absl/strings/string_view_benchmark.cc - third_party/github/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 "absl/strings/string_view.h"

 #include <algorithm>
 #include <cstddef>
 #include <cstdint>
 #include <map>
 #include <random>
 #include <string>
 #include <unordered_set>
 #include <vector>

 #include "benchmark/benchmark.h"
 #include "absl/base/attributes.h"
 #include "absl/base/internal/raw_logging.h"
 #include "absl/base/macros.h"
 #include "absl/strings/str_cat.h"

 namespace {

 void BM_StringViewFromString(benchmark::State& state) {
   std::string s(state.range(0), 'x');
   std::string* ps = &s;
   struct SV {
     SV() = default;
     explicit SV(const std::string& s) : sv(s) {}
     absl::string_view sv;
   } sv;
   SV* psv = &sv;
   benchmark::DoNotOptimize(ps);
   benchmark::DoNotOptimize(psv);
   for (auto _ : state) {
     new (psv) SV(*ps);
     benchmark::DoNotOptimize(sv);
   }
 }
 BENCHMARK(BM_StringViewFromString)->Arg(12)->Arg(128);

 // Provide a forcibly out-of-line wrapper for operator== that can be used in
 // benchmarks to measure the impact of inlining.
 ABSL_ATTRIBUTE_NOINLINE
 bool NonInlinedEq(absl::string_view a, absl::string_view b) { return a == b; }

 // We use functions that cannot be inlined to perform the comparison loops so
 // that inlining of the operator== can't optimize away *everything*.
 ABSL_ATTRIBUTE_NOINLINE
 void DoEqualityComparisons(benchmark::State& state, absl::string_view a,
                            absl::string_view b) {
   for (auto _ : state) {
     benchmark::DoNotOptimize(a == b);
   }
 }

 void BM_EqualIdentical(benchmark::State& state) {
   std::string x(state.range(0), 'a');
   DoEqualityComparisons(state, x, x);
 }
 BENCHMARK(BM_EqualIdentical)->DenseRange(0, 3)->Range(4, 1 << 10);

 void BM_EqualSame(benchmark::State& state) {
   std::string x(state.range(0), 'a');
   std::string y = x;
   DoEqualityComparisons(state, x, y);
 }
 BENCHMARK(BM_EqualSame)
     ->DenseRange(0, 10)
     ->Arg(20)
     ->Arg(40)
     ->Arg(70)
     ->Arg(110)
     ->Range(160, 4096);

 void BM_EqualDifferent(benchmark::State& state) {
   const int len = state.range(0);
   std::string x(len, 'a');
   std::string y = x;
   if (len > 0) {
     y[len - 1] = 'b';
   }
   DoEqualityComparisons(state, x, y);
 }
 BENCHMARK(BM_EqualDifferent)->DenseRange(0, 3)->Range(4, 1 << 10);

 // This benchmark is intended to check that important simplifications can be
 // made with absl::string_view comparisons against constant strings. The idea is
 // that if constant strings cause redundant components of the comparison, the
 // compiler should detect and eliminate them. Here we use 8 different strings,
 // each with the same size. Provided our comparison makes the implementation
 // inline-able by the compiler, it should fold all of these away into a single
 // size check once per loop iteration.
 ABSL_ATTRIBUTE_NOINLINE
 void DoConstantSizeInlinedEqualityComparisons(benchmark::State& state,
                                               absl::string_view a) {
   for (auto _ : state) {
     benchmark::DoNotOptimize(a == "aaa");
     benchmark::DoNotOptimize(a == "bbb");
     benchmark::DoNotOptimize(a == "ccc");
     benchmark::DoNotOptimize(a == "ddd");
     benchmark::DoNotOptimize(a == "eee");
     benchmark::DoNotOptimize(a == "fff");
     benchmark::DoNotOptimize(a == "ggg");
     benchmark::DoNotOptimize(a == "hhh");
   }
 }
 void BM_EqualConstantSizeInlined(benchmark::State& state) {
   std::string x(state.range(0), 'a');
   DoConstantSizeInlinedEqualityComparisons(state, x);
 }
 // We only need to check for size of 3, and <> 3 as this benchmark only has to
 // do with size differences.
 BENCHMARK(BM_EqualConstantSizeInlined)->DenseRange(2, 4);

