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rocksdb/cache/lru_cache_test.cc
gitbw95 f241d082b6 Prevent double caching in the compressed secondary cache (#9747) 
Summary:
###  **Summary:**
When both LRU Cache and CompressedSecondaryCache are configured together, there possibly are some data blocks double cached.

**Changes include:**
1. Update IS_PROMOTED to IS_IN_SECONDARY_CACHE to prevent confusions.
2. This PR updates SecondaryCacheResultHandle and use IsErasedFromSecondaryCache to determine whether the handle is erased in the secondary cache. Then, the caller can determine whether to SetIsInSecondaryCache().
3. Rename LRUSecondaryCache to CompressedSecondaryCache.

Pull Request resolved: https://github.com/facebook/rocksdb/pull/9747

Test Plan:
**Test Scripts:**
1. Populate a DB. The on disk footprint is 482 MB. The data is set to be 50% compressible, so the total decompressed size is expected to be 964 MB.
./db_bench --benchmarks=fillrandom --num=10000000 -db=/db_bench_1

2. overwrite it to a stable state:
./db_bench --benchmarks=overwrite,stats --num=10000000 -use_existing_db -duration=10 --benchmark_write_rate_limit=2000000 -db=/db_bench_1

4. Run read tests with diffeernt cache setting:

T1:
./db_bench --benchmarks=seekrandom,stats --threads=16 --num=10000000 -use_existing_db -duration=120 --benchmark_write_rate_limit=52000000 -use_direct_reads --cache_size=520000000  --statistics -db=/db_bench_1

T2:
./db_bench --benchmarks=seekrandom,stats --threads=16 --num=10000000 -use_existing_db -duration=120 --benchmark_write_rate_limit=52000000 -use_direct_reads --cache_size=320000000 -compressed_secondary_cache_size=400000000 --statistics -use_compressed_secondary_cache -db=/db_bench_1

T3:
./db_bench --benchmarks=seekrandom,stats --threads=16 --num=10000000 -use_existing_db -duration=120 --benchmark_write_rate_limit=52000000 -use_direct_reads --cache_size=520000000 -compressed_secondary_cache_size=400000000 --statistics -use_compressed_secondary_cache -db=/db_bench_1

T4:
./db_bench --benchmarks=seekrandom,stats --threads=16 --num=10000000 -use_existing_db -duration=120 --benchmark_write_rate_limit=52000000 -use_direct_reads --cache_size=20000000 -compressed_secondary_cache_size=500000000 --statistics -use_compressed_secondary_cache -db=/db_bench_1

**Before this PR**
| Cache Size | Compressed Secondary Cache Size | Cache Hit Rate |
|------------|-------------------------------------|----------------|
|520 MB | 0 MB | 85.5% |
|320 MB | 400 MB | 96.2% |
|520 MB | 400 MB | 98.3% |
|20 MB | 500 MB | 98.8% |

**Before this PR**
| Cache Size | Compressed Secondary Cache Size | Cache Hit Rate |
|------------|-------------------------------------|----------------|
|520 MB | 0 MB | 85.5% |
|320 MB | 400 MB | 99.9% |
|520 MB | 400 MB | 99.9% |
|20 MB | 500 MB | 99.2% |

Reviewed By: anand1976

Differential Revision: D35117499

Pulled By: gitbw95

fbshipit-source-id: ea2657749fc13efebe91a8a1b56bc61d6a224a12
2022-04-11 13:28:33 -07:00

