absl/container/internal/raw_hash_set_probe_benchmark.cc - third_party/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.
 //
 // Generates probe length statistics for many combinations of key types and key
 // distributions, all using the default hash function for swisstable.

 #include <memory>
 #include <regex>  // NOLINT
 #include <vector>

 #include "absl/container/flat_hash_map.h"
 #include "absl/container/internal/hash_function_defaults.h"
 #include "absl/container/internal/hashtable_debug.h"
 #include "absl/container/internal/raw_hash_set.h"
 #include "absl/random/distributions.h"
 #include "absl/random/random.h"
 #include "absl/strings/str_cat.h"
 #include "absl/strings/str_format.h"
 #include "absl/strings/string_view.h"
 #include "absl/strings/strip.h"

 namespace {

 enum class OutputStyle { kRegular, kBenchmark };

 // The --benchmark command line flag.
 // This is populated from main().
 // When run in "benchmark" mode, we have different output. This allows
 // A/B comparisons with tools like `benchy`.
 absl::string_view benchmarks;

 OutputStyle output() {
   return !benchmarks.empty() ? OutputStyle::kBenchmark : OutputStyle::kRegular;
 }

 template <class T>
 struct Policy {
   using slot_type = T;
   using key_type = T;
   using init_type = T;

   template <class allocator_type, class Arg>
   static void construct(allocator_type* alloc, slot_type* slot,
                         const Arg& arg) {
     std::allocator_traits<allocator_type>::construct(*alloc, slot, arg);
   }

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

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

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

 absl::BitGen& GlobalBitGen() {
   static auto* value = new absl::BitGen;
   return *value;
 }

 // Keeps a pool of allocations and randomly gives one out.
 // This introduces more randomization to the addresses given to swisstable and
 // should help smooth out this factor from probe length calculation.
 template <class T>
 class RandomizedAllocator {
  public:
   using value_type = T;

   RandomizedAllocator() = default;
   template <typename U>
   RandomizedAllocator(RandomizedAllocator<U>) {}  // NOLINT

   static T* allocate(size_t n) {
     auto& pointers = GetPointers(n);
     // Fill the pool
     while (pointers.size() < kRandomPool) {
       pointers.push_back(std::allocator<T>{}.allocate(n));
     }

     // Choose a random one.
     size_t i = absl::Uniform<size_t>(GlobalBitGen(), 0, pointers.size());
     T* result = pointers[i];
     pointers[i] = pointers.back();
     pointers.pop_back();
     return result;
   }

   static void deallocate(T* p, size_t n) {
     // Just put it back on the pool. No need to release the memory.
     GetPointers(n).push_back(p);
   }

  private:
   // We keep at least kRandomPool allocations for each size.
   static constexpr size_t kRandomPool = 20;

   static std::vector<T*>& GetPointers(size_t n) {
     static auto* m = new absl::flat_hash_map<size_t, std::vector<T*>>();
     return (*m)[n];
   }
 };

 template <class T>
 struct DefaultHash {
   using type = absl::container_internal::hash_default_hash<T>;
 };

 template <class T>
 using DefaultHashT = typename DefaultHash<T>::type;

 template <class T>
 struct Table : absl::container_internal::raw_hash_set<
                    Policy<T>, DefaultHashT<T>,
                    absl::container_internal::hash_default_eq<T>,
                    RandomizedAllocator<T>> {};

 struct LoadSizes {
   size_t min_load;
   size_t max_load;
 };

 LoadSizes GetMinMaxLoadSizes() {
   static const auto sizes = [] {
     Table<int> t;

     // First, fill enough to have a good distribution.
     constexpr size_t kMinSize = 10000;
     while (t.size() < kMinSize) t.insert(t.size());

     const auto reach_min_load_factor = [&] {
       const double lf = t.load_factor();
       while (lf <= t.load_factor()) t.insert(t.size());
     };

     // Then, insert until we reach min load factor.
     reach_min_load_factor();
     const size_t min_load_size = t.size();

     // Keep going until we hit min load factor again, then go back one.
     t.insert(t.size());
     reach_min_load_factor();

     return LoadSizes{min_load_size, t.size() - 1};
   }();
   return sizes;
 }

 struct Ratios {
   double min_load;
   double avg_load;
   double max_load;
 };

 // See absl/container/internal/hashtable_debug.h for details on
 // probe length calculation.
 template <class ElemFn>
 Ratios CollectMeanProbeLengths() {
   const auto min_max_sizes = GetMinMaxLoadSizes();