 // This benchmark exists purely to give context to the above timings: this is
 // what they would look like if the compiler is completely unable to simplify
 // between two comparisons when they are comparing against constant strings.
 ABSL_ATTRIBUTE_NOINLINE
 void DoConstantSizeNonInlinedEqualityComparisons(benchmark::State& state,
                                                  absl::string_view a) {
   for (auto _ : state) {
     // Force these out-of-line to compare with the above function.
     benchmark::DoNotOptimize(NonInlinedEq(a, "aaa"));
     benchmark::DoNotOptimize(NonInlinedEq(a, "bbb"));
     benchmark::DoNotOptimize(NonInlinedEq(a, "ccc"));
     benchmark::DoNotOptimize(NonInlinedEq(a, "ddd"));
     benchmark::DoNotOptimize(NonInlinedEq(a, "eee"));
     benchmark::DoNotOptimize(NonInlinedEq(a, "fff"));
     benchmark::DoNotOptimize(NonInlinedEq(a, "ggg"));
     benchmark::DoNotOptimize(NonInlinedEq(a, "hhh"));
   }
 }

 void BM_EqualConstantSizeNonInlined(benchmark::State& state) {
   std::string x(state.range(0), 'a');
   DoConstantSizeNonInlinedEqualityComparisons(state, x);
 }
 // We only need to check for size of 3, and <> 3 as this benchmark only has to
 // do with size differences.
 BENCHMARK(BM_EqualConstantSizeNonInlined)->DenseRange(2, 4);

 void BM_CompareSame(benchmark::State& state) {
   const int len = state.range(0);
   std::string x;
   for (int i = 0; i < len; i++) {
     x += 'a';
   }
   std::string y = x;
   absl::string_view a = x;
   absl::string_view b = y;

   for (auto _ : state) {
     benchmark::DoNotOptimize(a);
     benchmark::DoNotOptimize(b);
     benchmark::DoNotOptimize(a.compare(b));
   }
 }
 BENCHMARK(BM_CompareSame)->DenseRange(0, 3)->Range(4, 1 << 10);

 void BM_CompareFirstOneLess(benchmark::State& state) {
   const int len = state.range(0);
   std::string x(len, 'a');
   std::string y = x;
   y.back() = 'b';
   absl::string_view a = x;
   absl::string_view b = y;

   for (auto _ : state) {
     benchmark::DoNotOptimize(a);
     benchmark::DoNotOptimize(b);
     benchmark::DoNotOptimize(a.compare(b));
   }
 }
 BENCHMARK(BM_CompareFirstOneLess)->DenseRange(1, 3)->Range(4, 1 << 10);

 void BM_CompareSecondOneLess(benchmark::State& state) {
   const int len = state.range(0);
   std::string x(len, 'a');
   std::string y = x;
   x.back() = 'b';
   absl::string_view a = x;
   absl::string_view b = y;

   for (auto _ : state) {
     benchmark::DoNotOptimize(a);
     benchmark::DoNotOptimize(b);
     benchmark::DoNotOptimize(a.compare(b));
   }
 }
 BENCHMARK(BM_CompareSecondOneLess)->DenseRange(1, 3)->Range(4, 1 << 10);

 void BM_find_string_view_len_one(benchmark::State& state) {
   std::string haystack(state.range(0), '0');
   absl::string_view s(haystack);
   for (auto _ : state) {
     benchmark::DoNotOptimize(s.find("x"));  // not present; length 1
   }
 }
 BENCHMARK(BM_find_string_view_len_one)->Range(1, 1 << 20);

 void BM_find_string_view_len_two(benchmark::State& state) {
   std::string haystack(state.range(0), '0');
   absl::string_view s(haystack);
   for (auto _ : state) {
     benchmark::DoNotOptimize(s.find("xx"));  // not present; length 2
   }
 }
 BENCHMARK(BM_find_string_view_len_two)->Range(1, 1 << 20);

 void BM_find_one_char(benchmark::State& state) {
   std::string haystack(state.range(0), '0');
   absl::string_view s(haystack);
   for (auto _ : state) {
     benchmark::DoNotOptimize(s.find('x'));  // not present
   }
 }
 BENCHMARK(BM_find_one_char)->Range(1, 1 << 20);

 void BM_rfind_one_char(benchmark::State& state) {
   std::string haystack(state.range(0), '0');
   absl::string_view s(haystack);
   for (auto _ : state) {
     benchmark::DoNotOptimize(s.rfind('x'));  // not present
   }
 }
 BENCHMARK(BM_rfind_one_char)->Range(1, 1 << 20);

 void BM_worst_case_find_first_of(benchmark::State& state, int haystack_len) {
   const int needle_len = state.range(0);
   std::string needle;
   for (int i = 0; i < needle_len; ++i) {
     needle += 'a' + i;
   }
   std::string haystack(haystack_len, '0');  // 1000 zeros.