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// 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 <string>
#include <vector>
#include "cache/cache_key.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/testharness.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,
bool use_adaptive_mutex = kDefaultToAdaptiveMutex) {
DeleteCache();
cache_ = reinterpret_cast<LRUCacheShard*>(
port::cacheline_aligned_alloc(sizeof(LRUCacheShard)));
new (cache_) LRUCacheShard(
capacity, false /*strict_capcity_limit*/, high_pri_pool_ratio,
use_adaptive_mutex, kDontChargeCacheMetadata,
24 /*max_upper_hash_bits*/, nullptr /*secondary_cache*/);
}
void Insert(const std::string& key,
Cache::Priority priority = Cache::Priority::LOW) {
EXPECT_OK(cache_->Insert(key, 0 /*hash*/, nullptr /*value*/, 1 /*charge*/,
nullptr /*deleter*/, 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*/);
if (handle) {
cache_->Release(handle);
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<std::string> keys,
size_t num_high_pri_pool_keys = 0) {
LRUHandle* lru;
LRUHandle* lru_low_pri;
cache_->TEST_GetLRUList(&lru, &lru_low_pri);
LRUHandle* iter = lru;
bool in_high_pri_pool = false;
size_t high_pri_pool_keys = 0;
if (iter == lru_low_pri) {
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());
if (in_high_pri_pool) {
high_pri_pool_keys++;
}
if (iter == lru_low_pri) {
ASSERT_FALSE(in_high_pri_pool);
in_high_pri_pool = true;
}
}
ASSERT_EQ(lru, iter->next);
ASSERT_TRUE(in_high_pri_pool);
ASSERT_EQ(num_high_pri_pool_keys, high_pri_pool_keys);
}
private:
LRUCacheShard* cache_ = nullptr;
};
TEST_F(LRUCacheTest, BasicLRU) {
NewCache(5);
for (char ch = 'a'; ch <= 'e'; ch++) {
Insert(ch);
}
ValidateLRUList({"a", "b", "c", "d", "e"});
for (char ch = 'x'; ch <= 'z'; ch++) {
Insert(ch);
}
ValidateLRUList({"d", "e", "x", "y", "z"});
ASSERT_FALSE(Lookup("b"));
ValidateLRUList({"d", "e", "x", "y", "z"});
ASSERT_TRUE(Lookup("e"));
ValidateLRUList({"d", "x", "y", "z", "e"});
ASSERT_TRUE(Lookup("z"));
ValidateLRUList({"d", "x", "y", "e", "z"});
Erase("x");
ValidateLRUList({"d", "y", "e", "z"});
ASSERT_TRUE(Lookup("d"));
ValidateLRUList({"y", "e", "z", "d"});
Insert("u");
ValidateLRUList({"y", "e", "z", "d", "u"});
Insert("v");
ValidateLRUList({"e", "z", "d", "u", "v"});
}
TEST_F(LRUCacheTest, MidpointInsertion) {
// Allocate 2 cache entries to high-pri pool.
NewCache(5, 0.45);
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);
// 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);
ASSERT_TRUE(Lookup("d"));
ValidateLRUList({"b", "c", "x", "y", "d"}, 2);
// High-pri entries will be inserted to the tail of full list.
Insert("z", Cache::Priority::HIGH);
ValidateLRUList({"c", "x", "y", "d", "z"}, 2);
}
TEST_F(LRUCacheTest, EntriesWithPriority) {
// Allocate 2 cache entries to high-pri pool.
NewCache(5, 0.45);
Insert("a", Cache::Priority::LOW);
Insert("b", Cache::Priority::LOW);
Insert("c", Cache::Priority::LOW);
ValidateLRUList({"a", "b", "c"}, 0);
// Low-pri entries can take high-pri pool capacity if available
Insert("u", Cache::Priority::LOW);
Insert("v", Cache::Priority::LOW);
ValidateLRUList({"a", "b", "c", "u", "v"}, 0);
Insert("X", Cache::Priority::HIGH);
Insert("Y", Cache::Priority::HIGH);
ValidateLRUList({"c", "u", "v", "X", "Y"}, 2);
// High-pri entries can overflow to low-pri pool.
Insert("Z", Cache::Priority::HIGH);
ValidateLRUList({"u", "v", "X", "Y", "Z"}, 2);
// Low-pri entries will be inserted to head of low-pri pool.
Insert("a", Cache::Priority::LOW);
ValidateLRUList({"v", "X", "a", "Y", "Z"}, 2);
// Low-pri entries will be inserted to head of high-pri pool after lookup.
ASSERT_TRUE(Lookup("v"));
ValidateLRUList({"X", "a", "Y", "Z", "v"}, 2);
// High-pri entries will be inserted to the head of the list after lookup.
ASSERT_TRUE(Lookup("X"));
ValidateLRUList({"a", "Y", "Z", "v", "X"}, 2);
ASSERT_TRUE(Lookup("Z"));
ValidateLRUList({"a", "Y", "v", "X", "Z"}, 2);
Erase("Y");
ValidateLRUList({"a", "v", "X", "Z"}, 2);
Erase("X");
ValidateLRUList({"a", "v", "Z"}, 1);
Insert("d", Cache::Priority::LOW);
Insert("e", Cache::Priority::LOW);
ValidateLRUList({"a", "v", "d", "e", "Z"}, 1);
