mirror of
https://github.com/facebook/rocksdb.git
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9f7801c5f1
Summary: This is several refactorings bundled into one to avoid having to incrementally re-modify uses of Cache several times. Overall, there are breaking changes to Cache class, and it becomes more of low-level interface for implementing caches, especially block cache. New internal APIs make using Cache cleaner than before, and more insulated from block cache evolution. Hopefully, this is the last really big block cache refactoring, because of rather effectively decoupling the implementations from the uses. This change also removes the EXPERIMENTAL designation on the SecondaryCache support in Cache. It seems reasonably mature at this point but still subject to change/evolution (as I warn in the API docs for Cache). The high-level motivation for this refactoring is to minimize code duplication / compounding complexity in adding SecondaryCache support to HyperClockCache (in a later PR). Other benefits listed below. * static_cast lines of code +29 -35 (net removed 6) * reinterpret_cast lines of code +6 -32 (net removed 26) ## cache.h and secondary_cache.h * Always use CacheItemHelper with entries instead of just a Deleter. There are several motivations / justifications: * Simpler for implementations to deal with just one Insert and one Lookup. * Simpler and more efficient implementation because we don't have to track which entries are using helpers and which are using deleters * Gets rid of hack to classify cache entries by their deleter. Instead, the CacheItemHelper includes a CacheEntryRole. This simplifies a lot of code (cache_entry_roles.h almost eliminated). Fixes https://github.com/facebook/rocksdb/issues/9428. * Makes it trivial to adjust SecondaryCache behavior based on kind of block (e.g. don't re-compress filter blocks). * It is arguably less convenient for many direct users of Cache, but direct users of Cache are now rare with introduction of typed_cache.h (below). * I considered and rejected an alternative approach in which we reduce customizability by assuming each secondary cache compatible value starts with a Slice referencing the uncompressed block contents (already true or mostly true), but we apparently intend to stack secondary caches. Saving an entry from a compressed secondary to a lower tier requires custom handling offered by SaveToCallback, etc. * Make CreateCallback part of the helper and introduce CreateContext to work with it (alternative to https://github.com/facebook/rocksdb/issues/10562). This cleans up the interface while still allowing context to be provided for loading/parsing values into primary cache. This model works for async lookup in BlockBasedTable reader (reader owns a CreateContext) under the assumption that it always waits on secondary cache operations to finish. (Otherwise, the CreateContext could be destroyed while async operation depending on it continues.) This likely contributes most to the observed performance improvement because it saves an std::function backed by a heap allocation. * Use char* for serialized data, e.g. in SaveToCallback, where void* was confusingly used. (We use `char*` for serialized byte data all over RocksDB, with many advantages over `void*`. `memcpy` etc. are legacy APIs that should not be mimicked.) * Add a type alias Cache::ObjectPtr = void*, so that we can better indicate the intent of the void* when it is to be the object associated with a Cache entry. Related: started (but did not complete) a refactoring to move away from "value" of a cache entry toward "object" or "obj". (It is confusing to call Cache a key-value store (like DB) when it is really storing arbitrary in-memory objects, not byte strings.) * Remove unnecessary key param from DeleterFn. This is good for efficiency in HyperClockCache, which does not directly store the cache key in memory. (Alternative to https://github.com/facebook/rocksdb/issues/10774) * Add allocator to Cache DeleterFn. This is a kind of future-proofing change in case we get more serious about using the Cache allocator for memory tracked by the Cache. Right now, only the uncompressed block contents are allocated using the allocator, and a pointer to that allocator is saved as part of the cached object so that the deleter can use it. (See CacheAllocationPtr.) If in the future we are able to "flatten out" our Cache objects some more, it would be good not to have to track the allocator as part of each object. * Removes legacy `ApplyToAllCacheEntries` and changes `ApplyToAllEntries` signature for Deleter->CacheItemHelper change. ## typed_cache.h Adds various "typed" interfaces to the Cache as internal APIs, so that most uses of Cache can use simple type safe code without casting and without explicit deleters, etc. Almost all of the non-test, non-glue code uses of Cache have been migrated. (Follow-up work: CompressedSecondaryCache deserves deeper attention to migrate.) This change expands RocksDB's internal usage of metaprogramming and SFINAE (https://en.cppreference.com/w/cpp/language/sfinae). The existing usages of Cache are divided up at a high level into these new interfaces. See updated existing uses of Cache for examples of how these are used. * PlaceholderCacheInterface - Used for making cache reservations, with entries that have a charge but no value. * BasicTypedCacheInterface<TValue> - Used for primary cache storage of objects of type TValue, which can be cleaned up with std::default_delete<TValue>. The role is provided by TValue::kCacheEntryRole or given in an optional template parameter. * FullTypedCacheInterface<TValue, TCreateContext> - Used for secondary cache compatible storage of objects of type TValue. In addition to BasicTypedCacheInterface constraints, we require TValue::ContentSlice() to return persistable data. This simplifies usage for the normal case of simple secondary cache compatibility (can give you a Slice to the data already in memory). In addition to TCreateContext performing the role of Cache::CreateContext, it is also expected to provide a factory function for creating TValue. * For each of these, there's a "Shared" version (e.g. FullTypedSharedCacheInterface) that holds a shared_ptr to the Cache, rather than assuming external ownership by holding only a raw `Cache*`. These interfaces introduce specific handle types for each interface instantiation, so that it's easy to see what kind of object is controlled by a handle. (Ultimately, this might not be worth the extra complexity, but it seems OK so far.) Note: I attempted to make the cache 'charge' automatically inferred from the cache object type, such as by expecting an ApproximateMemoryUsage() function, but this is not so clean because there are cases where we need to compute the charge ahead of time and don't want to re-compute it. ## block_cache.h This header is essentially the replacement for the old block_like_traits.h. It includes various things to support block cache access with typed_cache.h for block-based table. ## block_based_table_reader.cc Before this change, accessing the block cache here was an awkward mix of static polymorphism (template TBlocklike) and switch-case on a dynamic BlockType value. This change mostly unifies on static polymorphism, relying on minor hacks in block_cache.h to distinguish variants of Block. We still check BlockType in some places (especially for stats, which could be improved in follow-up work) but at least the BlockType is a static constant from the template parameter. (No more awkward partial redundancy between static and dynamic info.) This likely contributes to the overall performance improvement, but hasn't been tested in isolation. The other key source of simplification here is a more unified system of creating block cache objects: for directly populating from primary cache and for promotion from secondary cache. Both use BlockCreateContext, for context and for factory functions. ## block_based_table_builder.cc, cache_dump_load_impl.cc Before this change, warming caches was super ugly code. Both of these source files had switch statements to basically transition from the dynamic BlockType world to the static TBlocklike world. None of that mess is needed anymore as there's a new, untyped WarmInCache function that handles all the details just as promotion from SecondaryCache would. (Fixes `TODO akanksha: Dedup below code` in block_based_table_builder.cc.) ## Everything else Mostly just updating Cache users to use new typed APIs when reasonably possible, or changed Cache APIs when not. Pull Request resolved: https://github.com/facebook/rocksdb/pull/10975 Test Plan: tests updated Performance test setup similar to https://github.com/facebook/rocksdb/issues/10626 (by cache size, LRUCache when not "hyper" for HyperClockCache): 34MB 1thread base.hyper -> kops/s: 0.745 io_bytes/op: 2.52504e+06 miss_ratio: 0.140906 max_rss_mb: 76.4844 34MB 1thread new.hyper -> kops/s: 0.751 io_bytes/op: 2.5123e+06 miss_ratio: 0.140161 max_rss_mb: 79.3594 34MB 1thread base -> kops/s: 0.254 io_bytes/op: 1.36073e+07 miss_ratio: 0.918818 max_rss_mb: 45.9297 34MB 1thread new -> kops/s: 0.252 io_bytes/op: 1.36157e+07 miss_ratio: 0.918999 max_rss_mb: 44.1523 34MB 32thread base.hyper -> kops/s: 7.272 io_bytes/op: 2.88323e+06 miss_ratio: 0.162532 max_rss_mb: 516.602 34MB 32thread new.hyper -> kops/s: 7.214 io_bytes/op: 2.99046e+06 miss_ratio: 0.168818 max_rss_mb: 518.293 34MB 32thread base -> kops/s: 3.528 io_bytes/op: 1.35722e+07 miss_ratio: 0.914691 max_rss_mb: 264.926 34MB 32thread new -> kops/s: 3.604 io_bytes/op: 1.35744e+07 miss_ratio: 0.915054 max_rss_mb: 264.488 233MB 1thread base.hyper -> kops/s: 53.909 io_bytes/op: 2552.35 miss_ratio: 0.0440566 max_rss_mb: 241.984 233MB 1thread new.hyper -> kops/s: 62.792 io_bytes/op: 2549.79 miss_ratio: 0.044043 max_rss_mb: 241.922 233MB 1thread base -> kops/s: 1.197 io_bytes/op: 2.75173e+06 miss_ratio: 0.103093 max_rss_mb: 241.559 233MB 1thread new -> kops/s: 1.199 io_bytes/op: 2.73723e+06 miss_ratio: 0.10305 max_rss_mb: 240.93 233MB 32thread base.hyper -> kops/s: 1298.69 io_bytes/op: 2539.12 miss_ratio: 0.0440307 max_rss_mb: 371.418 233MB 32thread new.hyper -> kops/s: 1421.35 io_bytes/op: 2538.75 miss_ratio: 0.0440307 max_rss_mb: 347.273 233MB 32thread base -> kops/s: 9.693 io_bytes/op: 2.77304e+06 miss_ratio: 0.103745 max_rss_mb: 569.691 233MB 32thread new -> kops/s: 9.75 io_bytes/op: 2.77559e+06 miss_ratio: 0.103798 max_rss_mb: 552.82 1597MB 1thread base.hyper -> kops/s: 58.607 io_bytes/op: 1449.14 miss_ratio: 0.0249324 max_rss_mb: 1583.55 1597MB 1thread new.hyper -> kops/s: 69.6 io_bytes/op: 1434.89 miss_ratio: 0.0247167 max_rss_mb: 1584.02 1597MB 1thread base -> kops/s: 60.478 io_bytes/op: 1421.28 miss_ratio: 0.024452 max_rss_mb: 1589.45 1597MB 1thread new -> kops/s: 63.973 io_bytes/op: 1416.07 miss_ratio: 0.0243766 max_rss_mb: 1589.24 1597MB 32thread base.hyper -> kops/s: 1436.2 io_bytes/op: 1357.93 miss_ratio: 0.0235353 max_rss_mb: 1692.92 1597MB 32thread new.hyper -> kops/s: 1605.03 io_bytes/op: 1358.04 miss_ratio: 0.023538 max_rss_mb: 1702.78 1597MB 32thread base -> kops/s: 280.059 io_bytes/op: 1350.34 miss_ratio: 0.023289 max_rss_mb: 1675.36 1597MB 32thread new -> kops/s: 283.125 io_bytes/op: 1351.05 miss_ratio: 0.0232797 max_rss_mb: 1703.83 Almost uniformly improving over base revision, especially for hot paths with HyperClockCache, up to 12% higher throughput seen (1597MB, 32thread, hyper). The improvement for that is likely coming from much simplified code for providing context for secondary cache promotion (CreateCallback/CreateContext), and possibly from less branching in block_based_table_reader. And likely a small improvement from not reconstituting key for DeleterFn. Reviewed By: anand1976 Differential Revision: D42417818 Pulled By: pdillinger fbshipit-source-id: f86bfdd584dce27c028b151ba56818ad14f7a432
