absl/container/internal/raw_hash_set_benchmark.cc - external/github.com/abseil/abseil-cpp - Git at Google

 // Copyright 2018 The Abseil Authors.
 //
 // 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
 //
 //      https://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 <array>
 #include <cmath>
 #include <numeric>
 #include <utility>
 #include <random>
 #include <vector>

 #include "absl/base/internal/raw_logging.h"
 #include "absl/container/internal/hash_function_defaults.h"
 #include "absl/container/internal/raw_hash_set.h"
 #include "absl/strings/str_format.h"
 #include "benchmark/benchmark.h"

 namespace absl {
 ABSL_NAMESPACE_BEGIN
 namespace container_internal {

 struct RawHashSetTestOnlyAccess {
   template <typename C>
   static auto GetSlots(const C& c) -> decltype(c.slots_) {
     return c.slots_;
   }
 };

 namespace {

 struct IntPolicy {
   using slot_type = int64_t;
   using key_type = int64_t;
   using init_type = int64_t;

   static void construct(void*, int64_t* slot, int64_t v) { *slot = v; }
   static void destroy(void*, int64_t*) {}
   static void transfer(void*, int64_t* new_slot, int64_t* old_slot) {
     *new_slot = *old_slot;
   }

   static int64_t& element(slot_type* slot) { return *slot; }

   template <class F>
   static auto apply(F&& f, int64_t x) -> decltype(std::forward<F>(f)(x, x)) {
     return std::forward<F>(f)(x, x);
   }
 };

 class StringPolicy {
   template <class F, class K, class V,
             class = typename std::enable_if<
                 std::is_convertible<const K&, absl::string_view>::value>::type>
   decltype(std::declval<F>()(
       std::declval<const absl::string_view&>(), std::piecewise_construct,
       std::declval<std::tuple<K>>(),
       std::declval<V>())) static apply_impl(F&& f,
                                             std::pair<std::tuple<K>, V> p) {
     const absl::string_view& key = std::get<0>(p.first);
     return std::forward<F>(f)(key, std::piecewise_construct, std::move(p.first),
                               std::move(p.second));
   }

  public:
   struct slot_type {
     struct ctor {};

     template <class... Ts>
     slot_type(ctor, Ts&&... ts) : pair(std::forward<Ts>(ts)...) {}

     std::pair<std::string, std::string> pair;
   };

   using key_type = std::string;
   using init_type = std::pair<std::string, std::string>;

   template <class allocator_type, class... Args>
   static void construct(allocator_type* alloc, slot_type* slot, Args... args) {
     std::allocator_traits<allocator_type>::construct(
         *alloc, slot, typename slot_type::ctor(), std::forward<Args>(args)...);
   }

   template <class allocator_type>
   static void destroy(allocator_type* alloc, slot_type* slot) {
     std::allocator_traits<allocator_type>::destroy(*alloc, slot);
   }

   template <class allocator_type>
   static void transfer(allocator_type* alloc, slot_type* new_slot,
                        slot_type* old_slot) {
     construct(alloc, new_slot, std::move(old_slot->pair));
     destroy(alloc, old_slot);
   }

   static std::pair<std::string, std::string>& element(slot_type* slot) {
     return slot->pair;
   }

   template <class F, class... Args>
   static auto apply(F&& f, Args&&... args)
       -> decltype(apply_impl(std::forward<F>(f),
                              PairArgs(std::forward<Args>(args)...))) {
     return apply_impl(std::forward<F>(f),
                       PairArgs(std::forward<Args>(args)...));
   }
 };

 struct StringHash : container_internal::hash_default_hash<absl::string_view> {
   using is_transparent = void;
 };
 struct StringEq : std::equal_to<absl::string_view> {
   using is_transparent = void;
 };

 struct StringTable
     : raw_hash_set<StringPolicy, StringHash, StringEq, std::allocator<int>> {
   using Base = typename StringTable::raw_hash_set;
   StringTable() {}
   using Base::Base;
 };

 struct IntTable
     : raw_hash_set<IntPolicy, container_internal::hash_default_hash<int64_t>,
                    std::equal_to<int64_t>, std::allocator<int64_t>> {
   using Base = typename IntTable::raw_hash_set;
   IntTable() {}
   using Base::Base;
 };

 struct string_generator {
   template <class RNG>
   std::string operator()(RNG& rng) const {
     std::string res;
     res.resize(12);
     std::uniform_int_distribution<uint32_t> printable_ascii(0x20, 0x7E);
     std::generate(res.begin(), res.end(), [&] { return printable_ascii(rng); });
     return res;
   }

   size_t size;
 };