   absl::string_view s(haystack);
   for (auto _ : state) {
     benchmark::DoNotOptimize(s.find_first_of(needle));
   }
 }

 void BM_find_first_of_short(benchmark::State& state) {
   BM_worst_case_find_first_of(state, 10);
 }

 void BM_find_first_of_medium(benchmark::State& state) {
   BM_worst_case_find_first_of(state, 100);
 }

 void BM_find_first_of_long(benchmark::State& state) {
   BM_worst_case_find_first_of(state, 1000);
 }

 BENCHMARK(BM_find_first_of_short)->DenseRange(0, 4)->Arg(8)->Arg(16)->Arg(32);
 BENCHMARK(BM_find_first_of_medium)->DenseRange(0, 4)->Arg(8)->Arg(16)->Arg(32);
 BENCHMARK(BM_find_first_of_long)->DenseRange(0, 4)->Arg(8)->Arg(16)->Arg(32);

 struct EasyMap : public std::map<absl::string_view, uint64_t> {
   explicit EasyMap(size_t) {}
 };

 // This templated benchmark helper function is intended to stress operator== or
 // operator< in a realistic test.  It surely isn't entirely realistic, but it's
 // a start.  The test creates a map of type Map, a template arg, and populates
 // it with table_size key/value pairs. Each key has WordsPerKey words.  After
 // creating the map, a number of lookups are done in random order.  Some keys
 // are used much more frequently than others in this phase of the test.
 template <typename Map, int WordsPerKey>
 void StringViewMapBenchmark(benchmark::State& state) {
   const int table_size = state.range(0);
   const double kFractionOfKeysThatAreHot = 0.2;
   const int kNumLookupsOfHotKeys = 20;
   const int kNumLookupsOfColdKeys = 1;
   const char* words[] = {"the",   "quick",  "brown",    "fox",      "jumped",
                          "over",  "the",    "lazy",     "dog",      "and",
                          "found", "a",      "large",    "mushroom", "and",
                          "a",     "couple", "crickets", "eating",   "pie"};
   // Create some keys that consist of words in random order.
   std::random_device r;
   std::seed_seq seed({r(), r(), r(), r(), r(), r(), r(), r()});
   std::mt19937 rng(seed);
   std::vector<std::string> keys(table_size);
   std::vector<int> all_indices;
   const int kBlockSize = 1 << 12;
   std::unordered_set<std::string> t(kBlockSize);
   std::uniform_int_distribution<int> uniform(0, ABSL_ARRAYSIZE(words) - 1);
   for (int i = 0; i < table_size; i++) {
     all_indices.push_back(i);
     do {
       keys[i].clear();
       for (int j = 0; j < WordsPerKey; j++) {
         absl::StrAppend(&keys[i], j > 0 ? " " : "", words[uniform(rng)]);
       }
     } while (!t.insert(keys[i]).second);
   }

   // Create a list of strings to lookup: a permutation of the array of
   // keys we just created, with repeats.  "Hot" keys get repeated more.
   std::shuffle(all_indices.begin(), all_indices.end(), rng);
   const int num_hot = table_size * kFractionOfKeysThatAreHot;
   const int num_cold = table_size - num_hot;
   std::vector<int> hot_indices(all_indices.begin(),
                                all_indices.begin() + num_hot);
   std::vector<int> indices;
   for (int i = 0; i < kNumLookupsOfColdKeys; i++) {
     indices.insert(indices.end(), all_indices.begin(), all_indices.end());
   }
   for (int i = 0; i < kNumLookupsOfHotKeys - kNumLookupsOfColdKeys; i++) {
     indices.insert(indices.end(), hot_indices.begin(), hot_indices.end());
   }
   std::shuffle(indices.begin(), indices.end(), rng);
   ABSL_RAW_CHECK(
       num_cold * kNumLookupsOfColdKeys + num_hot * kNumLookupsOfHotKeys ==
           indices.size(),
       "");
   // After constructing the array we probe it with absl::string_views built from
   // test_strings.  This means operator== won't see equal pointers, so
   // it'll have to check for equal lengths and equal characters.
   std::vector<std::string> test_strings(indices.size());
   for (int i = 0; i < indices.size(); i++) {
     test_strings[i] = keys[indices[i]];
   }

