// 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/lru_cache.h" #include #include #include #include "cache/cache_key.h" #include "cache/clock_cache.h" #include "cache_helpers.h" #include "db/db_test_util.h" #include "file/sst_file_manager_impl.h" #include "port/port.h" #include "port/stack_trace.h" #include "rocksdb/cache.h" #include "rocksdb/io_status.h" #include "rocksdb/sst_file_manager.h" #include "rocksdb/utilities/cache_dump_load.h" #include "test_util/secondary_cache_test_util.h" #include "test_util/testharness.h" #include "typed_cache.h" #include "util/coding.h" #include "util/random.h" #include "utilities/cache_dump_load_impl.h" #include "utilities/fault_injection_fs.h" namespace ROCKSDB_NAMESPACE { class LRUCacheTest : public testing::Test { public: LRUCacheTest() {} ~LRUCacheTest() override { DeleteCache(); } void DeleteCache() { if (cache_ != nullptr) { cache_->~LRUCacheShard(); port::cacheline_aligned_free(cache_); cache_ = nullptr; } } void NewCache(size_t capacity, double high_pri_pool_ratio = 0.0, double low_pri_pool_ratio = 1.0, bool use_adaptive_mutex = kDefaultToAdaptiveMutex) { DeleteCache(); cache_ = static_cast( port::cacheline_aligned_alloc(sizeof(LRUCacheShard))); new (cache_) LRUCacheShard(capacity, /*strict_capacity_limit=*/false, high_pri_pool_ratio, low_pri_pool_ratio, use_adaptive_mutex, kDontChargeCacheMetadata, /*max_upper_hash_bits=*/24, /*allocator*/ nullptr, &eviction_callback_); } void Insert(const std::string& key, Cache::Priority priority = Cache::Priority::LOW) { EXPECT_OK(cache_->Insert(key, 0 /*hash*/, nullptr /*value*/, &kNoopCacheItemHelper, 1 /*charge*/, nullptr /*handle*/, priority)); } void Insert(char key, Cache::Priority priority = Cache::Priority::LOW) { Insert(std::string(1, key), priority); } bool Lookup(const std::string& key) { auto handle = cache_->Lookup(key, 0 /*hash*/, nullptr, nullptr, Cache::Priority::LOW, nullptr); if (handle) { cache_->Release(handle, true /*useful*/, false /*erase*/); return true; } return false; } bool Lookup(char key) { return Lookup(std::string(1, key)); } void Erase(const std::string& key) { cache_->Erase(key, 0 /*hash*/); } void ValidateLRUList(std::vector keys, size_t num_high_pri_pool_keys = 0, size_t num_low_pri_pool_keys = 0, size_t num_bottom_pri_pool_keys = 0) { LRUHandle* lru; LRUHandle* lru_low_pri; LRUHandle* lru_bottom_pri; cache_->TEST_GetLRUList(&lru, &lru_low_pri, &lru_bottom_pri); LRUHandle* iter = lru; bool in_low_pri_pool = false; bool in_high_pri_pool = false; size_t high_pri_pool_keys = 0; size_t low_pri_pool_keys = 0; size_t bottom_pri_pool_keys = 0; if (iter == lru_bottom_pri) { in_low_pri_pool = true; in_high_pri_pool = false; } if (iter == lru_low_pri) { in_low_pri_pool = false; in_high_pri_pool = true; } for (const auto& key : keys) { iter = iter->next; ASSERT_NE(lru, iter); ASSERT_EQ(key, iter->key().ToString()); ASSERT_EQ(in_high_pri_pool, iter->InHighPriPool()); ASSERT_EQ(in_low_pri_pool, iter->InLowPriPool()); if (in_high_pri_pool) { ASSERT_FALSE(iter->InLowPriPool()); high_pri_pool_keys++; } else if (in_low_pri_pool) { ASSERT_FALSE(iter->InHighPriPool()); low_pri_pool_keys++; } else { bottom_pri_pool_keys++; } if (iter == lru_bottom_pri) { ASSERT_FALSE(in_low_pri_pool); ASSERT_FALSE(in_high_pri_pool); in_low_pri_pool = true; in_high_pri_pool = false; } if (iter == lru_low_pri) { ASSERT_TRUE(in_low_pri_pool); ASSERT_FALSE(in_high_pri_pool); in_low_pri_pool = false; in_high_pri_pool = true; } } ASSERT_EQ(lru, iter->next); ASSERT_FALSE(in_low_pri_pool); ASSERT_TRUE(in_high_pri_pool); ASSERT_EQ(num_high_pri_pool_keys, high_pri_pool_keys); ASSERT_EQ(num_low_pri_pool_keys, low_pri_pool_keys); ASSERT_EQ(num_bottom_pri_pool_keys, bottom_pri_pool_keys); } private: LRUCacheShard* cache_ = nullptr; Cache::EvictionCallback eviction_callback_; }; TEST_F(LRUCacheTest, BasicLRU) { NewCache(5); for (char ch = 'a'; ch <= 'e'; ch++) { Insert(ch); } ValidateLRUList({"a", "b", "c", "d", "e"}, 0, 5); for (char ch = 'x'; ch <= 'z'; ch++) { Insert(ch); } ValidateLRUList({"d", "e", "x", "y", "z"}, 0, 5); ASSERT_FALSE(Lookup("b")); ValidateLRUList({"d", "e", "x", "y", "z"}, 0, 5); ASSERT_TRUE(Lookup("e")); ValidateLRUList({"d", "x", "y", "z", "e"}, 0, 5); ASSERT_TRUE(Lookup("z")); ValidateLRUList({"d", "x", "y", "e", "z"}, 0, 5); Erase("x"); ValidateLRUList({"d", "y", "e", "z"}, 0, 4); ASSERT_TRUE(Lookup("d")); ValidateLRUList({"y", "e", "z", "d"}, 0, 4); Insert("u"); ValidateLRUList({"y", "e", "z", "d", "u"}, 0, 5); Insert("v"); ValidateLRUList({"e", "z", "d", "u", "v"}, 0, 5); } TEST_F(LRUCacheTest, LowPriorityMidpointInsertion) { // Allocate 2 cache entries to high-pri pool and 3 to low-pri pool. NewCache(5, /* high_pri_pool_ratio */ 0.40, /* low_pri_pool_ratio */ 0.60); Insert("a", Cache::Priority::LOW); Insert("b", Cache::Priority::LOW); Insert("c", Cache::Priority::LOW); Insert("x", Cache::Priority::HIGH); Insert("y", Cache::Priority::HIGH); ValidateLRUList({"a", "b", "c", "x", "y"}, 2, 3); // Low-pri entries inserted to the tail of low-pri list (the midpoint). // After lookup, it will move to the tail of the full list. Insert("d", Cache::Priority::LOW); ValidateLRUList({"b", "c", "d", "x", "y"}, 2, 3); ASSERT_TRUE(Lookup("d")); ValidateLRUList({"b", "c", "x", "y", "d"}, 2, 3); // High-pri entries will be inserted to the tail of full list. Insert("z", Cache::Priority::HIGH); ValidateLRUList({"c", "x", "y", "d", "z"}, 2, 3); } TEST_F(LRUCacheTest, BottomPriorityMidpointInsertion) { // Allocate 2 cache entries to high-pri pool and 2 to low-pri pool. NewCache(6, /* high_pri_pool_ratio */ 0.35, /* low_pri_pool_ratio */ 0.35); Insert("a", Cache::Priority::BOTTOM); Insert("b", Cache::Priority::BOTTOM); Insert("i", Cache::Priority::LOW); Insert("j", Cache::Priority::LOW); Insert("x", Cache::Priority::HIGH); Insert("y", Cache::Priority::HIGH); ValidateLRUList({"a", "b", "i", "j", "x", "y"}, 2, 2, 2); // Low-pri entries will be inserted to the tail of low-pri list (the // midpoint). After lookup, 'k' will move to the tail of the full list, and // 'x' will spill over to the low-pri pool. Insert("k", Cache::Priority::LOW); ValidateLRUList({"b", "i", "j", "k", "x", "y"}, 2, 2, 2); ASSERT_TRUE(Lookup("k")); ValidateLRUList({"b", "i", "j", "x", "y", "k"}, 2, 2, 2); // High-pri entries will be inserted to the tail of full list. Although y was // inserted with high priority, it got spilled over to the low-pri pool. As // a result, j also got spilled over to the bottom-pri pool. Insert("z", Cache::Priority::HIGH); ValidateLRUList({"i", "j", "x", "y", "k", "z"}, 2, 2, 2); Erase("x"); ValidateLRUList({"i", "j", "y", "k", "z"}, 2, 1, 2); Erase("y"); ValidateLRUList({"i", "j", "k", "z"}, 2, 0, 2); // Bottom-pri entries will be inserted to the tail of bottom-pri list. Insert("c", Cache::Priority::BOTTOM); ValidateLRUList({"i", "j", "c", "k", "z"}, 2, 0, 3); Insert("d", Cache::Priority::BOTTOM); ValidateLRUList({"i", "j", "c", "d", "k", "z"}, 2, 0, 4); Insert("e", Cache::Priority::BOTTOM); ValidateLRUList({"j", "c", "d", "e", "k", "z"}, 2, 0, 4); // Low-pri entries will be inserted to the tail of low-pri list (the // midpoint). Insert("l", Cache::Priority::LOW); ValidateLRUList({"c", "d", "e", "l", "k", "z"}, 2, 1, 3); Insert("m", Cache::Priority::LOW); ValidateLRUList({"d", "e", "l", "m", "k", "z"}, 2, 2, 2); Erase("k"); ValidateLRUList({"d", "e", "l", "m", "z"}, 1, 2, 2); Erase("z"); ValidateLRUList({"d", "e", "l", "m"}, 0, 2, 2); // Bottom-pri entries will be inserted to the tail of bottom-pri list. Insert("f", Cache::Priority::BOTTOM); ValidateLRUList({"d", "e", "f", "l", "m"}, 0, 2, 3); Insert("g", Cache::Priority::BOTTOM); ValidateLRUList({"d", "e", "f", "g", "l", "m"}, 0, 2, 4); // High-pri entries will be inserted to the tail of full list. Insert("o", Cache::Priority::HIGH); ValidateLRUList({"e", "f", "g", "l", "m", "o"}, 1, 2, 3); Insert("p", Cache::Priority::HIGH); ValidateLRUList({"f", "g", "l", "m", "o", "p"}, 2, 2, 2); } TEST_F(LRUCacheTest, EntriesWithPriority) { // Allocate 2 cache entries to high-pri pool and 2 to low-pri pool. NewCache(6, /* high_pri_pool_ratio */ 0.35, /* low_pri_pool_ratio */ 0.35); Insert("a", Cache::Priority::LOW); Insert("b", Cache::Priority::LOW); ValidateLRUList({"a", "b"}, 0, 2, 0); // Low-pri entries can overflow to bottom-pri pool. Insert("c", Cache::Priority::LOW); ValidateLRUList({"a", "b", "c"}, 0, 2, 1); // Bottom-pri entries can take high-pri pool capacity if available Insert("t", Cache::Priority::LOW); Insert("u", Cache::Priority::LOW); ValidateLRUList({"a", "b", "c", "t", "u"}, 0, 2, 3); Insert("v", Cache::Priority::LOW); ValidateLRUList({"a", "b", "c", "t", "u", "v"}, 0, 2, 4); Insert("w", Cache::Priority::LOW); ValidateLRUList({"b", "c", "t", "u", "v", "w"}, 0, 2, 4); Insert("X", Cache::Priority::HIGH); Insert("Y", Cache::Priority::HIGH); ValidateLRUList({"t", "u", "v", "w", "X", "Y"}, 2, 2, 2); // After lookup, the high-pri entry 'X' got spilled over to the low-pri pool. // The low-pri entry 'v' got spilled over to the bottom-pri pool. Insert("Z", Cache::Priority::HIGH); ValidateLRUList({"u", "v", "w", "X", "Y", "Z"}, 2, 2, 2); // Low-pri entries will be inserted to head of low-pri pool. Insert("a", Cache::Priority::LOW); ValidateLRUList({"v", "w", "X", "a", "Y", "Z"}, 2, 2, 2); // After lookup, the high-pri entry 'Y' got spilled over to the low-pri pool. // The low-pri entry 'X' got spilled over to the bottom-pri pool. ASSERT_TRUE(Lookup("v")); ValidateLRUList({"w", "X", "a", "Y", "Z", "v"}, 2, 2, 2); // After lookup, the high-pri entry 'Z' got spilled over to the low-pri pool. // The low-pri entry 'a' got spilled over to the bottom-pri pool. ASSERT_TRUE(Lookup("X")); ValidateLRUList({"w", "a", "Y", "Z", "v", "X"}, 2, 2, 2); // After lookup, the low pri entry 'Z' got promoted back to high-pri pool. The // high-pri entry 'v' got spilled over to the low-pri pool. ASSERT_TRUE(Lookup("Z")); ValidateLRUList({"w", "a", "Y", "v", "X", "Z"}, 2, 2, 2); Erase("Y"); ValidateLRUList({"w", "a", "v", "X", "Z"}, 2, 1, 2); Erase("X"); ValidateLRUList({"w", "a", "v", "Z"}, 1, 1, 2); Insert("d", Cache::Priority::LOW); Insert("e", Cache::Priority::LOW); ValidateLRUList({"w", "a", "v", "d", "e", "Z"}, 1, 2, 3); Insert("f", Cache::Priority::LOW); Insert("g", Cache::Priority::LOW); ValidateLRUList({"v", "d", "e", "f", "g", "Z"}, 1, 2, 3); ASSERT_TRUE(Lookup("d")); ValidateLRUList({"v", "e", "f", "g", "Z", "d"}, 2, 2, 2); // Erase some entries. Erase("e"); Erase("f"); Erase("Z"); ValidateLRUList({"v", "g", "d"}, 1, 1, 1); // Bottom-pri entries can take low- and high-pri pool capacity if available