 // Model a cache in steady state.
 //
 // On a table of size N, keep deleting the LRU entry and add a random one.
 void BM_CacheInSteadyState(benchmark::State& state) {
   std::random_device rd;
   std::mt19937 rng(rd());
   string_generator gen{12};
   StringTable t;
   std::deque<std::string> keys;
   while (t.size() < state.range(0)) {
     auto x = t.emplace(gen(rng), gen(rng));
     if (x.second) keys.push_back(x.first->first);
   }
   ABSL_RAW_CHECK(state.range(0) >= 10, "");
   while (state.KeepRunning()) {
     // Some cache hits.
     std::deque<std::string>::const_iterator it;
     for (int i = 0; i != 90; ++i) {
       if (i % 10 == 0) it = keys.end();
       ::benchmark::DoNotOptimize(t.find(*--it));
     }
     // Some cache misses.
     for (int i = 0; i != 10; ++i) ::benchmark::DoNotOptimize(t.find(gen(rng)));
     ABSL_RAW_CHECK(t.erase(keys.front()), keys.front().c_str());
     keys.pop_front();
     while (true) {
       auto x = t.emplace(gen(rng), gen(rng));
       if (x.second) {
         keys.push_back(x.first->first);
         break;
       }
     }
   }
   state.SetItemsProcessed(state.iterations());
   state.SetLabel(absl::StrFormat("load_factor=%.2f", t.load_factor()));
 }

 template <typename Benchmark>
 void CacheInSteadyStateArgs(Benchmark* bm) {
   // The default.
   const float max_load_factor = 0.875;
   // When the cache is at the steady state, the probe sequence will equal
   // capacity if there is no reclamation of deleted slots. Pick a number large
   // enough to make the benchmark slow for that case.
   const size_t capacity = 1 << 10;

   // Check N data points to cover load factors in [0.4, 0.8).
   const size_t kNumPoints = 10;
   for (size_t i = 0; i != kNumPoints; ++i)
     bm->Arg(std::ceil(
         capacity * (max_load_factor + i * max_load_factor / kNumPoints) / 2));
 }
 BENCHMARK(BM_CacheInSteadyState)->Apply(CacheInSteadyStateArgs);

 void BM_EndComparison(benchmark::State& state) {
   StringTable t = {{"a", "a"}, {"b", "b"}};
   auto it = t.begin();
   for (auto i : state) {
     benchmark::DoNotOptimize(t);
     benchmark::DoNotOptimize(it);
     benchmark::DoNotOptimize(it != t.end());
   }
 }
 BENCHMARK(BM_EndComparison);

 void BM_Iteration(benchmark::State& state) {
   std::random_device rd;
   std::mt19937 rng(rd());
   string_generator gen{12};
   StringTable t;

   size_t capacity = state.range(0);
   size_t size = state.range(1);
   t.reserve(capacity);

   while (t.size() < size) {
     t.emplace(gen(rng), gen(rng));
   }

   for (auto i : state) {
     benchmark::DoNotOptimize(t);
     for (auto it = t.begin(); it != t.end(); ++it) {
       benchmark::DoNotOptimize(*it);
     }
   }
 }

