Abseil Common Libraries (C++) (grcp 依赖)
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713 lines
26 KiB
713 lines
26 KiB
// Copyright 2018 The Abseil Authors. |
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// |
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// Licensed under the Apache License, Version 2.0 (the "License"); |
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// you may not use this file except in compliance with the License. |
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// You may obtain a copy of the License at |
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// |
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// https://www.apache.org/licenses/LICENSE-2.0 |
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// |
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// Unless required by applicable law or agreed to in writing, software |
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// distributed under the License is distributed on an "AS IS" BASIS, |
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
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// See the License for the specific language governing permissions and |
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// limitations under the License. |
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#include <stdint.h> |
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#include <algorithm> |
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#include <functional> |
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#include <map> |
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#include <numeric> |
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#include <random> |
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#include <set> |
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#include <string> |
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#include <type_traits> |
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#include <unordered_map> |
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#include <unordered_set> |
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#include <vector> |
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#include "absl/base/internal/raw_logging.h" |
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#include "absl/container/btree_map.h" |
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#include "absl/container/btree_set.h" |
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#include "absl/container/btree_test.h" |
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#include "absl/container/flat_hash_map.h" |
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#include "absl/container/flat_hash_set.h" |
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#include "absl/container/internal/hashtable_debug.h" |
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#include "absl/flags/flag.h" |
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#include "absl/hash/hash.h" |
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#include "absl/memory/memory.h" |
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#include "absl/strings/cord.h" |
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#include "absl/strings/str_format.h" |
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#include "absl/time/time.h" |
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#include "benchmark/benchmark.h" |
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namespace absl { |
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ABSL_NAMESPACE_BEGIN |
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namespace container_internal { |
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namespace { |
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constexpr size_t kBenchmarkValues = 1 << 20; |
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// How many times we add and remove sub-batches in one batch of *AddRem |
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// benchmarks. |
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constexpr size_t kAddRemBatchSize = 1 << 2; |
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// Generates n values in the range [0, 4 * n]. |
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template <typename V> |
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std::vector<V> GenerateValues(int n) { |
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constexpr int kSeed = 23; |
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return GenerateValuesWithSeed<V>(n, 4 * n, kSeed); |
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} |
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// Benchmark insertion of values into a container. |
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template <typename T> |
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void BM_InsertImpl(benchmark::State& state, bool sorted) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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typename KeyOfValue<typename T::key_type, V>::type key_of_value; |
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std::vector<V> values = GenerateValues<V>(kBenchmarkValues); |
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if (sorted) { |
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std::sort(values.begin(), values.end()); |
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} |
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T container(values.begin(), values.end()); |
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// Remove and re-insert 10% of the keys per batch. |
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const int batch_size = (kBenchmarkValues + 9) / 10; |
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while (state.KeepRunningBatch(batch_size)) { |
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state.PauseTiming(); |
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const auto i = static_cast<int>(state.iterations()); |
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for (int j = i; j < i + batch_size; j++) { |
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int x = j % kBenchmarkValues; |
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container.erase(key_of_value(values[x])); |
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} |
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state.ResumeTiming(); |
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for (int j = i; j < i + batch_size; j++) { |
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int x = j % kBenchmarkValues; |
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container.insert(values[x]); |
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} |
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} |
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} |
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template <typename T> |
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void BM_Insert(benchmark::State& state) { |
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BM_InsertImpl<T>(state, false); |
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} |
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template <typename T> |
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void BM_InsertSorted(benchmark::State& state) { |
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BM_InsertImpl<T>(state, true); |
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} |
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// container::insert sometimes returns a pair<iterator, bool> and sometimes |
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// returns an iterator (for multi- containers). |
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template <typename Iter> |
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Iter GetIterFromInsert(const std::pair<Iter, bool>& pair) { |
