src/benchmark_register.h - third_party/github/google/benchmark - Git at Google

 #ifndef BENCHMARK_REGISTER_H
 #define BENCHMARK_REGISTER_H

 #include <algorithm>
 #include <limits>
 #include <vector>

 #include "check.h"

 namespace benchmark {
 namespace internal {

 // Append the powers of 'mult' in the closed interval [lo, hi].
 // Returns iterator to the start of the inserted range.
 template <typename T>
 typename std::vector<T>::iterator AddPowers(std::vector<T>* dst, T lo, T hi,
                                             int mult) {
   BM_CHECK_GE(lo, 0);
   BM_CHECK_GE(hi, lo);
   BM_CHECK_GE(mult, 2);

   const size_t start_offset = dst->size();

   static const T kmax = std::numeric_limits<T>::max();

   // Space out the values in multiples of "mult"
   for (T i = static_cast<T>(1); i <= hi; i = static_cast<T>(i * mult)) {
     if (i >= lo) {
       dst->push_back(i);
     }
     // Break the loop here since multiplying by
     // 'mult' would move outside of the range of T
     if (i > kmax / mult) break;
   }

   return dst->begin() + static_cast<int>(start_offset);
 }

 template <typename T>
 void AddNegatedPowers(std::vector<T>* dst, T lo, T hi, int mult) {
   // We negate lo and hi so we require that they cannot be equal to 'min'.
   BM_CHECK_GT(lo, std::numeric_limits<T>::min());
   BM_CHECK_GT(hi, std::numeric_limits<T>::min());
   BM_CHECK_GE(hi, lo);
   BM_CHECK_LE(hi, 0);

   // Add positive powers, then negate and reverse.
   // Casts necessary since small integers get promoted
   // to 'int' when negating.
   const auto lo_complement = static_cast<T>(-lo);
   const auto hi_complement = static_cast<T>(-hi);

   const auto it = AddPowers(dst, hi_complement, lo_complement, mult);

   std::for_each(it, dst->end(), [](T& t) { t = static_cast<T>(t * -1); });
   std::reverse(it, dst->end());
 }

 template <typename T>
 void AddRange(std::vector<T>* dst, T lo, T hi, int mult) {
   static_assert(std::is_integral<T>::value && std::is_signed<T>::value,
                 "Args type must be a signed integer");

   BM_CHECK_GE(hi, lo);
   BM_CHECK_GE(mult, 2);

   // Add "lo"
   dst->push_back(lo);

   // Handle lo == hi as a special case, so we then know
   // lo < hi and so it is safe to add 1 to lo and subtract 1
   // from hi without falling outside of the range of T.
   if (lo == hi) return;

   // Ensure that lo_inner <= hi_inner below.
   if (lo + 1 == hi) {
     dst->push_back(hi);
     return;
   }

   // Add all powers of 'mult' in the range [lo+1, hi-1] (inclusive).
   const auto lo_inner = static_cast<T>(lo + 1);
   const auto hi_inner = static_cast<T>(hi - 1);

   // Insert negative values
   if (lo_inner < 0) {
     AddNegatedPowers(dst, lo_inner, std::min(hi_inner, T{-1}), mult);
   }

   // Treat 0 as a special case (see discussion on #762).
   if (lo < 0 && hi >= 0) {
     dst->push_back(0);
   }

   // Insert positive values
   if (hi_inner > 0) {
     AddPowers(dst, std::max(lo_inner, T{1}), hi_inner, mult);
   }

   // Add "hi" (if different from last value).
   if (hi != dst->back()) {
     dst->push_back(hi);
   }
 }

 }  // namespace internal
 }  // namespace benchmark

 #endif  // BENCHMARK_REGISTER_H
	#ifndef BENCHMARK_REGISTER_H
	#define BENCHMARK_REGISTER_H

	#include <algorithm>
	#include <limits>
	#include <vector>

	#include "check.h"

	namespace benchmark {
	namespace internal {

	// Append the powers of 'mult' in the closed interval [lo, hi].
	// Returns iterator to the start of the inserted range.
	template <typename T>
	typename std::vector<T>::iterator AddPowers(std::vector<T>* dst, T lo, T hi,
	int mult) {
	BM_CHECK_GE(lo, 0);
	BM_CHECK_GE(hi, lo);
	BM_CHECK_GE(mult, 2);

	const size_t start_offset = dst->size();

	static const T kmax = std::numeric_limits<T>::max();

	// Space out the values in multiples of "mult"
	for (T i = static_cast<T>(1); i <= hi; i = static_cast<T>(i * mult)) {
	if (i >= lo) {
	dst->push_back(i);
	}
	// Break the loop here since multiplying by
	// 'mult' would move outside of the range of T
	if (i > kmax / mult) break;
	}

	return dst->begin() + static_cast<int>(start_offset);
	}

	template <typename T>
	void AddNegatedPowers(std::vector<T>* dst, T lo, T hi, int mult) {
	// We negate lo and hi so we require that they cannot be equal to 'min'.
	BM_CHECK_GT(lo, std::numeric_limits<T>::min());
	BM_CHECK_GT(hi, std::numeric_limits<T>::min());
	BM_CHECK_GE(hi, lo);
	BM_CHECK_LE(hi, 0);

	// Add positive powers, then negate and reverse.
	// Casts necessary since small integers get promoted
	// to 'int' when negating.
	const auto lo_complement = static_cast<T>(-lo);
	const auto hi_complement = static_cast<T>(-hi);

	const auto it = AddPowers(dst, hi_complement, lo_complement, mult);

	std::for_each(it, dst->end(), [](T& t) { t = static_cast<T>(t * -1); });
	std::reverse(it, dst->end());
	}

	template <typename T>
	void AddRange(std::vector<T>* dst, T lo, T hi, int mult) {
	static_assert(std::is_integral<T>::value && std::is_signed<T>::value,
	"Args type must be a signed integer");

	BM_CHECK_GE(hi, lo);
	BM_CHECK_GE(mult, 2);

	// Add "lo"
	dst->push_back(lo);

	// Handle lo == hi as a special case, so we then know
	// lo < hi and so it is safe to add 1 to lo and subtract 1
	// from hi without falling outside of the range of T.
	if (lo == hi) return;

	// Ensure that lo_inner <= hi_inner below.
	if (lo + 1 == hi) {
	dst->push_back(hi);
	return;
	}

	// Add all powers of 'mult' in the range [lo+1, hi-1] (inclusive).
	const auto lo_inner = static_cast<T>(lo + 1);
	const auto hi_inner = static_cast<T>(hi - 1);

	// Insert negative values
	if (lo_inner < 0) {
	AddNegatedPowers(dst, lo_inner, std::min(hi_inner, T{-1}), mult);
	}

	// Treat 0 as a special case (see discussion on #762).
	if (lo < 0 && hi >= 0) {
	dst->push_back(0);
	}

	// Insert positive values
	if (hi_inner > 0) {
	AddPowers(dst, std::max(lo_inner, T{1}), hi_inner, mult);
	}

	// Add "hi" (if different from last value).
	if (hi != dst->back()) {
	dst->push_back(hi);
	}
	}

	} // namespace internal
	} // namespace benchmark

	#endif // BENCHMARK_REGISTER_H