   // Run the benchmark. It includes map construction but is mostly
   // map lookups.
   for (auto _ : state) {
     Map h(table_size);
     for (int i = 0; i < table_size; i++) {
       h[keys[i]] = i * 2;
     }
     ABSL_RAW_CHECK(h.size() == table_size, "");
     uint64_t sum = 0;
     for (int i = 0; i < indices.size(); i++) {
       sum += h[test_strings[i]];
     }
     benchmark::DoNotOptimize(sum);
   }
 }

 void BM_StdMap_4(benchmark::State& state) {
   StringViewMapBenchmark<EasyMap, 4>(state);
 }
 BENCHMARK(BM_StdMap_4)->Range(1 << 10, 1 << 16);

 void BM_StdMap_8(benchmark::State& state) {
   StringViewMapBenchmark<EasyMap, 8>(state);
 }
 BENCHMARK(BM_StdMap_8)->Range(1 << 10, 1 << 16);

 void BM_CopyToStringNative(benchmark::State& state) {
   std::string src(state.range(0), 'x');
   absl::string_view sv(src);
   std::string dst;
   for (auto _ : state) {
     dst.assign(sv.begin(), sv.end());
   }
 }
 BENCHMARK(BM_CopyToStringNative)->Range(1 << 3, 1 << 12);

 void BM_AppendToStringNative(benchmark::State& state) {
   std::string src(state.range(0), 'x');
   absl::string_view sv(src);
   std::string dst;
   for (auto _ : state) {
     dst.clear();
     dst.insert(dst.end(), sv.begin(), sv.end());
   }
 }
 BENCHMARK(BM_AppendToStringNative)->Range(1 << 3, 1 << 12);

 }  // namespace
	// 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 "absl/strings/string_view.h"

	#include <algorithm>
	#include <cstddef>
	#include <cstdint>
	#include <map>
	#include <random>
	#include <string>
	#include <unordered_set>
	#include <vector>

	#include "benchmark/benchmark.h"
	#include "absl/base/attributes.h"
	#include "absl/base/internal/raw_logging.h"
	#include "absl/base/macros.h"
	#include "absl/strings/str_cat.h"

	namespace {

	void BM_StringViewFromString(benchmark::State& state) {
	std::string s(state.range(0), 'x');
	std::string* ps = &s;
	struct SV {
	SV() = default;
	explicit SV(const std::string& s) : sv(s) {}
	absl::string_view sv;
	} sv;
	SV* psv = &sv;
	benchmark::DoNotOptimize(ps);
	benchmark::DoNotOptimize(psv);
	for (auto _ : state) {
	new (psv) SV(*ps);
	benchmark::DoNotOptimize(sv);
	}
	}
	BENCHMARK(BM_StringViewFromString)->Arg(12)->Arg(128);

	// Provide a forcibly out-of-line wrapper for operator== that can be used in
	// benchmarks to measure the impact of inlining.
	ABSL_ATTRIBUTE_NOINLINE
	bool NonInlinedEq(absl::string_view a, absl::string_view b) { return a == b; }

	// We use functions that cannot be inlined to perform the comparison loops so
	// that inlining of the operator== can't optimize away everything.
	ABSL_ATTRIBUTE_NOINLINE
	void DoEqualityComparisons(benchmark::State& state, absl::string_view a,
	absl::string_view b) {
	for (auto _ : state) {
	benchmark::DoNotOptimize(a == b);
	}
	}

	void BM_EqualIdentical(benchmark::State& state) {
	std::string x(state.range(0), 'a');
	DoEqualityComparisons(state, x, x);
	}
	BENCHMARK(BM_EqualIdentical)->DenseRange(0, 3)->Range(4, 1 << 10);