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return pair.first; |
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} |
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template <typename Iter> |
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Iter GetIterFromInsert(const Iter iter) { |
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return iter; |
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} |
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// Benchmark insertion of values into a container at the end. |
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template <typename T> |
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void BM_InsertEnd(benchmark::State& state) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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typename KeyOfValue<typename T::key_type, V>::type key_of_value; |
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T container; |
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const int kSize = 10000; |
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for (int i = 0; i < kSize; ++i) { |
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container.insert(Generator<V>(kSize)(i)); |
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} |
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V v = Generator<V>(kSize)(kSize - 1); |
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typename T::key_type k = key_of_value(v); |
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auto it = container.find(k); |
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while (state.KeepRunning()) { |
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// Repeatedly removing then adding v. |
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container.erase(it); |
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it = GetIterFromInsert(container.insert(v)); |
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} |
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} |
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template <typename T> |
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void BM_LookupImpl(benchmark::State& state, bool sorted) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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typename KeyOfValue<typename T::key_type, V>::type key_of_value; |
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std::vector<V> values = GenerateValues<V>(kBenchmarkValues); |
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if (sorted) { |
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std::sort(values.begin(), values.end()); |
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} |
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T container(values.begin(), values.end()); |
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while (state.KeepRunning()) { |
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int idx = state.iterations() % kBenchmarkValues; |
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benchmark::DoNotOptimize(container.find(key_of_value(values[idx]))); |
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} |
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} |
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// Benchmark lookup of values in a container. |
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template <typename T> |
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void BM_Lookup(benchmark::State& state) { |
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BM_LookupImpl<T>(state, false); |
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} |
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// Benchmark lookup of values in a full container, meaning that values |
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// are inserted in-order to take advantage of biased insertion, which |
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// yields a full tree. |
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template <typename T> |
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void BM_FullLookup(benchmark::State& state) { |
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BM_LookupImpl<T>(state, true); |
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} |
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// Benchmark deletion of values from a container. |
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template <typename T> |
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void BM_Delete(benchmark::State& state) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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typename KeyOfValue<typename T::key_type, V>::type key_of_value; |
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std::vector<V> values = GenerateValues<V>(kBenchmarkValues); |
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T container(values.begin(), values.end()); |
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// Remove and re-insert 10% of the keys per batch. |
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const int batch_size = (kBenchmarkValues + 9) / 10; |
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while (state.KeepRunningBatch(batch_size)) { |
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const int i = state.iterations(); |
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for (int j = i; j < i + batch_size; j++) { |
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int x = j % kBenchmarkValues; |
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container.erase(key_of_value(values[x])); |
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} |
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state.PauseTiming(); |
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for (int j = i; j < i + batch_size; j++) { |
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int x = j % kBenchmarkValues; |
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container.insert(values[x]); |
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} |
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state.ResumeTiming(); |
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} |
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} |
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// Benchmark deletion of multiple values from a container. |
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template <typename T> |
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void BM_DeleteRange(benchmark::State& state) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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typename KeyOfValue<typename T::key_type, V>::type key_of_value; |
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std::vector<V> values = GenerateValues<V>(kBenchmarkValues); |
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T container(values.begin(), values.end()); |
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// Remove and re-insert 10% of the keys per batch. |
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const int batch_size = (kBenchmarkValues + 9) / 10; |
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while (state.KeepRunningBatch(batch_size)) { |
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const int i = state.iterations(); |
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const int start_index = i % kBenchmarkValues; |
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state.PauseTiming(); |
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{ |
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std::vector<V> removed; |
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removed.reserve(batch_size); |
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auto itr = container.find(key_of_value(values[start_index])); |
