// Copyright (c) 2011-present, Facebook, Inc. All rights reserved. // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root directory). #include "cache/compressed_secondary_cache.h" #include #include #include #include #include "cache/secondary_cache_adapter.h" #include "memory/jemalloc_nodump_allocator.h" #include "rocksdb/cache.h" #include "rocksdb/convenience.h" #include "test_util/secondary_cache_test_util.h" #include "test_util/testharness.h" #include "test_util/testutil.h" #include "util/cast_util.h" namespace ROCKSDB_NAMESPACE { using secondary_cache_test_util::GetTestingCacheTypes; using secondary_cache_test_util::WithCacheType; // 16 bytes for HCC compatibility const std::string key0 = "____ ____key0"; const std::string key1 = "____ ____key1"; const std::string key2 = "____ ____key2"; const std::string key3 = "____ ____key3"; class CompressedSecondaryCacheTestBase : public testing::Test, public WithCacheType { public: CompressedSecondaryCacheTestBase() {} ~CompressedSecondaryCacheTestBase() override = default; protected: void BasicTestHelper(std::shared_ptr sec_cache, bool sec_cache_is_compressed) { get_perf_context()->Reset(); bool kept_in_sec_cache{true}; // Lookup an non-existent key. std::unique_ptr handle0 = sec_cache->Lookup(key0, GetHelper(), this, true, /*advise_erase=*/true, kept_in_sec_cache); ASSERT_EQ(handle0, nullptr); Random rnd(301); // Insert and Lookup the item k1 for the first time. std::string str1(rnd.RandomString(1000)); TestItem item1(str1.data(), str1.length()); // A dummy handle is inserted if the item is inserted for the first time. ASSERT_OK(sec_cache->Insert(key1, &item1, GetHelper(), false)); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_dummy_count, 1); ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 0); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 0); std::unique_ptr handle1_1 = sec_cache->Lookup(key1, GetHelper(), this, true, /*advise_erase=*/false, kept_in_sec_cache); ASSERT_EQ(handle1_1, nullptr); // Insert and Lookup the item k1 for the second time and advise erasing it. ASSERT_OK(sec_cache->Insert(key1, &item1, GetHelper(), false)); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_real_count, 1); std::unique_ptr handle1_2 = sec_cache->Lookup(key1, GetHelper(), this, true, /*advise_erase=*/true, kept_in_sec_cache); ASSERT_NE(handle1_2, nullptr); ASSERT_FALSE(kept_in_sec_cache); if (sec_cache_is_compressed) { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 1000); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 1007); } else { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 0); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 0); } std::unique_ptr val1 = std::unique_ptr(static_cast(handle1_2->Value())); ASSERT_NE(val1, nullptr); ASSERT_EQ(memcmp(val1->Buf(), item1.Buf(), item1.Size()), 0); // Lookup the item k1 again. std::unique_ptr handle1_3 = sec_cache->Lookup(key1, GetHelper(), this, true, /*advise_erase=*/true, kept_in_sec_cache); ASSERT_EQ(handle1_3, nullptr); // Insert and Lookup the item k2. std::string str2(rnd.RandomString(1000)); TestItem item2(str2.data(), str2.length()); ASSERT_OK(sec_cache->Insert(key2, &item2, GetHelper(), false)); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_dummy_count, 2); std::unique_ptr handle2_1 = sec_cache->Lookup(key2, GetHelper(), this, true, /*advise_erase=*/false, kept_in_sec_cache); ASSERT_EQ(handle2_1, nullptr); ASSERT_OK(sec_cache->Insert(key2, &item2, GetHelper(), false)); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_real_count, 2); if (sec_cache_is_compressed) { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 2000); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 2014); } else { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 0); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 0); } std::unique_ptr handle2_2 = sec_cache->Lookup(key2, GetHelper(), this, true, /*advise_erase=*/false, kept_in_sec_cache); ASSERT_NE(handle2_2, nullptr); std::unique_ptr val2 = std::unique_ptr(static_cast(handle2_2->Value())); ASSERT_NE(val2, nullptr); ASSERT_EQ(memcmp(val2->Buf(), item2.Buf(), item2.Size()), 0); std::vector handles = {handle1_2.get(), handle2_2.get()}; sec_cache->WaitAll(handles); sec_cache.reset(); } void BasicTest(bool sec_cache_is_compressed, bool use_jemalloc) { CompressedSecondaryCacheOptions opts; opts.capacity = 2048; opts.num_shard_bits = 0; if (sec_cache_is_compressed) { if (!LZ4_Supported()) { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); opts.compression_type = CompressionType::kNoCompression; sec_cache_is_compressed = false; } } else { opts.compression_type = CompressionType::kNoCompression; } if (use_jemalloc) { JemallocAllocatorOptions jopts; std::shared_ptr allocator; std::string msg; if (JemallocNodumpAllocator::IsSupported(&msg)) { Status s = NewJemallocNodumpAllocator(jopts, &allocator); if (s.ok()) { opts.memory_allocator = allocator; } } else { ROCKSDB_GTEST_BYPASS("JEMALLOC not supported"); } } std::shared_ptr sec_cache = NewCompressedSecondaryCache(opts); BasicTestHelper(sec_cache, sec_cache_is_compressed); } void FailsTest(bool sec_cache_is_compressed) { CompressedSecondaryCacheOptions secondary_cache_opts; if (sec_cache_is_compressed) { if (!LZ4_Supported()) { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); secondary_cache_opts.compression_type = CompressionType::kNoCompression; } } else { secondary_cache_opts.compression_type = CompressionType::kNoCompression; } secondary_cache_opts.capacity = 1100; secondary_cache_opts.num_shard_bits = 0; std::shared_ptr sec_cache = NewCompressedSecondaryCache(secondary_cache_opts); // Insert and Lookup the first item. Random rnd(301); std::string str1(rnd.RandomString(1000)); TestItem item1(str1.data(), str1.length()); // Insert a dummy handle. ASSERT_OK(sec_cache->Insert(key1, &item1, GetHelper(), false)); // Insert k1. ASSERT_OK(sec_cache->Insert(key1, &item1, GetHelper(), false)); // Insert and Lookup the second item. std::string str2(rnd.RandomString(200)); TestItem item2(str2.data(), str2.length()); // Insert a dummy handle, k1 is not evicted. ASSERT_OK(sec_cache->Insert(key2, &item2, GetHelper(), false)); bool kept_in_sec_cache{false}; std::unique_ptr handle1 = sec_cache->Lookup(key1, GetHelper(), this, true, /*advise_erase=*/false, kept_in_sec_cache); ASSERT_EQ(handle1, nullptr); // Insert k2 and k1 is evicted. ASSERT_OK(sec_cache->Insert(key2, &item2, GetHelper(), false)); std::unique_ptr handle2 = sec_cache->Lookup(key2, GetHelper(), this, true, /*advise_erase=*/false, kept_in_sec_cache); ASSERT_NE(handle2, nullptr); std::unique_ptr val2 = std::unique_ptr(static_cast(handle2->Value())); ASSERT_NE(val2, nullptr); ASSERT_EQ(memcmp(val2->Buf(), item2.Buf(), item2.Size()), 0); // Insert k1 again and a dummy handle is inserted. ASSERT_OK(sec_cache->Insert(key1, &item1, GetHelper(), false)); std::unique_ptr handle1_1 = sec_cache->Lookup(key1, GetHelper(), this, true, /*advise_erase=*/false, kept_in_sec_cache); ASSERT_EQ(handle1_1, nullptr); // Create Fails. SetFailCreate(true); std::unique_ptr handle2_1 = sec_cache->Lookup(key2, GetHelper(), this, true, /*advise_erase=*/true, kept_in_sec_cache); ASSERT_EQ(handle2_1, nullptr); // Save Fails. std::string str3 = rnd.RandomString(10); TestItem item3(str3.data(), str3.length()); // The Status is OK because a dummy handle is inserted. ASSERT_OK(sec_cache->Insert(key3, &item3, GetHelperFail(), false)); ASSERT_NOK(sec_cache->Insert(key3, &item3, GetHelperFail(), false)); sec_cache.reset(); } void BasicIntegrationTest(bool sec_cache_is_compressed, bool enable_custom_split_merge) { CompressedSecondaryCacheOptions secondary_cache_opts; if (sec_cache_is_compressed) { if (!LZ4_Supported()) { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); secondary_cache_opts.compression_type = CompressionType::kNoCompression; sec_cache_is_compressed = false; } } else { secondary_cache_opts.compression_type = CompressionType::kNoCompression; } secondary_cache_opts.capacity = 6000; secondary_cache_opts.num_shard_bits = 0; secondary_cache_opts.enable_custom_split_merge = enable_custom_split_merge; std::shared_ptr secondary_cache = NewCompressedSecondaryCache(secondary_cache_opts); std::shared_ptr cache = NewCache( /*_capacity =*/1300, /*_num_shard_bits =*/0, /*_strict_capacity_limit =*/true, secondary_cache); std::shared_ptr stats = CreateDBStatistics(); get_perf_context()->Reset(); Random rnd(301); std::string str1 = rnd.RandomString(1001); auto item1_1 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(key1, item1_1, GetHelper(), str1.length())); std::string str2 = rnd.RandomString(1012); auto item2_1 = new TestItem(str2.data(), str2.length()); // After this Insert, primary cache contains k2 and secondary cache contains // k1's dummy item. ASSERT_OK(cache->Insert(key2, item2_1, GetHelper(), str2.length())); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_dummy_count, 1); ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 0); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 0); std::string str3 = rnd.RandomString(1024); auto item3_1 = new TestItem(str3.data(), str3.length()); // After this Insert, primary cache contains k3 and secondary cache contains // k1's dummy item and k2's dummy item. ASSERT_OK(cache->Insert(key3, item3_1, GetHelper(), str3.length())); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_dummy_count, 2); // After this Insert, primary cache contains k1 and secondary cache contains // k1's dummy item, k2's dummy item, and k3's dummy item. auto item1_2 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(key1, item1_2, GetHelper(), str1.length())); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_dummy_count, 3); // After this Insert, primary cache contains k2 and secondary cache contains // k1's item, k2's dummy item, and k3's dummy item. auto item2_2 = new TestItem(str2.data(), str2.length()); ASSERT_OK(cache->Insert(key2, item2_2, GetHelper(), str2.length())); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_real_count, 1); if (sec_cache_is_compressed) { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, str1.length()); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 1008); } else { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 0); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 0); } // After this Insert, primary cache contains k3 and secondary cache contains // k1's item and k2's item. auto item3_2 = new TestItem(str3.data(), str3.length()); ASSERT_OK(cache->Insert(key3, item3_2, GetHelper(), str3.length())); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_real_count, 2); if (sec_cache_is_compressed) { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, str1.length() + str2.length()); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 2027); } else { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 0); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 0); } Cache::Handle* handle; handle = cache->Lookup(key3, GetHelper(), this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); auto val3 = static_cast(cache->Value(handle)); ASSERT_NE(val3, nullptr); ASSERT_EQ(memcmp(val3->Buf(), item3_2->Buf(), item3_2->Size()), 0); cache->Release(handle); // Lookup an non-existent key. handle = cache->Lookup(key0, GetHelper(), this, Cache::Priority::LOW, stats.get()); ASSERT_EQ(handle, nullptr); // This Lookup should just insert a dummy handle in the primary cache // and the k1 is still in the secondary cache. handle = cache->Lookup(key1, GetHelper(), this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); ASSERT_EQ(get_perf_context()->block_cache_standalone_handle_count, 1); auto val1_1 = static_cast(cache->Value(handle)); ASSERT_NE(val1_1, nullptr); ASSERT_EQ(memcmp(val1_1->Buf(), str1.data(), str1.size()), 0); cache->Release(handle); // This Lookup should erase k1 from the secondary cache and insert // it into primary cache; then k3 is demoted. // k2 and k3 are in secondary cache. handle = cache->Lookup(key1, GetHelper(), this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); ASSERT_EQ(get_perf_context()->block_cache_standalone_handle_count, 1); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_real_count, 3); cache->Release(handle); // k2 is still in secondary cache. handle = cache->Lookup(key2, GetHelper(), this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); ASSERT_EQ(get_perf_context()->block_cache_standalone_handle_count, 2); cache->Release(handle); // Testing SetCapacity(). ASSERT_OK(secondary_cache->SetCapacity(0)); handle = cache->Lookup(key3, GetHelper(), this, Cache::Priority::LOW, stats.get()); ASSERT_EQ(handle, nullptr); ASSERT_OK(secondary_cache->SetCapacity(7000)); size_t capacity; ASSERT_OK(secondary_cache->GetCapacity(capacity)); ASSERT_EQ(capacity, 7000); auto item1_3 = new TestItem(str1.data(), str1.length()); // After this Insert, primary cache contains k1. ASSERT_OK(cache->Insert(key1, item1_3, GetHelper(), str2.length())); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_dummy_count, 3); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_real_count, 4); auto item2_3 = new TestItem(str2.data(), str2.length()); // After this Insert, primary cache contains k2 and secondary cache contains // k1's dummy item. ASSERT_OK(cache->Insert(key2, item2_3, GetHelper(), str1.length())); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_dummy_count, 4); auto item1_4 = new TestItem(str1.data(), str1.length()); // After this Insert, primary cache contains k1 and secondary cache contains // k1's dummy item and k2's dummy item. ASSERT_OK(cache->Insert(key1, item1_4, GetHelper(), str2.length())); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_dummy_count, 5); auto item2_4 = new TestItem(str2.data(), str2.length()); // After this Insert, primary cache contains k2 and secondary cache contains // k1's real item and k2's dummy item. ASSERT_OK(cache->Insert(key2, item2_4, GetHelper(), str2.length())); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_real_count, 5); // This Lookup should just insert a dummy handle in the primary cache // and the k1 is still in the secondary cache. handle = cache->Lookup(key1, GetHelper(), this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); cache->Release(handle); ASSERT_EQ(get_perf_context()->block_cache_standalone_handle_count, 3); cache.reset(); secondary_cache.reset(); } void BasicIntegrationFailTest(bool sec_cache_is_compressed) { CompressedSecondaryCacheOptions secondary_cache_opts; if (sec_cache_is_compressed) { if (!LZ4_Supported()) { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); secondary_cache_opts.compression_type = CompressionType::kNoCompression; } } else { secondary_cache_opts.compression_type = CompressionType::kNoCompression; } secondary_cache_opts.capacity = 6000; secondary_cache_opts.num_shard_bits = 0; std::shared_ptr secondary_cache = NewCompressedSecondaryCache(secondary_cache_opts); std::shared_ptr cache = NewCache( /*_capacity=*/1300, /*_num_shard_bits=*/0, /*_strict_capacity_limit=*/false, secondary_cache); Random rnd(301); std::string str1 = rnd.RandomString(1001); auto item1 = std::make_unique(str1.data(), str1.length()); ASSERT_OK(cache->Insert(key1, item1.get(), GetHelper(), str1.length())); item1.release(); // Appease clang-analyze "potential memory leak" Cache::Handle* handle; handle = cache->Lookup(key2, nullptr, this, Cache::Priority::LOW); ASSERT_EQ(handle, nullptr); handle = cache->Lookup(key2, GetHelper(), this, Cache::Priority::LOW); ASSERT_EQ(handle, nullptr); Cache::AsyncLookupHandle ah; ah.key = key2; ah.helper = GetHelper(); ah.create_context = this; ah.priority = Cache::Priority::LOW; cache->StartAsyncLookup(ah); cache->Wait(ah); ASSERT_EQ(ah.Result(), nullptr); cache.reset(); secondary_cache.reset(); } void IntegrationSaveFailTest(bool sec_cache_is_compressed) { CompressedSecondaryCacheOptions secondary_cache_opts; if (sec_cache_is_compressed) { if (!LZ4_Supported()) { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); secondary_cache_opts.compression_type = CompressionType::kNoCompression; } } else { secondary_cache_opts.compression_type = CompressionType::kNoCompression; } secondary_cache_opts.capacity = 6000; secondary_cache_opts.num_shard_bits = 0; std::shared_ptr secondary_cache = NewCompressedSecondaryCache(secondary_cache_opts); std::shared_ptr cache = NewCache( /*_capacity=*/1300, /*_num_shard_bits=*/0, /*_strict_capacity_limit=*/true, secondary_cache); Random rnd(301); std::string str1 = rnd.RandomString(1001); auto item1 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(key1, item1, GetHelperFail(), str1.length())); std::string str2 = rnd.RandomString(1002); auto item2 = new TestItem(str2.data(), str2.length()); // k1 should be demoted to the secondary cache. ASSERT_OK(cache->Insert(key2, item2, GetHelperFail(), str2.length())); Cache::Handle* handle; handle = cache->Lookup(key2, GetHelperFail(), this, Cache::Priority::LOW); ASSERT_NE(handle, nullptr); cache->Release(handle); // This lookup should fail, since k1 demotion would have failed. handle = cache->Lookup(key1, GetHelperFail(), this, Cache::Priority::LOW); ASSERT_EQ(handle, nullptr); // Since k1 was not promoted, k2 should still be in cache. handle = cache->Lookup(key2, GetHelperFail(), this, Cache::Priority::LOW); ASSERT_NE(handle, nullptr); cache->Release(handle); cache.reset(); secondary_cache.reset(); } void IntegrationCreateFailTest(bool sec_cache_is_compressed) { CompressedSecondaryCacheOptions secondary_cache_opts; if (sec_cache_is_compressed) { if (!LZ4_Supported()) { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); secondary_cache_opts.compression_type = CompressionType::kNoCompression; } } else { secondary_cache_opts.compression_type = CompressionType::kNoCompression; } secondary_cache_opts.capacity = 6000; secondary_cache_opts.num_shard_bits = 0; std::shared_ptr secondary_cache = NewCompressedSecondaryCache(secondary_cache_opts); std::shared_ptr cache = NewCache( /*_capacity=*/1300, /*_num_shard_bits=*/0, /*_strict_capacity_limit=*/true, secondary_cache); Random rnd(301); std::string str1 = rnd.RandomString(1001); auto item1 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(key1, item1, GetHelper(), str1.length())); std::string str2 = rnd.RandomString(1002); auto item2 = new TestItem(str2.data(), str2.length()); // k1 should be demoted to the secondary cache. ASSERT_OK(cache->Insert(key2, item2, GetHelper(), str2.length())); Cache::Handle* handle; SetFailCreate(true); handle = cache->Lookup(key2, GetHelper(), this, Cache::Priority::LOW); ASSERT_NE(handle, nullptr); cache->Release(handle); // This lookup should fail, since k1 creation would have failed handle = cache->Lookup(key1, GetHelper(), this, Cache::Priority::LOW); ASSERT_EQ(handle, nullptr); // Since k1 didn't get promoted, k2 should still be in cache handle = cache->Lookup(key2, GetHelper(), this, Cache::Priority::LOW); ASSERT_NE(handle, nullptr); cache->Release(handle); cache.reset(); secondary_cache.reset(); } void IntegrationFullCapacityTest(bool sec_cache_is_compressed) { CompressedSecondaryCacheOptions secondary_cache_opts; if (sec_cache_is_compressed) { if (!LZ4_Supported()) { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); secondary_cache_opts.compression_type = CompressionType::kNoCompression; } } else { secondary_cache_opts.compression_type = CompressionType::kNoCompression; } secondary_cache_opts.capacity = 6000; secondary_cache_opts.num_shard_bits = 0; std::shared_ptr secondary_cache = NewCompressedSecondaryCache(secondary_cache_opts); std::shared_ptr cache = NewCache( /*_capacity=*/1300, /*_num_shard_bits=*/0, /*_strict_capacity_limit=*/false, secondary_cache); Random rnd(301); std::string str1 = rnd.RandomString(1001); auto item1_1 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(key1, item1_1, GetHelper(), str1.length())); std::string str2 = rnd.RandomString(1002); std::string str2_clone{str2}; auto item2 = new TestItem(str2.data(), str2.length()); // After this Insert, primary cache contains k2 and secondary cache contains // k1's dummy item. ASSERT_OK(cache->Insert(key2, item2, GetHelper(), str2.length())); // After this Insert, primary cache contains k1 and secondary cache contains // k1's dummy item and k2's dummy item. auto item1_2 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(key1, item1_2, GetHelper(), str1.length())); auto item2_2 = new TestItem(str2.data(), str2.length()); // After this Insert, primary cache contains k2 and secondary cache contains // k1's item and k2's dummy item. ASSERT_OK(cache->Insert(key2, item2_2, GetHelper(), str2.length())); Cache::Handle* handle2; handle2 = cache->Lookup(key2, GetHelper(), this, Cache::Priority::LOW); ASSERT_NE(handle2, nullptr); cache->Release(handle2); // k1 promotion should fail because cache is at capacity and // strict_capacity_limit is true, but the lookup should still succeed. // A k1's dummy item is inserted into primary cache. Cache::Handle* handle1; handle1 = cache->Lookup(key1, GetHelper(), this, Cache::Priority::LOW); ASSERT_NE(handle1, nullptr); cache->Release(handle1); // Since k1 didn't get inserted, k2 should still be in cache handle2 = cache->Lookup(key2, GetHelper(), this, Cache::Priority::LOW); ASSERT_NE(handle2, nullptr); cache->Release(handle2); cache.reset(); secondary_cache.reset(); } void SplitValueIntoChunksTest() { JemallocAllocatorOptions jopts; std::shared_ptr allocator; std::string msg; if (JemallocNodumpAllocator::IsSupported(&msg)) { Status s = NewJemallocNodumpAllocator(jopts, &allocator); if (!s.ok()) { ROCKSDB_GTEST_BYPASS("JEMALLOC not supported"); } } else { ROCKSDB_GTEST_BYPASS("JEMALLOC not supported"); } using CacheValueChunk = CompressedSecondaryCache::CacheValueChunk; std::unique_ptr sec_cache = std::make_unique( CompressedSecondaryCacheOptions(1000, 0, true, 0.5, 0.0, allocator)); Random rnd(301); // 8500 = 8169 + 233 + 98, so there should be 3 chunks after split. size_t str_size{8500}; std::string str = rnd.RandomString(static_cast(str_size)); size_t charge{0}; CacheValueChunk* chunks_head = sec_cache->SplitValueIntoChunks(str, kLZ4Compression, charge); ASSERT_EQ(charge, str_size + 3 * (sizeof(CacheValueChunk) - 1)); CacheValueChunk* current_chunk = chunks_head; ASSERT_EQ(current_chunk->size, 8192 - sizeof(CacheValueChunk) + 1); current_chunk = current_chunk->next; ASSERT_EQ(current_chunk->size, 256 - sizeof(CacheValueChunk) + 1); current_chunk = current_chunk->next; ASSERT_EQ(current_chunk->size, 98); sec_cache->GetHelper(true)->del_cb(chunks_head, /*alloc*/ nullptr); } void MergeChunksIntoValueTest() { using CacheValueChunk = CompressedSecondaryCache::CacheValueChunk; Random rnd(301); size_t size1{2048}; std::string str1 = rnd.RandomString(static_cast(size1)); CacheValueChunk* current_chunk = reinterpret_cast( new char[sizeof(CacheValueChunk) - 1 + size1]); CacheValueChunk* chunks_head = current_chunk; memcpy(current_chunk->data, str1.data(), size1); current_chunk->size = size1; size_t size2{256}; std::string str2 = rnd.RandomString(static_cast(size2)); current_chunk->next = reinterpret_cast( new char[sizeof(CacheValueChunk) - 1 + size2]); current_chunk = current_chunk->next; memcpy(current_chunk->data, str2.data(), size2); current_chunk->size = size2; size_t size3{31}; std::string str3 = rnd.RandomString(static_cast(size3)); current_chunk->next = reinterpret_cast( new char[sizeof(CacheValueChunk) - 1 + size3]); current_chunk = current_chunk->next; memcpy(current_chunk->data, str3.data(), size3); current_chunk->size = size3; current_chunk->next = nullptr; std::string str = str1 + str2 + str3; std::unique_ptr sec_cache = std::make_unique( CompressedSecondaryCacheOptions(1000, 0, true, 0.5, 0.0)); size_t charge{0}; CacheAllocationPtr value = sec_cache->MergeChunksIntoValue(chunks_head, charge); ASSERT_EQ(charge, size1 + size2 + size3); std::string value_str{value.get(), charge}; ASSERT_EQ(strcmp(value_str.data(), str.data()), 0); while (chunks_head != nullptr) { CacheValueChunk* tmp_chunk = chunks_head; chunks_head = chunks_head->next; tmp_chunk->Free(); } } void SplictValueAndMergeChunksTest() { JemallocAllocatorOptions jopts; std::shared_ptr allocator; std::string msg; if (JemallocNodumpAllocator::IsSupported(&msg)) { Status s = NewJemallocNodumpAllocator(jopts, &allocator); if (!s.ok()) { ROCKSDB_GTEST_BYPASS("JEMALLOC not supported"); } } else { ROCKSDB_GTEST_BYPASS("JEMALLOC not supported"); } using CacheValueChunk = CompressedSecondaryCache::CacheValueChunk; std::unique_ptr sec_cache = std::make_unique( CompressedSecondaryCacheOptions(1000, 0, true, 0.5, 0.0, allocator)); Random rnd(301); // 8500 = 8169 + 233 + 98, so there should be 3 chunks after split. size_t str_size{8500}; std::string str = rnd.RandomString(static_cast(str_size)); size_t charge{0}; CacheValueChunk* chunks_head = sec_cache->SplitValueIntoChunks(str, kLZ4Compression, charge); ASSERT_EQ(charge, str_size + 3 * (sizeof(CacheValueChunk) - 1)); CacheAllocationPtr value = sec_cache->MergeChunksIntoValue(chunks_head, charge); ASSERT_EQ(charge, str_size); std::string value_str{value.get(), charge}; ASSERT_EQ(strcmp(value_str.data(), str.data()), 0); sec_cache->GetHelper(true)->del_cb(chunks_head, /*alloc*/ nullptr); } }; class CompressedSecondaryCacheTest : public CompressedSecondaryCacheTestBase, public testing::WithParamInterface { const std::string& Type() const override { return GetParam(); } }; INSTANTIATE_TEST_CASE_P(CompressedSecondaryCacheTest, CompressedSecondaryCacheTest, GetTestingCacheTypes()); class CompressedSecCacheTestWithCompressAndAllocatorParam : public CompressedSecondaryCacheTestBase, public ::testing::WithParamInterface< std::tuple> { public: CompressedSecCacheTestWithCompressAndAllocatorParam() { sec_cache_is_compressed_ = std::get<0>(GetParam()); use_jemalloc_ = std::get<1>(GetParam()); } const std::string& Type() const override { return std::get<2>(GetParam()); } bool sec_cache_is_compressed_; bool use_jemalloc_; }; TEST_P(CompressedSecCacheTestWithCompressAndAllocatorParam, BasicTes) { BasicTest(sec_cache_is_compressed_, use_jemalloc_); } INSTANTIATE_TEST_CASE_P(CompressedSecCacheTests, CompressedSecCacheTestWithCompressAndAllocatorParam, ::testing::Combine(testing::Bool(), testing::Bool(), GetTestingCacheTypes())); class CompressedSecondaryCacheTestWithCompressionParam : public CompressedSecondaryCacheTestBase, public ::testing::WithParamInterface> { public: CompressedSecondaryCacheTestWithCompressionParam() { sec_cache_is_compressed_ = std::get<0>(GetParam()); } const std::string& Type() const override { return std::get<1>(GetParam()); } bool sec_cache_is_compressed_; }; TEST_P(CompressedSecondaryCacheTestWithCompressionParam, BasicTestFromString) { std::shared_ptr sec_cache{nullptr}; std::string sec_cache_uri; if (sec_cache_is_compressed_) { if (LZ4_Supported()) { sec_cache_uri = "compressed_secondary_cache://" "capacity=2048;num_shard_bits=0;compression_type=kLZ4Compression;" "compress_format_version=2"; } else { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); sec_cache_uri = "compressed_secondary_cache://" "capacity=2048;num_shard_bits=0;compression_type=kNoCompression"; sec_cache_is_compressed_ = false; } Status s = SecondaryCache::CreateFromString(ConfigOptions(), sec_cache_uri, &sec_cache); EXPECT_OK(s); } else { sec_cache_uri = "compressed_secondary_cache://" "capacity=2048;num_shard_bits=0;compression_type=kNoCompression"; Status s = SecondaryCache::CreateFromString(ConfigOptions(), sec_cache_uri, &sec_cache); EXPECT_OK(s); } BasicTestHelper(sec_cache, sec_cache_is_compressed_); } TEST_P(CompressedSecondaryCacheTestWithCompressionParam, BasicTestFromStringWithSplit) { std::shared_ptr sec_cache{nullptr}; std::string sec_cache_uri; if (sec_cache_is_compressed_) { if (LZ4_Supported()) { sec_cache_uri = "compressed_secondary_cache://" "capacity=2048;num_shard_bits=0;compression_type=kLZ4Compression;" "compress_format_version=2;enable_custom_split_merge=true"; } else { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); sec_cache_uri = "compressed_secondary_cache://" "capacity=2048;num_shard_bits=0;compression_type=kNoCompression;" "enable_custom_split_merge=true"; sec_cache_is_compressed_ = false; } Status s = SecondaryCache::CreateFromString(ConfigOptions(), sec_cache_uri, &sec_cache); EXPECT_OK(s); } else { sec_cache_uri = "compressed_secondary_cache://" "capacity=2048;num_shard_bits=0;compression_type=kNoCompression;" "enable_custom_split_merge=true"; Status s = SecondaryCache::CreateFromString(ConfigOptions(), sec_cache_uri, &sec_cache); EXPECT_OK(s); } BasicTestHelper(sec_cache, sec_cache_is_compressed_); } TEST_P(CompressedSecondaryCacheTestWithCompressionParam, FailsTest) { FailsTest(sec_cache_is_compressed_); } TEST_P(CompressedSecondaryCacheTestWithCompressionParam, BasicIntegrationFailTest) { BasicIntegrationFailTest(sec_cache_is_compressed_); } TEST_P(CompressedSecondaryCacheTestWithCompressionParam, IntegrationSaveFailTest) { IntegrationSaveFailTest(sec_cache_is_compressed_); } TEST_P(CompressedSecondaryCacheTestWithCompressionParam, IntegrationCreateFailTest) { IntegrationCreateFailTest(sec_cache_is_compressed_); } TEST_P(CompressedSecondaryCacheTestWithCompressionParam, IntegrationFullCapacityTest) { IntegrationFullCapacityTest(sec_cache_is_compressed_); } TEST_P(CompressedSecondaryCacheTestWithCompressionParam, EntryRoles) { CompressedSecondaryCacheOptions opts; opts.capacity = 2048; opts.num_shard_bits = 0; if (sec_cache_is_compressed_) { if (!LZ4_Supported()) { ROCKSDB_GTEST_SKIP("This test requires LZ4 support."); return; } } else { opts.compression_type = CompressionType::kNoCompression; } // Select a random subset to include, for fast test Random& r = *Random::GetTLSInstance(); CacheEntryRoleSet do_not_compress; for (uint32_t i = 0; i < kNumCacheEntryRoles; ++i) { // A few included on average, but decent chance of zero if (r.OneIn(5)) { do_not_compress.Add(static_cast(i)); } } opts.do_not_compress_roles = do_not_compress; std::shared_ptr sec_cache = NewCompressedSecondaryCache(opts); // Fixed seed to ensure consistent compressibility (doesn't compress) std::string junk(Random(301).RandomString(1000)); for (uint32_t i = 0; i < kNumCacheEntryRoles; ++i) { CacheEntryRole role = static_cast(i); // Uniquify `junk` junk[0] = static_cast(i); TestItem item{junk.data(), junk.length()}; Slice ith_key = Slice(junk.data(), 16); get_perf_context()->Reset(); ASSERT_OK(sec_cache->Insert(ith_key, &item, GetHelper(role), false)); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_dummy_count, 1U); ASSERT_OK(sec_cache->Insert(ith_key, &item, GetHelper(role), false)); ASSERT_EQ(get_perf_context()->compressed_sec_cache_insert_real_count, 1U); bool kept_in_sec_cache{true}; std::unique_ptr handle = sec_cache->Lookup(ith_key, GetHelper(role), this, true, /*advise_erase=*/true, kept_in_sec_cache); ASSERT_NE(handle, nullptr); // Lookup returns the right data std::unique_ptr val = std::unique_ptr(static_cast(handle->Value())); ASSERT_NE(val, nullptr); ASSERT_EQ(memcmp(val->Buf(), item.Buf(), item.Size()), 0); bool compressed = sec_cache_is_compressed_ && !do_not_compress.Contains(role); if (compressed) { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 1000); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 1007); } else { ASSERT_EQ(get_perf_context()->compressed_sec_cache_uncompressed_bytes, 0); ASSERT_EQ(get_perf_context()->compressed_sec_cache_compressed_bytes, 0); } } } INSTANTIATE_TEST_CASE_P(CompressedSecCacheTests, CompressedSecondaryCacheTestWithCompressionParam, testing::Combine(testing::Bool(), GetTestingCacheTypes())); class CompressedSecCacheTestWithCompressAndSplitParam : public CompressedSecondaryCacheTestBase, public ::testing::WithParamInterface< std::tuple> { public: CompressedSecCacheTestWithCompressAndSplitParam() { sec_cache_is_compressed_ = std::get<0>(GetParam()); enable_custom_split_merge_ = std::get<1>(GetParam()); } const std::string& Type() const override { return std::get<2>(GetParam()); } bool sec_cache_is_compressed_; bool enable_custom_split_merge_; }; TEST_P(CompressedSecCacheTestWithCompressAndSplitParam, BasicIntegrationTest) { BasicIntegrationTest(sec_cache_is_compressed_, enable_custom_split_merge_); } INSTANTIATE_TEST_CASE_P(CompressedSecCacheTests, CompressedSecCacheTestWithCompressAndSplitParam, ::testing::Combine(testing::Bool(), testing::Bool(), GetTestingCacheTypes())); TEST_P(CompressedSecondaryCacheTest, SplitValueIntoChunksTest) { SplitValueIntoChunksTest(); } TEST_P(CompressedSecondaryCacheTest, MergeChunksIntoValueTest) { MergeChunksIntoValueTest(); } TEST_P(CompressedSecondaryCacheTest, SplictValueAndMergeChunksTest) { SplictValueAndMergeChunksTest(); } using secondary_cache_test_util::WithCacheType; class CompressedSecCacheTestWithTiered : public testing::Test, public WithCacheType, public testing::WithParamInterface< std::tuple> { public: using secondary_cache_test_util::WithCacheType::TestItem; CompressedSecCacheTestWithTiered() { LRUCacheOptions