benchmarks/unordered_set_operations.bench.cpp - llvm-project/libcxx - Git at Google

 #include <cstdint>
 #include <cstdlib>
 #include <cstring>
 #include <functional>
 #include <unordered_set>
 #include <vector>

 #include "benchmark/benchmark.h"

 #include "ContainerBenchmarks.h"
 #include "GenerateInput.h"
 #include "test_macros.h"

 using namespace ContainerBenchmarks;

 constexpr std::size_t TestNumInputs = 1024;

 template <class _Size>
 inline TEST_ALWAYS_INLINE _Size loadword(const void* __p) {
   _Size __r;
   std::memcpy(&__r, __p, sizeof(__r));
   return __r;
 }

 inline TEST_ALWAYS_INLINE std::size_t rotate_by_at_least_1(std::size_t __val, int __shift) {
   return (__val >> __shift) | (__val << (64 - __shift));
 }

 inline TEST_ALWAYS_INLINE std::size_t hash_len_16(std::size_t __u, std::size_t __v) {
   const std::size_t __mul = 0x9ddfea08eb382d69ULL;
   std::size_t __a         = (__u ^ __v) * __mul;
   __a ^= (__a >> 47);
   std::size_t __b = (__v ^ __a) * __mul;
   __b ^= (__b >> 47);
   __b *= __mul;
   return __b;
 }

 template <std::size_t _Len>
 inline TEST_ALWAYS_INLINE std::size_t hash_len_0_to_8(const char* __s) {
   static_assert(_Len == 4 || _Len == 8, "");
   const uint64_t __a = loadword<uint32_t>(__s);
   const uint64_t __b = loadword<uint32_t>(__s + _Len - 4);
   return hash_len_16(_Len + (__a << 3), __b);
 }

 struct UInt32Hash {
   UInt32Hash() = default;
   inline TEST_ALWAYS_INLINE std::size_t operator()(uint32_t data) const {
     return hash_len_0_to_8<4>(reinterpret_cast<const char*>(&data));
   }
 };

 struct UInt64Hash {
   UInt64Hash() = default;
   inline TEST_ALWAYS_INLINE std::size_t operator()(uint64_t data) const {
     return hash_len_0_to_8<8>(reinterpret_cast<const char*>(&data));
   }
 };

 struct UInt128Hash {
   UInt128Hash() = default;
   inline TEST_ALWAYS_INLINE std::size_t operator()(__uint128_t data) const {
     const __uint128_t __mask = static_cast<std::size_t>(-1);
     const std::size_t __a    = (std::size_t)(data & __mask);
     const std::size_t __b    = (std::size_t)((data & (__mask << 64)) >> 64);
     return hash_len_16(__a, rotate_by_at_least_1(__b + 16, 16)) ^ __b;
   }
 };

 struct UInt32Hash2 {
   UInt32Hash2() = default;
   inline TEST_ALWAYS_INLINE std::size_t operator()(uint32_t data) const {
     const uint32_t __m = 0x5bd1e995;
     const uint32_t __r = 24;
     uint32_t __h       = 4;
     uint32_t __k       = data;
     __k *= __m;
     __k ^= __k >> __r;
     __k *= __m;
     __h *= __m;
     __h ^= __k;
     __h ^= __h >> 13;
     __h *= __m;
     __h ^= __h >> 15;
     return __h;
   }
 };

 struct UInt64Hash2 {
   UInt64Hash2() = default;
   inline TEST_ALWAYS_INLINE std::size_t operator()(uint64_t data) const {
     return hash_len_0_to_8<8>(reinterpret_cast<const char*>(&data));
   }
 };