1408 lines
55 KiB
C++
1408 lines
55 KiB
C++
// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
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// This source code is licensed under both the GPLv2 (found in the
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// COPYING file in the root directory) and Apache 2.0 License
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// (found in the LICENSE.Apache file in the root directory).
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//
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// Copyright (c) 2011 The LevelDB Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file. See the AUTHORS file for names of contributors.
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#include "cache/clock_cache.h"
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#include <cassert>
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#include <functional>
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#include <numeric>
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#include "cache/cache_key.h"
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#include "logging/logging.h"
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#include "monitoring/perf_context_imp.h"
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#include "monitoring/statistics.h"
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#include "port/lang.h"
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#include "util/hash.h"
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#include "util/math.h"
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#include "util/random.h"
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namespace ROCKSDB_NAMESPACE {
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namespace clock_cache {
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namespace {
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inline uint64_t GetRefcount(uint64_t meta) {
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return ((meta >> ClockHandle::kAcquireCounterShift) -
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(meta >> ClockHandle::kReleaseCounterShift)) &
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ClockHandle::kCounterMask;
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}
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inline uint64_t GetInitialCountdown(Cache::Priority priority) {
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// Set initial clock data from priority
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// TODO: configuration parameters for priority handling and clock cycle
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// count?
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switch (priority) {
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case Cache::Priority::HIGH:
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return ClockHandle::kHighCountdown;
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default:
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assert(false);
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FALLTHROUGH_INTENDED;
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case Cache::Priority::LOW:
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return ClockHandle::kLowCountdown;
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case Cache::Priority::BOTTOM:
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return ClockHandle::kBottomCountdown;
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}
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}
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inline void FreeDataMarkEmpty(ClockHandle& h, MemoryAllocator* allocator) {
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// NOTE: in theory there's more room for parallelism if we copy the handle
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// data and delay actions like this until after marking the entry as empty,
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// but performance tests only show a regression by copying the few words
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// of data.
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h.FreeData(allocator);
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#ifndef NDEBUG
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// Mark slot as empty, with assertion
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uint64_t meta = h.meta.exchange(0, std::memory_order_release);
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assert(meta >> ClockHandle::kStateShift == ClockHandle::kStateConstruction);
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#else
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// Mark slot as empty
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h.meta.store(0, std::memory_order_release);
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#endif
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}
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inline bool ClockUpdate(ClockHandle& h) {
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uint64_t meta = h.meta.load(std::memory_order_relaxed);
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uint64_t acquire_count =
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(meta >> ClockHandle::kAcquireCounterShift) & ClockHandle::kCounterMask;
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uint64_t release_count =
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(meta >> ClockHandle::kReleaseCounterShift) & ClockHandle::kCounterMask;
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// fprintf(stderr, "ClockUpdate @ %p: %lu %lu %u\n", &h, acquire_count,
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// release_count, (unsigned)(meta >> ClockHandle::kStateShift));
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if (acquire_count != release_count) {
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// Only clock update entries with no outstanding refs
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return false;
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}
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if (!((meta >> ClockHandle::kStateShift) & ClockHandle::kStateShareableBit)) {
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// Only clock update Shareable entries
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return false;
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}
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if ((meta >> ClockHandle::kStateShift == ClockHandle::kStateVisible) &&
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acquire_count > 0) {
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// Decrement clock
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uint64_t new_count =
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std::min(acquire_count - 1, uint64_t{ClockHandle::kMaxCountdown} - 1);
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// Compare-exchange in the decremented clock info, but
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// not aggressively
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uint64_t new_meta =
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(uint64_t{ClockHandle::kStateVisible} << ClockHandle::kStateShift) |
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(new_count << ClockHandle::kReleaseCounterShift) |
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(new_count << ClockHandle::kAcquireCounterShift);
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h.meta.compare_exchange_strong(meta, new_meta, std::memory_order_relaxed);
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return false;
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}
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// Otherwise, remove entry (either unreferenced invisible or
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// unreferenced and expired visible).
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if (h.meta.compare_exchange_strong(
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meta,
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uint64_t{ClockHandle::kStateConstruction} << ClockHandle::kStateShift,
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std::memory_order_acquire)) {
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// Took ownership.
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return true;
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} else {
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// Compare-exchange failing probably
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// indicates the entry was used, so skip it in that case.