Insert("f", Cache::Priority::LOW);
Insert("g", Cache::Priority::LOW);
ValidateLRUList({"d", "e", "f", "g", "Z"}, 1);
ASSERT_TRUE(Lookup("d"));
ValidateLRUList({"e", "f", "g", "Z", "d"}, 2);
}
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<std::string, ResultType>;
explicit TestSecondaryCache(size_t capacity)
: num_inserts_(0), num_lookups_(0), inject_failure_(false) {
cache_ = NewLRUCache(capacity, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
}
~TestSecondaryCache() override { cache_.reset(); }
const char* Name() const override { return "TestSecondaryCache"; }
void InjectFailure() { inject_failure_ = true; }
void ResetInjectFailure() { inject_failure_ = false; }
void SetDbSessionId(const std::string& db_session_id) {
// NOTE: we assume the file is smaller than kMaxFileSizeStandardEncoding
// for this to work, but that's safe in a test.
auto base = OffsetableCacheKey("unknown", db_session_id, 1, 1);
ckey_prefix_ = base.CommonPrefixSlice().ToString();
}
Status Insert(const Slice& key, void* value,
const Cache::CacheItemHelper* helper) override {
if (inject_failure_) {
return Status::Corruption("Insertion Data Corrupted");
}
EXPECT_TRUE(IsDbSessionLowerAsKeyPrefix(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,
[](const Slice& /*key*/, void* val) -> void {
delete[] static_cast<char*>(val);
});
}
std::unique_ptr<SecondaryCacheResultHandle> Lookup(
const Slice& key, const Cache::CreateCallback& create_cb, bool /*wait*/,
bool& is_in_sec_cache) override {
std::string key_str = key.ToString();
TEST_SYNC_POINT_CALLBACK("TestSecondaryCache::Lookup", &key_str);
std::unique_ptr<SecondaryCacheResultHandle> secondary_handle;
is_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;
}
Cache::Handle* handle = cache_->Lookup(key);
num_lookups_++;
if (handle) {
void* value = nullptr;
size_t charge = 0;
Status s;
if (type != ResultType::DEFER_AND_FAIL) {
char* ptr = (char*)cache_->Value(handle);
size_t size = DecodeFixed64(ptr);
ptr += sizeof(uint64_t);
s = create_cb(ptr, size, &value, &charge);
}
if (s.ok()) {
secondary_handle.reset(new TestSecondaryCacheResultHandle(
cache_.get(), handle, value, charge, type));
is_in_sec_cache = true;
} else {
cache_->Release(handle);
}
}
return secondary_handle;
}
void Erase(const Slice& /*key*/) override {}
void WaitAll(std::vector<SecondaryCacheResultHandle*> handles) override {
for (SecondaryCacheResultHandle* handle : handles) {
TestSecondaryCacheResultHandle* sec_handle =
static_cast<TestSecondaryCacheResultHandle*>(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_; }
bool IsDbSessionLowerAsKeyPrefix(const Slice& key) {
return key.starts_with(ckey_prefix_);
}
private:
class TestSecondaryCacheResultHandle : public SecondaryCacheResultHandle {
public:
TestSecondaryCacheResultHandle(Cache* cache, Cache::Handle* handle,
void* 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 {}
void* 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_;
void* value_;
size_t size_;
bool is_ready_;
};
std::shared_ptr<Cache> cache_;
uint32_t num_inserts_;
uint32_t num_lookups_;
bool inject_failure_;
std::string ckey_prefix_;
ResultMap result_map_;
};
class DBSecondaryCacheTest : public DBTestBase {
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<FaultInjectionTestFS> fault_fs_;
std::unique_ptr<Env> fault_env_;
};
class LRUCacheSecondaryCacheTest : public LRUCacheTest {
public:
LRUCacheSecondaryCacheTest() : fail_create_(false) {}
~LRUCacheSecondaryCacheTest() {}
protected:
class TestItem {
public:
TestItem(const char* buf, size_t size) : buf_(new char[size]), size_(size) {
memcpy(buf_.get(), buf, size);
}
~TestItem() {}
char* Buf() { return buf_.get(); }
size_t Size() { return size_; }
std::string ToString() { return std::string(Buf(), Size()); }
private:
std::unique_ptr<char[]> buf_;
size_t size_;
};
static size_t SizeCallback(void* obj) {
return reinterpret_cast<TestItem*>(obj)->Size();
}
static Status SaveToCallback(void* from_obj, size_t from_offset,
size_t length, void* out) {
TestItem* item = reinterpret_cast<TestItem*>(from_obj);
char* buf = item->Buf();
EXPECT_EQ(length, item->Size());