   ElemFn elem;
   using Key = decltype(elem());
   Table<Key> t;

   Ratios result;
   while (t.size() < min_max_sizes.min_load) t.insert(elem());
   result.min_load =
       absl::container_internal::GetHashtableDebugProbeSummary(t).mean;

   while (t.size() < (min_max_sizes.min_load + min_max_sizes.max_load) / 2)
     t.insert(elem());
   result.avg_load =
       absl::container_internal::GetHashtableDebugProbeSummary(t).mean;

   while (t.size() < min_max_sizes.max_load) t.insert(elem());
   result.max_load =
       absl::container_internal::GetHashtableDebugProbeSummary(t).mean;

   return result;
 }

 template <int Align>
 uintptr_t PointerForAlignment() {
   alignas(Align) static constexpr uintptr_t kInitPointer = 0;
   return reinterpret_cast<uintptr_t>(&kInitPointer);
 }

 // This incomplete type is used for testing hash of pointers of different
 // alignments.
 // NOTE: We are generating invalid pointer values on the fly with
 // reinterpret_cast. There are not "safely derived" pointers so using them is
 // technically UB. It is unlikely to be a problem, though.
 template <int Align>
 struct Ptr;

 template <int Align>
 Ptr<Align>* MakePtr(uintptr_t v) {
   if (sizeof(v) == 8) {
     constexpr int kCopyBits = 16;
     // Ensure high bits are all the same.
     v = static_cast<uintptr_t>(static_cast<intptr_t>(v << kCopyBits) >>
                                kCopyBits);
   }
   return reinterpret_cast<Ptr<Align>*>(v);
 }

 struct IntIdentity {
   uint64_t i;
   friend bool operator==(IntIdentity a, IntIdentity b) { return a.i == b.i; }
   IntIdentity operator++(int) { return IntIdentity{i++}; }
 };

 template <int Align>
 struct PtrIdentity {
   explicit PtrIdentity(uintptr_t val = PointerForAlignment<Align>()) : i(val) {}
   uintptr_t i;
   friend bool operator==(PtrIdentity a, PtrIdentity b) { return a.i == b.i; }
   PtrIdentity operator++(int) {
     PtrIdentity p(i);
     i += Align;
     return p;
   }
 };

 constexpr char kStringFormat[] = "/path/to/file/name-%07d-of-9999999.txt";

 template <bool small>
 struct String {
   std::string value;
   static std::string Make(uint32_t v) {
     return {small ? absl::StrCat(v) : absl::StrFormat(kStringFormat, v)};
   }
 };

 template <>
 struct DefaultHash<IntIdentity> {
   struct type {
     size_t operator()(IntIdentity t) const { return t.i; }
   };
 };

 template <int Align>
 struct DefaultHash<PtrIdentity<Align>> {
   struct type {
     size_t operator()(PtrIdentity<Align> t) const { return t.i; }
   };
 };

 template <class T>
 struct Sequential {
   T operator()() const { return current++; }
   mutable T current{};
 };

 template <int Align>
 struct Sequential<Ptr<Align>*> {
   Ptr<Align>* operator()() const {
     auto* result = MakePtr<Align>(current);
     current += Align;
     return result;
   }
   mutable uintptr_t current = PointerForAlignment<Align>();
 };


 template <bool small>
 struct Sequential<String<small>> {
   std::string operator()() const { return String<small>::Make(current++); }
   mutable uint32_t current = 0;
 };

 template <class T, class U>
 struct Sequential<std::pair<T, U>> {
   mutable Sequential<T> tseq;
   mutable Sequential<U> useq;

   using RealT = decltype(tseq());
   using RealU = decltype(useq());

   mutable std::vector<RealT> ts;
   mutable std::vector<RealU> us;
   mutable size_t ti = 0, ui = 0;

   std::pair<RealT, RealU> operator()() const {
     std::pair<RealT, RealU> value{get_t(), get_u()};
     if (ti == 0) {
       ti = ui + 1;
       ui = 0;
     } else {
       --ti;
       ++ui;
     }
     return value;
   }

   RealT get_t() const {
     while (ti >= ts.size()) ts.push_back(tseq());
     return ts[ti];
   }