 BENCHMARK(BM_Iteration)
     ->ArgPair(1, 1)
     ->ArgPair(2, 2)
     ->ArgPair(4, 4)
     ->ArgPair(7, 7)
     ->ArgPair(10, 10)
     ->ArgPair(15, 15)
     ->ArgPair(16, 16)
     ->ArgPair(54, 54)
     ->ArgPair(100, 100)
     ->ArgPair(400, 400)
     // empty
     ->ArgPair(0, 0)
     ->ArgPair(10, 0)
     ->ArgPair(100, 0)
     ->ArgPair(1000, 0)
     ->ArgPair(10000, 0)
     // sparse
     ->ArgPair(100, 1)
     ->ArgPair(1000, 10);

 void BM_CopyCtor(benchmark::State& state) {
   std::random_device rd;
   std::mt19937 rng(rd());
   IntTable t;
   std::uniform_int_distribution<uint64_t> dist(0, ~uint64_t{});

   while (t.size() < state.range(0)) {
     t.emplace(dist(rng));
   }

   for (auto _ : state) {
     IntTable t2 = t;
     benchmark::DoNotOptimize(t2);
   }
 }
 BENCHMARK(BM_CopyCtor)->Range(128, 4096);

 void BM_CopyAssign(benchmark::State& state) {
   std::random_device rd;
   std::mt19937 rng(rd());
   IntTable t;
   std::uniform_int_distribution<uint64_t> dist(0, ~uint64_t{});
   while (t.size() < state.range(0)) {
     t.emplace(dist(rng));
   }

   IntTable t2;
   for (auto _ : state) {
     t2 = t;
     benchmark::DoNotOptimize(t2);
   }
 }
 BENCHMARK(BM_CopyAssign)->Range(128, 4096);

 void BM_RangeCtor(benchmark::State& state) {
   std::random_device rd;
   std::mt19937 rng(rd());
   std::uniform_int_distribution<uint64_t> dist(0, ~uint64_t{});
   std::vector<int> values;
   const size_t desired_size = state.range(0);
   while (values.size() < desired_size) {
     values.emplace_back(dist(rng));
   }

   for (auto unused : state) {
     IntTable t{values.begin(), values.end()};
     benchmark::DoNotOptimize(t);
   }
 }
 BENCHMARK(BM_RangeCtor)->Range(128, 65536);

 void BM_NoOpReserveIntTable(benchmark::State& state) {
   IntTable t;
   t.reserve(100000);
   for (auto _ : state) {
     benchmark::DoNotOptimize(t);
     t.reserve(100000);
   }
 }
 BENCHMARK(BM_NoOpReserveIntTable);

 void BM_NoOpReserveStringTable(benchmark::State& state) {
   StringTable t;
   t.reserve(100000);
   for (auto _ : state) {
     benchmark::DoNotOptimize(t);
     t.reserve(100000);
   }
 }
 BENCHMARK(BM_NoOpReserveStringTable);

 void BM_ReserveIntTable(benchmark::State& state) {
   int reserve_size = state.range(0);
   for (auto _ : state) {
     state.PauseTiming();
     IntTable t;
     state.ResumeTiming();
     benchmark::DoNotOptimize(t);
     t.reserve(reserve_size);
   }
 }
 BENCHMARK(BM_ReserveIntTable)->Range(128, 4096);

 void BM_ReserveStringTable(benchmark::State& state) {
   int reserve_size = state.range(0);
   for (auto _ : state) {
     state.PauseTiming();
     StringTable t;
     state.ResumeTiming();
     benchmark::DoNotOptimize(t);
     t.reserve(reserve_size);
   }
 }
 BENCHMARK(BM_ReserveStringTable)->Range(128, 4096);

 // Like std::iota, except that ctrl_t doesn't support operator++.
 template <typename CtrlIter>
 void Iota(CtrlIter begin, CtrlIter end, int value) {
   for (; begin != end; ++begin, ++value) {
     *begin = static_cast<ctrl_t>(value);
   }
 }

 void BM_Group_Match(benchmark::State& state) {
   std::array<ctrl_t, Group::kWidth> group;
   Iota(group.begin(), group.end(), -4);
   Group g{group.data()};
   h2_t h = 1;
   for (auto _ : state) {
     ::benchmark::DoNotOptimize(h);
     ::benchmark::DoNotOptimize(g);
     ::benchmark::DoNotOptimize(g.Match(h));
   }
 }
 BENCHMARK(BM_Group_Match);

 void BM_Group_MaskEmpty(benchmark::State& state) {
   std::array<ctrl_t, Group::kWidth> group;
   Iota(group.begin(), group.end(), -4);
   Group g{group.data()};
   for (auto _ : state) {
     ::benchmark::DoNotOptimize(g);
     ::benchmark::DoNotOptimize(g.MaskEmpty());
   }
 }
 BENCHMARK(BM_Group_MaskEmpty);