EXPECT_EQ(from_offset, 0);
memcpy(out, buf, length);
return Status::OK();
}
static void DeletionCallback(const Slice& /*key*/, void* obj) {
delete reinterpret_cast<TestItem*>(obj);
}
static Cache::CacheItemHelper helper_;
static Status SaveToCallbackFail(void* /*obj*/, size_t /*offset*/,
size_t /*size*/, void* /*out*/) {
return Status::NotSupported();
}
static Cache::CacheItemHelper helper_fail_;
Cache::CreateCallback test_item_creator = [&](const void* buf, size_t size,
void** out_obj,
size_t* charge) -> Status {
if (fail_create_) {
return Status::NotSupported();
}
*out_obj = reinterpret_cast<void*>(new TestItem((char*)buf, size));
*charge = size;
return Status::OK();
};
void SetFailCreate(bool fail) { fail_create_ = fail; }
private:
bool fail_create_;
};
Cache::CacheItemHelper LRUCacheSecondaryCacheTest::helper_(
LRUCacheSecondaryCacheTest::SizeCallback,
LRUCacheSecondaryCacheTest::SaveToCallback,
LRUCacheSecondaryCacheTest::DeletionCallback);
Cache::CacheItemHelper LRUCacheSecondaryCacheTest::helper_fail_(
LRUCacheSecondaryCacheTest::SizeCallback,
LRUCacheSecondaryCacheTest::SaveToCallbackFail,
LRUCacheSecondaryCacheTest::DeletionCallback);
TEST_F(LRUCacheSecondaryCacheTest, BasicTest) {
LRUCacheOptions opts(1024, 0, false, 0.5, nullptr, kDefaultToAdaptiveMutex,
kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache =
std::make_shared<TestSecondaryCache>(2048);
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
std::shared_ptr<Statistics> stats = CreateDBStatistics();
Random rnd(301);
std::string str1 = rnd.RandomString(1020);
TestItem* item1 = new TestItem(str1.data(), str1.length());
ASSERT_OK(cache->Insert("k1", item1, &LRUCacheSecondaryCacheTest::helper_,
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", item2, &LRUCacheSecondaryCacheTest::helper_,
str2.length()));
get_perf_context()->Reset();
Cache::Handle* handle;
handle =
cache->Lookup("k2", &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, true, stats.get());
ASSERT_NE(handle, nullptr);
cache->Release(handle);
// This lookup should promote k1 and demote k2
handle =
cache->Lookup("k1", &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, true, stats.get());
ASSERT_NE(handle, nullptr);
cache->Release(handle);
ASSERT_EQ(secondary_cache->num_inserts(), 2u);
ASSERT_EQ(secondary_cache->num_lookups(), 1u);
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_F(LRUCacheSecondaryCacheTest, BasicFailTest) {
LRUCacheOptions opts(1024, 0, false, 0.5, nullptr, kDefaultToAdaptiveMutex,
kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache =
std::make_shared<TestSecondaryCache>(2048);
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
Random rnd(301);
std::string str1 = rnd.RandomString(1020);
auto item1 = std::make_unique<TestItem>(str1.data(), str1.length());
ASSERT_TRUE(cache->Insert("k1", item1.get(), nullptr, str1.length())
.IsInvalidArgument());
ASSERT_OK(cache->Insert("k1", item1.get(),
&LRUCacheSecondaryCacheTest::helper_, str1.length()));
item1.release(); // Appease clang-analyze "potential memory leak"
Cache::Handle* handle;
handle = cache->Lookup("k2", nullptr, test_item_creator, Cache::Priority::LOW,
true);
ASSERT_EQ(handle, nullptr);
handle = cache->Lookup("k2", &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, false);
ASSERT_EQ(handle, nullptr);
cache.reset();
secondary_cache.reset();
}
TEST_F(LRUCacheSecondaryCacheTest, SaveFailTest) {
LRUCacheOptions opts(1024, 0, false, 0.5, nullptr, kDefaultToAdaptiveMutex,
kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache =
std::make_shared<TestSecondaryCache>(2048);
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
Random rnd(301);
std::string str1 = rnd.RandomString(1020);
TestItem* item1 = new TestItem(str1.data(), str1.length());
ASSERT_OK(cache->Insert(
"k1", item1, &LRUCacheSecondaryCacheTest::helper_fail_, 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", item2, &LRUCacheSecondaryCacheTest::helper_fail_, str2.length()));
Cache::Handle* handle;
handle = cache->Lookup("k2", &LRUCacheSecondaryCacheTest::helper_fail_,
test_item_creator, Cache::Priority::LOW, true);
ASSERT_NE(handle, nullptr);