 // The sole purpose of this comparator is to be used in BM_Rehash, where
 // we need something slow enough to be easily noticable in benchmark results.
 // The default implementation of operator== for strings seems to be a little
 // too fast for that specific benchmark to reliably show a noticeable
 // improvement, but unoptimized bytewise comparison fits just right.
 // Early return is there just for convenience, since we only compare strings
 // of equal length in BM_Rehash.
 struct SlowStringEq {
   SlowStringEq() = default;
   inline TEST_ALWAYS_INLINE bool operator()(const std::string& lhs, const std::string& rhs) const {
     if (lhs.size() != rhs.size())
       return false;

     bool eq = true;
     for (size_t i = 0; i < lhs.size(); ++i) {
       eq &= lhs[i] == rhs[i];
     }
     return eq;
   }
 };

 //----------------------------------------------------------------------------//
 //                               BM_Hash
 // ---------------------------------------------------------------------------//

 template <class HashFn, class GenInputs>
 void BM_Hash(benchmark::State& st, HashFn fn, GenInputs gen) {
   auto in               = gen(st.range(0));
   const auto end        = in.data() + in.size();
   std::size_t last_hash = 0;
   benchmark::DoNotOptimize(&last_hash);
   while (st.KeepRunning()) {
     for (auto it = in.data(); it != end; ++it) {
       benchmark::DoNotOptimize(last_hash += fn(*it));
     }
     benchmark::ClobberMemory();
   }
 }

 BENCHMARK_CAPTURE(BM_Hash, uint32_random_std_hash, std::hash<uint32_t>{}, getRandomIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_Hash, uint32_random_custom_hash, UInt32Hash{}, getRandomIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_Hash, uint32_top_std_hash, std::hash<uint32_t>{}, getSortedTopBitsIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_Hash, uint32_top_custom_hash, UInt32Hash{}, getSortedTopBitsIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 //----------------------------------------------------------------------------//
 //                       BM_InsertValue
 // ---------------------------------------------------------------------------//

 // Sorted Ascending //
 BENCHMARK_CAPTURE(
     BM_InsertValue, unordered_set_uint32, std::unordered_set<uint32_t>{}, getRandomIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(
     BM_InsertValue, unordered_set_uint32_sorted, std::unordered_set<uint32_t>{}, getSortedIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 // Top Bytes //
 BENCHMARK_CAPTURE(BM_InsertValue,
                   unordered_set_top_bits_uint32,
                   std::unordered_set<uint32_t>{},
                   getSortedTopBitsIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_InsertValueRehash,
                   unordered_set_top_bits_uint32,
                   std::unordered_set<uint32_t, UInt32Hash>{},
                   getSortedTopBitsIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 // String //
 BENCHMARK_CAPTURE(BM_InsertValue, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_InsertValueRehash, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
     ->Arg(TestNumInputs);

 // Prefixed String //
 BENCHMARK_CAPTURE(
     BM_InsertValue, unordered_set_prefixed_string, std::unordered_set<std::string>{}, getPrefixedRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_InsertValueRehash,
                   unordered_set_prefixed_string,
                   std::unordered_set<std::string>{},
                   getPrefixedRandomStringInputs)
     ->Arg(TestNumInputs);

 //----------------------------------------------------------------------------//
 //                         BM_Find
 // ---------------------------------------------------------------------------//

 // Random //
 BENCHMARK_CAPTURE(
     BM_Find, unordered_set_random_uint64, std::unordered_set<uint64_t>{}, getRandomIntegerInputs<uint64_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_FindRehash,
                   unordered_set_random_uint64,
                   std::unordered_set<uint64_t, UInt64Hash>{},
                   getRandomIntegerInputs<uint64_t>)
     ->Arg(TestNumInputs);

 // Sorted //
 BENCHMARK_CAPTURE(
     BM_Find, unordered_set_sorted_uint64, std::unordered_set<uint64_t>{}, getSortedIntegerInputs<uint64_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_FindRehash,
                   unordered_set_sorted_uint64,
                   std::unordered_set<uint64_t, UInt64Hash>{},
                   getSortedIntegerInputs<uint64_t>)
     ->Arg(TestNumInputs);