   RealU get_u() const {
     while (ui >= us.size()) us.push_back(useq());
     return us[ui];
   }
 };

 template <class T, int percent_skip>
 struct AlmostSequential {
   mutable Sequential<T> current;

   auto operator()() const -> decltype(current()) {
     while (absl::Uniform(GlobalBitGen(), 0.0, 1.0) <= percent_skip / 100.)
       current();
     return current();
   }
 };

 struct Uniform {
   template <typename T>
   T operator()(T) const {
     return absl::Uniform<T>(absl::IntervalClosed, GlobalBitGen(), T{0}, ~T{0});
   }
 };

 struct Gaussian {
   template <typename T>
   T operator()(T) const {
     double d;
     do {
       d = absl::Gaussian<double>(GlobalBitGen(), 1e6, 1e4);
     } while (d <= 0 || d > std::numeric_limits<T>::max() / 2);
     return static_cast<T>(d);
   }
 };

 struct Zipf {
   template <typename T>
   T operator()(T) const {
     return absl::Zipf<T>(GlobalBitGen(), std::numeric_limits<T>::max(), 1.6);
   }
 };

 template <class T, class Dist>
 struct Random {
   T operator()() const { return Dist{}(T{}); }
 };

 template <class Dist, int Align>
 struct Random<Ptr<Align>*, Dist> {
   Ptr<Align>* operator()() const {
     return MakePtr<Align>(Random<uintptr_t, Dist>{}() * Align);
   }
 };

 template <class Dist>
 struct Random<IntIdentity, Dist> {
   IntIdentity operator()() const {
     return IntIdentity{Random<uint64_t, Dist>{}()};
   }
 };

 template <class Dist, int Align>
 struct Random<PtrIdentity<Align>, Dist> {
   PtrIdentity<Align> operator()() const {
     return PtrIdentity<Align>{Random<uintptr_t, Dist>{}() * Align};
   }
 };

 template <class Dist, bool small>
 struct Random<String<small>, Dist> {
   std::string operator()() const {
     return String<small>::Make(Random<uint32_t, Dist>{}());
   }
 };

 template <class T, class U, class Dist>
 struct Random<std::pair<T, U>, Dist> {
   auto operator()() const
       -> decltype(std::make_pair(Random<T, Dist>{}(), Random<U, Dist>{}())) {
     return std::make_pair(Random<T, Dist>{}(), Random<U, Dist>{}());
   }
 };

 template <typename>
 std::string Name();

 std::string Name(uint32_t*) { return "u32"; }
 std::string Name(uint64_t*) { return "u64"; }
 std::string Name(IntIdentity*) { return "IntIdentity"; }

 template <int Align>
 std::string Name(Ptr<Align>**) {
   return absl::StrCat("Ptr", Align);
 }

 template <int Align>
 std::string Name(PtrIdentity<Align>*) {
   return absl::StrCat("PtrIdentity", Align);
 }

 template <bool small>
 std::string Name(String<small>*) {
   return small ? "StrS" : "StrL";
 }

 template <class T, class U>
 std::string Name(std::pair<T, U>*) {
   if (output() == OutputStyle::kBenchmark)
     return absl::StrCat("P_", Name<T>(), "_", Name<U>());
   return absl::StrCat("P<", Name<T>(), ",", Name<U>(), ">");
 }

 template <class T>
 std::string Name(Sequential<T>*) {
   return "Sequential";
 }

 template <class T, int P>
 std::string Name(AlmostSequential<T, P>*) {
   return absl::StrCat("AlmostSeq_", P);
 }

 template <class T>
 std::string Name(Random<T, Uniform>*) {
   return "UnifRand";
 }

 template <class T>
 std::string Name(Random<T, Gaussian>*) {
   return "GausRand";
 }

 template <class T>
 std::string Name(Random<T, Zipf>*) {
   return "ZipfRand";
 }

 template <typename T>
 std::string Name() {
   return Name(static_cast<T*>(nullptr));
 }

 constexpr int kNameWidth = 15;
 constexpr int kDistWidth = 16;

 bool CanRunBenchmark(absl::string_view name) {
   static std::regex* const filter = []() -> std::regex* {
     return benchmarks.empty() || benchmarks == "all"
                ? nullptr
                : new std::regex(std::string(benchmarks));
   }();
   return filter == nullptr || std::regex_search(std::string(name), *filter);
 }

 struct Result {
   std::string name;
   std::string dist_name;
   Ratios ratios;
 };

 template <typename T, typename Dist>
 void RunForTypeAndDistribution(std::vector<Result>& results) {
   std::string name = absl::StrCat(Name<T>(), "/", Name<Dist>());
   // We have to check against all three names (min/avg/max) before we run it.
   // If any of them is enabled, we run it.
   if (!CanRunBenchmark(absl::StrCat(name, "/min")) &&
       !CanRunBenchmark(absl::StrCat(name, "/avg")) &&
       !CanRunBenchmark(absl::StrCat(name, "/max"))) {
     return;
   }
   results.push_back({Name<T>(), Name<Dist>(), CollectMeanProbeLengths<Dist>()});
 }