cache->Release(handle);
// This lookup should fail, since k1 demotion would have failed
handle = cache->Lookup("k1", &LRUCacheSecondaryCacheTest::helper_fail_,
test_item_creator, Cache::Priority::LOW, true);
ASSERT_EQ(handle, nullptr);
// Since k1 didn't get promoted, k2 should still be in cache
handle = cache->Lookup("k2", &LRUCacheSecondaryCacheTest::helper_fail_,
test_item_creator, Cache::Priority::LOW, true);
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_F(LRUCacheSecondaryCacheTest, CreateFailTest) {
LRUCacheOptions opts(1024, 0, false, 0.5, nullptr, kDefaultToAdaptiveMutex,
kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache =
std::make_shared<TestSecondaryCache>(2048);
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
Random rnd(301);
std::string str1 = rnd.RandomString(1020);
TestItem* item1 = new TestItem(str1.data(), str1.length());
ASSERT_OK(cache->Insert("k1", item1, &LRUCacheSecondaryCacheTest::helper_,
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", item2, &LRUCacheSecondaryCacheTest::helper_,
str2.length()));
Cache::Handle* handle;
SetFailCreate(true);
handle = cache->Lookup("k2", &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, true);
ASSERT_NE(handle, nullptr);
cache->Release(handle);
// This lookup should fail, since k1 creation would have failed
handle = cache->Lookup("k1", &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, true);
ASSERT_EQ(handle, nullptr);
// Since k1 didn't get promoted, k2 should still be in cache
handle = cache->Lookup("k2", &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, true);
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_F(LRUCacheSecondaryCacheTest, FullCapacityTest) {
LRUCacheOptions opts(1024, 0, /*_strict_capacity_limit=*/true, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache =
std::make_shared<TestSecondaryCache>(2048);
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
Random rnd(301);
std::string str1 = rnd.RandomString(1020);
TestItem* item1 = new TestItem(str1.data(), str1.length());
ASSERT_OK(cache->Insert("k1", item1, &LRUCacheSecondaryCacheTest::helper_,
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", item2, &LRUCacheSecondaryCacheTest::helper_,
str2.length()));
Cache::Handle* handle;
handle = cache->Lookup("k2", &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, true);
ASSERT_NE(handle, nullptr);
// k1 promotion should fail due to the block cache being at capacity,
// but the lookup should still succeed
Cache::Handle* handle2;
handle2 = cache->Lookup("k1", &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, true);
ASSERT_NE(handle2, nullptr);
// Since k1 didn't get inserted, k2 should still be in cache
cache->Release(handle);
cache->Release(handle2);
handle = cache->Lookup("k2", &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, true);
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();
}
// 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_F(DBSecondaryCacheTest, TestSecondaryCacheCorrectness1) {
LRUCacheOptions opts(4 * 1024, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache(
new TestSecondaryCache(2048 * 1024));
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
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);
std::string session_id;
ASSERT_OK(db_->GetDbSessionId(session_id));
secondary_cache->SetDbSessionId(session_id);
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_F(DBSecondaryCacheTest, TestSecondaryCacheCorrectness2) {
LRUCacheOptions opts(6100, 0, false, 0.5, nullptr, kDefaultToAdaptiveMutex,
kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache(
new TestSecondaryCache(2048 * 1024));
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
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);
std::string session_id;
ASSERT_OK(db_->GetDbSessionId(session_id));
secondary_cache->SetDbSessionId(session_id);
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_F(DBSecondaryCacheTest, NoSecondaryCacheInsertion) {
LRUCacheOptions opts(1024 * 1024, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache(
new TestSecondaryCache(2048 * 1024));
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
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);
std::string session_id;
ASSERT_OK(db_->GetDbSessionId(session_id));
secondary_cache->SetDbSessionId(session_id);
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_F(DBSecondaryCacheTest, SecondaryCacheIntensiveTesting) {
LRUCacheOptions opts(8 * 1024, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache(
new TestSecondaryCache(2048 * 1024));
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
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);
std::string session_id;
ASSERT_OK(db_->GetDbSessionId(session_id));
secondary_cache->SetDbSessionId(session_id);
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_F(DBSecondaryCacheTest, SecondaryCacheFailureTest) {
LRUCacheOptions opts(4 * 1024, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache(
new TestSecondaryCache(2048 * 1024));
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
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);
std::string session_id;
ASSERT_OK(db_->GetDbSessionId(session_id));
secondary_cache->SetDbSessionId(session_id);
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_F(LRUCacheSecondaryCacheTest, BasicWaitAllTest) {
LRUCacheOptions opts(1024, 2, false, 0.5, nullptr, kDefaultToAdaptiveMutex,
kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache =
std::make_shared<TestSecondaryCache>(32 * 1024);
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
const int num_keys = 32;
Random rnd(301);
std::vector<std::string> 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("k" + std::to_string(i), item,
&LRUCacheSecondaryCacheTest::helper_,
str.length()));
}
// Force all entries to be evicted to the secondary cache
cache->SetCapacity(0);
ASSERT_EQ(secondary_cache->num_inserts(), 32u);
cache->SetCapacity(32 * 1024);
secondary_cache->SetResultMap(
{{"k3", TestSecondaryCache::ResultType::DEFER},
{"k4", TestSecondaryCache::ResultType::DEFER_AND_FAIL},
{"k5", TestSecondaryCache::ResultType::FAIL}});
std::vector<Cache::Handle*> results;
for (int i = 0; i < 6; ++i) {
results.emplace_back(cache->Lookup(
"k" + std::to_string(i), &LRUCacheSecondaryCacheTest::helper_,
test_item_creator, Cache::Priority::LOW, false));
}
cache->WaitAll(results);
for (int i = 0; i < 6; ++i) {
if (i == 4) {
ASSERT_EQ(cache->Value(results[i]), nullptr);
} else if (i == 5) {
ASSERT_EQ(results[i], nullptr);
continue;
} else {
TestItem* item = static_cast<TestItem*>(cache->Value(results[i]));
ASSERT_EQ(item->ToString(), values[i]);
}
cache->Release(results[i]);
}
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_F(DBSecondaryCacheTest, TestSecondaryCacheMultiGet) {
LRUCacheOptions opts(1 << 20, 0, false, 0.5, nullptr, kDefaultToAdaptiveMutex,
kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache(
new TestSecondaryCache(2048 * 1024));
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
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<std::string> 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<std::string> cache_keys;
ROCKSDB_NAMESPACE::SyncPoint::GetInstance()->SetCallBack(
"TestSecondaryCache::Lookup", [&cache_keys](void* key) -> void {
cache_keys.emplace_back(*(static_cast<std::string*>(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<std::string> mget_keys(
{Key(0), Key(1), Key(2), Key(3), Key(4), Key(5), Key(6), Key(7)});
std::vector<PinnableSlice> values(mget_keys.size());
std::vector<Status> s(keys.size());
std::vector<Slice> 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 LRUCacheWithStat : public LRUCache {
public:
LRUCacheWithStat(
size_t _capacity, int _num_shard_bits, bool _strict_capacity_limit,
double _high_pri_pool_ratio,
std::shared_ptr<MemoryAllocator> _memory_allocator = nullptr,
bool _use_adaptive_mutex = kDefaultToAdaptiveMutex,
CacheMetadataChargePolicy _metadata_charge_policy =
kDontChargeCacheMetadata,
const std::shared_ptr<SecondaryCache>& _secondary_cache = nullptr)
: LRUCache(_capacity, _num_shard_bits, _strict_capacity_limit,
_high_pri_pool_ratio, _memory_allocator, _use_adaptive_mutex,
_metadata_charge_policy, _secondary_cache) {
insert_count_ = 0;
lookup_count_ = 0;
}
~LRUCacheWithStat() {}
Status Insert(const Slice& key, void* value, size_t charge, DeleterFn deleter,
Handle** handle, Priority priority) override {
insert_count_++;
return LRUCache::Insert(key, value, charge, deleter, handle, priority);
}
Status Insert(const Slice& key, void* value, const CacheItemHelper* helper,
size_t chargge, Handle** handle = nullptr,
Priority priority = Priority::LOW) override {
insert_count_++;
return LRUCache::Insert(key, value, helper, chargge, handle, priority);
}
Handle* Lookup(const Slice& key, Statistics* stats) override {
lookup_count_++;
return LRUCache::Lookup(key, stats);
}
Handle* Lookup(const Slice& key, const CacheItemHelper* helper,
const CreateCallback& create_cb, Priority priority, bool wait,
Statistics* stats = nullptr) override {
lookup_count_++;
return LRUCache::Lookup(key, helper, create_cb, priority, wait, 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_;
uint32_t lookup_count_;
};
#ifndef ROCKSDB_LITE
TEST_F(DBSecondaryCacheTest, LRUCacheDumpLoadBasic) {
LRUCacheOptions cache_opts(1024 * 1024, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
LRUCacheWithStat* tmp_cache = new LRUCacheWithStat(
cache_opts.capacity, cache_opts.num_shard_bits,
cache_opts.strict_capacity_limit, cache_opts.high_pri_pool_ratio,
cache_opts.memory_allocator, cache_opts.use_adaptive_mutex,
cache_opts.metadata_charge_policy, cache_opts.secondary_cache);
std::shared_ptr<Cache> cache(tmp_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<std::string> 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 = tmp_cache->GetInsertCount();
uint32_t start_lookup = tmp_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 = tmp_cache->GetInsertCount() - start_insert;
uint32_t dump_lookup = tmp_cache->GetLookupcount() - start_lookup;
ASSERT_EQ(63,
static_cast<int>(dump_insert)); // the insert in the block cache
ASSERT_EQ(256,
static_cast<int>(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<CacheDumpWriter> dump_writer;
Status s = NewToFileCacheDumpWriter(fault_fs_, FileOptions(), dump_path,
&dump_writer);
ASSERT_OK(s);
std::unique_ptr<CacheDumper> cache_dumper;
s = NewDefaultCacheDumper(cd_options, cache, std::move(dump_writer),
&cache_dumper);
ASSERT_OK(s);
std::vector<DB*> 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<TestSecondaryCache> secondary_cache =
std::make_shared<TestSecondaryCache>(2048 * 1024);
cache_opts.secondary_cache = secondary_cache;
tmp_cache = new LRUCacheWithStat(
cache_opts.capacity, cache_opts.num_shard_bits,
cache_opts.strict_capacity_limit, cache_opts.high_pri_pool_ratio,
cache_opts.memory_allocator, cache_opts.use_adaptive_mutex,
cache_opts.metadata_charge_policy, cache_opts.secondary_cache);
std::shared_ptr<Cache> cache_new(tmp_cache);
table_options.block_cache = cache_new;
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<CacheDumpReader> dump_reader;
s = NewFromFileCacheDumpReader(fault_fs_, FileOptions(), dump_path,
&dump_reader);
ASSERT_OK(s);
std::unique_ptr<CacheDumpedLoader> 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<int>(load_insert));
ASSERT_EQ(0, static_cast<int>(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 = tmp_cache->GetInsertCount();
uint32_t cache_lookup = tmp_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<int>(final_insert));
// lookup the secondary to get all blocks
ASSERT_EQ(64, static_cast<int>(final_lookup));
uint32_t block_insert = tmp_cache->GetInsertCount() - cache_insert;
uint32_t block_lookup = tmp_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<int>(block_insert));
ASSERT_EQ(256, static_cast<int>(block_lookup));
fault_fs_->SetFailGetUniqueId(false);
Destroy(options);
}
TEST_F(DBSecondaryCacheTest, LRUCacheDumpLoadWithFilter) {
LRUCacheOptions cache_opts(1024 * 1024, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
LRUCacheWithStat* tmp_cache = new LRUCacheWithStat(
cache_opts.capacity, cache_opts.num_shard_bits,
cache_opts.strict_capacity_limit, cache_opts.high_pri_pool_ratio,
cache_opts.memory_allocator, cache_opts.use_adaptive_mutex,
cache_opts.metadata_charge_policy, cache_opts.secondary_cache);
std::shared_ptr<Cache> cache(tmp_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<std::string> 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<std::string> 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 = tmp_cache->GetInsertCount();
uint32_t start_lookup = tmp_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 = tmp_cache->GetInsertCount() - start_insert;
uint32_t dump_lookup = tmp_cache->GetLookupcount() - start_lookup;
ASSERT_EQ(128,
static_cast<int>(dump_insert)); // the insert in the block cache
ASSERT_EQ(512,
static_cast<int>(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<CacheDumpWriter> dump_writer;
Status s = NewToFileCacheDumpWriter(fault_fs_, FileOptions(), dump_path,
&dump_writer);
ASSERT_OK(s);
std::unique_ptr<CacheDumper> cache_dumper;
s = NewDefaultCacheDumper(cd_options, cache, std::move(dump_writer),
&cache_dumper);
ASSERT_OK(s);
std::vector<DB*> 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<TestSecondaryCache> secondary_cache =
std::make_shared<TestSecondaryCache>(2048 * 1024);
cache_opts.secondary_cache = secondary_cache;
tmp_cache = new LRUCacheWithStat(
cache_opts.capacity, cache_opts.num_shard_bits,
cache_opts.strict_capacity_limit, cache_opts.high_pri_pool_ratio,
cache_opts.memory_allocator, cache_opts.use_adaptive_mutex,
cache_opts.metadata_charge_policy, cache_opts.secondary_cache);
std::shared_ptr<Cache> cache_new(tmp_cache);
table_options.block_cache = cache_new;
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<CacheDumpReader> dump_reader;
s = NewFromFileCacheDumpReader(fault_fs_, FileOptions(), dump_path,
&dump_reader);
ASSERT_OK(s);
std::unique_ptr<CacheDumpedLoader> 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<int>(load_insert));
ASSERT_EQ(0, static_cast<int>(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 = tmp_cache->GetInsertCount();
uint32_t cache_lookup = tmp_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<int>(final_insert));
// lookup the secondary to get all blocks
ASSERT_EQ(64, static_cast<int>(final_lookup));
uint32_t block_insert = tmp_cache->GetInsertCount() - cache_insert;
uint32_t block_lookup = tmp_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<int>(block_insert));
ASSERT_EQ(256, static_cast<int>(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_F(DBSecondaryCacheTest, TestSecondaryCacheOptionBasic) {
LRUCacheOptions opts(4 * 1024, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache(
new TestSecondaryCache(2048 * 1024));
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
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);
std::string session_id;
ASSERT_OK(db_->GetDbSessionId(session_id));
secondary_cache->SetDbSessionId(session_id);
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_F(DBSecondaryCacheTest, TestSecondaryCacheOptionChange) {
LRUCacheOptions opts(4 * 1024, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache(
new TestSecondaryCache(2048 * 1024));
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
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);
std::string session_id;
ASSERT_OK(db_->GetDbSessionId(session_id));
secondary_cache->SetDbSessionId(session_id);
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_F(DBSecondaryCacheTest, TestSecondaryCacheOptionTwoDB) {
LRUCacheOptions opts(4 * 1024, 0, false, 0.5, nullptr,
kDefaultToAdaptiveMutex, kDontChargeCacheMetadata);
std::shared_ptr<TestSecondaryCache> secondary_cache(
new TestSecondaryCache(2048 * 1024));
opts.secondary_cache = secondary_cache;
std::shared_ptr<Cache> cache = NewLRUCache(opts);
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);
// Set the file paranoid check, so after flush, the file will be read
// all the blocks will be accessed.
std::string session_id;
ASSERT_OK(db1->GetDbSessionId(session_id));
secondary_cache->SetDbSessionId(session_id);
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));
}
#endif // ROCKSDB_LITE
} // namespace ROCKSDB_NAMESPACE
int main(int argc, char** argv) {
::testing::InitGoogleTest(&argc, argv);
return RUN_ALL_TESTS();
}
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