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auto start = itr; |
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for (int j = 0; j < batch_size; j++) { |
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if (itr == container.end()) { |
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state.ResumeTiming(); |
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container.erase(start, itr); |
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state.PauseTiming(); |
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itr = container.begin(); |
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start = itr; |
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} |
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removed.push_back(*itr++); |
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} |
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state.ResumeTiming(); |
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container.erase(start, itr); |
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state.PauseTiming(); |
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container.insert(removed.begin(), removed.end()); |
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} |
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state.ResumeTiming(); |
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} |
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} |
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// Benchmark steady-state insert (into first half of range) and remove (from |
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// second half of range), treating the container approximately like a queue with |
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// log-time access for all elements. This benchmark does not test the case where |
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// insertion and removal happen in the same region of the tree. This benchmark |
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// counts two value constructors. |
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template <typename T> |
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void BM_QueueAddRem(benchmark::State& state) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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typename KeyOfValue<typename T::key_type, V>::type key_of_value; |
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ABSL_RAW_CHECK(kBenchmarkValues % 2 == 0, "for performance"); |
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T container; |
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const size_t half = kBenchmarkValues / 2; |
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std::vector<int> remove_keys(half); |
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std::vector<int> add_keys(half); |
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// We want to do the exact same work repeatedly, and the benchmark can end |
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// after a different number of iterations depending on the speed of the |
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// individual run so we use a large batch size here and ensure that we do |
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// deterministic work every batch. |
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while (state.KeepRunningBatch(half * kAddRemBatchSize)) { |
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state.PauseTiming(); |
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container.clear(); |
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for (size_t i = 0; i < half; ++i) { |
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remove_keys[i] = i; |
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add_keys[i] = i; |
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} |
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constexpr int kSeed = 5; |
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std::mt19937_64 rand(kSeed); |
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std::shuffle(remove_keys.begin(), remove_keys.end(), rand); |
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std::shuffle(add_keys.begin(), add_keys.end(), rand); |
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// Note needs lazy generation of values. |
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Generator<V> g(kBenchmarkValues * kAddRemBatchSize); |
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for (size_t i = 0; i < half; ++i) { |
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container.insert(g(add_keys[i])); |
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container.insert(g(half + remove_keys[i])); |
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} |
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// There are three parts each of size "half": |
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// 1 is being deleted from [offset - half, offset) |
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// 2 is standing [offset, offset + half) |
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// 3 is being inserted into [offset + half, offset + 2 * half) |
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size_t offset = 0; |
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for (size_t i = 0; i < kAddRemBatchSize; ++i) { |
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std::shuffle(remove_keys.begin(), remove_keys.end(), rand); |
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std::shuffle(add_keys.begin(), add_keys.end(), rand); |
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offset += half; |
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state.ResumeTiming(); |
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for (size_t idx = 0; idx < half; ++idx) { |
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container.erase(key_of_value(g(offset - half + remove_keys[idx]))); |
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container.insert(g(offset + half + add_keys[idx])); |
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} |
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state.PauseTiming(); |
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} |
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state.ResumeTiming(); |
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} |
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} |
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// Mixed insertion and deletion in the same range using pre-constructed values. |
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template <typename T> |
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void BM_MixedAddRem(benchmark::State& state) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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typename KeyOfValue<typename T::key_type, V>::type key_of_value; |
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ABSL_RAW_CHECK(kBenchmarkValues % 2 == 0, "for performance"); |
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T container; |
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// Create two random shuffles |
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std::vector<int> remove_keys(kBenchmarkValues); |
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std::vector<int> add_keys(kBenchmarkValues); |
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// We want to do the exact same work repeatedly, and the benchmark can end |
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// after a different number of iterations depending on the speed of the |
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// individual run so we use a large batch size here and ensure that we do |
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// deterministic work every batch. |
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while (state.KeepRunningBatch(kBenchmarkValues * kAddRemBatchSize)) { |