 void BM_Group_MaskEmptyOrDeleted(benchmark::State& state) {
   std::array<ctrl_t, Group::kWidth> group;
   Iota(group.begin(), group.end(), -4);
   Group g{group.data()};
   for (auto _ : state) {
     ::benchmark::DoNotOptimize(g);
     ::benchmark::DoNotOptimize(g.MaskEmptyOrDeleted());
   }
 }
 BENCHMARK(BM_Group_MaskEmptyOrDeleted);

 void BM_Group_CountLeadingEmptyOrDeleted(benchmark::State& state) {
   std::array<ctrl_t, Group::kWidth> group;
   Iota(group.begin(), group.end(), -2);
   Group g{group.data()};
   for (auto _ : state) {
     ::benchmark::DoNotOptimize(g);
     ::benchmark::DoNotOptimize(g.CountLeadingEmptyOrDeleted());
   }
 }
 BENCHMARK(BM_Group_CountLeadingEmptyOrDeleted);

 void BM_Group_MatchFirstEmptyOrDeleted(benchmark::State& state) {
   std::array<ctrl_t, Group::kWidth> group;
   Iota(group.begin(), group.end(), -2);
   Group g{group.data()};
   for (auto _ : state) {
     ::benchmark::DoNotOptimize(g);
     ::benchmark::DoNotOptimize(g.MaskEmptyOrDeleted().LowestBitSet());
   }
 }
 BENCHMARK(BM_Group_MatchFirstEmptyOrDeleted);

 void BM_DropDeletes(benchmark::State& state) {
   constexpr size_t capacity = (1 << 20) - 1;
   std::vector<ctrl_t> ctrl(capacity + 1 + Group::kWidth);
   ctrl[capacity] = ctrl_t::kSentinel;
   std::vector<ctrl_t> pattern = {ctrl_t::kEmpty,   static_cast<ctrl_t>(2),
                                  ctrl_t::kDeleted, static_cast<ctrl_t>(2),
                                  ctrl_t::kEmpty,   static_cast<ctrl_t>(1),
                                  ctrl_t::kDeleted};
   for (size_t i = 0; i != capacity; ++i) {
     ctrl[i] = pattern[i % pattern.size()];
   }
   while (state.KeepRunning()) {
     state.PauseTiming();
     std::vector<ctrl_t> ctrl_copy = ctrl;
     state.ResumeTiming();
     ConvertDeletedToEmptyAndFullToDeleted(ctrl_copy.data(), capacity);
     ::benchmark::DoNotOptimize(ctrl_copy[capacity]);
   }
 }
 BENCHMARK(BM_DropDeletes);

 }  // namespace
 }  // namespace container_internal
 ABSL_NAMESPACE_END
 }  // namespace absl

 // These methods are here to make it easy to examine the assembly for targeted
 // parts of the API.
 auto CodegenAbslRawHashSetInt64Find(absl::container_internal::IntTable* table,
                                     int64_t key) -> decltype(table->find(key)) {
   return table->find(key);
 }

 bool CodegenAbslRawHashSetInt64FindNeEnd(
     absl::container_internal::IntTable* table, int64_t key) {
   return table->find(key) != table->end();
 }

 auto CodegenAbslRawHashSetInt64Insert(absl::container_internal::IntTable* table,
                                       int64_t key)
     -> decltype(table->insert(key)) {
   return table->insert(key);
 }

 bool CodegenAbslRawHashSetInt64Contains(
     absl::container_internal::IntTable* table, int64_t key) {
   return table->contains(key);
 }

 void CodegenAbslRawHashSetInt64Iterate(
     absl::container_internal::IntTable* table) {
   for (auto x : *table) benchmark::DoNotOptimize(x);
 }

 int odr =
     (::benchmark::DoNotOptimize(std::make_tuple(
          &CodegenAbslRawHashSetInt64Find, &CodegenAbslRawHashSetInt64FindNeEnd,
          &CodegenAbslRawHashSetInt64Insert, &CodegenAbslRawHashSetInt64Contains,
          &CodegenAbslRawHashSetInt64Iterate)),
      1);
	// Copyright 2018 The Abseil Authors.
	//
	// 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
	//
	// https://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 <array>
	#include <cmath>
	#include <numeric>
	#include <utility>
	#include <random>
	#include <vector>