Insert("o", Cache::Priority::BOTTOM); ValidateLRUList({"v", "o", "g", "d"}, 1, 1, 2); Insert("p", Cache::Priority::BOTTOM); ValidateLRUList({"v", "o", "p", "g", "d"}, 1, 1, 3); Insert("q", Cache::Priority::BOTTOM); ValidateLRUList({"v", "o", "p", "q", "g", "d"}, 1, 1, 4); // High-pri entries can overflow to low-pri pool, and bottom-pri entries will // be evicted. Insert("x", Cache::Priority::HIGH); ValidateLRUList({"o", "p", "q", "g", "d", "x"}, 2, 1, 3); Insert("y", Cache::Priority::HIGH); ValidateLRUList({"p", "q", "g", "d", "x", "y"}, 2, 2, 2); Insert("z", Cache::Priority::HIGH); ValidateLRUList({"q", "g", "d", "x", "y", "z"}, 2, 2, 2); // 'g' is bottom-pri before this lookup, it will be inserted to head of // high-pri pool after lookup. ASSERT_TRUE(Lookup("g")); ValidateLRUList({"q", "d", "x", "y", "z", "g"}, 2, 2, 2); // High-pri entries will be inserted to head of high-pri pool after lookup. ASSERT_TRUE(Lookup("z")); ValidateLRUList({"q", "d", "x", "y", "g", "z"}, 2, 2, 2); // Bottom-pri entries will be inserted to head of high-pri pool after lookup. ASSERT_TRUE(Lookup("d")); ValidateLRUList({"q", "x", "y", "g", "z", "d"}, 2, 2, 2); // Bottom-pri entries will be inserted to the tail of bottom-pri list. Insert("m", Cache::Priority::BOTTOM); ValidateLRUList({"x", "m", "y", "g", "z", "d"}, 2, 2, 2); // Bottom-pri entries will be inserted to head of high-pri pool after lookup. ASSERT_TRUE(Lookup("m")); ValidateLRUList({"x", "y", "g", "z", "d", "m"}, 2, 2, 2); } namespace clock_cache { template class ClockCacheTest : public testing::Test { public: using Shard = typename ClockCache::Shard; using Table = typename Shard::Table; using TableOpts = typename Table::Opts; ClockCacheTest() {} ~ClockCacheTest() override { DeleteShard(); } void DeleteShard() { if (shard_ != nullptr) { shard_->~ClockCacheShard(); port::cacheline_aligned_free(shard_); shard_ = nullptr; } } void NewShard(size_t capacity, bool strict_capacity_limit = true, int eviction_effort_cap = 30) { DeleteShard(); shard_ = static_cast(port::cacheline_aligned_alloc(sizeof(Shard))); TableOpts opts{1 /*value_size*/, eviction_effort_cap}; new (shard_) Shard(capacity, strict_capacity_limit, kDontChargeCacheMetadata, /*allocator*/ nullptr, &eviction_callback_, &hash_seed_, opts); } Status Insert(const UniqueId64x2& hashed_key, Cache::Priority priority = Cache::Priority::LOW) { return shard_->Insert(TestKey(hashed_key), hashed_key, nullptr /*value*/, &kNoopCacheItemHelper, 1 /*charge*/, nullptr /*handle*/, priority); } Status Insert(char key, Cache::Priority priority = Cache::Priority::LOW) { return Insert(TestHashedKey(key), priority); } Status InsertWithLen(char key, size_t len) { std::string skey(len, key); return shard_->Insert(skey, TestHashedKey(key), nullptr /*value*/, &kNoopCacheItemHelper, 1 /*charge*/, nullptr /*handle*/, Cache::Priority::LOW); } bool Lookup(const Slice& key, const UniqueId64x2& hashed_key, bool useful = true) { auto handle = shard_->Lookup(key, hashed_key); if (handle) { shard_->Release(handle, useful, /*erase_if_last_ref=*/false); return true; } return false; } bool Lookup(const UniqueId64x2& hashed_key, bool useful = true) { return Lookup(TestKey(hashed_key), hashed_key, useful); } bool Lookup(char key, bool useful = true) { return Lookup(TestHashedKey(key), useful); } void Erase(char key) { UniqueId64x2 hashed_key = TestHashedKey(key); shard_->Erase(TestKey(hashed_key), hashed_key); } static inline Slice TestKey(const UniqueId64x2& hashed_key) { return Slice(reinterpret_cast(&hashed_key), 16U); } // A bad hash function for testing / stressing collision handling static inline UniqueId64x2 TestHashedKey(char key) { // For testing hash near-collision behavior, put the variance in // hashed_key in bits that are unlikely to be used as hash bits. return {(static_cast(key) << 56) + 1234U, 5678U}; } // A reasonable hash function, for testing "typical behavior" etc. template static inline UniqueId64x2 CheapHash(T i) { return {static_cast(i) * uint64_t{0x85EBCA77C2B2AE63}, static_cast(i) * uint64_t{0xC2B2AE3D27D4EB4F}}; } Shard* shard_ = nullptr; private: Cache::EvictionCallback eviction_callback_; uint32_t hash_seed_ = 0; }; using ClockCacheTypes = ::testing::Types; TYPED_TEST_CASE(ClockCacheTest, ClockCacheTypes); TYPED_TEST(ClockCacheTest, Misc) { this->NewShard(3); // NOTE: templated base class prevents simple naming of inherited members, // so lots of `this->` auto& shard = *this->shard_; // Key size stuff EXPECT_OK(this->InsertWithLen('a', 16)); EXPECT_NOK(this->InsertWithLen('b', 15)); EXPECT_OK(this->InsertWithLen('b', 16)); EXPECT_NOK(this->InsertWithLen('c', 17)); EXPECT_NOK(this->InsertWithLen('d', 1000)); EXPECT_NOK(this->InsertWithLen('e', 11)); EXPECT_NOK(this->InsertWithLen('f', 0)); // Some of this is motivated by code coverage std::string wrong_size_key(15, 'x'); EXPECT_FALSE(this->Lookup(wrong_size_key, this->TestHashedKey('x'))); EXPECT_FALSE(shard.Ref(nullptr)); EXPECT_FALSE(shard.Release(nullptr)); shard.Erase(wrong_size_key, this->TestHashedKey('x')); // no-op } TYPED_TEST(ClockCacheTest, Limits) { constexpr size_t kCapacity = 64; this->NewShard(kCapacity, false /*strict_capacity_limit*/); auto& shard = *this->shard_; using HandleImpl = typename ClockCacheTest::Shard::HandleImpl; for (bool strict_capacity_limit : {false, true, false}) { SCOPED_TRACE("strict_capacity_limit = " + std::to_string(strict_capacity_limit)); // Also tests switching between strict limit and not shard.SetStrictCapacityLimit(strict_capacity_limit); UniqueId64x2 hkey = this->TestHashedKey('x'); // Single entry charge beyond capacity { Status s = shard.Insert(this->TestKey(hkey), hkey, nullptr /*value*/, &kNoopCacheItemHelper, kCapacity + 2 /*charge*/, nullptr /*handle*/, Cache::Priority::LOW); if (strict_capacity_limit) { EXPECT_TRUE(s.IsMemoryLimit()); } else { EXPECT_OK(s); } } // Single entry fills capacity { HandleImpl* h; ASSERT_OK(shard.Insert(this->TestKey(hkey), hkey, nullptr /*value*/, &kNoopCacheItemHelper, kCapacity /*charge*/, &h, Cache::Priority::LOW)); // Try to insert more Status s = this->Insert('a'); if (strict_capacity_limit) { EXPECT_TRUE(s.IsMemoryLimit()); } else { EXPECT_OK(s); } // Release entry filling capacity. // Cover useful = false case. shard.Release(h, false /*useful*/, false /*erase_if_last_ref*/); } // Insert more than table size can handle to exceed occupancy limit. // (Cleverly using mostly zero-charge entries, but some non-zero to // verify usage tracking on detached entries.) { size_t n = kCapacity * 5 + 1; std::unique_ptr ha { new HandleImpl* [n] {} }; Status s; for (size_t i = 0; i < n && s.ok(); ++i) { hkey[1] = i; s = shard.Insert(this->TestKey(hkey), hkey, nullptr /*value*/, &kNoopCacheItemHelper, (i + kCapacity < n) ? 0 : 1 /*charge*/, &ha[i], Cache::Priority::LOW); if (i == 0) { EXPECT_OK(s); } } if (strict_capacity_limit) { EXPECT_TRUE(s.IsMemoryLimit()); } else { EXPECT_OK(s); } // Same result if not keeping a reference s = this->Insert('a'); if (strict_capacity_limit) { EXPECT_TRUE(s.IsMemoryLimit()); } else { EXPECT_OK(s); } EXPECT_EQ(shard.GetOccupancyCount(), shard.GetOccupancyLimit()); // Regardless, we didn't allow table to actually get full EXPECT_LT(shard.GetOccupancyCount(), shard.GetTableAddressCount()); // Release handles for (size_t i = 0; i < n; ++i) { if (ha[i]) { shard.Release(ha[i]); } } } } } TYPED_TEST(ClockCacheTest, ClockEvictionTest) { for (bool strict_capacity_limit : {false, true}) { SCOPED_TRACE("strict_capacity_limit = " + std::to_string(strict_capacity_limit)); this->NewShard(6, strict_capacity_limit); auto& shard = *this->shard_; EXPECT_OK(this->Insert('a', Cache::Priority::BOTTOM)); EXPECT_OK(this->Insert('b', Cache::Priority::LOW)); EXPECT_OK(this->Insert('c', Cache::Priority::HIGH)); EXPECT_OK(this->Insert('d', Cache::Priority::BOTTOM)); EXPECT_OK(this->Insert('e', Cache::Priority::LOW)); EXPECT_OK(this->Insert('f', Cache::Priority::HIGH)); EXPECT_TRUE(this->Lookup('a', /*use*/ false)); EXPECT_TRUE(this->Lookup('b', /*use*/ false)); EXPECT_TRUE(this->Lookup('c', /*use*/ false)); EXPECT_TRUE(this->Lookup('d', /*use*/ false)); EXPECT_TRUE(this->Lookup('e', /*use*/ false)); EXPECT_TRUE(this->Lookup('f', /*use*/ false)); // Ensure bottom are evicted first, even if new entries are low EXPECT_OK(this->Insert('g', Cache::Priority::LOW)); EXPECT_OK(this->Insert('h', Cache::Priority::LOW)); EXPECT_FALSE(this->Lookup('a', /*use*/ false)); EXPECT_TRUE(this->Lookup('b', /*use*/ false)); EXPECT_TRUE(this->Lookup('c', /*use*/ false)); EXPECT_FALSE(this->Lookup('d', /*use*/ false)); EXPECT_TRUE(this->Lookup('e', /*use*/ false)); EXPECT_TRUE(this->Lookup('f', /*use*/ false)); // Mark g & h useful EXPECT_TRUE(this->Lookup('g', /*use*/ true)); EXPECT_TRUE(this->Lookup('h', /*use*/ true)); // Then old LOW entries EXPECT_OK(this->Insert('i', Cache::Priority::LOW)); EXPECT_OK(this->Insert('j', Cache::Priority::LOW)); EXPECT_FALSE(this->Lookup('b', /*use*/ false)); EXPECT_TRUE(this->Lookup('c', /*use*/ false)); EXPECT_FALSE(this->Lookup('e', /*use*/ false)); EXPECT_TRUE(this->Lookup('f', /*use*/ false)); // Mark g & h useful once again EXPECT_TRUE(this->Lookup('g', /*use*/ true)); EXPECT_TRUE(this->Lookup('h', /*use*/ true)); EXPECT_TRUE(this->Lookup('i', /*use*/ false)); EXPECT_TRUE(this->Lookup('j', /*use*/ false)); // Then old HIGH entries EXPECT_OK(this->Insert('k', Cache::Priority::LOW)); EXPECT_OK(this->Insert('l', Cache::Priority::LOW)); EXPECT_FALSE(this->Lookup('c', /*use*/ false)); EXPECT_FALSE(this->Lookup('f', /*use*/ false)); EXPECT_TRUE(this->Lookup('g', /*use*/ false)); EXPECT_TRUE(this->Lookup('h', /*use*/ false)); EXPECT_TRUE(this->Lookup('i', /*use*/ false)); EXPECT_TRUE(this->Lookup('j', /*use*/ false)); EXPECT_TRUE(this->Lookup('k', /*use*/ false)); EXPECT_TRUE(this->Lookup('l', /*use*/ false)); // Then the (roughly) least recently useful EXPECT_OK(this->Insert('m', Cache::Priority::HIGH)); EXPECT_OK(this->Insert('n', Cache::Priority::HIGH)); EXPECT_TRUE(this->Lookup('g', /*use*/ false)); EXPECT_TRUE(this->Lookup('h', /*use*/ false)); EXPECT_FALSE(this->Lookup('i', /*use*/ false)); EXPECT_FALSE(this->Lookup('j', /*use*/ false)); EXPECT_TRUE(this->Lookup('k', /*use*/ false)); EXPECT_TRUE(this->Lookup('l', /*use*/ false)); // Now try changing capacity down shard.SetCapacity(4); // Insert to ensure evictions happen EXPECT_OK(this->Insert('o', Cache::Priority::LOW)); EXPECT_OK(this->Insert('p', Cache::Priority::LOW)); EXPECT_FALSE(this->Lookup('g', /*use*/ false)); EXPECT_FALSE(this->Lookup('h', /*use*/ false)); EXPECT_FALSE(this->Lookup('k', /*use*/ false)); EXPECT_FALSE(this->Lookup('l', /*use*/ false)); EXPECT_TRUE(this->Lookup('m', /*use*/ false)); EXPECT_TRUE(this->Lookup('n', /*use*/ false)); EXPECT_TRUE(this->Lookup('o', /*use*/ false)); EXPECT_TRUE(this->Lookup('p', /*use*/ false)); // Now try changing capacity up EXPECT_TRUE(this->Lookup('m', /*use*/ true)); EXPECT_TRUE(this->Lookup('n', /*use*/ true)); shard.SetCapacity(6); EXPECT_OK(this->Insert('q', Cache::Priority::HIGH)); EXPECT_OK(this->Insert('r', Cache::Priority::HIGH)); EXPECT_OK(this->Insert('s', Cache::Priority::HIGH)); EXPECT_OK(this->Insert('t', Cache::Priority::HIGH)); EXPECT_FALSE(this->Lookup('o', /*use*/ false)); EXPECT_FALSE(this->Lookup('p', /*use*/ false)); EXPECT_TRUE(this->Lookup('m', /*use*/ false)); EXPECT_TRUE(this->Lookup('n', /*use*/ false)); EXPECT_TRUE(this->Lookup('q', /*use*/ false)); EXPECT_TRUE(this->Lookup('r', /*use*/ false)); EXPECT_TRUE(this->Lookup('s', /*use*/ false)); EXPECT_TRUE(this->Lookup('t', /*use*/ false)); } } TYPED_TEST(ClockCacheTest, ClockEvictionEffortCapTest) { using HandleImpl = typename ClockCacheTest::Shard::HandleImpl; for (bool strict_capacity_limit : {true, false}) { SCOPED_TRACE("strict_capacity_limit = " + std::to_string(strict_capacity_limit)); for (int eec : {-42, 0, 1, 10, 100, 1000}) { SCOPED_TRACE("eviction_effort_cap = " + std::to_string(eec)); constexpr size_t kCapacity = 1000; // Start with much larger capacity to ensure that we can go way over // capacity without reaching table occupancy limit. this->NewShard(3 * kCapacity, strict_capacity_limit, eec); auto& shard = *this->shard_; shard.SetCapacity(kCapacity); // Nearly fill the cache with pinned entries, then add a bunch of // non-pinned entries. eviction_effort_cap should affect how many // evictable entries are present beyond the cache capacity, despite // being evictable. constexpr size_t kCount = kCapacity - 1; std::unique_ptr ha { new HandleImpl* [kCount] {} }; for (size_t i = 0; i < 2 * kCount; ++i) { UniqueId64x2 hkey = this->CheapHash(i); ASSERT_OK(shard.Insert( this->TestKey(hkey), hkey, nullptr /*value*/, &kNoopCacheItemHelper, 1 /*charge*/, i < kCount ? &ha[i] : nullptr, Cache::Priority::LOW)); } if (strict_capacity_limit) { // If strict_capacity_limit is enabled, the cache will never exceed its // capacity EXPECT_EQ(shard.GetOccupancyCount(), kCapacity); } else { // Rough inverse relationship between cap and possible memory // explosion, which shows up as increased table occupancy count. int effective_eec = std::max(int{1}, eec) + 1; EXPECT_NEAR(shard.GetOccupancyCount() * 1.0, kCount * (1 + 1.4 / effective_eec), kCount * (0.6 / effective_eec) + 1.0); } for (size_t i = 0; i < kCount; ++i) { shard.Release(ha[i]); } } } } namespace { struct DeleteCounter { int deleted = 0; }; const Cache::CacheItemHelper kDeleteCounterHelper{ CacheEntryRole::kMisc, [](Cache::ObjectPtr value, MemoryAllocator* /*alloc*/) { static_cast(value)->deleted += 1; }}; } // namespace // Testing calls to CorrectNearOverflow in Release TYPED_TEST(ClockCacheTest, ClockCounterOverflowTest) { this->NewShard(6, /*strict_capacity_limit*/ false); auto& shard = *this->shard_; using HandleImpl = typename ClockCacheTest::Shard::HandleImpl; HandleImpl* h; DeleteCounter val; UniqueId64x2 hkey = this->TestHashedKey('x'); ASSERT_OK(shard.Insert(this->TestKey(hkey), hkey, &val, &kDeleteCounterHelper, 1, &h, Cache::Priority::HIGH)); // Some large number outstanding shard.TEST_RefN(h, 123456789); // Simulate many lookup/ref + release, plenty to overflow counters for (int i = 0; i < 10000; ++i) { shard.TEST_RefN(h, 1234567); shard.TEST_ReleaseN(h, 1234567); } // Mark it invisible (to reach a different CorrectNearOverflow() in Release) shard.Erase(this->TestKey(hkey), hkey); // Simulate many more lookup/ref + release (one-by-one would be too // expensive for unit test) for (int i = 0; i < 10000; ++i) { shard.TEST_RefN(h, 1234567); shard.TEST_ReleaseN(h, 1234567); } // Free all but last 1 shard.TEST_ReleaseN(h, 123456789); // Still alive ASSERT_EQ(val.deleted, 0); // Free last ref, which will finalize erasure shard.Release(h); // Deleted ASSERT_EQ(val.deleted, 1); } TYPED_TEST(ClockCacheTest, ClockTableFull) { // Force clock cache table to fill up (not usually allowed) in order // to test full probe sequence that is theoretically possible due to // parallel operations this->NewShard(6, /*strict_capacity_limit*/ false); auto& shard = *this->shard_; using HandleImpl = typename ClockCacheTest::Shard::HandleImpl; size_t size = shard.GetTableAddressCount(); ASSERT_LE(size + 3, 256); // for using char keys // Modify occupancy and capacity limits to attempt insert on full shard.TEST_MutableOccupancyLimit() = size + 100; shard.SetCapacity(size + 100); DeleteCounter val; std::vector handles; // NOTE: the three extra insertions should create standalone entries for (size_t i = 0; i < size + 3; ++i) { UniqueId64x2 hkey = this->TestHashedKey(static_cast(i)); ASSERT_OK(shard.Insert(this->TestKey(hkey), hkey, &val, &kDeleteCounterHelper, 1, &handles.emplace_back(), Cache::Priority::HIGH)); } for (size_t i = 0; i < size + 3; ++i) { UniqueId64x2 hkey = this->TestHashedKey(static_cast(i)); HandleImpl* h = shard.Lookup(this->TestKey(hkey), hkey); if (i < size) { ASSERT_NE(h, nullptr); shard.Release(h); } else { // Standalone entries not visible by lookup ASSERT_EQ(h, nullptr); } } for (size_t i = 0; i < size + 3; ++i) { ASSERT_NE(handles[i], nullptr); shard.Release(handles[i]); if (i < size) { // Everything still in cache ASSERT_EQ(val.deleted, 0); } else { // Standalone entries freed on release ASSERT_EQ(val.deleted, i + 1 - size); } } for (size_t i = size + 3; i > 0; --i) { UniqueId64x2 hkey = this->TestHashedKey(static_cast(i - 1)); shard.Erase(this->TestKey(hkey), hkey); if (i - 1 > size) { ASSERT_EQ(val.deleted, 3); } else { ASSERT_EQ(val.deleted, 3 + size - (i - 1)); } } } // This test is mostly to exercise some corner case logic, by forcing two // keys to have the same hash, and more TYPED_TEST(ClockCacheTest, CollidingInsertEraseTest) { this->NewShard(6, /*strict_capacity_limit*/ false); auto& shard = *this->shard_; using HandleImpl = typename ClockCacheTest::Shard::HandleImpl; DeleteCounter val; UniqueId64x2 hkey1 = this->TestHashedKey('x'); Slice key1 = this->TestKey(hkey1); UniqueId64x2 hkey2 = this->TestHashedKey('y'); Slice key2 = this->TestKey(hkey2); UniqueId64x2 hkey3 = this->TestHashedKey('z'); Slice key3 = this->TestKey(hkey3); HandleImpl* h1; ASSERT_OK(shard.Insert(key1, hkey1, &val, &kDeleteCounterHelper, 1, &h1, Cache::Priority::HIGH)); HandleImpl* h2; ASSERT_OK(shard.Insert(key2, hkey2, &val, &kDeleteCounterHelper, 1, &h2, Cache::Priority::HIGH)); HandleImpl* h3; ASSERT_OK(shard.Insert(key3, hkey3, &val, &kDeleteCounterHelper, 1, &h3, Cache::Priority::HIGH)); // Can repeatedly lookup+release despite the hash collision HandleImpl* tmp_h; for (bool erase_if_last_ref : {true, false}) { // but not last ref tmp_h = shard.Lookup(key1, hkey1); ASSERT_EQ(h1, tmp_h); ASSERT_FALSE(shard.Release(tmp_h, erase_if_last_ref)); tmp_h = shard.Lookup(key2, hkey2); ASSERT_EQ(h2, tmp_h); ASSERT_FALSE(shard.Release(tmp_h, erase_if_last_ref)); tmp_h = shard.Lookup(key3, hkey3); ASSERT_EQ(h3, tmp_h); ASSERT_FALSE(shard.Release(tmp_h, erase_if_last_ref)); } // Make h1 invisible shard.Erase(key1, hkey1); // Redundant erase shard.Erase(key1, hkey1); // All still alive ASSERT_EQ(val.deleted, 0); // Invisible to Lookup tmp_h = shard.Lookup(key1, hkey1); ASSERT_EQ(nullptr, tmp_h); // Can still find h2, h3 for (bool erase_if_last_ref : {true, false}) { // but not last ref tmp_h = shard.Lookup(key2, hkey2); ASSERT_EQ(h2, tmp_h); ASSERT_FALSE(shard.Release(tmp_h, erase_if_last_ref)); tmp_h = shard.Lookup(key3, hkey3); ASSERT_EQ(h3, tmp_h); ASSERT_FALSE(shard.Release(tmp_h, erase_if_last_ref)); } // Also Insert with invisible entry there ASSERT_OK(shard.Insert(key1, hkey1, &val, &kDeleteCounterHelper, 1, nullptr, Cache::Priority::HIGH)); tmp_h = shard.Lookup(key1, hkey1); // Found but distinct handle ASSERT_NE(nullptr, tmp_h); ASSERT_NE(h1, tmp_h); ASSERT_TRUE(shard.Release(tmp_h, /*erase_if_last_ref*/ true)); // tmp_h deleted ASSERT_EQ(val.deleted--, 1); // Release last ref on h1 (already invisible) ASSERT_TRUE(shard.Release(h1, /*erase_if_last_ref*/ false)); // h1 deleted ASSERT_EQ(val.deleted--, 1); h1 = nullptr; // Can still find h2, h3 for (bool erase_if_last_ref : {true, false}) { // but not last ref tmp_h = shard.Lookup(key2, hkey2); ASSERT_EQ(h2, tmp_h); ASSERT_FALSE(shard.Release(tmp_h, erase_if_last_ref)); tmp_h = shard.Lookup(key3, hkey3); ASSERT_EQ(h3, tmp_h); ASSERT_FALSE(shard.Release(tmp_h, erase_if_last_ref)); } // Release last ref on h2 ASSERT_FALSE(shard.Release(h2, /*erase_if_last_ref*/ false)); // h2 still not deleted (unreferenced in cache) ASSERT_EQ(val.deleted, 0); // Can still find it tmp_h = shard.Lookup(key2, hkey2); ASSERT_EQ(h2, tmp_h); // Release last ref on h2, with erase ASSERT_TRUE(shard.Release(h2, /*erase_if_last_ref*/ true)); // h2 deleted ASSERT_EQ(val.deleted--, 1); tmp_h = shard.Lookup(key2, hkey2); ASSERT_EQ(nullptr, tmp_h); // Can still find h3 for (bool erase_if_last_ref : {true, false}) { // but not last ref tmp_h = shard.Lookup(key3, hkey3); ASSERT_EQ(h3, tmp_h); ASSERT_FALSE(shard.Release(tmp_h, erase_if_last_ref)); } // Release last ref on h3, without erase ASSERT_FALSE(shard.Release(h3, /*erase_if_last_ref*/ false)); // h3 still not deleted (unreferenced in cache) ASSERT_EQ(val.deleted, 0); // Explicit erase shard.Erase(key3, hkey3); // h3 deleted ASSERT_EQ(val.deleted--, 1); tmp_h = shard.Lookup(key3, hkey3); ASSERT_EQ(nullptr, tmp_h); } // This uses the public API to effectively test CalcHashBits etc. TYPED_TEST(ClockCacheTest, TableSizesTest) { for (size_t est_val_size : {1U, 5U, 123U, 2345U, 345678U}) { SCOPED_TRACE("est_val_size = " + std::to_string(est_val_size)); for (double est_count : {1.1, 2.2, 511.9, 512.1, 2345.0}) { SCOPED_TRACE("est_count = " + std::to_string(est_count)); size_t capacity = static_cast(est_val_size * est_count); // kDontChargeCacheMetadata auto cache = HyperClockCacheOptions( capacity, est_val_size, /*num shard_bits*/ -1, /*strict_capacity_limit*/ false, /*memory_allocator*/ nullptr, kDontChargeCacheMetadata) .MakeSharedCache(); // Table sizes are currently only powers of two EXPECT_GE(cache->GetTableAddressCount(), est_count / FixedHyperClockTable::kLoadFactor); EXPECT_LE(cache->GetTableAddressCount(), est_count / FixedHyperClockTable::kLoadFactor * 2.0); EXPECT_EQ(cache->GetUsage(), 0); // kFullChargeMetaData // Because table sizes are currently only powers of two, sizes get // really weird when metadata is a huge portion of capacity. For example, // doubling the table size could cut by 90% the space available to // values. Therefore, we omit those weird cases for now. if (est_val_size >= 512) { cache = HyperClockCacheOptions( capacity, est_val_size, /*num shard_bits*/ -1, /*strict_capacity_limit*/ false, /*memory_allocator*/ nullptr, kFullChargeCacheMetadata) .MakeSharedCache(); double est_count_after_meta = (capacity - cache->GetUsage()) * 1.0 / est_val_size; EXPECT_GE(cache->GetTableAddressCount(), est_count_after_meta / FixedHyperClockTable::kLoadFactor); EXPECT_LE( cache->GetTableAddressCount(), est_count_after_meta / FixedHyperClockTable::kLoadFactor * 2.0); } } } } } // namespace clock_cache class TestSecondaryCache : public SecondaryCache { public: // Specifies what action to take on a lookup for a particular key enum ResultType { SUCCESS, // Fail lookup immediately FAIL, // Defer the result. It will returned after Wait/WaitAll is called DEFER, // Defer the result and eventually return failure DEFER_AND_FAIL }; using ResultMap = std::unordered_map; explicit TestSecondaryCache(size_t capacity, bool insert_saved = false) : cache_(NewLRUCache(capacity, 0, false, 0.5 /* high_pri_pool_ratio */, nullptr, kDefaultToAdaptiveMutex, kDontChargeCacheMetadata)), num_inserts_(0), num_lookups_(0), inject_failure_(false), insert_saved_(insert_saved) {} const char* Name() const override { return "TestSecondaryCache"; } void InjectFailure() { inject_failure_ = true; } void ResetInjectFailure() { inject_failure_ = false; } Status Insert(const Slice& key, Cache::ObjectPtr value, const Cache::CacheItemHelper* helper, bool /*force_insert*/) override { if (inject_failure_) { return Status::Corruption("Insertion Data Corrupted"); } CheckCacheKeyCommonPrefix(key); size_t size; char* buf; Status s; num_inserts_++; size = (*helper->size_cb)(value); buf = new char[size + sizeof(uint64_t)]; EncodeFixed64(buf, size); s = (*helper->saveto_cb)(value, 0, size, buf + sizeof(uint64_t)); if (!s.ok()) { delete[] buf; return s; } return cache_.Insert(key, buf, size); } Status InsertSaved(const Slice& key, const Slice& saved, CompressionType /*type*/ = kNoCompression, CacheTier /*source*/ = CacheTier::kVolatileTier) override { if (insert_saved_) { return Insert(key, const_cast(&saved), &kSliceCacheItemHelper, /*force_insert=*/true); } else { return Status::OK(); } } std::unique_ptr Lookup( const Slice& key, const Cache::CacheItemHelper* helper, Cache::CreateContext* create_context, bool /*wait*/, bool /*advise_erase*/, Statistics* /*stats*/, bool& kept_in_sec_cache) override { std::string key_str = key.ToString(); TEST_SYNC_POINT_CALLBACK("TestSecondaryCache::Lookup", &key_str); std::unique_ptr secondary_handle; kept_in_sec_cache = false; ResultType type = ResultType::SUCCESS; auto iter = result_map_.find(key.ToString()); if (iter != result_map_.end()) { type = iter->second; } if (type == ResultType::FAIL) { return secondary_handle; } TypedHandle* handle = cache_.Lookup(key); num_lookups_++; if (handle) { Cache::ObjectPtr value = nullptr; size_t charge = 0; Status s; if (type != ResultType::DEFER_AND_FAIL) { char* ptr = cache_.Value(handle); size_t size = DecodeFixed64(ptr); ptr += sizeof(uint64_t); s = helper->create_cb(Slice(ptr, size), kNoCompression, CacheTier::kVolatileTier, create_context, /*alloc*/ nullptr, &value, &charge); } if (s.ok()) { secondary_handle.reset(new TestSecondaryCacheResultHandle( cache_.get(), handle, value, charge, type)); kept_in_sec_cache = true; } else { cache_.Release(handle); } } return secondary_handle; } bool SupportForceErase() const override { return false; } void Erase(const Slice& /*key*/) override {} void WaitAll(std::vector handles) override { for (SecondaryCacheResultHandle* handle : handles) { TestSecondaryCacheResultHandle* sec_handle = static_cast(handle); sec_handle->SetReady(); } } std::string GetPrintableOptions() const override { return ""; } void SetResultMap(ResultMap&& map) { result_map_ = std::move(map); } uint32_t num_inserts() { return num_inserts_; } uint32_t num_lookups() { return num_lookups_; } void CheckCacheKeyCommonPrefix(const Slice& key) { Slice current_prefix(key.data(), OffsetableCacheKey::kCommonPrefixSize); if (ckey_prefix_.empty()) { ckey_prefix_ = current_prefix.ToString(); } else { EXPECT_EQ(ckey_prefix_, current_prefix.ToString()); } } private: class TestSecondaryCacheResultHandle : public SecondaryCacheResultHandle { public: TestSecondaryCacheResultHandle(Cache* cache, Cache::Handle* handle, Cache::ObjectPtr value, size_t size, ResultType type) : cache_(cache), handle_(handle), value_(value), size_(size), is_ready_(true) { if (type != ResultType::SUCCESS) { is_ready_ = false; } } ~TestSecondaryCacheResultHandle() override { cache_->Release(handle_); } bool IsReady() override { return is_ready_; } void Wait() override {} Cache::ObjectPtr Value() override { assert(is_ready_); return value_; } size_t Size() override { return Value() ? size_ : 0; } void SetReady() { is_ready_ = true; } private: Cache* cache_; Cache::Handle* handle_; Cache::ObjectPtr value_; size_t size_; bool is_ready_; }; using SharedCache = BasicTypedSharedCacheInterface; using TypedHandle = SharedCache::TypedHandle; SharedCache cache_; uint32_t num_inserts_; uint32_t num_lookups_; bool inject_failure_; bool insert_saved_; std::string ckey_prefix_; ResultMap result_map_; }; using secondary_cache_test_util::GetTestingCacheTypes; using secondary_cache_test_util::WithCacheTypeParam; class BasicSecondaryCacheTest : public testing::Test, public WithCacheTypeParam {}; INSTANTIATE_TEST_CASE_P(BasicSecondaryCacheTest, BasicSecondaryCacheTest, GetTestingCacheTypes()); class DBSecondaryCacheTest : public DBTestBase, public WithCacheTypeParam { public: DBSecondaryCacheTest() : DBTestBase("db_secondary_cache_test", /*env_do_fsync=*/true) { fault_fs_.reset(new FaultInjectionTestFS(env_->GetFileSystem())); fault_env_.reset(new CompositeEnvWrapper(env_, fault_fs_)); } std::shared_ptr fault_fs_; std::unique_ptr fault_env_; }; INSTANTIATE_TEST_CASE_P(DBSecondaryCacheTest, DBSecondaryCacheTest, GetTestingCacheTypes()); TEST_P(BasicSecondaryCacheTest, BasicTest) { std::shared_ptr secondary_cache = std::make_shared(4096, true); std::shared_ptr cache = NewCache(1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); std::shared_ptr stats = CreateDBStatistics(); CacheKey k1 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); CacheKey k2 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); CacheKey k3 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); Random rnd(301); // Start with warming k3 std::string str3 = rnd.RandomString(1021); ASSERT_OK(secondary_cache->InsertSaved(k3.AsSlice(), str3)); std::string str1 = rnd.RandomString(1021); TestItem* item1 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(k1.AsSlice(), item1, GetHelper(), str1.length())); std::string str2 = rnd.RandomString(1021); TestItem* item2 = new TestItem(str2.data(), str2.length()); // k1 should be demoted to NVM ASSERT_OK(cache->Insert(k2.AsSlice(), item2, GetHelper(), str2.length())); get_perf_context()->Reset(); Cache::Handle* handle; handle = cache->Lookup(k2.AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); ASSERT_EQ(static_cast(cache->Value(handle))->Size(), str2.size()); cache->Release(handle); // This lookup should promote k1 and demote k2 handle = cache->Lookup(k1.AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); ASSERT_EQ(static_cast(cache->Value(handle))->Size(), str1.size()); cache->Release(handle); // This lookup should promote k3 and demote k1 handle = cache->Lookup(k3.AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); ASSERT_EQ(static_cast(cache->Value(handle))->Size(), str3.size()); cache->Release(handle); ASSERT_EQ(secondary_cache->num_inserts(), 3u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); ASSERT_EQ(stats->getTickerCount(SECONDARY_CACHE_HITS), secondary_cache->num_lookups()); PerfContext perf_ctx = *get_perf_context(); ASSERT_EQ(perf_ctx.secondary_cache_hit_count, secondary_cache->num_lookups()); cache.reset(); secondary_cache.reset(); } TEST_P(BasicSecondaryCacheTest, StatsTest) { std::shared_ptr secondary_cache = std::make_shared(4096, true); std::shared_ptr cache = NewCache(1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); std::shared_ptr stats = CreateDBStatistics(); CacheKey k1 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); CacheKey k2 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); CacheKey k3 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); Random rnd(301); // Start with warming secondary cache std::string str1 = rnd.RandomString(1020); std::string str2 = rnd.RandomString(1020); std::string str3 = rnd.RandomString(1020); ASSERT_OK(secondary_cache->InsertSaved(k1.AsSlice(), str1)); ASSERT_OK(secondary_cache->InsertSaved(k2.AsSlice(), str2)); ASSERT_OK(secondary_cache->InsertSaved(k3.AsSlice(), str3)); get_perf_context()->Reset(); Cache::Handle* handle; handle = cache->Lookup(k1.AsSlice(), GetHelper(CacheEntryRole::kFilterBlock), /*context*/ this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); ASSERT_EQ(static_cast(cache->Value(handle))->Size(), str1.size()); cache->Release(handle); handle = cache->Lookup(k2.AsSlice(), GetHelper(CacheEntryRole::kIndexBlock), /*context*/ this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); ASSERT_EQ(static_cast(cache->Value(handle))->Size(), str2.size()); cache->Release(handle); handle = cache->Lookup(k3.AsSlice(), GetHelper(CacheEntryRole::kDataBlock), /*context*/ this, Cache::Priority::LOW, stats.get()); ASSERT_NE(handle, nullptr); ASSERT_EQ(static_cast(cache->Value(handle))->Size(), str3.size()); cache->Release(handle); ASSERT_EQ(secondary_cache->num_inserts(), 3u); ASSERT_EQ(secondary_cache->num_lookups(), 3u); ASSERT_EQ(stats->getTickerCount(SECONDARY_CACHE_HITS), secondary_cache->num_lookups()); ASSERT_EQ(stats->getTickerCount(SECONDARY_CACHE_FILTER_HITS), 1); ASSERT_EQ(stats->getTickerCount(SECONDARY_CACHE_INDEX_HITS), 1); ASSERT_EQ(stats->getTickerCount(SECONDARY_CACHE_DATA_HITS), 1); PerfContext perf_ctx = *get_perf_context(); ASSERT_EQ(perf_ctx.secondary_cache_hit_count, secondary_cache->num_lookups()); cache.reset(); secondary_cache.reset(); } TEST_P(BasicSecondaryCacheTest, BasicFailTest) { std::shared_ptr secondary_cache = std::make_shared(2048, true); std::shared_ptr cache = NewCache(1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); CacheKey k1 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); CacheKey k2 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); Random