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return false;
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}
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}
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} // namespace
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void ClockHandleBasicData::FreeData(MemoryAllocator* allocator) const {
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if (helper->del_cb) {
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helper->del_cb(value, allocator);
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}
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}
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HyperClockTable::HyperClockTable(
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size_t capacity, bool /*strict_capacity_limit*/,
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CacheMetadataChargePolicy metadata_charge_policy,
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MemoryAllocator* allocator, const Opts& opts)
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: length_bits_(CalcHashBits(capacity, opts.estimated_value_size,
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metadata_charge_policy)),
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length_bits_mask_((size_t{1} << length_bits_) - 1),
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occupancy_limit_(static_cast<size_t>((uint64_t{1} << length_bits_) *
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kStrictLoadFactor)),
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array_(new HandleImpl[size_t{1} << length_bits_]),
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allocator_(allocator) {
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if (metadata_charge_policy ==
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CacheMetadataChargePolicy::kFullChargeCacheMetadata) {
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usage_ += size_t{GetTableSize()} * sizeof(HandleImpl);
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}
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static_assert(sizeof(HandleImpl) == 64U,
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"Expecting size / alignment with common cache line size");
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}
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HyperClockTable::~HyperClockTable() {
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// Assumes there are no references or active operations on any slot/element
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// in the table.
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for (size_t i = 0; i < GetTableSize(); i++) {
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HandleImpl& h = array_[i];
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switch (h.meta >> ClockHandle::kStateShift) {
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case ClockHandle::kStateEmpty:
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// noop
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break;
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case ClockHandle::kStateInvisible: // rare but possible
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case ClockHandle::kStateVisible:
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assert(GetRefcount(h.meta) == 0);
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h.FreeData(allocator_);
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#ifndef NDEBUG
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Rollback(h.hashed_key, &h);
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ReclaimEntryUsage(h.GetTotalCharge());
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#endif
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break;
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// otherwise
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default:
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assert(false);
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break;
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}
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}
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#ifndef NDEBUG
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for (size_t i = 0; i < GetTableSize(); i++) {
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assert(array_[i].displacements.load() == 0);
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}
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#endif
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assert(usage_.load() == 0 ||
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usage_.load() == size_t{GetTableSize()} * sizeof(HandleImpl));
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assert(occupancy_ == 0);
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}
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// If an entry doesn't receive clock updates but is repeatedly referenced &
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// released, the acquire and release counters could overflow without some
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// intervention. This is that intervention, which should be inexpensive
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// because it only incurs a simple, very predictable check. (Applying a bit
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// mask in addition to an increment to every Release likely would be
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// relatively expensive, because it's an extra atomic update.)
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//
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// We do have to assume that we never have many millions of simultaneous
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// references to a cache handle, because we cannot represent so many
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// references with the difference in counters, masked to the number of
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// counter bits. Similarly, we assume there aren't millions of threads
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// holding transient references (which might be "undone" rather than
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// released by the way).
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//
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// Consider these possible states for each counter:
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// low: less than kMaxCountdown
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// medium: kMaxCountdown to half way to overflow + kMaxCountdown
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// high: half way to overflow + kMaxCountdown, or greater
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//
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// And these possible states for the combination of counters:
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// acquire / release
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// ------- -------
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// low low - Normal / common, with caveats (see below)
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// medium low - Can happen while holding some refs
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// high low - Violates assumptions (too many refs)
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// low medium - Violates assumptions (refs underflow, etc.)
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// medium medium - Normal (very read heavy cache)
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// high medium - Can happen while holding some refs
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// low high - This function is supposed to prevent
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// medium high - Violates assumptions (refs underflow, etc.)
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// high high - Needs CorrectNearOverflow
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//
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// Basically, this function detects (high, high) state (inferred from
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// release alone being high) and bumps it back down to (medium, medium)
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// state with the same refcount and the same logical countdown counter
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// (everything > kMaxCountdown is logically the same). Note that bumping
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// down to (low, low) would modify the countdown counter, so is "reserved"
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// in a sense.
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//
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// If near-overflow correction is triggered here, there's no guarantee
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// that another thread hasn't freed the entry and replaced it with another.
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// Therefore, it must be the case that the correction does not affect
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// entries unless they are very old (many millions of acquire-release cycles).
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// (Our bit manipulation is indeed idempotent and only affects entries in
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// exceptional cases.) We assume a pre-empted thread will not stall that long.
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// If it did, the state could be corrupted in the (unlikely) case that the top
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// bit of the acquire counter is set but not the release counter, and thus
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// we only clear the top bit of the acquire counter on resumption. It would
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// then appear that there are too many refs and the entry would be permanently
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// pinned (which is not terrible for an exceptionally rare occurrence), unless
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// it is referenced enough (at least kMaxCountdown more times) for the release
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// counter to reach "high" state again and bumped back to "medium." (This
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// motivates only checking for release counter in high state, not both in high
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// state.)
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inline void CorrectNearOverflow(uint64_t old_meta,
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std::atomic<uint64_t>& meta) {
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// We clear both top-most counter bits at the same time.
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constexpr uint64_t kCounterTopBit = uint64_t{1}
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<< (ClockHandle::kCounterNumBits - 1);
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constexpr uint64_t kClearBits =
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(kCounterTopBit << ClockHandle::kAcquireCounterShift) |
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(kCounterTopBit << ClockHandle::kReleaseCounterShift);
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// A simple check that allows us to initiate clearing the top bits for
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// a large portion of the "high" state space on release counter.
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constexpr uint64_t kCheckBits =
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(kCounterTopBit | (ClockHandle::kMaxCountdown + 1))
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<< ClockHandle::kReleaseCounterShift;
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if (UNLIKELY(old_meta & kCheckBits)) {
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meta.fetch_and(~kClearBits, std::memory_order_relaxed);
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}
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}
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inline Status HyperClockTable::ChargeUsageMaybeEvictStrict(
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size_t total_charge, size_t capacity, bool need_evict_for_occupancy) {
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if (total_charge > capacity) {
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return Status::MemoryLimit(
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"Cache entry too large for a single cache shard: " +
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std::to_string(total_charge) + " > " + std::to_string(capacity));
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}
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// Grab any available capacity, and free up any more required.
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size_t old_usage = usage_.load(std::memory_order_relaxed);
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size_t new_usage;
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if (LIKELY(old_usage != capacity)) {
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do {
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new_usage = std::min(capacity, old_usage + total_charge);
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} while (!usage_.compare_exchange_weak(old_usage, new_usage,
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std::memory_order_relaxed));
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} else {
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new_usage = old_usage;
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}
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// How much do we need to evict then?
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size_t need_evict_charge = old_usage + total_charge - new_usage;
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size_t request_evict_charge = need_evict_charge;
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if (UNLIKELY(need_evict_for_occupancy) && request_evict_charge == 0) {
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// Require at least 1 eviction.
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request_evict_charge = 1;
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}
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if (request_evict_charge > 0) {
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size_t evicted_charge = 0;
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size_t evicted_count = 0;
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Evict(request_evict_charge, &evicted_charge, &evicted_count);
|
|
occupancy_.fetch_sub(evicted_count, std::memory_order_release);
|
|
if (LIKELY(evicted_charge > need_evict_charge)) {
|
|
assert(evicted_count > 0);
|
|
// Evicted more than enough
|
|
usage_.fetch_sub(evicted_charge - need_evict_charge,
|
|
std::memory_order_relaxed);
|
|
} else if (evicted_charge < need_evict_charge ||
|
|
(UNLIKELY(need_evict_for_occupancy) && evicted_count == 0)) {
|
|
// Roll back to old usage minus evicted
|
|
usage_.fetch_sub(evicted_charge + (new_usage - old_usage),
|
|
std::memory_order_relaxed);
|
|
if (evicted_charge < need_evict_charge) {
|
|
return Status::MemoryLimit(
|
|
"Insert failed because unable to evict entries to stay within "
|
|
"capacity limit.");
|
|
} else {
|
|
return Status::MemoryLimit(
|
|
"Insert failed because unable to evict entries to stay within "
|
|
"table occupancy limit.");
|
|
}
|
|
}
|
|
// If we needed to evict something and we are proceeding, we must have
|
|
// evicted something.
|
|
assert(evicted_count > 0);
|
|
}
|
|
return Status::OK();
|
|
}
|
|
|
|
inline bool HyperClockTable::ChargeUsageMaybeEvictNonStrict(
|
|
size_t total_charge, size_t capacity, bool need_evict_for_occupancy) {
|
|
// For simplicity, we consider that either the cache can accept the insert
|
|
// with no evictions, or we must evict enough to make (at least) enough
|
|
// space. It could lead to unnecessary failures or excessive evictions in
|
|
// some extreme cases, but allows a fast, simple protocol. If we allow a
|
|
// race to get us over capacity, then we might never get back to capacity
|
|
// limit if the sizes of entries allow each insertion to evict the minimum
|
|
// charge. Thus, we should evict some extra if it's not a signifcant
|
|
// portion of the shard capacity. This can have the side benefit of
|
|
// involving fewer threads in eviction.
|
|
size_t old_usage = usage_.load(std::memory_order_relaxed);
|
|
size_t need_evict_charge;
|
|
// NOTE: if total_charge > old_usage, there isn't yet enough to evict
|
|
// `total_charge` amount. Even if we only try to evict `old_usage` amount,
|
|
// there's likely something referenced and we would eat CPU looking for
|
|
// enough to evict.
|
|
if (old_usage + total_charge <= capacity || total_charge > old_usage) {
|
|
// Good enough for me (might run over with a race)
|
|
need_evict_charge = 0;
|
|
} else {
|
|
// Try to evict enough space, and maybe some extra
|
|
need_evict_charge = total_charge;
|
|
if (old_usage > capacity) {
|
|
// Not too much to avoid thundering herd while avoiding strict
|
|
// synchronization, such as the compare_exchange used with strict
|
|
// capacity limit.
|
|
need_evict_charge += std::min(capacity / 1024, total_charge) + 1;
|
|
}
|
|
}
|
|
if (UNLIKELY(need_evict_for_occupancy) && need_evict_charge == 0) {
|
|
// Special case: require at least 1 eviction if we only have to
|
|
// deal with occupancy
|
|
need_evict_charge = 1;
|
|
}
|
|
size_t evicted_charge = 0;
|
|
size_t evicted_count = 0;
|
|
if (need_evict_charge > 0) {
|
|
Evict(need_evict_charge, &evicted_charge, &evicted_count);
|
|
// Deal with potential occupancy deficit
|
|
if (UNLIKELY(need_evict_for_occupancy) && evicted_count == 0) {
|
|
assert(evicted_charge == 0);
|
|
// Can't meet occupancy requirement
|
|
return false;
|
|
} else {
|
|
// Update occupancy for evictions
|
|
occupancy_.fetch_sub(evicted_count, std::memory_order_release);
|
|
}
|
|
}
|
|
// Track new usage even if we weren't able to evict enough
|
|
usage_.fetch_add(total_charge - evicted_charge, std::memory_order_relaxed);
|
|
// No underflow
|
|
assert(usage_.load(std::memory_order_relaxed) < SIZE_MAX / 2);
|
|
// Success
|
|
return true;
|
|
}
|
|
|
|
inline HyperClockTable::HandleImpl* HyperClockTable::DetachedInsert(
|
|
const ClockHandleBasicData& proto) {
|
|
// Heap allocated separate from table
|
|
HandleImpl* h = new HandleImpl();
|
|
ClockHandleBasicData* h_alias = h;
|
|
*h_alias = proto;
|
|
h->SetDetached();
|
|
// Single reference (detached entries only created if returning a refed
|
|
// Handle back to user)
|
|
uint64_t meta = uint64_t{ClockHandle::kStateInvisible}
|
|
<< ClockHandle::kStateShift;
|
|
meta |= uint64_t{1} << ClockHandle::kAcquireCounterShift;
|
|
h->meta.store(meta, std::memory_order_release);
|
|
// Keep track of how much of usage is detached
|
|
detached_usage_.fetch_add(proto.GetTotalCharge(), std::memory_order_relaxed);
|
|
return h;
|
|
}
|
|
|
|
Status HyperClockTable::Insert(const ClockHandleBasicData& proto,
|
|
HandleImpl** handle, Cache::Priority priority,
|
|
size_t capacity, bool strict_capacity_limit) {
|
|
// Do we have the available occupancy? Optimistically assume we do
|
|
// and deal with it if we don't.
|
|
size_t old_occupancy = occupancy_.fetch_add(1, std::memory_order_acquire);
|
|
auto revert_occupancy_fn = [&]() {
|
|
occupancy_.fetch_sub(1, std::memory_order_relaxed);
|
|
};
|
|
// Whether we over-committed and need an eviction to make up for it
|
|
bool need_evict_for_occupancy = old_occupancy >= occupancy_limit_;
|
|
|
|
// Usage/capacity handling is somewhat different depending on
|
|
// strict_capacity_limit, but mostly pessimistic.
|
|
bool use_detached_insert = false;
|
|
const size_t total_charge = proto.GetTotalCharge();
|
|
if (strict_capacity_limit) {
|
|
Status s = ChargeUsageMaybeEvictStrict(total_charge, capacity,
|
|
need_evict_for_occupancy);
|
|
if (!s.ok()) {
|
|
revert_occupancy_fn();
|
|
return s;
|
|
}
|
|
} else {
|
|
// Case strict_capacity_limit == false
|
|
bool success = ChargeUsageMaybeEvictNonStrict(total_charge, capacity,
|
|
need_evict_for_occupancy);
|
|
if (!success) {
|
|
revert_occupancy_fn();
|
|
if (handle == nullptr) {
|
|
// Don't insert the entry but still return ok, as if the entry
|
|
// inserted into cache and evicted immediately.
|
|
proto.FreeData(allocator_);
|
|
return Status::OK();
|
|
} else {
|
|
// Need to track usage of fallback detached insert
|
|
usage_.fetch_add(total_charge, std::memory_order_relaxed);
|
|
use_detached_insert = true;
|
|
}
|
|
}
|
|
}
|
|
auto revert_usage_fn = [&]() {
|
|
usage_.fetch_sub(total_charge, std::memory_order_relaxed);
|
|
// No underflow
|
|
assert(usage_.load(std::memory_order_relaxed) < SIZE_MAX / 2);
|
|
};
|
|
|
|
if (!use_detached_insert) {
|
|
// Attempt a table insert, but abort if we find an existing entry for the
|
|
// key. If we were to overwrite old entries, we would either
|
|
// * Have to gain ownership over an existing entry to overwrite it, which
|
|
// would only work if there are no outstanding (read) references and would
|
|
// create a small gap in availability of the entry (old or new) to lookups.
|
|
// * Have to insert into a suboptimal location (more probes) so that the
|
|
// old entry can be kept around as well.
|
|
|
|
uint64_t initial_countdown = GetInitialCountdown(priority);
|
|
assert(initial_countdown > 0);
|
|
|
|
size_t probe = 0;
|
|
HandleImpl* e = FindSlot(
|
|
proto.hashed_key,
|
|
[&](HandleImpl* h) {
|
|
// Optimistically transition the slot from "empty" to
|
|
// "under construction" (no effect on other states)
|
|
uint64_t old_meta =
|
|
h->meta.fetch_or(uint64_t{ClockHandle::kStateOccupiedBit}
|
|
<< ClockHandle::kStateShift,
|
|
std::memory_order_acq_rel);
|
|
uint64_t old_state = old_meta >> ClockHandle::kStateShift;
|
|
|
|
if (old_state == ClockHandle::kStateEmpty) {
|
|
// We've started inserting into an available slot, and taken
|
|
// ownership Save data fields
|
|
ClockHandleBasicData* h_alias = h;
|
|
*h_alias = proto;
|
|
|
|
// Transition from "under construction" state to "visible" state
|
|
uint64_t new_meta = uint64_t{ClockHandle::kStateVisible}
|
|
<< ClockHandle::kStateShift;
|
|
|
|
// Maybe with an outstanding reference
|
|
new_meta |= initial_countdown << ClockHandle::kAcquireCounterShift;
|
|
new_meta |= (initial_countdown - (handle != nullptr))
|
|
<< ClockHandle::kReleaseCounterShift;
|
|
|
|
#ifndef NDEBUG
|
|
// Save the state transition, with assertion
|
|
old_meta = h->meta.exchange(new_meta, std::memory_order_release);
|
|
assert(old_meta >> ClockHandle::kStateShift ==
|
|
ClockHandle::kStateConstruction);
|
|
#else
|
|
// Save the state transition
|
|
h->meta.store(new_meta, std::memory_order_release);
|
|
#endif
|
|
return true;
|
|
} else if (old_state != ClockHandle::kStateVisible) {
|
|
// Slot not usable / touchable now
|
|
return false;
|
|
}
|
|
// Existing, visible entry, which might be a match.
|
|
// But first, we need to acquire a ref to read it. In fact, number of
|
|
// refs for initial countdown, so that we boost the clock state if
|
|
// this is a match.
|
|
old_meta = h->meta.fetch_add(
|
|
ClockHandle::kAcquireIncrement * initial_countdown,
|
|
std::memory_order_acq_rel);
|
|
// Like Lookup
|
|
if ((old_meta >> ClockHandle::kStateShift) ==
|
|
ClockHandle::kStateVisible) {
|
|
// Acquired a read reference
|
|
if (h->hashed_key == proto.hashed_key) {
|
|
// Match. Release in a way that boosts the clock state
|
|
old_meta = h->meta.fetch_add(
|
|
ClockHandle::kReleaseIncrement * initial_countdown,
|
|
std::memory_order_acq_rel);
|
|
// Correct for possible (but rare) overflow
|
|
CorrectNearOverflow(old_meta, h->meta);
|
|
// Insert detached instead (only if return handle needed)
|
|
use_detached_insert = true;
|
|
return true;
|
|
} else {
|
|
// Mismatch. Pretend we never took the reference
|
|
old_meta = h->meta.fetch_sub(
|
|
ClockHandle::kAcquireIncrement * initial_countdown,
|
|
std::memory_order_acq_rel);
|
|
}
|
|
} else if (UNLIKELY((old_meta >> ClockHandle::kStateShift) ==
|
|
ClockHandle::kStateInvisible)) {
|
|
// Pretend we never took the reference
|
|
// WART: there's a tiny chance we release last ref to invisible
|
|
// entry here. If that happens, we let eviction take care of it.
|
|
old_meta = h->meta.fetch_sub(
|
|
ClockHandle::kAcquireIncrement * initial_countdown,
|
|
std::memory_order_acq_rel);
|
|
} else {
|
|
// For other states, incrementing the acquire counter has no effect
|
|
// so we don't need to undo it.
|
|
// Slot not usable / touchable now.
|
|
}
|
|
(void)old_meta;
|
|
return false;
|
|
},
|
|
[&](HandleImpl* /*h*/) { return false; },
|
|
[&](HandleImpl* h) {
|
|
h->displacements.fetch_add(1, std::memory_order_relaxed);
|
|
},
|
|
probe);
|
|
if (e == nullptr) {
|
|
// Occupancy check and never abort FindSlot above should generally
|
|
// prevent this, except it's theoretically possible for other threads
|
|
// to evict and replace entries in the right order to hit every slot
|
|
// when it is populated. Assuming random hashing, the chance of that
|
|
// should be no higher than pow(kStrictLoadFactor, n) for n slots.
|
|
// That should be infeasible for roughly n >= 256, so if this assertion
|
|
// fails, that suggests something is going wrong.
|
|
assert(GetTableSize() < 256);
|
|
use_detached_insert = true;
|
|
}
|
|
if (!use_detached_insert) {
|
|
// Successfully inserted
|
|
if (handle) {
|
|
*handle = e;
|
|
}
|
|
return Status::OK();
|
|
}
|
|
// Roll back table insertion
|
|
Rollback(proto.hashed_key, e);
|
|
revert_occupancy_fn();
|
|
// Maybe fall back on detached insert
|
|
if (handle == nullptr) {
|
|
revert_usage_fn();
|
|
// As if unrefed entry immdiately evicted
|
|
proto.FreeData(allocator_);
|
|
return Status::OK();
|
|
}
|
|
}
|
|
|
|
// Run detached insert
|
|
assert(use_detached_insert);
|
|
|
|
*handle = DetachedInsert(proto);
|
|
|
|
// The OkOverwritten status is used to count "redundant" insertions into
|
|
// block cache. This implementation doesn't strictly check for redundant
|
|
// insertions, but we instead are probably interested in how many insertions
|
|
// didn't go into the table (instead "detached"), which could be redundant
|
|
// Insert or some other reason (use_detached_insert reasons above).
|
|
return Status::OkOverwritten();
|
|
}
|
|
|
|
HyperClockTable::HandleImpl* HyperClockTable::Lookup(
|
|
const UniqueId64x2& hashed_key) {
|
|
size_t probe = 0;
|
|
HandleImpl* e = FindSlot(
|
|
hashed_key,
|
|
[&](HandleImpl* h) {
|
|
// Mostly branch-free version (similar performance)
|
|
/*
|
|
uint64_t old_meta = h->meta.fetch_add(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_acquire);
|
|
bool Shareable = (old_meta >> (ClockHandle::kStateShift + 1)) & 1U;
|
|
bool visible = (old_meta >> ClockHandle::kStateShift) & 1U;
|
|
bool match = (h->key == key) & visible;
|
|
h->meta.fetch_sub(static_cast<uint64_t>(Shareable & !match) <<
|
|
ClockHandle::kAcquireCounterShift, std::memory_order_release); return
|
|
match;
|
|
*/
|
|
// Optimistic lookup should pay off when the table is relatively
|
|
// sparse.
|
|
constexpr bool kOptimisticLookup = true;
|
|
uint64_t old_meta;
|
|
if (!kOptimisticLookup) {
|
|
old_meta = h->meta.load(std::memory_order_acquire);
|
|
if ((old_meta >> ClockHandle::kStateShift) !=
|
|
ClockHandle::kStateVisible) {
|
|
return false;
|
|
}
|
|
}
|
|
// (Optimistically) increment acquire counter
|
|
old_meta = h->meta.fetch_add(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_acquire);
|
|
// Check if it's an entry visible to lookups
|
|
if ((old_meta >> ClockHandle::kStateShift) ==
|
|
ClockHandle::kStateVisible) {
|
|
// Acquired a read reference
|
|
if (h->hashed_key == hashed_key) {
|
|
// Match
|
|
return true;
|
|
} else {
|
|
// Mismatch. Pretend we never took the reference
|
|
old_meta = h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_release);
|
|
}
|
|
} else if (UNLIKELY((old_meta >> ClockHandle::kStateShift) ==
|
|
ClockHandle::kStateInvisible)) {
|
|
// Pretend we never took the reference
|
|
// WART: there's a tiny chance we release last ref to invisible
|
|
// entry here. If that happens, we let eviction take care of it.
|
|
old_meta = h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_release);
|
|
} else {
|
|
// For other states, incrementing the acquire counter has no effect
|
|
// so we don't need to undo it. Furthermore, we cannot safely undo
|
|
// it because we did not acquire a read reference to lock the
|
|
// entry in a Shareable state.
|
|
}
|
|
(void)old_meta;
|
|
return false;
|
|
},
|
|
[&](HandleImpl* h) {
|
|
return h->displacements.load(std::memory_order_relaxed) == 0;
|
|
},
|
|
[&](HandleImpl* /*h*/) {}, probe);
|
|
|
|
return e;
|
|
}
|
|
|
|
bool HyperClockTable::Release(HandleImpl* h, bool useful,
|
|
bool erase_if_last_ref) {
|
|
// In contrast with LRUCache's Release, this function won't delete the handle
|
|
// when the cache is above capacity and the reference is the last one. Space
|
|
// is only freed up by EvictFromClock (called by Insert when space is needed)
|
|
// and Erase. We do this to avoid an extra atomic read of the variable usage_.
|
|
|
|
uint64_t old_meta;
|
|
if (useful) {
|
|
// Increment release counter to indicate was used
|
|
old_meta = h->meta.fetch_add(ClockHandle::kReleaseIncrement,
|
|
std::memory_order_release);
|
|
} else {
|
|
// Decrement acquire counter to pretend it never happened
|
|
old_meta = h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_release);
|
|
}
|
|
|
|
assert((old_meta >> ClockHandle::kStateShift) &
|
|
ClockHandle::kStateShareableBit);
|
|
// No underflow
|
|
assert(((old_meta >> ClockHandle::kAcquireCounterShift) &
|
|
ClockHandle::kCounterMask) !=
|
|
((old_meta >> ClockHandle::kReleaseCounterShift) &
|
|
ClockHandle::kCounterMask));
|
|
|
|
if (erase_if_last_ref || UNLIKELY(old_meta >> ClockHandle::kStateShift ==
|
|
ClockHandle::kStateInvisible)) {
|
|
// Update for last fetch_add op
|
|
if (useful) {
|
|
old_meta += ClockHandle::kReleaseIncrement;
|
|
} else {
|
|
old_meta -= ClockHandle::kAcquireIncrement;
|
|
}
|
|
// Take ownership if no refs
|
|
do {
|
|
if (GetRefcount(old_meta) != 0) {
|
|
// Not last ref at some point in time during this Release call
|
|
// Correct for possible (but rare) overflow
|
|
CorrectNearOverflow(old_meta, h->meta);
|
|
return false;
|
|
}
|
|
if ((old_meta & (uint64_t{ClockHandle::kStateShareableBit}
|
|
<< ClockHandle::kStateShift)) == 0) {
|
|
// Someone else took ownership
|
|
return false;
|
|
}
|
|
// Note that there's a small chance that we release, another thread
|
|
// replaces this entry with another, reaches zero refs, and then we end
|
|
// up erasing that other entry. That's an acceptable risk / imprecision.
|
|
} while (!h->meta.compare_exchange_weak(
|
|
old_meta,
|
|
uint64_t{ClockHandle::kStateConstruction} << ClockHandle::kStateShift,
|
|
std::memory_order_acquire));
|
|
// Took ownership
|
|
size_t total_charge = h->GetTotalCharge();
|
|
if (UNLIKELY(h->IsDetached())) {
|
|
h->FreeData(allocator_);
|
|
// Delete detached handle
|
|
delete h;
|
|
detached_usage_.fetch_sub(total_charge, std::memory_order_relaxed);
|
|
usage_.fetch_sub(total_charge, std::memory_order_relaxed);
|
|
} else {
|
|
Rollback(h->hashed_key, h);
|
|
FreeDataMarkEmpty(*h, allocator_);
|
|
ReclaimEntryUsage(total_charge);
|
|
}
|
|
return true;
|
|
} else {
|
|
// Correct for possible (but rare) overflow
|
|
CorrectNearOverflow(old_meta, h->meta);
|
|
return false;
|
|
}
|
|
}
|
|
|
|
void HyperClockTable::Ref(HandleImpl& h) {
|
|
// Increment acquire counter
|
|
uint64_t old_meta = h.meta.fetch_add(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_acquire);
|
|
|
|
assert((old_meta >> ClockHandle::kStateShift) &
|
|
ClockHandle::kStateShareableBit);
|
|
// Must have already had a reference
|
|
assert(GetRefcount(old_meta) > 0);
|
|
(void)old_meta;
|
|
}
|
|
|
|
void HyperClockTable::TEST_RefN(HandleImpl& h, size_t n) {
|
|
// Increment acquire counter
|
|
uint64_t old_meta = h.meta.fetch_add(n * ClockHandle::kAcquireIncrement,
|
|
std::memory_order_acquire);
|
|
|
|
assert((old_meta >> ClockHandle::kStateShift) &
|
|
ClockHandle::kStateShareableBit);
|
|
(void)old_meta;
|
|
}
|
|
|
|
void HyperClockTable::TEST_ReleaseN(HandleImpl* h, size_t n) {
|
|
if (n > 0) {
|
|
// Split into n - 1 and 1 steps.
|
|
uint64_t old_meta = h->meta.fetch_add(
|
|
(n - 1) * ClockHandle::kReleaseIncrement, std::memory_order_acquire);
|
|
assert((old_meta >> ClockHandle::kStateShift) &
|
|
ClockHandle::kStateShareableBit);
|
|
(void)old_meta;
|
|
|
|
Release(h, /*useful*/ true, /*erase_if_last_ref*/ false);
|
|
}
|
|
}
|
|
|
|
void HyperClockTable::Erase(const UniqueId64x2& hashed_key) {
|
|
size_t probe = 0;
|
|
(void)FindSlot(
|
|
hashed_key,
|
|
[&](HandleImpl* h) {
|
|
// Could be multiple entries in rare cases. Erase them all.
|
|
// Optimistically increment acquire counter
|
|
uint64_t old_meta = h->meta.fetch_add(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_acquire);
|
|
// Check if it's an entry visible to lookups
|
|
if ((old_meta >> ClockHandle::kStateShift) ==
|
|
ClockHandle::kStateVisible) {
|
|
// Acquired a read reference
|
|
if (h->hashed_key == hashed_key) {
|
|
// Match. Set invisible.
|
|
old_meta =
|
|
h->meta.fetch_and(~(uint64_t{ClockHandle::kStateVisibleBit}
|
|
<< ClockHandle::kStateShift),
|
|
std::memory_order_acq_rel);
|
|
// Apply update to local copy
|
|
old_meta &= ~(uint64_t{ClockHandle::kStateVisibleBit}
|
|
<< ClockHandle::kStateShift);
|
|
for (;;) {
|
|
uint64_t refcount = GetRefcount(old_meta);
|
|
assert(refcount > 0);
|
|
if (refcount > 1) {
|
|
// Not last ref at some point in time during this Erase call
|
|
// Pretend we never took the reference
|
|
h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_release);
|
|
break;
|
|
} else if (h->meta.compare_exchange_weak(
|
|
old_meta,
|
|
uint64_t{ClockHandle::kStateConstruction}
|
|
<< ClockHandle::kStateShift,
|
|
std::memory_order_acq_rel)) {
|
|
// Took ownership
|
|
assert(hashed_key == h->hashed_key);
|
|
size_t total_charge = h->GetTotalCharge();
|
|
FreeDataMarkEmpty(*h, allocator_);
|
|
ReclaimEntryUsage(total_charge);
|
|
// We already have a copy of hashed_key in this case, so OK to
|
|
// delay Rollback until after releasing the entry
|
|
Rollback(hashed_key, h);
|
|
break;
|
|
}
|
|
}
|
|
} else {
|
|
// Mismatch. Pretend we never took the reference
|
|
h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_release);
|
|
}
|
|
} else if (UNLIKELY((old_meta >> ClockHandle::kStateShift) ==
|
|
ClockHandle::kStateInvisible)) {
|
|
// Pretend we never took the reference
|
|
// WART: there's a tiny chance we release last ref to invisible
|
|
// entry here. If that happens, we let eviction take care of it.
|
|
h->meta.fetch_sub(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_release);
|
|
} else {
|
|
// For other states, incrementing the acquire counter has no effect
|
|
// so we don't need to undo it.
|
|
}
|
|
return false;
|
|
},
|
|
[&](HandleImpl* h) {
|
|
return h->displacements.load(std::memory_order_relaxed) == 0;
|
|
},
|
|
[&](HandleImpl* /*h*/) {}, probe);
|
|
}
|
|
|
|
void HyperClockTable::ConstApplyToEntriesRange(
|
|
std::function<void(const HandleImpl&)> func, size_t index_begin,
|
|
size_t index_end, bool apply_if_will_be_deleted) const {
|
|
uint64_t check_state_mask = ClockHandle::kStateShareableBit;
|
|
if (!apply_if_will_be_deleted) {
|
|
check_state_mask |= ClockHandle::kStateVisibleBit;
|
|
}
|
|
|
|
for (size_t i = index_begin; i < index_end; i++) {
|
|
HandleImpl& h = array_[i];
|
|
|
|
// Note: to avoid using compare_exchange, we have to be extra careful.
|
|
uint64_t old_meta = h.meta.load(std::memory_order_relaxed);
|
|
// Check if it's an entry visible to lookups
|
|
if ((old_meta >> ClockHandle::kStateShift) & check_state_mask) {
|
|
// Increment acquire counter. Note: it's possible that the entry has
|
|
// completely changed since we loaded old_meta, but incrementing acquire
|
|
// count is always safe. (Similar to optimistic Lookup here.)
|
|
old_meta = h.meta.fetch_add(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_acquire);
|
|
// Check whether we actually acquired a reference.
|
|
if ((old_meta >> ClockHandle::kStateShift) &
|
|
ClockHandle::kStateShareableBit) {
|
|
// Apply func if appropriate
|
|
if ((old_meta >> ClockHandle::kStateShift) & check_state_mask) {
|
|
func(h);
|
|
}
|
|
// Pretend we never took the reference
|
|
h.meta.fetch_sub(ClockHandle::kAcquireIncrement,
|
|
std::memory_order_release);
|
|
// No net change, so don't need to check for overflow
|
|
} else {
|
|
// For other states, incrementing the acquire counter has no effect
|
|
// so we don't need to undo it. Furthermore, we cannot safely undo
|
|
// it because we did not acquire a read reference to lock the
|
|
// entry in a Shareable state.
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
void HyperClockTable::EraseUnRefEntries() {
|
|
for (size_t i = 0; i <= this->length_bits_mask_; i++) {
|
|
HandleImpl& h = array_[i];
|
|
|
|
uint64_t old_meta = h.meta.load(std::memory_order_relaxed);
|
|
if (old_meta & (uint64_t{ClockHandle::kStateShareableBit}
|
|
<< ClockHandle::kStateShift) &&
|
|
GetRefcount(old_meta) == 0 &&
|
|
h.meta.compare_exchange_strong(old_meta,
|
|
uint64_t{ClockHandle::kStateConstruction}
|
|
<< ClockHandle::kStateShift,
|
|
std::memory_order_acquire)) {
|
|
// Took ownership
|
|
size_t total_charge = h.GetTotalCharge();
|
|
Rollback(h.hashed_key, &h);
|
|
FreeDataMarkEmpty(h, allocator_);
|
|
ReclaimEntryUsage(total_charge);
|
|
}
|
|
}
|
|
}
|
|
|
|
inline HyperClockTable::HandleImpl* HyperClockTable::FindSlot(
|
|
const UniqueId64x2& hashed_key, std::function<bool(HandleImpl*)> match_fn,
|
|
std::function<bool(HandleImpl*)> abort_fn,
|
|
std::function<void(HandleImpl*)> update_fn, size_t& probe) {
|
|
// NOTE: upper 32 bits of hashed_key[0] is used for sharding
|
|
//
|
|
// We use double-hashing probing. Every probe in the sequence is a
|
|
// pseudorandom integer, computed as a linear function of two random hashes,
|
|
// which we call base and increment. Specifically, the i-th probe is base + i
|
|
// * increment modulo the table size.
|
|
size_t base = static_cast<size_t>(hashed_key[1]);
|
|
// We use an odd increment, which is relatively prime with the power-of-two
|
|
// table size. This implies that we cycle back to the first probe only
|
|
// after probing every slot exactly once.
|
|
// TODO: we could also reconsider linear probing, though locality benefits
|
|
// are limited because each slot is a full cache line
|
|
size_t increment = static_cast<size_t>(hashed_key[0]) | 1U;
|
|
size_t current = ModTableSize(base + probe * increment);
|
|
while (probe <= length_bits_mask_) {
|
|
HandleImpl* h = &array_[current];
|
|
if (match_fn(h)) {
|
|
probe++;
|
|
return h;
|
|
}
|
|
if (abort_fn(h)) {
|
|
return nullptr;
|
|
}
|
|
probe++;
|
|
update_fn(h);
|
|
current = ModTableSize(current + increment);
|
|
}
|
|
// We looped back.
|
|
return nullptr;
|
|
}
|
|
|
|
inline void HyperClockTable::Rollback(const UniqueId64x2& hashed_key,
|
|
const HandleImpl* h) {
|
|
size_t current = ModTableSize(hashed_key[1]);
|
|
size_t increment = static_cast<size_t>(hashed_key[0]) | 1U;
|
|
while (&array_[current] != h) {
|
|
array_[current].displacements.fetch_sub(1, std::memory_order_relaxed);
|
|
current = ModTableSize(current + increment);
|
|
}
|
|
}
|
|
|
|
inline void HyperClockTable::ReclaimEntryUsage(size_t total_charge) {
|
|
auto old_occupancy = occupancy_.fetch_sub(1U, std::memory_order_release);
|
|
(void)old_occupancy;
|
|
// No underflow
|
|
assert(old_occupancy > 0);
|
|
auto old_usage = usage_.fetch_sub(total_charge, std::memory_order_relaxed);
|
|
(void)old_usage;
|
|
// No underflow
|
|
assert(old_usage >= total_charge);
|
|
}
|
|
|
|
inline void HyperClockTable::Evict(size_t requested_charge,
|
|
size_t* freed_charge, size_t* freed_count) {
|
|
// precondition
|
|
assert(requested_charge > 0);
|
|
|
|
// TODO: make a tuning parameter?
|
|
constexpr size_t step_size = 4;
|
|
|
|
// First (concurrent) increment clock pointer
|
|
uint64_t old_clock_pointer =
|
|
clock_pointer_.fetch_add(step_size, std::memory_order_relaxed);
|
|
|
|
// Cap the eviction effort at this thread (along with those operating in
|
|
// parallel) circling through the whole structure kMaxCountdown times.
|
|
// In other words, this eviction run must find something/anything that is
|
|
// unreferenced at start of and during the eviction run that isn't reclaimed
|
|
// by a concurrent eviction run.
|
|
uint64_t max_clock_pointer =
|
|
old_clock_pointer + (ClockHandle::kMaxCountdown << length_bits_);
|
|
|
|
for (;;) {
|
|
for (size_t i = 0; i < step_size; i++) {
|
|
HandleImpl& h = array_[ModTableSize(Lower32of64(old_clock_pointer + i))];
|
|
bool evicting = ClockUpdate(h);
|
|
if (evicting) {
|
|
Rollback(h.hashed_key, &h);
|
|
*freed_charge += h.GetTotalCharge();
|
|
*freed_count += 1;
|
|
FreeDataMarkEmpty(h, allocator_);
|
|
}
|
|
}
|
|
|
|
// Loop exit condition
|
|
if (*freed_charge >= requested_charge) {
|
|
return;
|
|
}
|
|
if (old_clock_pointer >= max_clock_pointer) {
|
|
return;
|
|
}
|
|
|
|
// Advance clock pointer (concurrently)
|
|
old_clock_pointer =
|
|
clock_pointer_.fetch_add(step_size, std::memory_order_relaxed);
|
|
}
|
|
}
|
|
|
|
template <class Table>
|
|
ClockCacheShard<Table>::ClockCacheShard(
|
|
size_t capacity, bool strict_capacity_limit,
|
|
CacheMetadataChargePolicy metadata_charge_policy,
|
|
MemoryAllocator* allocator, const typename Table::Opts& opts)
|
|
: CacheShardBase(metadata_charge_policy),
|
|
table_(capacity, strict_capacity_limit, metadata_charge_policy, allocator,
|
|
opts),
|
|
capacity_(capacity),
|
|
strict_capacity_limit_(strict_capacity_limit) {
|
|
// Initial charge metadata should not exceed capacity
|
|
assert(table_.GetUsage() <= capacity_ || capacity_ < sizeof(HandleImpl));
|
|
}
|
|
|
|
template <class Table>
|
|
void ClockCacheShard<Table>::EraseUnRefEntries() {
|
|
table_.EraseUnRefEntries();
|
|
}
|
|
|
|
template <class Table>
|
|
void ClockCacheShard<Table>::ApplyToSomeEntries(
|
|
const std::function<void(const Slice& key, Cache::ObjectPtr value,
|
|
size_t charge,
|
|
const Cache::CacheItemHelper* helper)>& callback,
|
|
size_t average_entries_per_lock, size_t* state) {
|
|
// The state is essentially going to be the starting hash, which works
|
|
// nicely even if we resize between calls because we use upper-most
|
|
// hash bits for table indexes.