	#include "absl/base/internal/raw_logging.h"
	#include "absl/container/internal/hash_function_defaults.h"
	#include "absl/container/internal/raw_hash_set.h"
	#include "absl/strings/str_format.h"
	#include "benchmark/benchmark.h"

	namespace absl {
	ABSL_NAMESPACE_BEGIN
	namespace container_internal {

	struct RawHashSetTestOnlyAccess {
	template <typename C>
	static auto GetSlots(const C& c) -> decltype(c.slots_) {
	return c.slots_;
	}
	};

	namespace {

	struct IntPolicy {
	using slot_type = int64_t;
	using key_type = int64_t;
	using init_type = int64_t;

	static void construct(void, int64_t slot, int64_t v) { *slot = v; }
	static void destroy(void, int64_t) {}
	static void transfer(void, int64_t new_slot, int64_t* old_slot) {
	new_slot = old_slot;
	}

	static int64_t& element(slot_type* slot) { return *slot; }

	template <class F>
	static auto apply(F&& f, int64_t x) -> decltype(std::forward<F>(f)(x, x)) {
	return std::forward<F>(f)(x, x);
	}
	};

	class StringPolicy {
	template <class F, class K, class V,
	class = typename std::enable_if<
	std::is_convertible<const K&, absl::string_view>::value>::type>
	decltype(std::declval<F>()(
	std::declval<const absl::string_view&>(), std::piecewise_construct,
	std::declval<std::tuple<K>>(),
	std::declval<V>())) static apply_impl(F&& f,
	std::pair<std::tuple<K>, V> p) {
	const absl::string_view& key = std::get<0>(p.first);
	return std::forward<F>(f)(key, std::piecewise_construct, std::move(p.first),
	std::move(p.second));
	}

	public:
	struct slot_type {
	struct ctor {};

	template <class... Ts>
	slot_type(ctor, Ts&&... ts) : pair(std::forward<Ts>(ts)...) {}

	std::pair<std::string, std::string> pair;
	};

	using key_type = std::string;
	using init_type = std::pair<std::string, std::string>;

	template <class allocator_type, class... Args>
	static void construct(allocator_type* alloc, slot_type* slot, Args... args) {
	std::allocator_traits<allocator_type>::construct(
	*alloc, slot, typename slot_type::ctor(), std::forward<Args>(args)...);
	}

	template <class allocator_type>
	static void destroy(allocator_type* alloc, slot_type* slot) {
	std::allocator_traits<allocator_type>::destroy(*alloc, slot);
	}

	template <class allocator_type>
	static void transfer(allocator_type* alloc, slot_type* new_slot,
	slot_type* old_slot) {
	construct(alloc, new_slot, std::move(old_slot->pair));
	destroy(alloc, old_slot);
	}

	static std::pair<std::string, std::string>& element(slot_type* slot) {
	return slot->pair;
	}

	template <class F, class... Args>
	static auto apply(F&& f, Args&&... args)
	-> decltype(apply_impl(std::forward<F>(f),
	PairArgs(std::forward<Args>(args)...))) {
	return apply_impl(std::forward<F>(f),
	PairArgs(std::forward<Args>(args)...));
	}
	};

	struct StringHash : container_internal::hash_default_hash<absl::string_view> {
	using is_transparent = void;
	};
	struct StringEq : std::equal_to<absl::string_view> {
	using is_transparent = void;
	};

	struct StringTable
	: raw_hash_set<StringPolicy, StringHash, StringEq, std::allocator<int>> {
	using Base = typename StringTable::raw_hash_set;
	StringTable() {}
	using Base::Base;
	};

	struct IntTable
	: raw_hash_set<IntPolicy, container_internal::hash_default_hash<int64_t>,
	std::equal_to<int64_t>, std::allocator<int64_t>> {
	using Base = typename IntTable::raw_hash_set;
	IntTable() {}
	using Base::Base;
	};

	struct string_generator {
	template <class RNG>
	std::string operator()(RNG& rng) const {
	std::string res;
	res.resize(12);
	std::uniform_int_distribution<uint32_t> printable_ascii(0x20, 0x7E);
	std::generate(res.begin(), res.end(), [&] { return printable_ascii(rng); });
	return res;
	}

	size_t size;
	};