lru_opts; HyperClockCacheOptions hcc_opts( /*_capacity=*/0, /*_estimated_entry_charge=*/256 << 10, /*_num_shard_bits=*/0); TieredCacheOptions opts; lru_opts.capacity = 0; lru_opts.num_shard_bits = 0; lru_opts.high_pri_pool_ratio = 0; opts.cache_type = std::get<0>(GetParam()); if (opts.cache_type == PrimaryCacheType::kCacheTypeLRU) { opts.cache_opts = &lru_opts; } else { opts.cache_opts = &hcc_opts; } opts.adm_policy = std::get<1>(GetParam()); ; opts.comp_cache_opts.capacity = 0; opts.comp_cache_opts.num_shard_bits = 0; opts.total_capacity = 100 << 20; opts.compressed_secondary_ratio = 0.3; cache_ = NewTieredCache(opts); cache_res_mgr_ = std::make_shared>( cache_); } const std::string& Type() const override { if (std::get<0>(GetParam()) == PrimaryCacheType::kCacheTypeLRU) { return lru_str; } else { return hcc_str; } } protected: CacheReservationManager* cache_res_mgr() { return cache_res_mgr_.get(); } std::shared_ptr GetTieredCache() { return cache_; } Cache* GetCache() { return static_cast_with_check( cache_.get()) ->TEST_GetCache(); } SecondaryCache* GetSecondaryCache() { return static_cast_with_check( cache_.get()) ->TEST_GetSecondaryCache(); } size_t GetPercent(size_t val, unsigned int percent) { return static_cast(val * percent / 100); } private: std::shared_ptr cache_; std::shared_ptr cache_res_mgr_; static std::string lru_str; static std::string hcc_str; }; std::string CompressedSecCacheTestWithTiered::lru_str(WithCacheType::kLRU); std::string CompressedSecCacheTestWithTiered::hcc_str( WithCacheType::kFixedHyperClock); bool CacheUsageWithinBounds(size_t val1, size_t val2, size_t error) { return ((val1 < (val2 + error)) && (val1 > (val2 - error))); } TEST_P(CompressedSecCacheTestWithTiered, CacheReservationManager) { CompressedSecondaryCache* sec_cache = reinterpret_cast(GetSecondaryCache()); // Use EXPECT_PRED3 instead of EXPECT_NEAR to void too many size_t to // double explicit casts EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (30 << 20), GetPercent(30 << 20, 1)); EXPECT_EQ(sec_cache->TEST_GetUsage(), 0); ASSERT_OK(cache_res_mgr()->UpdateCacheReservation(10 << 20)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (37 << 20), GetPercent(37 << 20, 1)); EXPECT_PRED3(CacheUsageWithinBounds, sec_cache->TEST_GetUsage(), (3 << 20), GetPercent(3 << 20, 1)); ASSERT_OK(cache_res_mgr()->UpdateCacheReservation(0)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (30 << 20), GetPercent(30 << 20, 1)); EXPECT_EQ(sec_cache->TEST_GetUsage(), 0); } TEST_P(CompressedSecCacheTestWithTiered, CacheReservationManagerMultipleUpdate) { CompressedSecondaryCache* sec_cache = reinterpret_cast(GetSecondaryCache()); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (30 << 20), GetPercent(30 << 20, 1)); EXPECT_EQ(sec_cache->TEST_GetUsage(), 0); int i; for (i = 0; i < 10; ++i) { ASSERT_OK(cache_res_mgr()->UpdateCacheReservation((1 + i) << 20)); } EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (37 << 20), GetPercent(37 << 20, 1)); EXPECT_PRED3(CacheUsageWithinBounds, sec_cache->TEST_GetUsage(), (3 << 20), GetPercent(3 << 20, 1)); for (i = 10; i > 0; --i) { ASSERT_OK(cache_res_mgr()->UpdateCacheReservation(((i - 1) << 20))); } EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (30 << 20), GetPercent(30 << 20, 1)); EXPECT_EQ(sec_cache->TEST_GetUsage(), 0); } TEST_P(CompressedSecCacheTestWithTiered, AdmissionPolicy) { if (!LZ4_Supported()) { ROCKSDB_GTEST_BYPASS("This test requires LZ4 support\n"); return; } Cache* tiered_cache = GetTieredCache().get(); Cache* cache = GetCache(); std::vector keys; std::vector vals; // Make the item size slightly less than 10MB to ensure we can fit the // expected number of items in the cache int item_size = (10 << 20) - (1 << 18); int i; Random rnd(301); for (i = 0; i < 14; ++i) { keys.emplace_back(CacheKey::CreateUniqueForCacheLifetime(cache)); vals.emplace_back(rnd.RandomString(item_size)); } for (i = 0; i < 7; ++i) { TestItem* item = new TestItem(vals[i].data(), vals[i].length()); ASSERT_OK(tiered_cache->Insert(keys[i].AsSlice(), item, GetHelper(), vals[i].length())); } Cache::Handle* handle1; handle1 = tiered_cache->Lookup(keys[0].AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle1, nullptr); Cache::Handle* handle2; handle2 = tiered_cache->Lookup(keys[1].AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle2, nullptr); tiered_cache->Release(handle1); tiered_cache->Release(handle2); // Flush all previous entries out of the primary cache for (i = 7; i < 14; ++i) { TestItem* item = new TestItem(vals[i].data(), vals[i].length()); ASSERT_OK(tiered_cache->Insert(keys[i].AsSlice(), item, GetHelper(), vals[i].length())); } // keys 0 and 1 should be found as they had the hit bit set handle1 = tiered_cache->Lookup(keys[0].AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle1, nullptr); handle2 = tiered_cache->Lookup(keys[1].AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle2, nullptr); tiered_cache->Release(handle1); tiered_cache->Release(handle2); handle1 = tiered_cache->Lookup(keys[2].AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_EQ(handle1, nullptr); handle1 = tiered_cache->Lookup(keys[3].AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_EQ(handle1, nullptr); } TEST_P(CompressedSecCacheTestWithTiered, DynamicUpdate) { CompressedSecondaryCache* sec_cache = reinterpret_cast(GetSecondaryCache()); std::shared_ptr tiered_cache = GetTieredCache(); // Use EXPECT_PRED3 instead of EXPECT_NEAR to void too many