	void BM_EqualSame(benchmark::State& state) {
	std::string x(state.range(0), 'a');
	std::string y = x;
	DoEqualityComparisons(state, x, y);
	}
	BENCHMARK(BM_EqualSame)
	->DenseRange(0, 10)
	->Arg(20)
	->Arg(40)
	->Arg(70)
	->Arg(110)
	->Range(160, 4096);

	void BM_EqualDifferent(benchmark::State& state) {
	const int len = state.range(0);
	std::string x(len, 'a');
	std::string y = x;
	if (len > 0) {
	y[len - 1] = 'b';
	}
	DoEqualityComparisons(state, x, y);
	}
	BENCHMARK(BM_EqualDifferent)->DenseRange(0, 3)->Range(4, 1 << 10);

	// This benchmark is intended to check that important simplifications can be
	// made with absl::string_view comparisons against constant strings. The idea is
	// that if constant strings cause redundant components of the comparison, the
	// compiler should detect and eliminate them. Here we use 8 different strings,
	// each with the same size. Provided our comparison makes the implementation
	// inline-able by the compiler, it should fold all of these away into a single
	// size check once per loop iteration.
	ABSL_ATTRIBUTE_NOINLINE
	void DoConstantSizeInlinedEqualityComparisons(benchmark::State& state,
	absl::string_view a) {
	for (auto _ : state) {
	benchmark::DoNotOptimize(a == "aaa");
	benchmark::DoNotOptimize(a == "bbb");
	benchmark::DoNotOptimize(a == "ccc");
	benchmark::DoNotOptimize(a == "ddd");
	benchmark::DoNotOptimize(a == "eee");
	benchmark::DoNotOptimize(a == "fff");
	benchmark::DoNotOptimize(a == "ggg");
	benchmark::DoNotOptimize(a == "hhh");
	}
	}
	void BM_EqualConstantSizeInlined(benchmark::State& state) {
	std::string x(state.range(0), 'a');
	DoConstantSizeInlinedEqualityComparisons(state, x);
	}
	// We only need to check for size of 3, and <> 3 as this benchmark only has to
	// do with size differences.
	BENCHMARK(BM_EqualConstantSizeInlined)->DenseRange(2, 4);

	// This benchmark exists purely to give context to the above timings: this is
	// what they would look like if the compiler is completely unable to simplify
	// between two comparisons when they are comparing against constant strings.
	ABSL_ATTRIBUTE_NOINLINE
	void DoConstantSizeNonInlinedEqualityComparisons(benchmark::State& state,
	absl::string_view a) {
	for (auto _ : state) {
	// Force these out-of-line to compare with the above function.
	benchmark::DoNotOptimize(NonInlinedEq(a, "aaa"));
	benchmark::DoNotOptimize(NonInlinedEq(a, "bbb"));
	benchmark::DoNotOptimize(NonInlinedEq(a, "ccc"));
	benchmark::DoNotOptimize(NonInlinedEq(a, "ddd"));
	benchmark::DoNotOptimize(NonInlinedEq(a, "eee"));
	benchmark::DoNotOptimize(NonInlinedEq(a, "fff"));
	benchmark::DoNotOptimize(NonInlinedEq(a, "ggg"));
	benchmark::DoNotOptimize(NonInlinedEq(a, "hhh"));
	}
	}

	void BM_EqualConstantSizeNonInlined(benchmark::State& state) {
	std::string x(state.range(0), 'a');
	DoConstantSizeNonInlinedEqualityComparisons(state, x);
	}
	// We only need to check for size of 3, and <> 3 as this benchmark only has to
	// do with size differences.
	BENCHMARK(BM_EqualConstantSizeNonInlined)->DenseRange(2, 4);

	void BM_CompareSame(benchmark::State& state) {
	const int len = state.range(0);
	std::string x;
	for (int i = 0; i < len; i++) {
	x += 'a';
	}
	std::string y = x;
	absl::string_view a = x;
	absl::string_view b = y;

	for (auto _ : state) {
	benchmark::DoNotOptimize(a);
	benchmark::DoNotOptimize(b);
	benchmark::DoNotOptimize(a.compare(b));
	}
	}
	BENCHMARK(BM_CompareSame)->DenseRange(0, 3)->Range(4, 1 << 10);

	void BM_CompareFirstOneLess(benchmark::State& state) {
	const int len = state.range(0);
	std::string x(len, 'a');
	std::string y = x;
	y.back() = 'b';
	absl::string_view a = x;
	absl::string_view b = y;

	for (auto _ : state) {
	benchmark::DoNotOptimize(a);
	benchmark::DoNotOptimize(b);
	benchmark::DoNotOptimize(a.compare(b));
	}
	}
	BENCHMARK(BM_CompareFirstOneLess)->DenseRange(1, 3)->Range(4, 1 << 10);

	void BM_CompareSecondOneLess(benchmark::State& state) {
	const int len = state.range(0);
	std::string x(len, 'a');
	std::string y = x;
	x.back() = 'b';
	absl::string_view a = x;
	absl::string_view b = y;

	for (auto _ : state) {
	benchmark::DoNotOptimize(a);
	benchmark::DoNotOptimize(b);
	benchmark::DoNotOptimize(a.compare(b));
	}
	}
	BENCHMARK(BM_CompareSecondOneLess)->DenseRange(1, 3)->Range(4, 1 << 10);

	void BM_find_string_view_len_one(benchmark::State& state) {
	std::string haystack(state.range(0), '0');
	absl::string_view s(haystack);
	for (auto _ : state) {
	benchmark::DoNotOptimize(s.find("x")); // not present; length 1
	}
	}
	BENCHMARK(BM_find_string_view_len_one)->Range(1, 1 << 20);

	void BM_find_string_view_len_two(benchmark::State& state) {
	std::string haystack(state.range(0), '0');
	absl::string_view s(haystack);
	for (auto _ : state) {
	benchmark::DoNotOptimize(s.find("xx")); // not present; length 2
	}
	}
	BENCHMARK(BM_find_string_view_len_two)->Range(1, 1 << 20);

	void BM_find_one_char(benchmark::State& state) {
	std::string haystack(state.range(0), '0');
	absl::string_view s(haystack);
	for (auto _ : state) {
	benchmark::DoNotOptimize(s.find('x')); // not present
	}
	}
	BENCHMARK(BM_find_one_char)->Range(1, 1 << 20);

	void BM_rfind_one_char(benchmark::State& state) {
	std::string haystack(state.range(0), '0');
	absl::string_view s(haystack);
	for (auto _ : state) {
	benchmark::DoNotOptimize(s.rfind('x')); // not present
	}
	}
	BENCHMARK(BM_rfind_one_char)->Range(1, 1 << 20);

	void BM_worst_case_find_first_of(benchmark::State& state, int haystack_len) {
	const int needle_len = state.range(0);
	std::string needle;
	for (int i = 0; i < needle_len; ++i) {
	needle += 'a' + i;
	}
	std::string haystack(haystack_len, '0'); // 1000 zeros.

	absl::string_view s(haystack);
	for (auto _ : state) {
	benchmark::DoNotOptimize(s.find_first_of(needle));
	}
	}

	void BM_find_first_of_short(benchmark::State& state) {
	BM_worst_case_find_first_of(state, 10);
	}

	void BM_find_first_of_medium(benchmark::State& state) {
	BM_worst_case_find_first_of(state, 100);
	}

	void BM_find_first_of_long(benchmark::State& state) {
	BM_worst_case_find_first_of(state, 1000);
	}

	BENCHMARK(BM_find_first_of_short)->DenseRange(0, 4)->Arg(8)->Arg(16)->Arg(32);
	BENCHMARK(BM_find_first_of_medium)->DenseRange(0, 4)->Arg(8)->Arg(16)->Arg(32);
	BENCHMARK(BM_find_first_of_long)->DenseRange(0, 4)->Arg(8)->Arg(16)->Arg(32);

	struct EasyMap : public std::map<absl::string_view, uint64_t> {
	explicit EasyMap(size_t) {}
	};