	// Model a cache in steady state.
	//
	// On a table of size N, keep deleting the LRU entry and add a random one.
	void BM_CacheInSteadyState(benchmark::State& state) {
	std::random_device rd;
	std::mt19937 rng(rd());
	string_generator gen{12};
	StringTable t;
	std::deque<std::string> keys;
	while (t.size() < state.range(0)) {
	auto x = t.emplace(gen(rng), gen(rng));
	if (x.second) keys.push_back(x.first->first);
	}
	ABSL_RAW_CHECK(state.range(0) >= 10, "");
	while (state.KeepRunning()) {
	// Some cache hits.
	std::deque<std::string>::const_iterator it;
	for (int i = 0; i != 90; ++i) {
	if (i % 10 == 0) it = keys.end();
	::benchmark::DoNotOptimize(t.find(*--it));
	}
	// Some cache misses.
	for (int i = 0; i != 10; ++i) ::benchmark::DoNotOptimize(t.find(gen(rng)));
	ABSL_RAW_CHECK(t.erase(keys.front()), keys.front().c_str());
	keys.pop_front();
	while (true) {
	auto x = t.emplace(gen(rng), gen(rng));
	if (x.second) {
	keys.push_back(x.first->first);
	break;
	}
	}
	}
	state.SetItemsProcessed(state.iterations());
	state.SetLabel(absl::StrFormat("load_factor=%.2f", t.load_factor()));
	}

	template <typename Benchmark>
	void CacheInSteadyStateArgs(Benchmark* bm) {
	// The default.
	const float max_load_factor = 0.875;
	// When the cache is at the steady state, the probe sequence will equal
	// capacity if there is no reclamation of deleted slots. Pick a number large
	// enough to make the benchmark slow for that case.
	const size_t capacity = 1 << 10;

	// Check N data points to cover load factors in [0.4, 0.8).
	const size_t kNumPoints = 10;
	for (size_t i = 0; i != kNumPoints; ++i)
	bm->Arg(std::ceil(
	capacity * (max_load_factor + i * max_load_factor / kNumPoints) / 2));
	}
	BENCHMARK(BM_CacheInSteadyState)->Apply(CacheInSteadyStateArgs);

	void BM_EndComparison(benchmark::State& state) {
	StringTable t = {{"a", "a"}, {"b", "b"}};
	auto it = t.begin();
	for (auto i : state) {
	benchmark::DoNotOptimize(t);
	benchmark::DoNotOptimize(it);
	benchmark::DoNotOptimize(it != t.end());
	}
	}
	BENCHMARK(BM_EndComparison);

	void BM_Iteration(benchmark::State& state) {
	std::random_device rd;
	std::mt19937 rng(rd());
	string_generator gen{12};
	StringTable t;

	size_t capacity = state.range(0);
	size_t size = state.range(1);
	t.reserve(capacity);

	while (t.size() < size) {
	t.emplace(gen(rng), gen(rng));
	}

	for (auto i : state) {
	benchmark::DoNotOptimize(t);
	for (auto it = t.begin(); it != t.end(); ++it) {
	benchmark::DoNotOptimize(*it);
	}
	}
	}