size_t to // double explicit casts EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (30 << 20), GetPercent(30 << 20, 1)); size_t sec_capacity; ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (30 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, 130 << 20)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (39 << 20), GetPercent(39 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (39 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, 70 << 20)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (21 << 20), GetPercent(21 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (21 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, 100 << 20)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (30 << 20), GetPercent(30 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (30 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, -1, 0.4)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (40 << 20), GetPercent(40 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (40 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, -1, 0.2)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (20 << 20), GetPercent(20 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (20 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, -1, 1.0)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (100 << 20), GetPercent(100 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, 100 << 20); ASSERT_OK(UpdateTieredCache(tiered_cache, -1, 0.0)); // Only check usage for LRU cache. HCC shows a 64KB usage for some reason if (std::get<0>(GetParam()) == PrimaryCacheType::kCacheTypeLRU) { ASSERT_EQ(GetCache()->GetUsage(), 0); } ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, 0); ASSERT_NOK(UpdateTieredCache(tiered_cache, -1, 0.3)); // Only check usage for LRU cache. HCC shows a 64KB usage for some reason if (std::get<0>(GetParam()) == PrimaryCacheType::kCacheTypeLRU) { ASSERT_EQ(GetCache()->GetUsage(), 0); } ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, 0); } TEST_P(CompressedSecCacheTestWithTiered, DynamicUpdateWithReservation) { CompressedSecondaryCache* sec_cache = reinterpret_cast(GetSecondaryCache()); std::shared_ptr tiered_cache = GetTieredCache(); ASSERT_OK(cache_res_mgr()->UpdateCacheReservation(10 << 20)); // Use EXPECT_PRED3 instead of EXPECT_NEAR to void too many size_t to // double explicit casts EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (37 << 20), GetPercent(37 << 20, 1)); EXPECT_PRED3(CacheUsageWithinBounds, sec_cache->TEST_GetUsage(), (3 << 20), GetPercent(3 << 20, 1)); size_t sec_capacity; ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (30 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, 70 << 20)); // Only check usage for LRU cache. HCC is slightly off for some reason if (std::get<0>(GetParam()) == PrimaryCacheType::kCacheTypeLRU) { EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (28 << 20), GetPercent(28 << 20, 1)); } EXPECT_PRED3(CacheUsageWithinBounds, sec_cache->TEST_GetUsage(), (3 << 20), GetPercent(3 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (21 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, 130 << 20)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (46 << 20), GetPercent(46 << 20, 1)); EXPECT_PRED3(CacheUsageWithinBounds, sec_cache->TEST_GetUsage(), (3 << 20), GetPercent(3 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (39 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, 100 << 20)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (37 << 20), GetPercent(37 << 20, 1)); EXPECT_PRED3(CacheUsageWithinBounds, sec_cache->TEST_GetUsage(), (3 << 20), GetPercent(3 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (30 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, -1, 0.39)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (45 << 20), GetPercent(45 << 20, 1)); EXPECT_PRED3(CacheUsageWithinBounds, sec_cache->TEST_GetUsage(), (4 << 20), GetPercent(4 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (39 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, -1, 0.2)); // Only check usage for LRU cache. HCC is slightly off for some reason if (std::get<0>(GetParam()) == PrimaryCacheType::kCacheTypeLRU) { EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (28 << 20), GetPercent(28 << 20, 1)); } EXPECT_PRED3(CacheUsageWithinBounds, sec_cache->TEST_GetUsage(), (2 << 20), GetPercent(2 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, (20 << 20)); ASSERT_OK(UpdateTieredCache(tiered_cache, -1, 1.0)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (100 << 20), GetPercent(100 << 20, 1)); EXPECT_PRED3(CacheUsageWithinBounds, sec_cache->TEST_GetUsage(), (10 << 20), GetPercent(10 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, 100 << 20); ASSERT_OK(UpdateTieredCache(tiered_cache, -1, 0.0)); EXPECT_PRED3(CacheUsageWithinBounds, GetCache()->GetUsage(), (10 << 20), GetPercent(10 << 20, 1)); ASSERT_OK(sec_cache->GetCapacity(sec_capacity)); ASSERT_EQ(sec_capacity, 0); ASSERT_OK(cache_res_mgr()->UpdateCacheReservation(0)); } INSTANTIATE_TEST_CASE_P( CompressedSecCacheTests, CompressedSecCacheTestWithTiered, ::testing::Values( std::make_tuple(PrimaryCacheType::kCacheTypeLRU, TieredAdmissionPolicy::kAdmPolicyAllowCacheHits), std::make_tuple(PrimaryCacheType::kCacheTypeHCC, TieredAdmissionPolicy::kAdmPolicyAllowCacheHits))); } // namespace ROCKSDB_NAMESPACE int main(int argc, char** argv) { ROCKSDB_NAMESPACE::port::InstallStackTraceHandler(); ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }