// 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/container/internal/hashtablez_sampler.h" #include #include #include #include #include #include #include #include "gmock/gmock.h" #include "gtest/gtest.h" #include "absl/base/attributes.h" #include "absl/base/config.h" #include "absl/profiling/internal/sample_recorder.h" #include "absl/synchronization/blocking_counter.h" #include "absl/synchronization/internal/thread_pool.h" #include "absl/synchronization/mutex.h" #include "absl/synchronization/notification.h" #include "absl/time/clock.h" #include "absl/time/time.h" #ifdef ABSL_INTERNAL_HAVE_SSE2 constexpr int kProbeLength = 16; #else constexpr int kProbeLength = 8; #endif namespace absl { ABSL_NAMESPACE_BEGIN namespace container_internal { #if defined(ABSL_INTERNAL_HASHTABLEZ_SAMPLE) class HashtablezInfoHandlePeer { public: static HashtablezInfo* GetInfo(HashtablezInfoHandle* h) { return h->info_; } }; #else class HashtablezInfoHandlePeer { public: static HashtablezInfo* GetInfo(HashtablezInfoHandle*) { return nullptr; } }; #endif // defined(ABSL_INTERNAL_HASHTABLEZ_SAMPLE) namespace { using ::absl::synchronization_internal::ThreadPool; using ::testing::IsEmpty; using ::testing::UnorderedElementsAre; std::vector GetSizes(HashtablezSampler* s) { std::vector res; s->Iterate([&](const HashtablezInfo& info) { res.push_back(info.size.load(std::memory_order_acquire)); }); return res; } HashtablezInfo* Register(HashtablezSampler* s, size_t size) { const int64_t test_stride = 123; const size_t test_element_size = 17; const size_t test_key_size = 3; const size_t test_value_size = 5; auto* info = s->Register(test_stride, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity=*/0); assert(info != nullptr); info->size.store(size); return info; } TEST(HashtablezInfoTest, PrepareForSampling) { absl::Time test_start = absl::Now(); const int64_t test_stride = 123; const size_t test_element_size = 17; const size_t test_key_size = 15; const size_t test_value_size = 13; HashtablezInfo info; absl::MutexLock l(&info.init_mu); info.PrepareForSampling(test_stride, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity_value=*/1); EXPECT_EQ(info.capacity.load(), 0); EXPECT_EQ(info.size.load(), 0); EXPECT_EQ(info.num_erases.load(), 0); EXPECT_EQ(info.num_rehashes.load(), 0); EXPECT_EQ(info.max_probe_length.load(), 0); EXPECT_EQ(info.total_probe_length.load(), 0); EXPECT_EQ(info.hashes_bitwise_or.load(), 0); EXPECT_EQ(info.hashes_bitwise_and.load(), ~size_t{}); EXPECT_EQ(info.hashes_bitwise_xor.load(), 0); EXPECT_EQ(info.max_reserve.load(), 0); EXPECT_GE(info.create_time, test_start); EXPECT_EQ(info.weight, test_stride); EXPECT_EQ(info.inline_element_size, test_element_size); EXPECT_EQ(info.key_size, test_key_size); EXPECT_EQ(info.value_size, test_value_size); EXPECT_EQ(info.soo_capacity, 1); info.capacity.store(1, std::memory_order_relaxed); info.size.store(1, std::memory_order_relaxed); info.num_erases.store(1, std::memory_order_relaxed); info.max_probe_length.store(1, std::memory_order_relaxed); info.total_probe_length.store(1, std::memory_order_relaxed); info.hashes_bitwise_or.store(1, std::memory_order_relaxed); info.hashes_bitwise_and.store(1, std::memory_order_relaxed); info.hashes_bitwise_xor.store(1, std::memory_order_relaxed); info.max_reserve.store(1, std::memory_order_relaxed); info.create_time = test_start - absl::Hours(20); info.PrepareForSampling(test_stride * 2, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity_value=*/0); EXPECT_EQ(info.capacity.load(), 0); EXPECT_EQ(info.size.load(), 0); EXPECT_EQ(info.num_erases.load(), 0); EXPECT_EQ(info.num_rehashes.load(), 0); EXPECT_EQ(info.max_probe_length.load(), 0); EXPECT_EQ(info.total_probe_length.load(), 0); EXPECT_EQ(info.hashes_bitwise_or.load(), 0); EXPECT_EQ(info.hashes_bitwise_and.load(), ~size_t{}); EXPECT_EQ(info.hashes_bitwise_xor.load(), 0); EXPECT_EQ(info.max_reserve.load(), 0); EXPECT_EQ(info.weight, 2 * test_stride); EXPECT_EQ(info.inline_element_size, test_element_size); EXPECT_EQ(info.key_size, test_key_size); EXPECT_EQ(info.value_size, test_value_size); EXPECT_GE(info.create_time, test_start); EXPECT_EQ(info.soo_capacity, 0); } TEST(HashtablezInfoTest, RecordStorageChanged) { HashtablezInfo info; absl::MutexLock l(&info.init_mu); const int64_t test_stride = 21; const size_t test_element_size = 19; const size_t test_key_size = 17; const size_t test_value_size = 15; info.PrepareForSampling(test_stride, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity_value=*/0); RecordStorageChangedSlow(&info, 17, 47); EXPECT_EQ(info.size.load(), 17); EXPECT_EQ(info.capacity.load(), 47); RecordStorageChangedSlow(&info, 20, 20); EXPECT_EQ(info.size.load(), 20); EXPECT_EQ(info.capacity.load(), 20); } TEST(HashtablezInfoTest, RecordInsert) { HashtablezInfo info; absl::MutexLock l(&info.init_mu); const int64_t test_stride = 25; const size_t test_element_size = 23; const size_t test_key_size = 21; const size_t test_value_size = 19; info.PrepareForSampling(test_stride, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity_value=*/0); EXPECT_EQ(info.max_probe_length.load(), 0); RecordInsertSlow(&info, 0x0000FF00, 6 * kProbeLength); EXPECT_EQ(info.max_probe_length.load(), 6); EXPECT_EQ(info.hashes_bitwise_and.load(), 0x0000FF00); EXPECT_EQ(info.hashes_bitwise_or.load(), 0x0000FF00); EXPECT_EQ(info.hashes_bitwise_xor.load(), 0x0000FF00); RecordInsertSlow(&info, 0x000FF000, 4 * kProbeLength); EXPECT_EQ(info.max_probe_length.load(), 6); EXPECT_EQ(info.hashes_bitwise_and.load(), 0x0000F000); EXPECT_EQ(info.hashes_bitwise_or.load(), 0x000FFF00); EXPECT_EQ(info.hashes_bitwise_xor.load(), 0x000F0F00); RecordInsertSlow(&info, 0x00FF0000, 12 * kProbeLength); EXPECT_EQ(info.max_probe_length.load(), 12); EXPECT_EQ(info.hashes_bitwise_and.load(), 0x00000000); EXPECT_EQ(info.hashes_bitwise_or.load(), 0x00FFFF00); EXPECT_EQ(info.hashes_bitwise_xor.load(), 0x00F00F00); } TEST(HashtablezInfoTest, RecordErase) { const int64_t test_stride = 31; const size_t test_element_size = 29; const size_t test_key_size = 27; const size_t test_value_size = 25; HashtablezInfo info; absl::MutexLock l(&info.init_mu); info.PrepareForSampling(test_stride, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity_value=*/1); EXPECT_EQ(info.num_erases.load(), 0); EXPECT_EQ(info.size.load(), 0); RecordInsertSlow(&info, 0x0000FF00, 6 * kProbeLength); EXPECT_EQ(info.size.load(), 1); RecordEraseSlow(&info); EXPECT_EQ(info.size.load(), 0); EXPECT_EQ(info.num_erases.load(), 1); EXPECT_EQ(info.inline_element_size, test_element_size); EXPECT_EQ(info.key_size, test_key_size); EXPECT_EQ(info.value_size, test_value_size); EXPECT_EQ(info.soo_capacity, 1); } TEST(HashtablezInfoTest, RecordRehash) { const int64_t test_stride = 33; const size_t test_element_size = 31; const size_t test_key_size = 29; const size_t test_value_size = 27; HashtablezInfo info; absl::MutexLock l(&info.init_mu); info.PrepareForSampling(test_stride, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity_value=*/0); RecordInsertSlow(&info, 0x1, 0); RecordInsertSlow(&info, 0x2, kProbeLength); RecordInsertSlow(&info, 0x4, kProbeLength); RecordInsertSlow(&info, 0x8, 2 * kProbeLength); EXPECT_EQ(info.size.load(), 4); EXPECT_EQ(info.total_probe_length.load(), 