	BENCHMARK(BM_Iteration)
	->ArgPair(1, 1)
	->ArgPair(2, 2)
	->ArgPair(4, 4)
	->ArgPair(7, 7)
	->ArgPair(10, 10)
	->ArgPair(15, 15)
	->ArgPair(16, 16)
	->ArgPair(54, 54)
	->ArgPair(100, 100)
	->ArgPair(400, 400)
	// empty
	->ArgPair(0, 0)
	->ArgPair(10, 0)
	->ArgPair(100, 0)
	->ArgPair(1000, 0)
	->ArgPair(10000, 0)
	// sparse
	->ArgPair(100, 1)
	->ArgPair(1000, 10);

	void BM_CopyCtor(benchmark::State& state) {
	std::random_device rd;
	std::mt19937 rng(rd());
	IntTable t;
	std::uniform_int_distribution<uint64_t> dist(0, ~uint64_t{});

	while (t.size() < state.range(0)) {
	t.emplace(dist(rng));
	}

	for (auto _ : state) {
	IntTable t2 = t;
	benchmark::DoNotOptimize(t2);
	}
	}
	BENCHMARK(BM_CopyCtor)->Range(128, 4096);

	void BM_CopyAssign(benchmark::State& state) {
	std::random_device rd;
	std::mt19937 rng(rd());
	IntTable t;
	std::uniform_int_distribution<uint64_t> dist(0, ~uint64_t{});
	while (t.size() < state.range(0)) {
	t.emplace(dist(rng));
	}

	IntTable t2;
	for (auto _ : state) {
	t2 = t;
	benchmark::DoNotOptimize(t2);
	}
	}
	BENCHMARK(BM_CopyAssign)->Range(128, 4096);

	void BM_RangeCtor(benchmark::State& state) {
	std::random_device rd;
	std::mt19937 rng(rd());
	std::uniform_int_distribution<uint64_t> dist(0, ~uint64_t{});
	std::vector<int> values;
	const size_t desired_size = state.range(0);
	while (values.size() < desired_size) {
	values.emplace_back(dist(rng));
	}

	for (auto unused : state) {
	IntTable t{values.begin(), values.end()};
	benchmark::DoNotOptimize(t);
	}
	}
	BENCHMARK(BM_RangeCtor)->Range(128, 65536);

	void BM_NoOpReserveIntTable(benchmark::State& state) {
	IntTable t;
	t.reserve(100000);
	for (auto _ : state) {
	benchmark::DoNotOptimize(t);
	t.reserve(100000);
	}
	}
	BENCHMARK(BM_NoOpReserveIntTable);

	void BM_NoOpReserveStringTable(benchmark::State& state) {
	StringTable t;
	t.reserve(100000);
	for (auto _ : state) {
	benchmark::DoNotOptimize(t);
	t.reserve(100000);
	}
	}
	BENCHMARK(BM_NoOpReserveStringTable);

	void BM_ReserveIntTable(benchmark::State& state) {
	int reserve_size = state.range(0);
	for (auto _ : state) {
	state.PauseTiming();
	IntTable t;
	state.ResumeTiming();
	benchmark::DoNotOptimize(t);
	t.reserve(reserve_size);
	}
	}
	BENCHMARK(BM_ReserveIntTable)->Range(128, 4096);

	void BM_ReserveStringTable(benchmark::State& state) {
	int reserve_size = state.range(0);
	for (auto _ : state) {
	state.PauseTiming();
	StringTable t;
	state.ResumeTiming();
	benchmark::DoNotOptimize(t);
	t.reserve(reserve_size);
	}
	}
	BENCHMARK(BM_ReserveStringTable)->Range(128, 4096);

	// Like std::iota, except that ctrl_t doesn't support operator++.
	template <typename CtrlIter>
	void Iota(CtrlIter begin, CtrlIter end, int value) {
	for (; begin != end; ++begin, ++value) {
	*begin = static_cast<ctrl_t>(value);
	}
	}

	void BM_Group_Match(benchmark::State& state) {
	std::array<ctrl_t, Group::kWidth> group;
	Iota(group.begin(), group.end(), -4);
	Group g{group.data()};
	h2_t h = 1;
	for (auto _ : state) {
	::benchmark::DoNotOptimize(h);
	::benchmark::DoNotOptimize(g);
	::benchmark::DoNotOptimize(g.Match(h));
	}
	}
	BENCHMARK(BM_Group_Match);

	void BM_Group_MaskEmpty(benchmark::State& state) {
	std::array<ctrl_t, Group::kWidth> group;
	Iota(group.begin(), group.end(), -4);
	Group g{group.data()};
	for (auto _ : state) {
	::benchmark::DoNotOptimize(g);
	::benchmark::DoNotOptimize(g.MaskEmpty());
	}
	}
	BENCHMARK(BM_Group_MaskEmpty);

