchmarks().size()) {
	if (i == baselineIndex) {
	continue;
	}
	double elapsed = 0.0;
	if (strcmp(get<1>(benchmarks()[i]), "-") != 0) { // skip separators
	if (bmRegex && !boost::regex_search(get<1>(benchmarks()[i]), *bmRegex)) {
	continue;
	}
	elapsed = runBenchmarkGetNSPerIteration(get<2>(benchmarks()[i]),
	globalBaseline);
	}
	results.emplace_back(get<0>(benchmarks()[i]),
	get<1>(benchmarks()[i]), elapsed);
	}

	// PLEASE MAKE NOISE. MEASUREMENTS DONE.

	printBenchmarkResults(results);
	}

	} // namespace folly