 template <class T>
 void RunForType(std::vector<Result>& results) {
   RunForTypeAndDistribution<T, Sequential<T>>(results);
   RunForTypeAndDistribution<T, AlmostSequential<T, 20>>(results);
   RunForTypeAndDistribution<T, AlmostSequential<T, 50>>(results);
   RunForTypeAndDistribution<T, Random<T, Uniform>>(results);
 #ifdef NDEBUG
   // Disable these in non-opt mode because they take too long.
   RunForTypeAndDistribution<T, Random<T, Gaussian>>(results);
   RunForTypeAndDistribution<T, Random<T, Zipf>>(results);
 #endif  // NDEBUG
 }

 }  // namespace

 int main(int argc, char** argv) {
   // Parse the benchmark flags. Ignore all of them except the regex pattern.
   for (int i = 1; i < argc; ++i) {
     absl::string_view arg = argv[i];
     const auto next = [&] { return argv[std::min(i + 1, argc - 1)]; };

     if (absl::ConsumePrefix(&arg, "--benchmark_filter")) {
       if (arg == "") {
         // --benchmark_filter X
         benchmarks = next();
       } else if (absl::ConsumePrefix(&arg, "=")) {
         // --benchmark_filter=X
         benchmarks = arg;
       }
     }

     // Any --benchmark flag turns on the mode.
     if (absl::ConsumePrefix(&arg, "--benchmark")) {
       if (benchmarks.empty()) benchmarks="all";
     }
   }

   std::vector<Result> results;
   RunForType<uint64_t>(results);
   RunForType<IntIdentity>(results);
   RunForType<Ptr<8>*>(results);
   RunForType<Ptr<16>*>(results);
   RunForType<Ptr<32>*>(results);
   RunForType<Ptr<64>*>(results);
   RunForType<PtrIdentity<8>>(results);
   RunForType<PtrIdentity<16>>(results);
   RunForType<PtrIdentity<32>>(results);
   RunForType<PtrIdentity<64>>(results);
   RunForType<std::pair<uint32_t, uint32_t>>(results);
   RunForType<String<true>>(results);
   RunForType<String<false>>(results);
   RunForType<std::pair<uint64_t, String<true>>>(results);
   RunForType<std::pair<String<true>, uint64_t>>(results);
   RunForType<std::pair<uint64_t, String<false>>>(results);
   RunForType<std::pair<String<false>, uint64_t>>(results);

   switch (output()) {
     case OutputStyle::kRegular:
       absl::PrintF("%-*s%-*s       Min       Avg       Max\n%s\n", kNameWidth,
                    "Type", kDistWidth, "Distribution",
                    std::string(kNameWidth + kDistWidth + 10 * 3, '-'));
       for (const auto& result : results) {
         absl::PrintF("%-*s%-*s  %8.4f  %8.4f  %8.4f\n", kNameWidth, result.name,
                      kDistWidth, result.dist_name, result.ratios.min_load,
                      result.ratios.avg_load, result.ratios.max_load);
       }
       break;
     case OutputStyle::kBenchmark: {
       absl::PrintF("{\n");
       absl::PrintF("  \"benchmarks\": [\n");
       absl::string_view comma;
       for (const auto& result : results) {
         auto print = [&](absl::string_view stat, double Ratios::*val) {
           std::string name =
               absl::StrCat(result.name, "/", result.dist_name, "/", stat);
           // Check the regex again. We might had have enabled only one of the
           // stats for the benchmark.
           if (!CanRunBenchmark(name)) return;
           absl::PrintF("    %s{\n", comma);
           absl::PrintF("      \"cpu_time\": %f,\n", 1e9 * result.ratios.*val);
           absl::PrintF("      \"real_time\": %f,\n", 1e9 * result.ratios.*val);
           absl::PrintF("      \"iterations\": 1,\n");
           absl::PrintF("      \"name\": \"%s\",\n", name);
           absl::PrintF("      \"time_unit\": \"ns\"\n");
           absl::PrintF("    }\n");
           comma = ",";
         };
         print("min", &Ratios::min_load);
         print("avg", &Ratios::avg_load);
         print("max", &Ratios::max_load);
       }
       absl::PrintF("  ],\n");
       absl::PrintF("  \"context\": {\n");
       absl::PrintF("  }\n");
       absl::PrintF("}\n");
       break;
     }
   }

   return 0;
 }
	// 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.
	//
	// Generates probe length statistics for many combinations of key types and key
	// distributions, all using the default hash function for swisstable.

	#include <memory>
	#include <regex> // NOLINT
	#include <vector>

	#include "absl/container/flat_hash_map.h"
	#include "absl/container/internal/hash_function_defaults.h"
	#include "absl/container/internal/hashtable_debug.h"
	#include "absl/container/internal/raw_hash_set.h"
	#include "absl/random/distributions.h"
	#include "absl/random/random.h"
	#include "absl/strings/str_cat.h"
	#include "absl/strings/str_format.h"
	#include "absl/strings/string_view.h"
	#include "absl/strings/strip.h"

	namespace {

	enum class OutputStyle { kRegular, kBenchmark };

	// The --benchmark command line flag.
	// This is populated from main().
	// When run in "benchmark" mode, we have different output. This allows
	// A/B comparisons with tools like `benchy`.
	absl::string_view benchmarks;

	OutputStyle output() {
	return !benchmarks.empty() ? OutputStyle::kBenchmark : OutputStyle::kRegular;
	}

	template <class T>
	struct Policy {
	using slot_type = T;
	using key_type = T;
	using init_type = T;

	template <class allocator_type, class Arg>
	static void construct(allocator_type* alloc, slot_type* slot,
	const Arg& arg) {
	std::allocator_traits<allocator_type>::construct(*alloc, slot, arg);
	}

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

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

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

	absl::BitGen& GlobalBitGen() {
	static auto* value = new absl::BitGen;
	return *value;
	}

	// Keeps a pool of allocations and randomly gives one out.
	// This introduces more randomization to the addresses given to swisstable and
	// should help smooth out this factor from probe length calculation.
	template <class T>
	class RandomizedAllocator {
	public:
	using value_type = T;

	RandomizedAllocator() = default;
	template <typename U>
	RandomizedAllocator(RandomizedAllocator<U>) {} // NOLINT

	static T* allocate(size_t n) {
	auto& pointers = GetPointers(n);
	// Fill the pool
	while (pointers.size() < kRandomPool) {
	pointers.push_back(std::allocator<T>{}.allocate(n));
	}

	// Choose a random one.
	size_t i = absl::Uniform<size_t>(GlobalBitGen(), 0, pointers.size());
	T* result = pointers[i];
	pointers[i] = pointers.back();
	pointers.pop_back();
	return result;
	}

	static void deallocate(T* p, size_t n) {
	// Just put it back on the pool. No need to release the memory.
	GetPointers(n).push_back(p);
	}

	private:
	// We keep at least kRandomPool allocations for each size.
	static constexpr size_t kRandomPool = 20;

	static std::vector<T*>& GetPointers(size_t n) {
	static auto* m = new absl::flat_hash_map<size_t, std::vector<T*>>();
	return (*m)[n];
	}
	};

	template <class T>
	struct DefaultHash {
	using type = absl::container_internal::hash_default_hash<T>;
	};

	template <class T>
	using DefaultHashT = typename DefaultHash<T>::type;

	template <class T>
	struct Table : absl::container_internal::raw_hash_set<
	Policy<T>, DefaultHashT<T>,
	absl::container_internal::hash_default_eq<T>,
	RandomizedAllocator<T>> {};

	struct LoadSizes {
	size_t min_load;
	size_t max_load;
	};

	LoadSizes GetMinMaxLoadSizes() {
	static const auto sizes = [] {
	Table<int> t;

	// First, fill enough to have a good distribution.
	constexpr size_t kMinSize = 10000;
	while (t.size() < kMinSize) t.insert(t.size());

	const auto reach_min_load_factor = [&] {
	const double lf = t.load_factor();
	while (lf <= t.load_factor()) t.insert(t.size());
	};

	// Then, insert until we reach min load factor.
	reach_min_load_factor();
	const size_t min_load_size = t.size();

	// Keep going until we hit min load factor again, then go back one.
	t.insert(t.size());
	reach_min_load_factor();

	return LoadSizes{min_load_size, t.size() - 1};
	}();
	return sizes;
	}

	struct Ratios {
	double min_load;
	double avg_load;
	double max_load;
	};

	// See absl/container/internal/hashtable_debug.h for details on
	// probe length calculation.
	template <class ElemFn>
	Ratios CollectMeanProbeLengths() {
	const auto min_max_sizes = GetMinMaxLoadSizes();

	ElemFn elem;
	using Key = decltype(elem());
	Table<Key> t;

	Ratios result;
	while (t.size() < min_max_sizes.min_load) t.insert(elem());
	result.min_load =
	absl::container_internal::GetHashtableDebugProbeSummary(t).mean;

	while (t.size() < (min_max_sizes.min_load + min_max_sizes.max_load) / 2)
	t.insert(elem());
	result.avg_load =
	absl::container_internal::GetHashtableDebugProbeSummary(t).mean;

	while (t.size() < min_max_sizes.max_load) t.insert(elem());
	result.max_load =
	absl::container_internal::GetHashtableDebugProbeSummary(t).mean;

	return result;
	}

	template <int Align>
	uintptr_t PointerForAlignment() {
	alignas(Align) static constexpr uintptr_t kInitPointer = 0;
	return reinterpret_cast<uintptr_t>(&kInitPointer);
	}

	// This incomplete type is used for testing hash of pointers of different
	// alignments.
	// NOTE: We are generating invalid pointer values on the fly with
	// reinterpret_cast. There are not "safely derived" pointers so using them is
	// technically UB. It is unlikely to be a problem, though.
	template <int Align>
	struct Ptr;

	template <int Align>
	Ptr<Align>* MakePtr(uintptr_t v) {
	if (sizeof(v) == 8) {
	constexpr int kCopyBits = 16;
	// Ensure high bits are all the same.
	v = static_cast<uintptr_t>(static_cast<intptr_t>(v << kCopyBits) >>
	kCopyBits);
	}
	return reinterpret_cast<Ptr<Align>*>(v);
	}

	struct IntIdentity {
	uint64_t i;
	friend bool operator==(IntIdentity a, IntIdentity b) { return a.i == b.i; }
	IntIdentity operator++(int) { return IntIdentity{i++}; }
	};

	template <int Align>
	struct PtrIdentity {
	explicit PtrIdentity(uintptr_t val = PointerForAlignment<Align>()) : i(val) {}
	uintptr_t i;
	friend bool operator==(PtrIdentity a, PtrIdentity b) { return a.i == b.i; }
	PtrIdentity operator++(int) {
	PtrIdentity p(i);
	i += Align;
	return p;
	}
	};

	constexpr char kStringFormat[] = "/path/to/file/name-%07d-of-9999999.txt";

	template <bool small>
	struct String {
	std::string value;
	static std::string Make(uint32_t v) {
	return {small ? absl::StrCat(v) : absl::StrFormat(kStringFormat, v)};
	}
	};

	template <>
	struct DefaultHash<IntIdentity> {
	struct type {
	size_t operator()(IntIdentity t) const { return t.i; }
	};
	};

	template <int Align>
	struct DefaultHash<PtrIdentity<Align>> {
	struct type {
	size_t operator()(PtrIdentity<Align> t) const { return t.i; }
	};
	};

	template <class T>
	struct Sequential {
	T operator()() const { return current++; }
	mutable T current{};
	};

	template <int Align>
	struct Sequential<Ptr<Align>*> {
	Ptr<Align>* operator()() const {
	auto* result = MakePtr<Align>(current);
	current += Align;
	return result;
	}
	mutable uintptr_t current = PointerForAlignment<Align>();
	};


	template <bool small>
	struct Sequential<String<small>> {
	std::string operator()() const { return String<small>::Make(current++); }
	mutable uint32_t current = 0;
	};

	template <class T, class U>
	struct Sequential<std::pair<T, U>> {
	mutable Sequential<T> tseq;
	mutable Sequential<U> useq;

	using RealT = decltype(tseq());
	using RealU = decltype(useq());

	mutable std::vector<RealT> ts;
	mutable std::vector<RealU> us;
	mutable size_t ti = 0, ui = 0;

	std::pair<RealT, RealU> operator()() const {
	std::pair<RealT, RealU> value{get_t(), get_u()};
	if (ti == 0) {
	ti = ui + 1;
	ui = 0;
	} else {
	--ti;
	++ui;
	}
	return value;
	}

	RealT get_t() const {
	while (ti >= ts.size()) ts.push_back(tseq());
	return ts[ti];
	}

	RealU get_u() const {
	while (ui >= us.size()) us.push_back(useq());
	return us[ui];
	}
	};

	template <class T, int percent_skip>
	struct AlmostSequential {
	mutable Sequential<T> current;

	auto operator()() const -> decltype(current()) {
	while (absl::Uniform(GlobalBitGen(), 0.0, 1.0) <= percent_skip / 100.)
	current();
	return current();
	}
	};

	struct Uniform {
	template <typename T>
	T operator()(T) const {
	return absl::Uniform<T>(absl::IntervalClosed, GlobalBitGen(), T{0}, ~T{0});
	}
	};

	struct Gaussian {
	template <typename T>
	T operator()(T) const {
	double d;
	do {
	d = absl::Gaussian<double>(GlobalBitGen(), 1e6, 1e4);
	} while (d <= 0 \|\| d > std::numeric_limits<T>::max() / 2);
	return static_cast<T>(d);
	}
	};

	struct Zipf {
	template <typename T>
	T operator()(T) const {
	return absl::Zipf<T>(GlobalBitGen(), std::numeric_limits<T>::max(), 1.6);
	}
	};

	template <class T, class Dist>
	struct Random {
	T operator()() const { return Dist{}(T{}); }
	};

	template <class Dist, int Align>
	struct Random<Ptr<Align>*, Dist> {
	Ptr<Align>* operator()() const {
	return MakePtr<Align>(Random<uintptr_t, Dist>{}() * Align);
	}
	};

	template <class Dist>
	struct Random<IntIdentity, Dist> {
	IntIdentity operator()() const {
	return IntIdentity{Random<uint64_t, Dist>{}()};
	}
	};

	template <class Dist, int Align>
	struct Random<PtrIdentity<Align>, Dist> {
	PtrIdentity<Align> operator()() const {
	return PtrIdentity<Align>{Random<uintptr_t, Dist>{}() * Align};
	}
	};

	template <class Dist, bool small>
	struct Random<String<small>, Dist> {
	std::string operator()() const {
	return String<small>::Make(Random<uint32_t, Dist>{}());
	}
	};

	template <class T, class U, class Dist>
	struct Random<std::pair<T, U>, Dist> {
	auto operator()() const
	-> decltype(std::make_pair(Random<T, Dist>{}(), Random<U, Dist>{}())) {
	return std::make_pair(Random<T, Dist>{}(), Random<U, Dist>{}());
	}
	};

	template <typename>
	std::string Name();

	std::string Name(uint32_t*) { return "u32"; }
	std::string Name(uint64_t*) { return "u64"; }
	std::string Name(IntIdentity*) { return "IntIdentity"; }

	template <int Align>
	std::string Name(Ptr<Align>**) {
	return absl::StrCat("Ptr", Align);
	}

	template <int Align>
	std::string Name(PtrIdentity<Align>*) {
	return absl::StrCat("PtrIdentity", Align);
	}

	template <bool small>
	std::string Name(String<small>*) {
	return small ? "StrS" : "StrL";
	}

	template <class T, class U>
	std::string Name(std::pair<T, U>*) {
	if (output() == OutputStyle::kBenchmark)
	return absl::StrCat("P_", Name<T>(), "_", Name<U>());
	return absl::StrCat("P<", Name<T>(), ",", Name<U>(), ">");
	}

	template <class T>
	std::string Name(Sequential<T>*) {
	return "Sequential";
	}

	template <class T, int P>
	std::string Name(AlmostSequential<T, P>*) {
	return absl::StrCat("AlmostSeq_", P);
	}

	template <class T>
	std::string Name(Random<T, Uniform>*) {
	return "UnifRand";
	}

	template <class T>
	std::string Name(Random<T, Gaussian>*) {
	return "GausRand";
	}

	template <class T>
	std::string Name(Random<T, Zipf>*) {
	return "ZipfRand";
	}

	template <typename T>
	std::string Name() {
	return Name(static_cast<T*>(nullptr));
	}

	constexpr int kNameWidth = 15;
	constexpr int kDistWidth = 16;

	bool CanRunBenchmark(absl::string_view name) {
	static std::regex* const filter = []() -> std::regex* {
	return benchmarks.empty() \|\| benchmarks == "all"
	? nullptr
	: new std::regex(std::string(benchmarks));
	}();
	return filter == nullptr \|\| std::regex_search(std::string(name), *filter);
	}

	struct Result {
	std::string name;
	std::string dist_name;
	Ratios ratios;
	};

	template <typename T, typename Dist>
	void RunForTypeAndDistribution(std::vector<Result>& results) {
	std::string name = absl::StrCat(Name<T>(), "/", Name<Dist>());
	// We have to check against all three names (min/avg/max) before we run it.
	// If any of them is enabled, we run it.
	if (!CanRunBenchmark(absl::StrCat(name, "/min")) &&
	!CanRunBenchmark(absl::StrCat(name, "/avg")) &&
	!CanRunBenchmark(absl::StrCat(name, "/max"))) {
	return;
	}
	results.push_back({Name<T>(), Name<Dist>(), CollectMeanProbeLengths<Dist>()});
	}

	template <class T>
	void RunForType(std::vector<Result>& results) {
	RunForTypeAndDistribution<T, Sequential<T>>(results);
	RunForTypeAndDistribution<T, AlmostSequential<T, 20>>(results);
	RunForTypeAndDistribution<T, AlmostSequential<T, 50>>(results);
	RunForTypeAndDistribution<T, Random<T, Uniform>>(results);
	#ifdef NDEBUG
	// Disable these in non-opt mode because they take too long.
	RunForTypeAndDistribution<T, Random<T, Gaussian>>(results);
	RunForTypeAndDistribution<T, Random<T, Zipf>>(results);
	#endif // NDEBUG
	}

	} // namespace

	int main(int argc, char** argv) {
	// Parse the benchmark flags. Ignore all of them except the regex pattern.
	for (int i = 1; i < argc; ++i) {
	absl::string_view arg = argv[i];
	const auto next = [&] { return argv[std::min(i + 1, argc - 1)]; };

	if (absl::ConsumePrefix(&arg, "--benchmark_filter")) {
	if (arg == "") {
	// --benchmark_filter X
	benchmarks = next();
	} else if (absl::ConsumePrefix(&arg, "=")) {
	// --benchmark_filter=X
	benchmarks = arg;
	}
	}

	// Any --benchmark flag turns on the mode.
	if (absl::ConsumePrefix(&arg, "--benchmark")) {
	if (benchmarks.empty()) benchmarks="all";
	}
	}

	std::vector<Result> results;
	RunForType<uint64_t>(results);
	RunForType<IntIdentity>(results);
	RunForType<Ptr<8>*>(results);
	RunForType<Ptr<16>*>(results);
	RunForType<Ptr<32>*>(results);
	RunForType<Ptr<64>*>(results);
	RunForType<PtrIdentity<8>>(results);
	RunForType<PtrIdentity<16>>(results);
	RunForType<PtrIdentity<32>>(results);
	RunForType<PtrIdentity<64>>(results);
	RunForType<std::pair<uint32_t, uint32_t>>(results);
	RunForType<String<true>>(results);
	RunForType<String<false>>(results);
	RunForType<std::pair<uint64_t, String<true>>>(results);
	RunForType<std::pair<String<true>, uint64_t>>(results);
	RunForType<std::pair<uint64_t, String<false>>>(results);
	RunForType<std::pair<String<false>, uint64_t>>(results);

	switch (output()) {
	case OutputStyle::kRegular:
	absl::PrintF("%-s%-s Min Avg Max\n%s\n", kNameWidth,
	"Type", kDistWidth, "Distribution",
	std::string(kNameWidth + kDistWidth + 10 * 3, '-'));
	for (const auto& result : results) {
	absl::PrintF("%-s%-s %8.4f %8.4f %8.4f\n", kNameWidth, result.name,
	kDistWidth, result.dist_name, result.ratios.min_load,
	result.ratios.avg_load, result.ratios.max_load);
	}
	break;
	case OutputStyle::kBenchmark: {
	absl::PrintF("{\n");
	absl::PrintF(" \"benchmarks\": [\n");
	absl::string_view comma;
	for (const auto& result : results) {
	auto print = [&](absl::string_view stat, double Ratios::*val) {
	std::string name =
	absl::StrCat(result.name, "/", result.dist_name, "/", stat);
	// Check the regex again. We might had have enabled only one of the
	// stats for the benchmark.
	if (!CanRunBenchmark(name)) return;
	absl::PrintF(" %s{\n", comma);
	absl::PrintF(" \"cpu_time\": %f,\n", 1e9 * result.ratios.*val);
	absl::PrintF(" \"real_time\": %f,\n", 1e9 * result.ratios.*val);
	absl::PrintF(" \"iterations\": 1,\n");
	absl::PrintF(" \"name\": \"%s\",\n", name);
	absl::PrintF(" \"time_unit\": \"ns\"\n");
	absl::PrintF(" }\n");
	comma = ",";
	};
	print("min", &Ratios::min_load);
	print("avg", &Ratios::avg_load);
	print("max", &Ratios::max_load);
	}
	absl::PrintF(" ],\n");
	absl::PrintF(" \"context\": {\n");
	absl::PrintF(" }\n");
	absl::PrintF("}\n");
	break;
	}
	}

	return 0;
	}