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state.PauseTiming(); |
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container.clear(); |
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constexpr int kSeed = 7; |
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std::mt19937_64 rand(kSeed); |
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std::vector<V> values = GenerateValues<V>(kBenchmarkValues * 2); |
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// Insert the first half of the values (already in random order) |
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container.insert(values.begin(), values.begin() + kBenchmarkValues); |
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// Insert the first half of the values (already in random order) |
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for (size_t i = 0; i < kBenchmarkValues; ++i) { |
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// remove_keys and add_keys will be swapped before each round, |
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// therefore fill add_keys here w/ the keys being inserted, so |
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// they'll be the first to be removed. |
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remove_keys[i] = i + kBenchmarkValues; |
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add_keys[i] = i; |
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} |
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for (size_t i = 0; i < kAddRemBatchSize; ++i) { |
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remove_keys.swap(add_keys); |
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std::shuffle(remove_keys.begin(), remove_keys.end(), rand); |
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std::shuffle(add_keys.begin(), add_keys.end(), rand); |
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state.ResumeTiming(); |
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for (size_t idx = 0; idx < kBenchmarkValues; ++idx) { |
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container.erase(key_of_value(values[remove_keys[idx]])); |
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container.insert(values[add_keys[idx]]); |
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} |
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state.PauseTiming(); |
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} |
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state.ResumeTiming(); |
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} |
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} |
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// Insertion at end, removal from the beginning. This benchmark |
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// counts two value constructors. |
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// TODO(ezb): we could add a GenerateNext version of generator that could reduce |
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// noise for string-like types. |
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template <typename T> |
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void BM_Fifo(benchmark::State& state) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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T container; |
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// Need lazy generation of values as state.max_iterations is large. |
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Generator<V> g(kBenchmarkValues + state.max_iterations); |
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for (int i = 0; i < kBenchmarkValues; i++) { |
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container.insert(g(i)); |
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} |
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while (state.KeepRunning()) { |
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container.erase(container.begin()); |
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container.insert(container.end(), g(state.iterations() + kBenchmarkValues)); |
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} |
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} |
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// Iteration (forward) through the tree |
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template <typename T> |
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void BM_FwdIter(benchmark::State& state) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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using R = typename T::value_type const*; |
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std::vector<V> values = GenerateValues<V>(kBenchmarkValues); |
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T container(values.begin(), values.end()); |
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auto iter = container.end(); |
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R r = nullptr; |
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while (state.KeepRunning()) { |
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if (iter == container.end()) iter = container.begin(); |
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r = &(*iter); |
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++iter; |
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} |
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benchmark::DoNotOptimize(r); |
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} |
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// Benchmark random range-construction of a container. |
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template <typename T> |
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void BM_RangeConstructionImpl(benchmark::State& state, bool sorted) { |
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using V = typename remove_pair_const<typename T::value_type>::type; |
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std::vector<V> values = GenerateValues<V>(kBenchmarkValues); |
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if (sorted) { |
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std::sort(values.begin(), values.end()); |
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} |
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{ |
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T container(values.begin(), values.end()); |
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} |
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while (state.KeepRunning()) { |
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T container(values.begin(), values.end()); |
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benchmark::DoNotOptimize(container); |
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} |
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} |
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template <typename T> |
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void BM_InsertRangeRandom(benchmark::State& state) { |
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BM_RangeConstructionImpl<T>(state, false); |
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} |
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template <typename T> |
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void BM_InsertRangeSorted(benchmark::State& state) { |
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BM_RangeConstructionImpl<T>(state, true); |
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} |
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#define STL_ORDERED_TYPES(value) \ |
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using stl_set_##value = std::set<value>; \ |
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using stl_map_##value = std::map<value, intptr_t>; \ |
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using stl_multiset_##value = std::multiset<value>; \ |
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using stl_multimap_##value = std::multimap<value, intptr_t> |
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using StdString = std::string; |
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STL_ORDERED_TYPES(int32_t); |
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STL_ORDERED_TYPES(int64_t); |
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STL_ORDERED_TYPES(StdString); |
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STL_ORDERED_TYPES(Cord); |
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STL_ORDERED_TYPES(Time); |
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#define STL_UNORDERED_TYPES(value) \ |
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using stl_unordered_set_##value = std::unordered_set<value>; \ |
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using stl_unordered_map_##value = std::unordered_map<value, intptr_t>; \ |
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using flat_hash_set_##value = flat_hash_set<value>; \ |
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using flat_hash_map_##value = flat_hash_map<value, intptr_t>; \ |
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using stl_unordered_multiset_##value = std::unordered_multiset<value>; \ |
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using stl_unordered_multimap_##value = \ |
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std::unordered_multimap<value, intptr_t> |
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#define STL_UNORDERED_TYPES_CUSTOM_HASH(value, hash) \ |
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using stl_unordered_set_##value = std::unordered_set<value, hash>; \ |
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using stl_unordered_map_##value = std::unordered_map<value, intptr_t, hash>; \ |
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using flat_hash_set_##value = flat_hash_set<value, hash>; \ |
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using flat_hash_map_##value = flat_hash_map<value, intptr_t, hash>; \ |
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using stl_unordered_multiset_##value = std::unordered_multiset<value, hash>; \ |
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using stl_unordered_multimap_##value = \ |
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std::unordered_multimap<value, intptr_t, hash> |
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STL_UNORDERED_TYPES_CUSTOM_HASH(Cord, absl::Hash<absl::Cord>); |
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STL_UNORDERED_TYPES(int32_t); |
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STL_UNORDERED_TYPES(int64_t); |
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STL_UNORDERED_TYPES(StdString); |
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STL_UNORDERED_TYPES_CUSTOM_HASH(Time, absl::Hash<absl::Time>); |
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#define BTREE_TYPES(value) \ |
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using btree_256_set_##value = \ |
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btree_set<value, std::less<value>, std::allocator<value>>; \ |
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using btree_256_map_##value = \ |
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btree_map<value, intptr_t, std::less<value>, \ |
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std::allocator<std::pair<const value, intptr_t>>>; \ |
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using btree_256_multiset_##value = \ |
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btree_multiset<value, std::less<value>, std::allocator<value>>; \ |
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using btree_256_multimap_##value = \ |
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btree_multimap<value, intptr_t, std::less<value>, \ |
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std::allocator<std::pair<const value, intptr_t>>> |
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BTREE_TYPES(int32_t); |
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BTREE_TYPES(int64_t); |
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BTREE_TYPES(StdString); |
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BTREE_TYPES(Cord); |
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BTREE_TYPES(Time); |
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#define MY_BENCHMARK4(type, func) \ |
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void BM_##type##_##func(benchmark::State& state) { BM_##func<type>(state); } \ |
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BENCHMARK(BM_##type##_##func) |
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#define MY_BENCHMARK3(type) \ |
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MY_BENCHMARK4(type, Insert); \ |
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MY_BENCHMARK4(type, InsertSorted); \ |
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MY_BENCHMARK4(type, InsertEnd); \ |
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MY_BENCHMARK4(type, Lookup); \ |
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MY_BENCHMARK4(type, FullLookup); \ |
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MY_BENCHMARK4(type, Delete); \ |
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MY_BENCHMARK4(type, DeleteRange); \ |
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MY_BENCHMARK4(type, QueueAddRem); \ |
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MY_BENCHMARK4(type, MixedAddRem); \ |
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MY_BENCHMARK4(type, Fifo); \ |
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MY_BENCHMARK4(type, FwdIter); \ |
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MY_BENCHMARK4(type, InsertRangeRandom); \ |
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MY_BENCHMARK4(type, InsertRangeSorted) |
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#define MY_BENCHMARK2_SUPPORTS_MULTI_ONLY(type) \ |
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MY_BENCHMARK3(stl_##type); \ |
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MY_BENCHMARK3(stl_unordered_##type); \ |
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MY_BENCHMARK3(btree_256_##type) |
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#define MY_BENCHMARK2(type) \ |
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MY_BENCHMARK2_SUPPORTS_MULTI_ONLY(type); \ |
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MY_BENCHMARK3(flat_hash_##type) |
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// Define MULTI_TESTING to see benchmarks for multi-containers also. |
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// |
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// You can use --copt=-DMULTI_TESTING. |
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#ifdef MULTI_TESTING |
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#define MY_BENCHMARK(type) \ |
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MY_BENCHMARK2(set_##type); \ |
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MY_BENCHMARK2(map_##type); \ |
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MY_BENCHMARK2_SUPPORTS_MULTI_ONLY(multiset_##type); \ |
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MY_BENCHMARK2_SUPPORTS_MULTI_ONLY(multimap_##type) |
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#else |
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#define MY_BENCHMARK(type) \ |
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MY_BENCHMARK2(set_##type); \ |
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MY_BENCHMARK2(map_##type) |
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#endif |
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MY_BENCHMARK(int32_t); |
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MY_BENCHMARK(int64_t); |
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MY_BENCHMARK(StdString); |
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MY_BENCHMARK(Cord); |
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MY_BENCHMARK(Time); |
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// Define a type whose size and cost of moving are independently customizable. |
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// When sizeof(value_type) increases, we expect btree to no longer have as much |
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// cache-locality advantage over STL. When cost of moving increases, we expect |
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// btree to actually do more work than STL because it has to move values around |
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// and STL doesn't have to. |
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template <int Size, int Copies> |
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struct BigType { |
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BigType() : BigType(0) {} |
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explicit BigType(int x) { std::iota(values.begin(), values.end(), x); } |
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void Copy(const BigType& other) { |
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for (int i = 0; i < Size && i < Copies; ++i) values[i] = other.values[i]; |
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// If Copies > Size, do extra copies. |
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for (int i = Size, idx = 0; i < Copies; ++i) { |
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int64_t tmp = other.values[idx]; |
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benchmark::DoNotOptimize(tmp); |
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idx = idx + 1 == Size ? 0 : idx + 1; |
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} |
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} |
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BigType(const BigType& other) { Copy(other); } |
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BigType& operator=(const BigType& other) { |
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Copy(other); |
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return *this; |
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} |
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// Compare only the first Copies elements if Copies is less than Size. |
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bool operator<(const BigType& other) const { |
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return std::lexicographical_compare( |
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values.begin(), values.begin() + std::min(Size, Copies), |
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other.values.begin(), other.values.begin() + std::min(Size, Copies)); |
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} |
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bool operator==(const BigType& other) const { |
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return std::equal(values.begin(), values.begin() + std::min(Size, Copies), |
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other.values.begin()); |
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} |
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// Support absl::Hash. |
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template <typename State> |
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friend State AbslHashValue(State h, const BigType& b) { |
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for (int i = 0; i < Size && i < Copies; ++i) |
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h = State::combine(std::move(h), b.values[i]); |
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return h; |
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} |
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std::array<int64_t, Size> values; |
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}; |
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#define BIG_TYPE_BENCHMARKS(SIZE, COPIES) \ |
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using stl_set_size##SIZE##copies##COPIES = std::set<BigType<SIZE, COPIES>>; \ |
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using stl_map_size##SIZE##copies##COPIES = \ |
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std::map<BigType<SIZE, COPIES>, intptr_t>; \ |
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using stl_multiset_size##SIZE##copies##COPIES = \ |
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std::multiset<BigType<SIZE, COPIES>>; \ |
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using stl_multimap_size##SIZE##copies##COPIES = \ |
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std::multimap<BigType<SIZE, COPIES>, intptr_t>; \ |
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using stl_unordered_set_size##SIZE##copies##COPIES = \ |
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std::unordered_set<BigType<SIZE, COPIES>, \ |
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absl::Hash<BigType<SIZE, COPIES>>>; \ |
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using stl_unordered_map_size##SIZE##copies##COPIES = \ |
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std::unordered_map<BigType<SIZE, COPIES>, intptr_t, \ |
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absl::Hash<BigType<SIZE, COPIES>>>; \ |
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using flat_hash_set_size##SIZE##copies##COPIES = \ |
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flat_hash_set<BigType<SIZE, COPIES>>; \ |
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using flat_hash_map_size##SIZE##copies##COPIES = \ |
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flat_hash_map<BigType<SIZE, COPIES>, intptr_t>; \ |
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using stl_unordered_multiset_size##SIZE##copies##COPIES = \ |
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std::unordered_multiset<BigType<SIZE, COPIES>, \ |
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absl::Hash<BigType<SIZE, COPIES>>>; \ |
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using stl_unordered_multimap_size##SIZE##copies##COPIES = \ |
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std::unordered_multimap<BigType<SIZE, COPIES>, intptr_t, \ |
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absl::Hash<BigType<SIZE, COPIES>>>; \ |
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using btree_256_set_size##SIZE##copies##COPIES = \ |
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btree_set<BigType<SIZE, COPIES>>; \ |
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using btree_256_map_size##SIZE##copies##COPIES = \ |
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btree_map<BigType<SIZE, COPIES>, intptr_t>; \ |
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using btree_256_multiset_size##SIZE##copies##COPIES = \ |
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btree_multiset<BigType<SIZE, COPIES>>; \ |
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using btree_256_multimap_size##SIZE##copies##COPIES = \ |
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btree_multimap<BigType<SIZE, COPIES>, intptr_t>; \ |
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MY_BENCHMARK(size##SIZE##copies##COPIES) |
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// Define BIG_TYPE_TESTING to see benchmarks for more big types. |
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// |
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// You can use --copt=-DBIG_TYPE_TESTING. |
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#ifndef NODESIZE_TESTING |