	void BM_Group_MaskEmptyOrDeleted(benchmark::State& state) {
	std::array<ctrl_t, Group::kWidth> group;
	Iota(group.begin(), group.end(), -4);
	Group g{group.data()};
	for (auto _ : state) {
	::benchmark::DoNotOptimize(g);
	::benchmark::DoNotOptimize(g.MaskEmptyOrDeleted());
	}
	}
	BENCHMARK(BM_Group_MaskEmptyOrDeleted);

	void BM_Group_CountLeadingEmptyOrDeleted(benchmark::State& state) {
	std::array<ctrl_t, Group::kWidth> group;
	Iota(group.begin(), group.end(), -2);
	Group g{group.data()};
	for (auto _ : state) {
	::benchmark::DoNotOptimize(g);
	::benchmark::DoNotOptimize(g.CountLeadingEmptyOrDeleted());
	}
	}
	BENCHMARK(BM_Group_CountLeadingEmptyOrDeleted);

	void BM_Group_MatchFirstEmptyOrDeleted(benchmark::State& state) {
	std::array<ctrl_t, Group::kWidth> group;
	Iota(group.begin(), group.end(), -2);
	Group g{group.data()};
	for (auto _ : state) {
	::benchmark::DoNotOptimize(g);
	::benchmark::DoNotOptimize(g.MaskEmptyOrDeleted().LowestBitSet());
	}
	}
	BENCHMARK(BM_Group_MatchFirstEmptyOrDeleted);

	void BM_DropDeletes(benchmark::State& state) {
	constexpr size_t capacity = (1 << 20) - 1;
	std::vector<ctrl_t> ctrl(capacity + 1 + Group::kWidth);
	ctrl[capacity] = ctrl_t::kSentinel;
	std::vector<ctrl_t> pattern = {ctrl_t::kEmpty, static_cast<ctrl_t>(2),
	ctrl_t::kDeleted, static_cast<ctrl_t>(2),
	ctrl_t::kEmpty, static_cast<ctrl_t>(1),
	ctrl_t::kDeleted};
	for (size_t i = 0; i != capacity; ++i) {
	ctrl[i] = pattern[i % pattern.size()];
	}
	while (state.KeepRunning()) {
	state.PauseTiming();
	std::vector<ctrl_t> ctrl_copy = ctrl;
	state.ResumeTiming();
	ConvertDeletedToEmptyAndFullToDeleted(ctrl_copy.data(), capacity);
	::benchmark::DoNotOptimize(ctrl_copy[capacity]);
	}
	}
	BENCHMARK(BM_DropDeletes);

	} // namespace
	} // namespace container_internal
	ABSL_NAMESPACE_END
	} // namespace absl

	// These methods are here to make it easy to examine the assembly for targeted
	// parts of the API.
	auto CodegenAbslRawHashSetInt64Find(absl::container_internal::IntTable* table,
	int64_t key) -> decltype(table->find(key)) {
	return table->find(key);
	}

	bool CodegenAbslRawHashSetInt64FindNeEnd(
	absl::container_internal::IntTable* table, int64_t key) {
	return table->find(key) != table->end();
	}

	auto CodegenAbslRawHashSetInt64Insert(absl::container_internal::IntTable* table,
	int64_t key)
	-> decltype(table->insert(key)) {
	return table->insert(key);
	}

	bool CodegenAbslRawHashSetInt64Contains(
	absl::container_internal::IntTable* table, int64_t key) {
	return table->contains(key);
	}

	void CodegenAbslRawHashSetInt64Iterate(
	absl::container_internal::IntTable* table) {
	for (auto x : *table) benchmark::DoNotOptimize(x);
	}

	int odr =
	(::benchmark::DoNotOptimize(std::make_tuple(
	&CodegenAbslRawHashSetInt64Find, &CodegenAbslRawHashSetInt64FindNeEnd,
	&CodegenAbslRawHashSetInt64Insert, &CodegenAbslRawHashSetInt64Contains,
	&CodegenAbslRawHashSetInt64Iterate)),
	1);