 // Sorted //
 BENCHMARK_CAPTURE(BM_Find,
                   unordered_set_sorted_uint128,
                   std::unordered_set<__uint128_t, UInt128Hash>{},
                   getSortedTopBitsIntegerInputs<__uint128_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_FindRehash,
                   unordered_set_sorted_uint128,
                   std::unordered_set<__uint128_t, UInt128Hash>{},
                   getSortedTopBitsIntegerInputs<__uint128_t>)
     ->Arg(TestNumInputs);

 // Sorted //
 BENCHMARK_CAPTURE(
     BM_Find, unordered_set_sorted_uint32, std::unordered_set<uint32_t>{}, getSortedIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_FindRehash,
                   unordered_set_sorted_uint32,
                   std::unordered_set<uint32_t, UInt32Hash2>{},
                   getSortedIntegerInputs<uint32_t>)
     ->Arg(TestNumInputs);

 // Sorted Ascending //
 BENCHMARK_CAPTURE(
     BM_Find, unordered_set_sorted_large_uint64, std::unordered_set<uint64_t>{}, getSortedLargeIntegerInputs<uint64_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_FindRehash,
                   unordered_set_sorted_large_uint64,
                   std::unordered_set<uint64_t, UInt64Hash>{},
                   getSortedLargeIntegerInputs<uint64_t>)
     ->Arg(TestNumInputs);

 // Top Bits //
 BENCHMARK_CAPTURE(
     BM_Find, unordered_set_top_bits_uint64, std::unordered_set<uint64_t>{}, getSortedTopBitsIntegerInputs<uint64_t>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_FindRehash,
                   unordered_set_top_bits_uint64,
                   std::unordered_set<uint64_t, UInt64Hash>{},
                   getSortedTopBitsIntegerInputs<uint64_t>)
     ->Arg(TestNumInputs);

 // String //
 BENCHMARK_CAPTURE(BM_Find, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_FindRehash, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
     ->Arg(TestNumInputs);

 // Prefixed String //
 BENCHMARK_CAPTURE(
     BM_Find, unordered_set_prefixed_string, std::unordered_set<std::string>{}, getPrefixedRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(
     BM_FindRehash, unordered_set_prefixed_string, std::unordered_set<std::string>{}, getPrefixedRandomStringInputs)
     ->Arg(TestNumInputs);

 //----------------------------------------------------------------------------//
 //                         BM_Rehash
 // ---------------------------------------------------------------------------//

 BENCHMARK_CAPTURE(BM_Rehash,
                   unordered_set_string_arg,
                   std::unordered_set<std::string, std::hash<std::string>, SlowStringEq>{},
                   getRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_Rehash, unordered_set_int_arg, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
     ->Arg(TestNumInputs);

 //----------------------------------------------------------------------------//
 //                         BM_Compare
 // ---------------------------------------------------------------------------//

 BENCHMARK_CAPTURE(
     BM_Compare_same_container, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_Compare_same_container, unordered_set_int, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(
     BM_Compare_different_containers, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(
     BM_Compare_different_containers, unordered_set_int, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
     ->Arg(TestNumInputs);

 ///////////////////////////////////////////////////////////////////////////////
 BENCHMARK_CAPTURE(BM_InsertDuplicate, unordered_set_int, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
     ->Arg(TestNumInputs);
 BENCHMARK_CAPTURE(BM_InsertDuplicate, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(BM_EmplaceDuplicate, unordered_set_int, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
     ->Arg(TestNumInputs);
 BENCHMARK_CAPTURE(BM_EmplaceDuplicate, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(
     BM_InsertDuplicate, unordered_set_int_insert_arg, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
     ->Arg(TestNumInputs);
 BENCHMARK_CAPTURE(
     BM_InsertDuplicate, unordered_set_string_insert_arg, std::unordered_set<std::string>{}, getRandomStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(
     BM_EmplaceDuplicate, unordered_set_int_insert_arg, std::unordered_set<int>{}, getRandomIntegerInputs<unsigned>)
     ->Arg(TestNumInputs);

 BENCHMARK_CAPTURE(
     BM_EmplaceDuplicate, unordered_set_string_arg, std::unordered_set<std::string>{}, getRandomCStringInputs)
     ->Arg(TestNumInputs);