rnd(301); std::string str1 = rnd.RandomString(1020); auto item1 = std::make_unique(str1.data(), str1.length()); // NOTE: changed to assert helper != nullptr for efficiency / code size // ASSERT_TRUE(cache->Insert(k1.AsSlice(), item1.get(), nullptr, // str1.length()).IsInvalidArgument()); ASSERT_OK( cache->Insert(k1.AsSlice(), item1.get(), GetHelper(), str1.length())); item1.release(); // Appease clang-analyze "potential memory leak" Cache::Handle* handle; handle = cache->Lookup(k2.AsSlice(), nullptr, /*context*/ this, Cache::Priority::LOW); ASSERT_EQ(handle, nullptr); handle = cache->Lookup(k2.AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_EQ(handle, nullptr); Cache::AsyncLookupHandle async_handle; async_handle.key = k2.AsSlice(); async_handle.helper = GetHelper(); async_handle.create_context = this; async_handle.priority = Cache::Priority::LOW; cache->StartAsyncLookup(async_handle); cache->Wait(async_handle); handle = async_handle.Result(); ASSERT_EQ(handle, nullptr); cache.reset(); secondary_cache.reset(); } TEST_P(BasicSecondaryCacheTest, SaveFailTest) { std::shared_ptr secondary_cache = std::make_shared(2048, true); std::shared_ptr cache = NewCache(1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); CacheKey k1 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); CacheKey k2 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); Random rnd(301); std::string str1 = rnd.RandomString(1020); TestItem* item1 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(k1.AsSlice(), item1, GetHelperFail(), str1.length())); std::string str2 = rnd.RandomString(1020); TestItem* item2 = new TestItem(str2.data(), str2.length()); // k1 should be demoted to NVM ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_OK(cache->Insert(k2.AsSlice(), item2, GetHelperFail(), str2.length())); ASSERT_EQ(secondary_cache->num_inserts(), 1u); Cache::Handle* handle; handle = cache->Lookup(k2.AsSlice(), GetHelperFail(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle, nullptr); cache->Release(handle); // This lookup should fail, since k1 demotion would have failed handle = cache->Lookup(k1.AsSlice(), GetHelperFail(), /*context*/ this, Cache::Priority::LOW); ASSERT_EQ(handle, nullptr); // Since k1 didn't get promoted, k2 should still be in cache handle = cache->Lookup(k2.AsSlice(), GetHelperFail(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle, nullptr); cache->Release(handle); ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 1u); cache.reset(); secondary_cache.reset(); } TEST_P(BasicSecondaryCacheTest, CreateFailTest) { std::shared_ptr secondary_cache = std::make_shared(2048, true); std::shared_ptr cache = NewCache(1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); CacheKey k1 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); CacheKey k2 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); Random rnd(301); std::string str1 = rnd.RandomString(1020); TestItem* item1 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(k1.AsSlice(), item1, GetHelper(), str1.length())); std::string str2 = rnd.RandomString(1020); TestItem* item2 = new TestItem(str2.data(), str2.length()); // k1 should be demoted to NVM ASSERT_OK(cache->Insert(k2.AsSlice(), item2, GetHelper(), str2.length())); Cache::Handle* handle; SetFailCreate(true); handle = cache->Lookup(k2.AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle, nullptr); cache->Release(handle); // This lookup should fail, since k1 creation would have failed handle = cache->Lookup(k1.AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_EQ(handle, nullptr); // Since k1 didn't get promoted, k2 should still be in cache handle = cache->Lookup(k2.AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle, nullptr); cache->Release(handle); ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 1u); cache.reset(); secondary_cache.reset(); } TEST_P(BasicSecondaryCacheTest, FullCapacityTest) { for (bool strict_capacity_limit : {false, true}) { std::shared_ptr secondary_cache = std::make_shared(2048, true); std::shared_ptr cache = NewCache(1024 /* capacity */, 0 /* num_shard_bits */, strict_capacity_limit, secondary_cache); CacheKey k1 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); CacheKey k2 = CacheKey::CreateUniqueForCacheLifetime(cache.get()); Random rnd(301); std::string str1 = rnd.RandomString(1020); TestItem* item1 = new TestItem(str1.data(), str1.length()); ASSERT_OK(cache->Insert(k1.AsSlice(), item1, GetHelper(), str1.length())); std::string str2 = rnd.RandomString(1020); TestItem* item2 = new TestItem(str2.data(), str2.length()); // k1 should be demoted to NVM ASSERT_OK(cache->Insert(k2.AsSlice(), item2, GetHelper(), str2.length())); Cache::Handle* handle2; handle2 = cache->Lookup(k2.AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle2, nullptr); // k1 lookup fails without secondary cache support Cache::Handle* handle1; handle1 = cache->Lookup( k1.AsSlice(), GetHelper(CacheEntryRole::kDataBlock, /*secondary_compatible=*/false), /*context*/ this, Cache::Priority::LOW); ASSERT_EQ(handle1, nullptr); // k1 promotion can fail with strict_capacit_limit=true, but Lookup still // succeeds using a standalone handle handle1 = cache->Lookup(k1.AsSlice(), GetHelper(), /*context*/ this, Cache::Priority::LOW); ASSERT_NE(handle1, nullptr); ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 1u); // Releasing k2's handle first, k2 is evicted from primary iff k1 promotion // was charged to the cache (except HCC doesn't erase in Release() over // capacity) // FIXME: Insert to secondary from Release disabled cache->Release(handle2); cache->Release(handle1); handle2 = cache->Lookup( k2.AsSlice(), GetHelper(CacheEntryRole::kDataBlock, /*secondary_compatible=*/false), /*context*/ this, Cache::Priority::LOW); if (strict_capacity_limit || IsHyperClock()) { ASSERT_NE(handle2, nullptr); cache->Release(handle2); ASSERT_EQ(secondary_cache->num_inserts(), 1u); } else { ASSERT_EQ(handle2, nullptr); // FIXME: Insert to secondary from Release disabled // ASSERT_EQ(secondary_cache->num_inserts(), 2u); ASSERT_EQ(secondary_cache->num_inserts(), 1u); } cache.reset(); secondary_cache.reset(); } } // In this test, the block cache size is set to 4096, after insert 6 KV-pairs // and flush, there are 5 blocks in this SST file, 2 data blocks and 3 meta // blocks. block_1 size is 4096 and block_2 size is 2056. The total size // of the meta blocks are about 900 to 1000. Therefore, in any situation, // if we try to insert block_1 to the block cache, it will always fails. Only // block_2 will be successfully inserted into the block cache. // CORRECTION: this is not quite right. block_1 can be inserted into the block // cache because strict_capacity_limit=false, but it is removed from the cache // in Release() because of being over-capacity, without demoting to secondary // cache. FixedHyperClockCache doesn't check capacity on release (for // efficiency) so can demote the over-capacity item to secondary cache. Also, we // intend to add support for demotion in Release, but that currently causes too // much unit test churn. TEST_P(DBSecondaryCacheTest, TestSecondaryCacheCorrectness1) { if (IsHyperClock()) { // See CORRECTION above ROCKSDB_GTEST_BYPASS("Test depends on LRUCache-specific behaviors"); return; } std::shared_ptr secondary_cache( new TestSecondaryCache(2048 * 1024)); std::shared_ptr cache = NewCache(4 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); fault_fs_->SetFailGetUniqueId(true); // Set the file paranoid check, so after flush, the file will be read // all the blocks will be accessed. options.paranoid_file_checks = true; DestroyAndReopen(options); Random rnd(301); const int N = 6; for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1007); ASSERT_OK(Put(Key(i), p_v)); } ASSERT_OK(Flush()); // After Flush is successful, RocksDB will do the paranoid check for the new // SST file. Meta blocks are always cached in the block cache and they // will not be evicted. When block_2 is cache miss and read out, it is // inserted to the block cache. Note that, block_1 is never successfully // inserted to the block cache. Here are 2 lookups in the secondary cache // for block_1 and block_2 ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); Compact("a", "z"); // Compaction will create the iterator to scan the whole file. So all the // blocks are needed. Meta blocks are always cached. When block_1 is read // out, block_2 is evicted from block cache and inserted to secondary // cache. ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 3u); std::string v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // The first data block is not in the cache, similarly, trigger the block // cache Lookup and secondary cache lookup for block_1. But block_1 will not // be inserted successfully due to the size. Currently, cache only has // the meta blocks. ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 4u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // The second data block is not in the cache, similarly, trigger the block // cache Lookup and secondary cache lookup for block_2 and block_2 is found // in the secondary cache. Now block cache has block_2 ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 5u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // block_2 is in the block cache. There is a block cache hit. No need to // lookup or insert the secondary cache. ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 5u); v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // Lookup the first data block, not in the block cache, so lookup the // secondary cache. Also not in the secondary cache. After Get, still // block_1 is will not be cached. ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 6u); v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // Lookup the first data block, not in the block cache, so lookup the // secondary cache. Also not in the secondary cache. After Get, still // block_1 is will not be cached. ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 7u); Destroy(options); } // In this test, the block cache size is set to 6100, after insert 6 KV-pairs // and flush, there are 5 blocks in this SST file, 2 data blocks and 3 meta // blocks. block_1 size is 4096 and block_2 size is 2056. The total size // of the meta blocks are about 900 to 1000. Therefore, we can successfully // insert and cache block_1 in the block cache (this is the different place // from TestSecondaryCacheCorrectness1) TEST_P(DBSecondaryCacheTest, TestSecondaryCacheCorrectness2) { if (IsHyperClock()) { ROCKSDB_GTEST_BYPASS("Test depends on LRUCache-specific behaviors"); return; } std::shared_ptr secondary_cache( new TestSecondaryCache(2048 * 1024)); std::shared_ptr cache = NewCache(6100 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.paranoid_file_checks = true; options.env = fault_env_.get(); fault_fs_->SetFailGetUniqueId(true); DestroyAndReopen(options); Random rnd(301); const int N = 6; for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1007); ASSERT_OK(Put(Key(i), p_v)); } ASSERT_OK(Flush()); // After Flush is successful, RocksDB will do the paranoid check for the new // SST file. Meta blocks are always cached in the block cache and they // will not be evicted. When block_2 is cache miss and read out, it is // inserted to the block cache. Thefore, block_1 is evicted from block // cache and successfully inserted to the secondary cache. Here are 2 // lookups in the secondary cache for block_1 and block_2. ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); Compact("a", "z"); // Compaction will create the iterator to scan the whole file. So all the // blocks are needed. After Flush, only block_2 is cached in block cache // and block_1 is in the secondary cache. So when read block_1, it is // read out from secondary cache and inserted to block cache. At the same // time, block_2 is inserted to secondary cache. Now, secondary cache has // both block_1 and block_2. After compaction, block_1 is in the cache. ASSERT_EQ(secondary_cache->num_inserts(), 2u); ASSERT_EQ(secondary_cache->num_lookups(), 3u); std::string v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // This Get needs to access block_1, since block_1 is cached in block cache // there is no secondary cache lookup. ASSERT_EQ(secondary_cache->num_inserts(), 2u); ASSERT_EQ(secondary_cache->num_lookups(), 3u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // This Get needs to access block_2 which is not in the block cache. So // it will lookup the secondary cache for block_2 and cache it in the // block_cache. ASSERT_EQ(secondary_cache->num_inserts(), 2u); ASSERT_EQ(secondary_cache->num_lookups(), 4u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // This Get needs to access block_2 which is already in the block cache. // No need to lookup secondary cache. ASSERT_EQ(secondary_cache->num_inserts(), 2u); ASSERT_EQ(secondary_cache->num_lookups(), 4u); v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // This Get needs to access block_1, since block_1 is not in block cache // there is one econdary cache lookup. Then, block_1 is cached in the // block cache. ASSERT_EQ(secondary_cache->num_inserts(), 2u); ASSERT_EQ(secondary_cache->num_lookups(), 5u); v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // This Get needs to access block_1, since block_1 is cached in block cache // there is no secondary cache lookup. ASSERT_EQ(secondary_cache->num_inserts(), 2u); ASSERT_EQ(secondary_cache->num_lookups(), 5u); Destroy(options); } // The block cache size is set to 1024*1024, after insert 6 KV-pairs // and flush, there are 5 blocks in this SST file, 2 data blocks and 3 meta // blocks. block_1 size is 4096 and block_2 size is 2056. The total size // of the meta blocks are about 900 to 1000. Therefore, we can successfully // cache all the blocks in the block cache and there is not secondary cache // insertion. 2 lookup is needed for the blocks. TEST_P(DBSecondaryCacheTest, NoSecondaryCacheInsertion) { std::shared_ptr secondary_cache( new TestSecondaryCache(2048 * 1024)); std::shared_ptr cache = NewCache(1024 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.paranoid_file_checks = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); fault_fs_->SetFailGetUniqueId(true); DestroyAndReopen(options); Random rnd(301); const int N = 6; for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1000); ASSERT_OK(Put(Key(i), p_v)); } ASSERT_OK(Flush()); // After Flush is successful, RocksDB will do the paranoid check for the new // SST file. Meta blocks are always cached in the block cache and they // will not be evicted. Now, block cache is large enough, it cache // both block_1 and block_2. When first time read block_1 and block_2 // there are cache misses. So 2 secondary cache lookups are needed for // the 2 blocks ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); Compact("a", "z"); // Compaction will iterate the whole SST file. Since all the data blocks // are in the block cache. No need to lookup the secondary cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); std::string v = Get(Key(0)); ASSERT_EQ(1000, v.size()); // Since the block cache is large enough, all the blocks are cached. we // do not need to lookup the seondary cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); Destroy(options); } TEST_P(DBSecondaryCacheTest, SecondaryCacheIntensiveTesting) { std::shared_ptr secondary_cache( new TestSecondaryCache(2048 * 1024)); std::shared_ptr cache = NewCache(8 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); fault_fs_->SetFailGetUniqueId(true); DestroyAndReopen(options); Random rnd(301); const int N = 256; for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1000); ASSERT_OK(Put(Key(i), p_v)); } ASSERT_OK(Flush()); Compact("a", "z"); Random r_index(47); std::string v; for (int i = 0; i < 1000; i++) { uint32_t key_i = r_index.Next() % N; v = Get(Key(key_i)); } // We have over 200 data blocks there will be multiple insertion // and lookups. ASSERT_GE(secondary_cache->num_inserts(), 1u); ASSERT_GE(secondary_cache->num_lookups(), 1u); Destroy(options); } // In this test, the block cache size is set to 4096, after insert 6 KV-pairs // and flush, there are 5 blocks in this SST file, 2 data blocks and 3 meta // blocks. block_1 size is 4096 and block_2 size is 2056. The total size // of the meta blocks are about 900 to 1000. Therefore, in any situation, // if we try to insert block_1 to the block cache, it will always fails. Only // block_2 will be successfully inserted into the block cache. TEST_P(DBSecondaryCacheTest, SecondaryCacheFailureTest) { if (IsHyperClock()) { ROCKSDB_GTEST_BYPASS("Test depends on LRUCache-specific behaviors"); return; } std::shared_ptr secondary_cache( new TestSecondaryCache(2048 * 1024)); std::shared_ptr cache = NewCache(4 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.paranoid_file_checks = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); fault_fs_->SetFailGetUniqueId(true); DestroyAndReopen(options); Random rnd(301); const int N = 6; for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1007); ASSERT_OK(Put(Key(i), p_v)); } ASSERT_OK(Flush()); // After Flush is successful, RocksDB will do the paranoid check for the new // SST file. Meta blocks are always cached in the block cache and they // will not be evicted. When block_2 is cache miss and read out, it is // inserted to the block cache. Note that, block_1 is never successfully // inserted to the block cache. Here are 2 lookups in the secondary cache // for block_1 and block_2 ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); // Fail the insertion, in LRU cache, the secondary insertion returned status // is not checked, therefore, the DB will not be influenced. secondary_cache->InjectFailure(); Compact("a", "z"); // Compaction will create the iterator to scan the whole file. So all the // blocks are needed. Meta blocks are always cached. When block_1 is read // out, block_2 is evicted from block cache and inserted to secondary // cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 3u); std::string v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // The first data block is not in the cache, similarly, trigger the block // cache Lookup and secondary cache lookup for block_1. But block_1 will not // be inserted successfully due to the size. Currently, cache only has // the meta blocks. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 4u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // The second data block is not in the cache, similarly, trigger the block // cache Lookup and secondary cache lookup for block_2 and block_2 is found // in the secondary cache. Now block cache has block_2 ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 5u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // block_2 is in the block cache. There is a block cache hit. No need to // lookup or insert the secondary cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 5u); v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // Lookup the first data block, not in the block cache, so lookup the // secondary cache. Also not in the secondary cache. After Get, still // block_1 is will not be cached. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 6u); v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // Lookup the first data block, not in the block cache, so lookup the // secondary cache. Also not in the secondary cache. After Get, still // block_1 is will not be cached. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 7u); secondary_cache->ResetInjectFailure(); Destroy(options); } TEST_P(BasicSecondaryCacheTest, BasicWaitAllTest) { std::shared_ptr secondary_cache = std::make_shared(32 * 1024); std::shared_ptr cache = NewCache(1024 /* capacity */, 2 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); const int num_keys = 32; OffsetableCacheKey ock{"foo", "bar", 1}; Random rnd(301); std::vector values; for (int i = 0; i < num_keys; ++i) { std::string str = rnd.RandomString(1020); values.emplace_back(str); TestItem* item = new TestItem(str.data(), str.length()); ASSERT_OK(cache->Insert(ock.WithOffset(i).AsSlice(), item, GetHelper(), str.length())); } // Force all entries to be evicted to the secondary cache if (IsHyperClock()) { // HCC doesn't respond immediately to SetCapacity for (int i = 9000; i < 9030; ++i) { ASSERT_OK(cache->Insert(ock.WithOffset(i).AsSlice(), nullptr, &kNoopCacheItemHelper, 256)); } } else { cache->SetCapacity(0); } ASSERT_EQ(secondary_cache->num_inserts(), 32u); cache->SetCapacity(32 * 1024); secondary_cache->SetResultMap( {{ock.WithOffset(3).AsSlice().ToString(), TestSecondaryCache::ResultType::DEFER}, {ock.WithOffset(4).AsSlice().ToString(), TestSecondaryCache::ResultType::DEFER_AND_FAIL}, {ock.WithOffset(5).AsSlice().ToString(), TestSecondaryCache::ResultType::FAIL}}); std::array async_handles; std::array cache_keys; for (size_t i = 0; i < async_handles.size(); ++i) { auto& ah = async_handles[i]; cache_keys[i] = ock.WithOffset(i); ah.key = cache_keys[i].AsSlice(); ah.helper = GetHelper(); ah.create_context = this; ah.priority = Cache::Priority::LOW; cache->StartAsyncLookup(ah); } cache->WaitAll(&async_handles[0], async_handles.size()); for (size_t i = 0; i < async_handles.size(); ++i) { SCOPED_TRACE("i = " + std::to_string(i)); Cache::Handle* result = async_handles[i].Result(); if (i == 4 || i == 5) { ASSERT_EQ(result, nullptr); continue; } else { ASSERT_NE(result, nullptr); TestItem* item = static_cast(cache->Value(result)); ASSERT_EQ(item->ToString(), values[i]); } cache->Release(result); } cache.reset(); secondary_cache.reset(); } // In this test, we have one KV pair per data block. We indirectly determine // the cache key associated with each data block (and thus each KV) by using // a sync point callback in TestSecondaryCache::Lookup. We then control the // lookup result by setting the ResultMap. TEST_P(DBSecondaryCacheTest, TestSecondaryCacheMultiGet) { if (IsHyperClock()) { ROCKSDB_GTEST_BYPASS("Test depends on LRUCache-specific behaviors"); return; } std::shared_ptr secondary_cache( new TestSecondaryCache(2048 * 1024)); std::shared_ptr cache = NewCache(1 << 20 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; table_options.cache_index_and_filter_blocks = false; Options options = GetDefaultOptions(); options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.paranoid_file_checks = true; DestroyAndReopen(options); Random rnd(301); const int N = 8; std::vector keys; for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(4000); keys.emplace_back(p_v); ASSERT_OK(Put(Key(i), p_v)); } ASSERT_OK(Flush()); // After Flush is successful, RocksDB does the paranoid check for the new // SST file. This will try to lookup all data blocks in the secondary // cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 8u); cache->SetCapacity(0); ASSERT_EQ(secondary_cache->num_inserts(), 8u); cache->SetCapacity(1 << 20); std::vector cache_keys; ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack( "TestSecondaryCache::Lookup", [&cache_keys](void* key) -> void { cache_keys.emplace_back(*(static_cast(key))); }); ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->EnableProcessing(); for (int i = 0; i < N; ++i) { std::string v = Get(Key(i)); ASSERT_EQ(4000, v.size()); ASSERT_EQ(v, keys[i]); } ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->DisableProcessing(); ASSERT_EQ(secondary_cache->num_lookups(), 16u); cache->SetCapacity(0); cache->SetCapacity(1 << 20); ASSERT_EQ(Get(Key(2)), keys[2]); ASSERT_EQ(Get(Key(7)), keys[7]); secondary_cache->SetResultMap( {{cache_keys[3], TestSecondaryCache::ResultType::DEFER}, {cache_keys[4], TestSecondaryCache::ResultType::DEFER_AND_FAIL}, {cache_keys[5], TestSecondaryCache::ResultType::FAIL}}); std::vector mget_keys( {Key(0), Key(1), Key(2), Key(3), Key(4), Key(5), Key(6), Key(7)}); std::vector values(mget_keys.size()); std::vector s(keys.size()); std::vector key_slices; for (const std::string& key : mget_keys) { key_slices.emplace_back(key); } uint32_t num_lookups = secondary_cache->num_lookups(); dbfull()->MultiGet(ReadOptions(), dbfull()->DefaultColumnFamily(), key_slices.size(), key_slices.data(), values.data(), s.data(), false); ASSERT_EQ(secondary_cache->num_lookups(), num_lookups + 5); for (int i = 0; i < N; ++i) { ASSERT_OK(s[i]); ASSERT_EQ(values[i].ToString(), keys[i]); values[i].Reset(); } Destroy(options); } class CacheWithStats : public CacheWrapper { public: using CacheWrapper::CacheWrapper; static const char* kClassName() { return "CacheWithStats"; } const char* Name() const override { return kClassName(); } Status Insert(const Slice& key, Cache::ObjectPtr value, const CacheItemHelper* helper, size_t charge, Handle** handle = nullptr, Priority priority = Priority::LOW, const Slice& /*compressed*/ = Slice(), CompressionType /*type*/ = kNoCompression) override { insert_count_++; return target_->Insert(key, value, helper, charge, handle, priority); } Handle* Lookup(const Slice& key, const CacheItemHelper* helper, CreateContext* create_context, Priority priority, Statistics* stats = nullptr) override { lookup_count_++; return target_->Lookup(key, helper, create_context, priority, stats); } uint32_t GetInsertCount() { return insert_count_; } uint32_t GetLookupcount() { return lookup_count_; } void ResetCount() { insert_count_ = 0; lookup_count_ = 0; } private: uint32_t insert_count_ = 0; uint32_t lookup_count_ = 0; }; TEST_P(DBSecondaryCacheTest, LRUCacheDumpLoadBasic) { std::shared_ptr base_cache = NewCache(1024 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */); std::shared_ptr cache = std::make_shared(base_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); DestroyAndReopen(options); fault_fs_->SetFailGetUniqueId(true); Random rnd(301); const int N = 256; std::vector value; char buf[1000]; memset(buf, 'a', 1000); value.resize(N); for (int i = 0; i < N; i++) { // std::string p_v = rnd.RandomString(1000); std::string p_v(buf, 1000); value[i] = p_v; ASSERT_OK(Put(Key(i), p_v)); } ASSERT_OK(Flush()); Compact("a", "z"); // do th eread for all the key value pairs, so all the blocks should be in // cache uint32_t start_insert = cache->GetInsertCount(); uint32_t start_lookup = cache->GetLookupcount(); std::string v; for (int i = 0; i < N; i++) { v = Get(Key(i)); ASSERT_EQ(v, value[i]); } uint32_t dump_insert = cache->GetInsertCount() - start_insert; uint32_t dump_lookup = cache->GetLookupcount() - start_lookup; ASSERT_EQ(63, static_cast(dump_insert)); // the insert in the block cache ASSERT_EQ(256, static_cast(dump_lookup)); // the lookup in the block cache // We have enough blocks in the block cache CacheDumpOptions cd_options; cd_options.clock = fault_env_->GetSystemClock().get(); std::string dump_path = db_->GetName() + "/cache_dump"; std::unique_ptr dump_writer; Status s = NewToFileCacheDumpWriter(fault_fs_, FileOptions(), dump_path, &dump_writer); ASSERT_OK(s); std::unique_ptr cache_dumper; s = NewDefaultCacheDumper(cd_options, cache, std::move(dump_writer), &cache_dumper); ASSERT_OK(s); std::vector db_list; db_list.push_back(db_); s = cache_dumper->SetDumpFilter(db_list); ASSERT_OK(s); s = cache_dumper->DumpCacheEntriesToWriter(); ASSERT_OK(s); cache_dumper.reset(); // we have a new cache it is empty, then, before we do the Get, we do the // dumpload std::shared_ptr secondary_cache = std::make_shared(2048 * 1024, true); // This time with secondary cache base_cache = NewCache(1024 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); cache = std::make_shared(base_cache); table_options.block_cache = cache; table_options.block_size = 4 * 1024; options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); // start to load the data to new block cache start_insert = secondary_cache->num_inserts(); start_lookup = secondary_cache->num_lookups(); std::unique_ptr dump_reader; s = NewFromFileCacheDumpReader(fault_fs_, FileOptions(), dump_path, &dump_reader); ASSERT_OK(s); std::unique_ptr cache_loader; s = NewDefaultCacheDumpedLoader(cd_options, table_options, secondary_cache, std::move(dump_reader), &cache_loader); ASSERT_OK(s); s = cache_loader->RestoreCacheEntriesToSecondaryCache(); ASSERT_OK(s); uint32_t load_insert = secondary_cache->num_inserts() - start_insert; uint32_t load_lookup = secondary_cache->num_lookups() - start_lookup; // check the number we inserted ASSERT_EQ(64, static_cast(load_insert)); ASSERT_EQ(0, static_cast(load_lookup)); ASSERT_OK(s); Reopen(options); // After load, we do the Get again start_insert = secondary_cache->num_inserts(); start_lookup = secondary_cache->num_lookups(); uint32_t cache_insert = cache->GetInsertCount(); uint32_t cache_lookup = cache->GetLookupcount(); for (int i = 0; i < N; i++) { v = Get(Key(i)); ASSERT_EQ(v, value[i]); } uint32_t final_insert = secondary_cache->num_inserts() - start_insert; uint32_t final_lookup = secondary_cache->num_lookups() - start_lookup; // no insert to secondary cache ASSERT_EQ(0, static_cast(final_insert)); // lookup the secondary to get all blocks ASSERT_EQ(64, static_cast(final_lookup)); uint32_t block_insert = cache->GetInsertCount() - cache_insert; uint32_t block_lookup = cache->GetLookupcount() - cache_lookup; // Check the new block cache insert and lookup, should be no insert since all // blocks are from the secondary cache. ASSERT_EQ(0, static_cast(block_insert)); ASSERT_EQ(256, static_cast(block_lookup)); fault_fs_->SetFailGetUniqueId(false); Destroy(options); } TEST_P(DBSecondaryCacheTest, LRUCacheDumpLoadWithFilter) { std::shared_ptr base_cache = NewCache(1024 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */); std::shared_ptr cache = std::make_shared(base_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); std::string dbname1 = test::PerThreadDBPath("db_1"); ASSERT_OK(DestroyDB(dbname1, options)); DB* db1 = nullptr; ASSERT_OK(DB::Open(options, dbname1, &db1)); std::string dbname2 = test::PerThreadDBPath("db_2"); ASSERT_OK(DestroyDB(dbname2, options)); DB* db2 = nullptr; ASSERT_OK(DB::Open(options, dbname2, &db2)); fault_fs_->SetFailGetUniqueId(true); // write the KVs to db1 Random rnd(301); const int N = 256; std::vector value1; WriteOptions wo; char buf[1000]; memset(buf, 'a', 1000); value1.resize(N); for (int i = 0; i < N; i++) { std::string p_v(buf, 1000); value1[i] = p_v; ASSERT_OK(db1->Put(wo, Key(i), p_v)); } ASSERT_OK(db1->Flush(FlushOptions())); Slice bg("a"); Slice ed("b"); ASSERT_OK(db1->CompactRange(CompactRangeOptions(), &bg, &ed)); // Write the KVs to DB2 std::vector value2; memset(buf, 'b', 1000); value2.resize(N); for (int i = 0; i < N; i++) { std::string p_v(buf, 1000); value2[i] = p_v; ASSERT_OK(db2->Put(wo, Key(i), p_v)); } ASSERT_OK(db2->Flush(FlushOptions())); ASSERT_OK(db2->CompactRange(CompactRangeOptions(), &bg, &ed)); // do th eread for all the key value pairs, so all the blocks should be in // cache uint32_t start_insert = cache->GetInsertCount(); uint32_t start_lookup = cache->GetLookupcount(); ReadOptions ro; std::string v; for (int i = 0; i < N; i++) { ASSERT_OK(db1->Get(ro, Key(i), &v)); ASSERT_EQ(v, value1[i]); } for (int i = 0; i < N; i++) { ASSERT_OK(db2->Get(ro, Key(i), &v)); ASSERT_EQ(v, value2[i]); } uint32_t dump_insert = cache->GetInsertCount() - start_insert; uint32_t dump_lookup = cache->GetLookupcount() - start_lookup; ASSERT_EQ(128, static_cast(dump_insert)); // the insert in the block cache ASSERT_EQ(512, static_cast(dump_lookup)); // the lookup in the block cache // We have enough blocks in the block cache CacheDumpOptions cd_options; cd_options.clock = fault_env_->GetSystemClock().get(); std::string dump_path = db1->GetName() + "/cache_dump"; std::unique_ptr dump_writer; Status s = NewToFileCacheDumpWriter(fault_fs_, FileOptions(), dump_path, &dump_writer); ASSERT_OK(s); std::unique_ptr cache_dumper; s = NewDefaultCacheDumper(cd_options, cache, std::move(dump_writer), &cache_dumper); ASSERT_OK(s); std::vector db_list; db_list.push_back(db1); s = cache_dumper->SetDumpFilter(db_list); ASSERT_OK(s); s = cache_dumper->DumpCacheEntriesToWriter(); ASSERT_OK(s); cache_dumper.reset(); // we have a new cache it is empty, then, before we do the Get, we do the // dumpload std::shared_ptr secondary_cache = std::make_shared(2048 * 1024, true); // This time with secondary_cache base_cache = NewCache(1024 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); cache = std::make_shared(base_cache); table_options.block_cache = cache; table_options.block_size = 4 * 1024; options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); // Start the cache loading process start_insert = secondary_cache->num_inserts(); start_lookup = secondary_cache->num_lookups(); std::unique_ptr dump_reader; s = NewFromFileCacheDumpReader(fault_fs_, FileOptions(), dump_path, &dump_reader); ASSERT_OK(s); std::unique_ptr cache_loader; s = NewDefaultCacheDumpedLoader(cd_options, table_options, secondary_cache, std::move(dump_reader), &cache_loader); ASSERT_OK(s); s = cache_loader->RestoreCacheEntriesToSecondaryCache(); ASSERT_OK(s); uint32_t load_insert = secondary_cache->num_inserts() - start_insert; uint32_t load_lookup = secondary_cache->num_lookups() - start_lookup; // check the number we inserted ASSERT_EQ(64, static_cast(load_insert)); ASSERT_EQ(0, static_cast(load_lookup)); ASSERT_OK(s); ASSERT_OK(db1->Close()); delete db1; ASSERT_OK(DB::Open(options, dbname1, &db1)); // After load, we do the Get again. To validate the cache, we do not allow any // I/O, so we set the file system to false. IOStatus error_msg = IOStatus::IOError("Retryable IO Error"); fault_fs_->SetFilesystemActive(false, error_msg); start_insert = secondary_cache->num_inserts(); start_lookup = secondary_cache->num_lookups(); uint32_t cache_insert = cache->GetInsertCount(); uint32_t cache_lookup = cache->GetLookupcount(); for (int i = 0; i < N; i++) { ASSERT_OK(db1->Get(ro, Key(i), &v)); ASSERT_EQ(v, value1[i]); } uint32_t final_insert = secondary_cache->num_inserts() - start_insert; uint32_t final_lookup = secondary_cache->num_lookups() - start_lookup; // no insert to secondary cache ASSERT_EQ(0, static_cast(final_insert)); // lookup the secondary to get all blocks ASSERT_EQ(64, static_cast(final_lookup)); uint32_t block_insert = cache->GetInsertCount() - cache_insert; uint32_t block_lookup = cache->GetLookupcount() - cache_lookup; // Check the new block cache insert and lookup, should be no insert since all // blocks are from the secondary cache. ASSERT_EQ(0, static_cast(block_insert)); ASSERT_EQ(256, static_cast(block_lookup)); fault_fs_->SetFailGetUniqueId(false); fault_fs_->SetFilesystemActive(true); delete db1; delete db2; ASSERT_OK(DestroyDB(dbname1, options)); ASSERT_OK(DestroyDB(dbname2, options)); } // Test the option not to use the secondary cache in a certain DB. TEST_P(DBSecondaryCacheTest, TestSecondaryCacheOptionBasic) { std::shared_ptr secondary_cache( new TestSecondaryCache(2048 * 1024)); std::shared_ptr cache = NewCache(4 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); fault_fs_->SetFailGetUniqueId(true); options.lowest_used_cache_tier = CacheTier::kVolatileTier; // Set the file paranoid check, so after flush, the file will be read // all the blocks will be accessed. options.paranoid_file_checks = true; DestroyAndReopen(options); Random rnd(301); const int N = 6; for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1007); ASSERT_OK(Put(Key(i), p_v)); } ASSERT_OK(Flush()); for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1007); ASSERT_OK(Put(Key(i + 70), p_v)); } ASSERT_OK(Flush()); // Flush will trigger the paranoid check and read blocks. But only block cache // will be read. No operations for secondary cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); Compact("a", "z"); // Compaction will also insert and evict blocks, no operations to the block // cache. No operations for secondary cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); std::string v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // Check the data in first block. Cache miss, direclty read from SST file. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // Check the second block. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // block cache hit ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); v = Get(Key(70)); ASSERT_EQ(1007, v.size()); // Check the first block in the second SST file. Cache miss and trigger SST // file read. No operations for secondary cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); v = Get(Key(75)); ASSERT_EQ(1007, v.size()); // Check the second block in the second SST file. Cache miss and trigger SST // file read. No operations for secondary cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); Destroy(options); } // We disable the secondary cache in DBOptions at first. Close and reopen the DB // with new options, which set the lowest_used_cache_tier to // kNonVolatileBlockTier. So secondary cache will be used. TEST_P(DBSecondaryCacheTest, TestSecondaryCacheOptionChange) { if (IsHyperClock()) { ROCKSDB_GTEST_BYPASS("Test depends on LRUCache-specific behaviors"); return; } std::shared_ptr secondary_cache( new TestSecondaryCache(2048 * 1024)); std::shared_ptr cache = NewCache(4 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); fault_fs_->SetFailGetUniqueId(true); options.lowest_used_cache_tier = CacheTier::kVolatileTier; // Set the file paranoid check, so after flush, the file will be read // all the blocks will be accessed. options.paranoid_file_checks = true; DestroyAndReopen(options); Random rnd(301); const int N = 6; for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1007); ASSERT_OK(Put(Key(i), p_v)); } ASSERT_OK(Flush()); for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1007); ASSERT_OK(Put(Key(i + 70), p_v)); } ASSERT_OK(Flush()); // Flush will trigger the paranoid check and read blocks. But only block cache // will be read. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); Compact("a", "z"); // Compaction will also insert and evict blocks, no operations to the block // cache. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); std::string v = Get(Key(0)); ASSERT_EQ(1007, v.size()); // Check the data in first block. Cache miss, direclty read from SST file. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // Check the second block. ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); v = Get(Key(5)); ASSERT_EQ(1007, v.size()); // block cache hit ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); // Change the option to enable secondary cache after we Reopen the DB options.lowest_used_cache_tier = CacheTier::kNonVolatileBlockTier; Reopen(options); v = Get(Key(70)); ASSERT_EQ(1007, v.size()); // Enable the secondary cache, trigger lookup of the first block in second SST ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 1u); v = Get(Key(75)); ASSERT_EQ(1007, v.size()); // trigger lookup of the second block in second SST ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); Destroy(options); } // Two DB test. We create 2 DBs sharing the same block cache and secondary // cache. We diable the secondary cache option for DB2. TEST_P(DBSecondaryCacheTest, TestSecondaryCacheOptionTwoDB) { if (IsHyperClock()) { ROCKSDB_GTEST_BYPASS("Test depends on LRUCache-specific behaviors"); return; } std::shared_ptr secondary_cache( new TestSecondaryCache(2048 * 1024)); std::shared_ptr cache = NewCache(4 * 1024 /* capacity */, 0 /* num_shard_bits */, false /* strict_capacity_limit */, secondary_cache); BlockBasedTableOptions table_options; table_options.block_cache = cache; table_options.block_size = 4 * 1024; Options options = GetDefaultOptions(); options.create_if_missing = true; options.table_factory.reset(NewBlockBasedTableFactory(table_options)); options.env = fault_env_.get(); options.paranoid_file_checks = true; std::string dbname1 = test::PerThreadDBPath("db_t_1"); ASSERT_OK(DestroyDB(dbname1, options)); DB* db1 = nullptr; ASSERT_OK(DB::Open(options, dbname1, &db1)); std::string dbname2 = test::PerThreadDBPath("db_t_2"); ASSERT_OK(DestroyDB(dbname2, options)); DB* db2 = nullptr; Options options2 = options; options2.lowest_used_cache_tier = CacheTier::kVolatileTier; ASSERT_OK(DB::Open(options2, dbname2, &db2)); fault_fs_->SetFailGetUniqueId(true); WriteOptions wo; Random rnd(301); const int N = 6; for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1007); ASSERT_OK(db1->Put(wo, Key(i), p_v)); } ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 0u); ASSERT_OK(db1->Flush(FlushOptions())); ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); for (int i = 0; i < N; i++) { std::string p_v = rnd.RandomString(1007); ASSERT_OK(db2->Put(wo, Key(i), p_v)); } // No change in the secondary cache, since it is disabled in DB2 ASSERT_EQ(secondary_cache->num_inserts(), 0u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); ASSERT_OK(db2->Flush(FlushOptions())); ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); Slice bg("a"); Slice ed("b"); ASSERT_OK(db1->CompactRange(CompactRangeOptions(), &bg, &ed)); ASSERT_OK(db2->CompactRange(CompactRangeOptions(), &bg, &ed)); ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 2u); ReadOptions ro; std::string v; ASSERT_OK(db1->Get(ro, Key(0), &v)); ASSERT_EQ(1007, v.size()); // DB 1 has lookup block 1 and it is miss in block cache, trigger secondary // cache lookup ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 3u); ASSERT_OK(db1->Get(ro, Key(5), &v)); ASSERT_EQ(1007, v.size()); // DB 1 lookup the second block and it is miss in block cache, trigger // secondary cache lookup ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 4u); ASSERT_OK(db2->Get(ro, Key(0), &v)); ASSERT_EQ(1007, v.size()); // For db2, it is not enabled with secondary cache, so no search in the // secondary cache ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 4u); ASSERT_OK(db2->Get(ro, Key(5), &v)); ASSERT_EQ(1007, v.size()); // For db2, it is not enabled with secondary cache, so no search in the // secondary cache ASSERT_EQ(secondary_cache->num_inserts(), 1u); ASSERT_EQ(secondary_cache->num_lookups(), 4u); fault_fs_->SetFailGetUniqueId(false); fault_fs_->SetFilesystemActive(true); delete db1; delete db2; ASSERT_OK(DestroyDB(dbname1, options)); ASSERT_OK(DestroyDB(dbname2, options)); } } // namespace ROCKSDB_NAMESPACE int main(int argc, char** argv) { ROCKSDB_NAMESPACE::port::InstallStackTraceHandler(); ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }