rocksdb/cache/secondary_cache_adapter.cc

296 lines
11 KiB
C++

// Copyright (c) Meta Platforms, Inc. and affiliates.
// 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/secondary_cache_adapter.h"
#include "monitoring/perf_context_imp.h"
namespace ROCKSDB_NAMESPACE {
namespace {
// A distinct pointer value for marking "dummy" cache entries
struct Dummy {
char val[7] = "kDummy";
};
const Dummy kDummy{};
Cache::ObjectPtr const kDummyObj = const_cast<Dummy*>(&kDummy);
} // namespace
CacheWithSecondaryAdapter::CacheWithSecondaryAdapter(
std::shared_ptr<Cache> target,
std::shared_ptr<SecondaryCache> secondary_cache)
: CacheWrapper(std::move(target)),
secondary_cache_(std::move(secondary_cache)) {
target_->SetEvictionCallback([this](const Slice& key, Handle* handle) {
return EvictionHandler(key, handle);
});
}
CacheWithSecondaryAdapter::~CacheWithSecondaryAdapter() {
// `*this` will be destroyed before `*target_`, so we have to prevent
// use after free
target_->SetEvictionCallback({});
}
bool CacheWithSecondaryAdapter::EvictionHandler(const Slice& key,
Handle* handle) {
auto helper = GetCacheItemHelper(handle);
if (helper->IsSecondaryCacheCompatible()) {
auto obj = target_->Value(handle);
// Ignore dummy entry
if (obj != kDummyObj) {
// Spill into secondary cache.
secondary_cache_->Insert(key, obj, helper).PermitUncheckedError();
}
}
// Never takes ownership of obj
return false;
}
bool CacheWithSecondaryAdapter::ProcessDummyResult(Cache::Handle** handle,
bool erase) {
if (*handle && target_->Value(*handle) == kDummyObj) {
target_->Release(*handle, erase);
*handle = nullptr;
return true;
} else {
return false;
}
}
void CacheWithSecondaryAdapter::CleanupCacheObject(
ObjectPtr obj, const CacheItemHelper* helper) {
if (helper->del_cb) {
helper->del_cb(obj, memory_allocator());
}
}
Cache::Handle* CacheWithSecondaryAdapter::Promote(
std::unique_ptr<SecondaryCacheResultHandle>&& secondary_handle,
const Slice& key, const CacheItemHelper* helper, Priority priority,
Statistics* stats, bool found_dummy_entry, bool kept_in_sec_cache) {
assert(secondary_handle->IsReady());
ObjectPtr obj = secondary_handle->Value();
if (!obj) {
// Nothing found.
return nullptr;
}
// Found something.
switch (helper->role) {
case CacheEntryRole::kFilterBlock:
RecordTick(stats, SECONDARY_CACHE_FILTER_HITS);
break;
case CacheEntryRole::kIndexBlock:
RecordTick(stats, SECONDARY_CACHE_INDEX_HITS);
break;
case CacheEntryRole::kDataBlock:
RecordTick(stats, SECONDARY_CACHE_DATA_HITS);
break;
default:
break;
}
PERF_COUNTER_ADD(secondary_cache_hit_count, 1);
RecordTick(stats, SECONDARY_CACHE_HITS);
// Note: SecondaryCache::Size() is really charge (from the CreateCallback)
size_t charge = secondary_handle->Size();
Handle* result = nullptr;
// Insert into primary cache, possibly as a standalone+dummy entries.
if (secondary_cache_->SupportForceErase() && !found_dummy_entry) {
// Create standalone and insert dummy
// Allow standalone to be created even if cache is full, to avoid
// reading the entry from storage.
result =
CreateStandalone(key, obj, helper, charge, /*allow_uncharged*/ true);
assert(result);
PERF_COUNTER_ADD(block_cache_standalone_handle_count, 1);
// Insert dummy to record recent use
// TODO: try to avoid case where inserting this dummy could overwrite a
// regular entry
Status s = Insert(key, kDummyObj, &kNoopCacheItemHelper, /*charge=*/0,
/*handle=*/nullptr, priority);
s.PermitUncheckedError();
// Nothing to do or clean up on dummy insertion failure
} else {
// Insert regular entry into primary cache.
// Don't allow it to spill into secondary cache again if it was kept there.
Status s = Insert(
key, obj, kept_in_sec_cache ? helper->without_secondary_compat : helper,
charge, &result, priority);
if (s.ok()) {
assert(result);
PERF_COUNTER_ADD(block_cache_real_handle_count, 1);
} else {
// Create standalone result instead, even if cache is full, to avoid
// reading the entry from storage.
result =
CreateStandalone(key, obj, helper, charge, /*allow_uncharged*/ true);
assert(result);
PERF_COUNTER_ADD(block_cache_standalone_handle_count, 1);
}
}
return result;
}
Cache::Handle* CacheWithSecondaryAdapter::Lookup(const Slice& key,
const CacheItemHelper* helper,
CreateContext* create_context,
Priority priority,
Statistics* stats) {
// NOTE: we could just StartAsyncLookup() and Wait(), but this should be a bit
// more efficient
Handle* result =
target_->Lookup(key, helper, create_context, priority, stats);
bool secondary_compatible = helper && helper->IsSecondaryCacheCompatible();
bool found_dummy_entry =
ProcessDummyResult(&result, /*erase=*/secondary_compatible);
if (!result && secondary_compatible) {
// Try our secondary cache
bool kept_in_sec_cache = false;
std::unique_ptr<SecondaryCacheResultHandle> secondary_handle =
secondary_cache_->Lookup(key, helper, create_context, /*wait*/ true,
found_dummy_entry, /*out*/ kept_in_sec_cache);
if (secondary_handle) {
result = Promote(std::move(secondary_handle), key, helper, priority,
stats, found_dummy_entry, kept_in_sec_cache);
}
}
return result;
}
Cache::ObjectPtr CacheWithSecondaryAdapter::Value(Handle* handle) {
ObjectPtr v = target_->Value(handle);
// TODO with stacked secondaries: might fail in EvictionHandler
assert(v != kDummyObj);
return v;
}
void CacheWithSecondaryAdapter::StartAsyncLookupOnMySecondary(
AsyncLookupHandle& async_handle) {
assert(!async_handle.IsPending());
assert(async_handle.result_handle == nullptr);
std::unique_ptr<SecondaryCacheResultHandle> secondary_handle =
secondary_cache_->Lookup(async_handle.key, async_handle.helper,
async_handle.create_context, /*wait*/ false,
async_handle.found_dummy_entry,
/*out*/ async_handle.kept_in_sec_cache);
if (secondary_handle) {
// TODO with stacked secondaries: Check & process if already ready?
async_handle.pending_handle = secondary_handle.release();
async_handle.pending_cache = secondary_cache_.get();
}
}
void CacheWithSecondaryAdapter::StartAsyncLookup(
AsyncLookupHandle& async_handle) {
target_->StartAsyncLookup(async_handle);
if (!async_handle.IsPending()) {
bool secondary_compatible =
async_handle.helper &&
async_handle.helper->IsSecondaryCacheCompatible();
async_handle.found_dummy_entry |= ProcessDummyResult(
&async_handle.result_handle, /*erase=*/secondary_compatible);
if (async_handle.Result() == nullptr && secondary_compatible) {
// Not found and not pending on another secondary cache
StartAsyncLookupOnMySecondary(async_handle);
}
}
}
void CacheWithSecondaryAdapter::WaitAll(AsyncLookupHandle* async_handles,
size_t count) {
if (count == 0) {
// Nothing to do
return;
}
// Requests that are pending on *my* secondary cache, at the start of this
// function
std::vector<AsyncLookupHandle*> my_pending;
// Requests that are pending on an "inner" secondary cache (managed somewhere
// under target_), as of the start of this function
std::vector<AsyncLookupHandle*> inner_pending;
// Initial accounting of pending handles, excluding those already handled
// by "outer" secondary caches. (See cur->pending_cache = nullptr.)
for (size_t i = 0; i < count; ++i) {
AsyncLookupHandle* cur = async_handles + i;
if (cur->pending_cache) {
assert(cur->IsPending());
assert(cur->helper);
assert(cur->helper->IsSecondaryCacheCompatible());
if (cur->pending_cache == secondary_cache_.get()) {
my_pending.push_back(cur);
// Mark as "to be handled by this caller"
cur->pending_cache = nullptr;
} else {
// Remember as potentially needing a lookup in my secondary
inner_pending.push_back(cur);
}
}
}
// Wait on inner-most cache lookups first
// TODO with stacked secondaries: because we are not using proper
// async/await constructs here yet, there is a false synchronization point
// here where all the results at one level are needed before initiating
// any lookups at the next level. Probably not a big deal, but worth noting.
if (!inner_pending.empty()) {
target_->WaitAll(async_handles, count);
}
// For those that failed to find something, convert to lookup in my
// secondary cache.
for (AsyncLookupHandle* cur : inner_pending) {
if (cur->Result() == nullptr) {
// Not found, try my secondary
StartAsyncLookupOnMySecondary(*cur);
if (cur->IsPending()) {
assert(cur->pending_cache == secondary_cache_.get());
my_pending.push_back(cur);
// Mark as "to be handled by this caller"
cur->pending_cache = nullptr;
}
}
}
// Wait on all lookups on my secondary cache
{
std::vector<SecondaryCacheResultHandle*> my_secondary_handles;
for (AsyncLookupHandle* cur : my_pending) {
my_secondary_handles.push_back(cur->pending_handle);
}
secondary_cache_->WaitAll(my_secondary_handles);
}
// Process results
for (AsyncLookupHandle* cur : my_pending) {
std::unique_ptr<SecondaryCacheResultHandle> secondary_handle(
cur->pending_handle);
cur->pending_handle = nullptr;
cur->result_handle = Promote(
std::move(secondary_handle), cur->key, cur->helper, cur->priority,
cur->stats, cur->found_dummy_entry, cur->kept_in_sec_cache);
assert(cur->pending_cache == nullptr);
}
}
std::string CacheWithSecondaryAdapter::GetPrintableOptions() const {
std::string str = target_->GetPrintableOptions();
str.append(" secondary_cache:\n");
str.append(secondary_cache_->GetPrintableOptions());
return str;
}
const char* CacheWithSecondaryAdapter::Name() const {
// To the user, at least for now, configure the underlying cache with
// a secondary cache. So we pretend to be that cache
return target_->Name();
}
} // namespace ROCKSDB_NAMESPACE