4); RecordEraseSlow(&info); RecordEraseSlow(&info); EXPECT_EQ(info.size.load(), 2); EXPECT_EQ(info.total_probe_length.load(), 4); EXPECT_EQ(info.num_erases.load(), 2); RecordRehashSlow(&info, 3 * kProbeLength); EXPECT_EQ(info.size.load(), 2); EXPECT_EQ(info.total_probe_length.load(), 3); EXPECT_EQ(info.num_erases.load(), 0); EXPECT_EQ(info.num_rehashes.load(), 1); EXPECT_EQ(info.inline_element_size, test_element_size); EXPECT_EQ(info.key_size, test_key_size); EXPECT_EQ(info.value_size, test_value_size); EXPECT_EQ(info.soo_capacity, 0); } TEST(HashtablezInfoTest, RecordReservation) { HashtablezInfo info; absl::MutexLock l(&info.init_mu); const int64_t test_stride = 35; const size_t test_element_size = 33; const size_t test_key_size = 31; const size_t test_value_size = 29; info.PrepareForSampling(test_stride, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity_value=*/0); RecordReservationSlow(&info, 3); EXPECT_EQ(info.max_reserve.load(), 3); RecordReservationSlow(&info, 2); // High watermark does not change EXPECT_EQ(info.max_reserve.load(), 3); RecordReservationSlow(&info, 10); // High watermark does change EXPECT_EQ(info.max_reserve.load(), 10); } #if defined(ABSL_INTERNAL_HASHTABLEZ_SAMPLE) TEST(HashtablezSamplerTest, SmallSampleParameter) { const size_t test_element_size = 31; const size_t test_key_size = 33; const size_t test_value_size = 35; SetHashtablezEnabled(true); SetHashtablezSampleParameter(100); for (int i = 0; i < 1000; ++i) { SamplingState next_sample = {0, 0}; HashtablezInfo* sample = SampleSlow(next_sample, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity=*/0); EXPECT_GT(next_sample.next_sample, 0); EXPECT_EQ(next_sample.next_sample, next_sample.sample_stride); EXPECT_NE(sample, nullptr); UnsampleSlow(sample); } } TEST(HashtablezSamplerTest, LargeSampleParameter) { const size_t test_element_size = 31; const size_t test_key_size = 33; const size_t test_value_size = 35; SetHashtablezEnabled(true); SetHashtablezSampleParameter(std::numeric_limits::max()); for (int i = 0; i < 1000; ++i) { SamplingState next_sample = {0, 0}; HashtablezInfo* sample = SampleSlow(next_sample, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity=*/0); EXPECT_GT(next_sample.next_sample, 0); EXPECT_EQ(next_sample.next_sample, next_sample.sample_stride); EXPECT_NE(sample, nullptr); UnsampleSlow(sample); } } TEST(HashtablezSamplerTest, Sample) { const size_t test_element_size = 31; const size_t test_key_size = 33; const size_t test_value_size = 35; SetHashtablezEnabled(true); SetHashtablezSampleParameter(100); int64_t num_sampled = 0; int64_t total = 0; double sample_rate = 0.0; for (int i = 0; i < 1000000; ++i) { HashtablezInfoHandle h = Sample(test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity=*/0); ++total; if (h.IsSampled()) { ++num_sampled; } sample_rate = static_cast(num_sampled) / total; if (0.005 < sample_rate && sample_rate < 0.015) break; } EXPECT_NEAR(sample_rate, 0.01, 0.005); } TEST(HashtablezSamplerTest, Handle) { auto& sampler = GlobalHashtablezSampler(); const int64_t test_stride = 41; const size_t test_element_size = 39; const size_t test_key_size = 37; const size_t test_value_size = 35; HashtablezInfoHandle h(sampler.Register(test_stride, test_element_size, /*key_size=*/test_key_size, /*value_size=*/test_value_size, /*soo_capacity=*/0)); auto* info = HashtablezInfoHandlePeer::GetInfo(&h); info->hashes_bitwise_and.store(0x12345678, std::memory_order_relaxed); bool found = false; sampler.Iterate([&](const HashtablezInfo& h) { if (&h == info) { EXPECT_EQ(h.weight, test_stride); EXPECT_EQ(h.hashes_bitwise_and.load(), 0x12345678); found = true; } }); EXPECT_TRUE(found); h.Unregister(); h = HashtablezInfoHandle(); found = false; sampler.Iterate([&](const HashtablezInfo& h) { if (&h == info) { // this will only happen if some other thread has resurrected the info // the old handle was using. if (h.hashes_bitwise_and.load() == 0x12345678) { found = true; } } }); EXPECT_FALSE(found); } #endif TEST(HashtablezSamplerTest, Registration) { HashtablezSampler sampler; auto* info1 = Register(&sampler, 1); EXPECT_THAT(GetSizes(&sampler), UnorderedElementsAre(1)); auto* info2 = Register(&sampler, 2); EXPECT_THAT(GetSizes(&sampler), UnorderedElementsAre(1, 2)); info1->size.store(3); EXPECT_THAT(GetSizes(&sampler), UnorderedElementsAre(3, 2)); sampler.Unregister(info1); sampler.Unregister(info2); } TEST(HashtablezSamplerTest, Unregistration) { HashtablezSampler sampler; std::vector infos; for (size_t i = 0; i < 3; ++i) { infos.push_back(Register(&sampler, i)); } EXPECT_THAT(GetSizes(&sampler), UnorderedElementsAre(0, 1, 2)); sampler.Unregister(infos[1]); EXPECT_THAT(GetSizes(&sampler), UnorderedElementsAre(0, 2)); infos.push_back(Register(&sampler, 3)); infos.push_back(Register(&sampler, 4)); EXPECT_THAT(GetSizes(&sampler), UnorderedElementsAre(0, 2, 3, 4)); sampler.Unregister(infos[3]); EXPECT_THAT(GetSizes(&sampler), UnorderedElementsAre(0, 2, 4)); sampler.Unregister(infos[0]); sampler.Unregister(infos[2]); sampler.Unregister(infos[4]); EXPECT_THAT(GetSizes(&sampler), IsEmpty()); } TEST(HashtablezSamplerTest, MultiThreaded) { HashtablezSampler sampler; Notification stop; ThreadPool pool(10); for (int i = 0; i < 10; ++i) { const int64_t sampling_stride = 11 + i % 3; const size_t elt_size = 10 + i % 2; const size_t key_size = 12 + i % 4; const size_t value_size = 13 + i % 5; pool.Schedule([&sampler, &stop, sampling_stride, elt_size, key_size, value_size]() { std::random_device rd; std::mt19937 gen(rd()); std::vector infoz; while (!stop.HasBeenNotified()) { if (infoz.empty()) { infoz.push_back(sampler.Register(sampling_stride, elt_size, /*key_size=*/key_size, /*value_size=*/value_size, /*soo_capacity=*/0)); } switch (std::uniform_int_distribution<>(0, 2)(gen)) { case 0: { infoz.push_back(sampler.Register(sampling_stride, elt_size, /*key_size=*/key_size, /*value_size=*/value_size, /*soo_capacity=*/0)); break; } case 1: { size_t p = std::uniform_int_distribution<>(0, infoz.size() - 1)(gen); HashtablezInfo* info = infoz[p]; infoz[p] = infoz.back(); infoz.pop_back(); EXPECT_EQ(info->weight, sampling_stride); sampler.Unregister(info); break; } case 2: { absl::Duration oldest = absl::ZeroDuration(); sampler.Iterate([&](const HashtablezInfo& info) { oldest = std::max(oldest, absl::Now() - info.create_time); }); ASSERT_GE(oldest, absl::ZeroDuration()); break; } } } }); } // The threads will hammer away. Give it a little bit of time for tsan to // spot errors. absl::SleepFor(absl::Seconds(3)); stop.Notify(); } TEST(HashtablezSamplerTest, Callback) { HashtablezSampler sampler; auto* info1 = Register(&sampler, 1); auto* info2 = Register(&sampler, 2); static const HashtablezInfo* expected; auto callback = [](const HashtablezInfo& info) { // We can't use `info` outside of this callback because the object will be // disposed as soon as we return from here. EXPECT_EQ(&info, expected); }; // Set the callback. EXPECT_EQ(sampler.SetDisposeCallback(callback), nullptr); expected = info1; sampler.Unregister(info1); // Unset the callback. EXPECT_EQ(callback, sampler.SetDisposeCallback(nullptr)); expected = nullptr; // no more calls. sampler.Unregister(info2); } } // namespace } // namespace container_internal ABSL_NAMESPACE_END } // namespace absl