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#ifdef BIG_TYPE_TESTING |
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BIG_TYPE_BENCHMARKS(1, 4); |
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BIG_TYPE_BENCHMARKS(4, 1); |
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BIG_TYPE_BENCHMARKS(4, 4); |
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BIG_TYPE_BENCHMARKS(1, 8); |
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BIG_TYPE_BENCHMARKS(8, 1); |
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BIG_TYPE_BENCHMARKS(8, 8); |
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BIG_TYPE_BENCHMARKS(1, 16); |
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BIG_TYPE_BENCHMARKS(16, 1); |
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BIG_TYPE_BENCHMARKS(16, 16); |
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BIG_TYPE_BENCHMARKS(1, 32); |
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BIG_TYPE_BENCHMARKS(32, 1); |
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BIG_TYPE_BENCHMARKS(32, 32); |
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#else |
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BIG_TYPE_BENCHMARKS(32, 32); |
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#endif |
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#endif |
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// Benchmark using unique_ptrs to large value types. In order to be able to use |
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// the same benchmark code as the other types, use a type that holds a |
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// unique_ptr and has a copy constructor. |
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template <int Size> |
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struct BigTypePtr { |
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BigTypePtr() : BigTypePtr(0) {} |
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explicit BigTypePtr(int x) { |
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ptr = absl::make_unique<BigType<Size, Size>>(x); |
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} |
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BigTypePtr(const BigTypePtr& other) { |
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ptr = absl::make_unique<BigType<Size, Size>>(*other.ptr); |
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} |
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BigTypePtr(BigTypePtr&& other) noexcept = default; |
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BigTypePtr& operator=(const BigTypePtr& other) { |
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ptr = absl::make_unique<BigType<Size, Size>>(*other.ptr); |
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} |
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BigTypePtr& operator=(BigTypePtr&& other) noexcept = default; |
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bool operator<(const BigTypePtr& other) const { return *ptr < *other.ptr; } |
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bool operator==(const BigTypePtr& other) const { return *ptr == *other.ptr; } |
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std::unique_ptr<BigType<Size, Size>> ptr; |
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}; |
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template <int Size> |
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double ContainerInfo(const btree_set<BigTypePtr<Size>>& b) { |
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const double bytes_used = |
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b.bytes_used() + b.size() * sizeof(BigType<Size, Size>); |
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const double bytes_per_value = bytes_used / b.size(); |
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BtreeContainerInfoLog(b, bytes_used, bytes_per_value); |
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return bytes_per_value; |
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} |
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template <int Size> |
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double ContainerInfo(const btree_map<int, BigTypePtr<Size>>& b) { |
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const double bytes_used = |
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b.bytes_used() + b.size() * sizeof(BigType<Size, Size>); |
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const double bytes_per_value = bytes_used / b.size(); |
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BtreeContainerInfoLog(b, bytes_used, bytes_per_value); |
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return bytes_per_value; |
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} |
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#define BIG_TYPE_PTR_BENCHMARKS(SIZE) \ |
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using stl_set_size##SIZE##copies##SIZE##ptr = std::set<BigType<SIZE, SIZE>>; \ |
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using stl_map_size##SIZE##copies##SIZE##ptr = \ |
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std::map<int, BigType<SIZE, SIZE>>; \ |
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using stl_unordered_set_size##SIZE##copies##SIZE##ptr = \ |
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std::unordered_set<BigType<SIZE, SIZE>, \ |
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absl::Hash<BigType<SIZE, SIZE>>>; \ |
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using stl_unordered_map_size##SIZE##copies##SIZE##ptr = \ |
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std::unordered_map<int, BigType<SIZE, SIZE>>; \ |
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using flat_hash_set_size##SIZE##copies##SIZE##ptr = \ |
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flat_hash_set<BigType<SIZE, SIZE>>; \ |
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using flat_hash_map_size##SIZE##copies##SIZE##ptr = \ |
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flat_hash_map<int, BigTypePtr<SIZE>>; \ |
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using btree_256_set_size##SIZE##copies##SIZE##ptr = \ |
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btree_set<BigTypePtr<SIZE>>; \ |
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using btree_256_map_size##SIZE##copies##SIZE##ptr = \ |
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btree_map<int, BigTypePtr<SIZE>>; \ |
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MY_BENCHMARK3(stl_set_size##SIZE##copies##SIZE##ptr); \ |
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MY_BENCHMARK3(stl_unordered_set_size##SIZE##copies##SIZE##ptr); \ |
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MY_BENCHMARK3(flat_hash_set_size##SIZE##copies##SIZE##ptr); \ |
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MY_BENCHMARK3(btree_256_set_size##SIZE##copies##SIZE##ptr); \ |
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MY_BENCHMARK3(stl_map_size##SIZE##copies##SIZE##ptr); \ |
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MY_BENCHMARK3(stl_unordered_map_size##SIZE##copies##SIZE##ptr); \ |
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MY_BENCHMARK3(flat_hash_map_size##SIZE##copies##SIZE##ptr); \ |
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MY_BENCHMARK3(btree_256_map_size##SIZE##copies##SIZE##ptr) |
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BIG_TYPE_PTR_BENCHMARKS(32); |
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} // namespace |
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} // namespace container_internal |
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ABSL_NAMESPACE_END |
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} // namespace absl
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