	// This templated benchmark helper function is intended to stress operator== or
	// operator< in a realistic test. It surely isn't entirely realistic, but it's
	// a start. The test creates a map of type Map, a template arg, and populates
	// it with table_size key/value pairs. Each key has WordsPerKey words. After
	// creating the map, a number of lookups are done in random order. Some keys
	// are used much more frequently than others in this phase of the test.
	template <typename Map, int WordsPerKey>
	void StringViewMapBenchmark(benchmark::State& state) {
	const int table_size = state.range(0);
	const double kFractionOfKeysThatAreHot = 0.2;
	const int kNumLookupsOfHotKeys = 20;
	const int kNumLookupsOfColdKeys = 1;
	const char* words[] = {"the", "quick", "brown", "fox", "jumped",
	"over", "the", "lazy", "dog", "and",
	"found", "a", "large", "mushroom", "and",
	"a", "couple", "crickets", "eating", "pie"};
	// Create some keys that consist of words in random order.
	std::random_device r;
	std::seed_seq seed({r(), r(), r(), r(), r(), r(), r(), r()});
	std::mt19937 rng(seed);
	std::vector<std::string> keys(table_size);
	std::vector<int> all_indices;
	const int kBlockSize = 1 << 12;
	std::unordered_set<std::string> t(kBlockSize);
	std::uniform_int_distribution<int> uniform(0, ABSL_ARRAYSIZE(words) - 1);
	for (int i = 0; i < table_size; i++) {
	all_indices.push_back(i);
	do {
	keys[i].clear();
	for (int j = 0; j < WordsPerKey; j++) {
	absl::StrAppend(&keys[i], j > 0 ? " " : "", words[uniform(rng)]);
	}
	} while (!t.insert(keys[i]).second);
	}

	// Create a list of strings to lookup: a permutation of the array of
	// keys we just created, with repeats. "Hot" keys get repeated more.
	std::shuffle(all_indices.begin(), all_indices.end(), rng);
	const int num_hot = table_size * kFractionOfKeysThatAreHot;
	const int num_cold = table_size - num_hot;
	std::vector<int> hot_indices(all_indices.begin(),
	all_indices.begin() + num_hot);
	std::vector<int> indices;
	for (int i = 0; i < kNumLookupsOfColdKeys; i++) {
	indices.insert(indices.end(), all_indices.begin(), all_indices.end());
	}
	for (int i = 0; i < kNumLookupsOfHotKeys - kNumLookupsOfColdKeys; i++) {
	indices.insert(indices.end(), hot_indices.begin(), hot_indices.end());
	}
	std::shuffle(indices.begin(), indices.end(), rng);
	ABSL_RAW_CHECK(
	num_cold * kNumLookupsOfColdKeys + num_hot * kNumLookupsOfHotKeys ==
	indices.size(),
	"");
	// After constructing the array we probe it with absl::string_views built from
	// test_strings. This means operator== won't see equal pointers, so
	// it'll have to check for equal lengths and equal characters.
	std::vector<std::string> test_strings(indices.size());
	for (int i = 0; i < indices.size(); i++) {
	test_strings[i] = keys[indices[i]];
	}

	// Run the benchmark. It includes map construction but is mostly
	// map lookups.
	for (auto _ : state) {
	Map h(table_size);
	for (int i = 0; i < table_size; i++) {
	h[keys[i]] = i * 2;
	}
	ABSL_RAW_CHECK(h.size() == table_size, "");
	uint64_t sum = 0;
	for (int i = 0; i < indices.size(); i++) {
	sum += h[test_strings[i]];
	}
	benchmark::DoNotOptimize(sum);
	}
	}

	void BM_StdMap_4(benchmark::State& state) {
	StringViewMapBenchmark<EasyMap, 4>(state);
	}
	BENCHMARK(BM_StdMap_4)->Range(1 << 10, 1 << 16);

	void BM_StdMap_8(benchmark::State& state) {
	StringViewMapBenchmark<EasyMap, 8>(state);
	}
	BENCHMARK(BM_StdMap_8)->Range(1 << 10, 1 << 16);

	void BM_CopyToStringNative(benchmark::State& state) {
	std::string src(state.range(0), 'x');
	absl::string_view sv(src);
	std::string dst;
	for (auto _ : state) {
	dst.assign(sv.begin(), sv.end());
	}
	}
	BENCHMARK(BM_CopyToStringNative)->Range(1 << 3, 1 << 12);

	void BM_AppendToStringNative(benchmark::State& state) {
	std::string src(state.range(0), 'x');
	absl::string_view sv(src);
	std::string dst;
	for (auto _ : state) {
	dst.clear();
	dst.insert(dst.end(), sv.begin(), sv.end());
	}
	}
	BENCHMARK(BM_AppendToStringNative)->Range(1 << 3, 1 << 12);

	} // namespace