 BENCHMARK_MAIN();
	#include <cstdint>
	#include <cstdlib>
	#include <cstring>
	#include <functional>
	#include <unordered_set>
	#include <vector>

	#include "benchmark/benchmark.h"

	#include "ContainerBenchmarks.h"
	#include "GenerateInput.h"
	#include "test_macros.h"

	using namespace ContainerBenchmarks;

	constexpr std::size_t TestNumInputs = 1024;

	template <class _Size>
	inline TEST_ALWAYS_INLINE _Size loadword(const void* __p) {
	_Size __r;
	std::memcpy(&__r, __p, sizeof(__r));
	return __r;
	}

	inline TEST_ALWAYS_INLINE std::size_t rotate_by_at_least_1(std::size_t __val, int __shift) {
	return (__val >> __shift) \| (__val << (64 - __shift));
	}

	inline TEST_ALWAYS_INLINE std::size_t hash_len_16(std::size_t __u, std::size_t __v) {
	const std::size_t __mul = 0x9ddfea08eb382d69ULL;
	std::size_t __a = (__u ^ __v) * __mul;
	__a ^= (__a >> 47);
	std::size_t __b = (__v ^ __a) * __mul;
	__b ^= (__b >> 47);
	__b *= __mul;
	return __b;
	}

	template <std::size_t _Len>
	inline TEST_ALWAYS_INLINE std::size_t hash_len_0_to_8(const char* __s) {
	static_assert(_Len == 4 \|\| _Len == 8, "");
	const uint64_t __a = loadword<uint32_t>(__s);
	const uint64_t __b = loadword<uint32_t>(__s + _Len - 4);
	return hash_len_16(_Len + (__a << 3), __b);
	}

	struct UInt32Hash {
	UInt32Hash() = default;
	inline TEST_ALWAYS_INLINE std::size_t operator()(uint32_t data) const {
	return hash_len_0_to_8<4>(reinterpret_cast<const char*>(&data));
	}
	};

	struct UInt64Hash {
	UInt64Hash() = default;
	inline TEST_ALWAYS_INLINE std::size_t operator()(uint64_t data) const {
	return hash_len_0_to_8<8>(reinterpret_cast<const char*>(&data));
	}
	};

	struct UInt128Hash {
	UInt128Hash() = default;
	inline TEST_ALWAYS_INLINE std::size_t operator()(__uint128_t data) const {
	const __uint128_t __mask = static_cast<std::size_t>(-1);
	const std::size_t __a = (std::size_t)(data & __mask);
	const std::size_t __b = (std::size_t)((data & (__mask << 64)) >> 64);
	return hash_len_16(__a, rotate_by_at_least_1(__b + 16, 16)) ^ __b;
	}
	};

	struct UInt32Hash2 {
	UInt32Hash2() = default;
	inline TEST_ALWAYS_INLINE std::size_t operator()(uint32_t data) const {
	const uint32_t __m = 0x5bd1e995;
	const uint32_t __r = 24;
	uint32_t __h = 4;
	uint32_t __k = data;
	__k *= __m;
	__k ^= __k >> __r;
	__k *= __m;
	__h *= __m;
	__h ^= __k;
	__h ^= __h >> 13;
	__h *= __m;
	__h ^= __h >> 15;
	return __h;
	}
	};

	struct UInt64Hash2 {
	UInt64Hash2() = default;
	inline TEST_ALWAYS_INLINE std::size_t operator()(uint64_t data) const {
	return hash_len_0_to_8<8>(reinterpret_cast<const char*>(&data));
	}
	};

	// The sole purpose of this comparator is to be used in BM_Rehash, where
	// we need something slow enough to be easily noticable in benchmark results.
	// The default implementation of operator== for strings seems to be a little
	// too fast for that specific benchmark to reliably show a noticeable
	// improvement, but unoptimized bytewise comparison fits just right.
	// Early return is there just for convenience, since we only compare strings
	// of equal length in BM_Rehash.
	struct SlowStringEq {
	SlowStringEq() = default;
	inline TEST_ALWAYS_INLINE bool operator()(const std::string& lhs, const std::string& rhs) const {
	if (lhs.size() != rhs.size())
	return false;

	bool eq = true;
	for (size_t i = 0; i < lhs.size(); ++i) {
	eq &= lhs[i] == rhs[i];
	}
	return eq;
	}
	};

	//----------------------------------------------------------------------------//
	// BM_Hash
	// ---------------------------------------------------------------------------//

	template <class HashFn, class GenInputs>
	void BM_Hash(benchmark::State& st, HashFn fn, GenInputs gen) {
	auto in = gen(st.range(0));
	const auto end = in.data() + in.size();
	std::size_t last_hash = 0;
	benchmark::DoNotOptimize(&last_hash);
	while (st.KeepRunning()) {
	for (auto it = in.data(); it != end; ++it) {
	benchmark::DoNotOptimize(last_hash += fn(*it));
	}
	benchmark::ClobberMemory();
	}
	}

	BENCHMARK_CAPTURE(BM_Hash, uint32_random_std_hash, std::hash<uint32_t>{}, getRandomIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_Hash, uint32_random_custom_hash, UInt32Hash{}, getRandomIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_Hash, uint32_top_std_hash, std::hash<uint32_t>{}, getSortedTopBitsIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_Hash, uint32_top_custom_hash, UInt32Hash{}, getSortedTopBitsIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	//----------------------------------------------------------------------------//
	// BM_InsertValue
	// ---------------------------------------------------------------------------//

	// Sorted Ascending //
	BENCHMARK_CAPTURE(
	BM_InsertValue, unordered_set_uint32, std::unordered_set<uint32_t>{}, getRandomIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(
	BM_InsertValue, unordered_set_uint32_sorted, std::unordered_set<uint32_t>{}, getSortedIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	// Top Bytes //
	BENCHMARK_CAPTURE(BM_InsertValue,
	unordered_set_top_bits_uint32,
	std::unordered_set<uint32_t>{},
	getSortedTopBitsIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_InsertValueRehash,
	unordered_set_top_bits_uint32,
	std::unordered_set<uint32_t, UInt32Hash>{},
	getSortedTopBitsIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	// String //
	BENCHMARK_CAPTURE(BM_InsertValue, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_InsertValueRehash, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
	->Arg(TestNumInputs);

	// Prefixed String //
	BENCHMARK_CAPTURE(
	BM_InsertValue, unordered_set_prefixed_string, std::unordered_set<std::string>{}, getPrefixedRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_InsertValueRehash,
	unordered_set_prefixed_string,
	std::unordered_set<std::string>{},
	getPrefixedRandomStringInputs)
	->Arg(TestNumInputs);

	//----------------------------------------------------------------------------//
	// BM_Find
	// ---------------------------------------------------------------------------//

	// Random //
	BENCHMARK_CAPTURE(
	BM_Find, unordered_set_random_uint64, std::unordered_set<uint64_t>{}, getRandomIntegerInputs<uint64_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_FindRehash,
	unordered_set_random_uint64,
	std::unordered_set<uint64_t, UInt64Hash>{},
	getRandomIntegerInputs<uint64_t>)
	->Arg(TestNumInputs);

	// Sorted //
	BENCHMARK_CAPTURE(
	BM_Find, unordered_set_sorted_uint64, std::unordered_set<uint64_t>{}, getSortedIntegerInputs<uint64_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_FindRehash,
	unordered_set_sorted_uint64,
	std::unordered_set<uint64_t, UInt64Hash>{},
	getSortedIntegerInputs<uint64_t>)
	->Arg(TestNumInputs);

	// Sorted //
	BENCHMARK_CAPTURE(BM_Find,
	unordered_set_sorted_uint128,
	std::unordered_set<__uint128_t, UInt128Hash>{},
	getSortedTopBitsIntegerInputs<__uint128_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_FindRehash,
	unordered_set_sorted_uint128,
	std::unordered_set<__uint128_t, UInt128Hash>{},
	getSortedTopBitsIntegerInputs<__uint128_t>)
	->Arg(TestNumInputs);

	// Sorted //
	BENCHMARK_CAPTURE(
	BM_Find, unordered_set_sorted_uint32, std::unordered_set<uint32_t>{}, getSortedIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_FindRehash,
	unordered_set_sorted_uint32,
	std::unordered_set<uint32_t, UInt32Hash2>{},
	getSortedIntegerInputs<uint32_t>)
	->Arg(TestNumInputs);

	// Sorted Ascending //
	BENCHMARK_CAPTURE(
	BM_Find, unordered_set_sorted_large_uint64, std::unordered_set<uint64_t>{}, getSortedLargeIntegerInputs<uint64_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_FindRehash,
	unordered_set_sorted_large_uint64,
	std::unordered_set<uint64_t, UInt64Hash>{},
	getSortedLargeIntegerInputs<uint64_t>)
	->Arg(TestNumInputs);

	// Top Bits //
	BENCHMARK_CAPTURE(
	BM_Find, unordered_set_top_bits_uint64, std::unordered_set<uint64_t>{}, getSortedTopBitsIntegerInputs<uint64_t>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_FindRehash,
	unordered_set_top_bits_uint64,
	std::unordered_set<uint64_t, UInt64Hash>{},
	getSortedTopBitsIntegerInputs<uint64_t>)
	->Arg(TestNumInputs);

	// String //
	BENCHMARK_CAPTURE(BM_Find, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_FindRehash, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
	->Arg(TestNumInputs);

	// Prefixed String //
	BENCHMARK_CAPTURE(
	BM_Find, unordered_set_prefixed_string, std::unordered_set<std::string>{}, getPrefixedRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(
	BM_FindRehash, unordered_set_prefixed_string, std::unordered_set<std::string>{}, getPrefixedRandomStringInputs)
	->Arg(TestNumInputs);

	//----------------------------------------------------------------------------//
	// BM_Rehash
	// ---------------------------------------------------------------------------//

	BENCHMARK_CAPTURE(BM_Rehash,
	unordered_set_string_arg,
	std::unordered_set<std::string, std::hash<std::string>, SlowStringEq>{},
	getRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_Rehash, unordered_set_int_arg, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
	->Arg(TestNumInputs);

	//----------------------------------------------------------------------------//
	// BM_Compare
	// ---------------------------------------------------------------------------//

	BENCHMARK_CAPTURE(
	BM_Compare_same_container, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_Compare_same_container, unordered_set_int, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(
	BM_Compare_different_containers, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(
	BM_Compare_different_containers, unordered_set_int, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
	->Arg(TestNumInputs);

	///////////////////////////////////////////////////////////////////////////////
	BENCHMARK_CAPTURE(BM_InsertDuplicate, unordered_set_int, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
	->Arg(TestNumInputs);
	BENCHMARK_CAPTURE(BM_InsertDuplicate, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(BM_EmplaceDuplicate, unordered_set_int, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
	->Arg(TestNumInputs);
	BENCHMARK_CAPTURE(BM_EmplaceDuplicate, unordered_set_string, std::unordered_set<std::string>{}, getRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(
	BM_InsertDuplicate, unordered_set_int_insert_arg, std::unordered_set<int>{}, getRandomIntegerInputs<int>)
	->Arg(TestNumInputs);
	BENCHMARK_CAPTURE(
	BM_InsertDuplicate, unordered_set_string_insert_arg, std::unordered_set<std::string>{}, getRandomStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(
	BM_EmplaceDuplicate, unordered_set_int_insert_arg, std::unordered_set<int>{}, getRandomIntegerInputs<unsigned>)
	->Arg(TestNumInputs);

	BENCHMARK_CAPTURE(
	BM_EmplaceDuplicate, unordered_set_string_arg, std::unordered_set<std::string>{}, getRandomCStringInputs)
	->Arg(TestNumInputs);

	BENCHMARK_MAIN();