|
|
size_t length_bits = table_.GetLengthBits();
|
|
size_t length = table_.GetTableSize();
|
|
|
|
assert(average_entries_per_lock > 0);
|
|
// Assuming we are called with same average_entries_per_lock repeatedly,
|
|
// this simplifies some logic (index_end will not overflow).
|
|
assert(average_entries_per_lock < length || *state == 0);
|
|
|
|
size_t index_begin = *state >> (sizeof(size_t) * 8u - length_bits);
|
|
size_t index_end = index_begin + average_entries_per_lock;
|
|
if (index_end >= length) {
|
|
// Going to end.
|
|
index_end = length;
|
|
*state = SIZE_MAX;
|
|
} else {
|
|
*state = index_end << (sizeof(size_t) * 8u - length_bits);
|
|
}
|
|
|
|
table_.ConstApplyToEntriesRange(
|
|
[callback](const HandleImpl& h) {
|
|
UniqueId64x2 unhashed;
|
|
callback(ReverseHash(h.hashed_key, &unhashed), h.value,
|
|
h.GetTotalCharge(), h.helper);
|
|
},
|
|
index_begin, index_end, false);
|
|
}
|
|
|
|
int HyperClockTable::CalcHashBits(
|
|
size_t capacity, size_t estimated_value_size,
|
|
CacheMetadataChargePolicy metadata_charge_policy) {
|
|
double average_slot_charge = estimated_value_size * kLoadFactor;
|
|
if (metadata_charge_policy == kFullChargeCacheMetadata) {
|
|
average_slot_charge += sizeof(HandleImpl);
|
|
}
|
|
assert(average_slot_charge > 0.0);
|
|
uint64_t num_slots =
|
|
static_cast<uint64_t>(capacity / average_slot_charge + 0.999999);
|
|
|
|
int hash_bits = FloorLog2((num_slots << 1) - 1);
|
|
if (metadata_charge_policy == kFullChargeCacheMetadata) {
|
|
// For very small estimated value sizes, it's possible to overshoot
|
|
while (hash_bits > 0 &&
|
|
uint64_t{sizeof(HandleImpl)} << hash_bits > capacity) {
|
|
hash_bits--;
|
|
}
|
|
}
|
|
return hash_bits;
|
|
}
|
|
|
|
template <class Table>
|
|
void ClockCacheShard<Table>::SetCapacity(size_t capacity) {
|
|
capacity_.store(capacity, std::memory_order_relaxed);
|
|
// next Insert will take care of any necessary evictions
|
|
}
|
|
|
|
template <class Table>
|
|
void ClockCacheShard<Table>::SetStrictCapacityLimit(
|
|
bool strict_capacity_limit) {
|
|
strict_capacity_limit_.store(strict_capacity_limit,
|
|
std::memory_order_relaxed);
|
|
// next Insert will take care of any necessary evictions
|
|
}
|
|
|
|
template <class Table>
|
|
Status ClockCacheShard<Table>::Insert(const Slice& key,
|
|
const UniqueId64x2& hashed_key,
|
|
Cache::ObjectPtr value,
|
|
const Cache::CacheItemHelper* helper,
|
|
size_t charge, HandleImpl** handle,
|
|
Cache::Priority priority) {
|
|
if (UNLIKELY(key.size() != kCacheKeySize)) {
|
|
return Status::NotSupported("ClockCache only supports key size " +
|
|
std::to_string(kCacheKeySize) + "B");
|
|
}
|
|
ClockHandleBasicData proto;
|
|
proto.hashed_key = hashed_key;
|
|
proto.value = value;
|
|
proto.helper = helper;
|
|
proto.total_charge = charge;
|
|
Status s = table_.Insert(
|
|
proto, handle, priority, capacity_.load(std::memory_order_relaxed),
|
|
strict_capacity_limit_.load(std::memory_order_relaxed));
|
|
return s;
|
|
}
|
|
|
|
template <class Table>
|
|
typename ClockCacheShard<Table>::HandleImpl* ClockCacheShard<Table>::Lookup(
|
|
const Slice& key, const UniqueId64x2& hashed_key) {
|
|
if (UNLIKELY(key.size() != kCacheKeySize)) {
|
|
return nullptr;
|
|
}
|
|
return table_.Lookup(hashed_key);
|
|
}
|
|
|
|
template <class Table>
|
|
bool ClockCacheShard<Table>::Ref(HandleImpl* h) {
|
|
if (h == nullptr) {
|
|
return false;
|
|
}
|
|
table_.Ref(*h);
|
|
return true;
|
|
}
|
|
|
|
template <class Table>
|
|
bool ClockCacheShard<Table>::Release(HandleImpl* handle, bool useful,
|
|
bool erase_if_last_ref) {
|
|
if (handle == nullptr) {
|
|
return false;
|
|
}
|
|
return table_.Release(handle, useful, erase_if_last_ref);
|
|
}
|
|
|
|
template <class Table>
|
|
void ClockCacheShard<Table>::TEST_RefN(HandleImpl* h, size_t n) {
|
|
table_.TEST_RefN(*h, n);
|
|
}
|
|
|
|
template <class Table>
|
|
void ClockCacheShard<Table>::TEST_ReleaseN(HandleImpl* h, size_t n) {
|
|
table_.TEST_ReleaseN(h, n);
|
|
}
|
|
|
|
template <class Table>
|
|
bool ClockCacheShard<Table>::Release(HandleImpl* handle,
|
|
bool erase_if_last_ref) {
|
|
return Release(handle, /*useful=*/true, erase_if_last_ref);
|
|
}
|
|
|
|
template <class Table>
|
|
void ClockCacheShard<Table>::Erase(const Slice& key,
|
|
const UniqueId64x2& hashed_key) {
|
|
if (UNLIKELY(key.size() != kCacheKeySize)) {
|
|
return;
|
|
}
|
|
table_.Erase(hashed_key);
|
|
}
|
|
|
|
template <class Table>
|
|
size_t ClockCacheShard<Table>::GetUsage() const {
|
|
return table_.GetUsage();
|
|
}
|
|
|
|
template <class Table>
|
|
size_t ClockCacheShard<Table>::GetDetachedUsage() const {
|
|
return table_.GetDetachedUsage();
|
|
}
|
|
|
|
template <class Table>
|
|
size_t ClockCacheShard<Table>::GetCapacity() const {
|
|
return capacity_;
|
|
}
|
|
|
|
template <class Table>
|
|
size_t ClockCacheShard<Table>::GetPinnedUsage() const {
|
|
// Computes the pinned usage by scanning the whole hash table. This
|
|
// is slow, but avoids keeping an exact counter on the clock usage,
|
|
// i.e., the number of not externally referenced elements.
|
|
// Why avoid this counter? Because Lookup removes elements from the clock
|
|
// list, so it would need to update the pinned usage every time,
|
|
// which creates additional synchronization costs.
|
|
size_t table_pinned_usage = 0;
|
|
const bool charge_metadata =
|
|
metadata_charge_policy_ == kFullChargeCacheMetadata;
|
|
table_.ConstApplyToEntriesRange(
|
|
[&table_pinned_usage, charge_metadata](const HandleImpl& h) {
|
|
uint64_t meta = h.meta.load(std::memory_order_relaxed);
|
|
uint64_t refcount = GetRefcount(meta);
|
|
// Holding one ref for ConstApplyToEntriesRange
|
|
assert(refcount > 0);
|
|
if (refcount > 1) {
|
|
table_pinned_usage += h.GetTotalCharge();
|
|
if (charge_metadata) {
|
|
table_pinned_usage += sizeof(HandleImpl);
|
|
}
|
|
}
|
|
},
|
|
0, table_.GetTableSize(), true);
|
|
|
|
return table_pinned_usage + table_.GetDetachedUsage();
|
|
}
|
|
|
|
template <class Table>
|
|
size_t ClockCacheShard<Table>::GetOccupancyCount() const {
|
|
return table_.GetOccupancy();
|
|
}
|
|
|
|
template <class Table>
|
|
size_t ClockCacheShard<Table>::GetOccupancyLimit() const {
|
|
return table_.GetOccupancyLimit();
|
|
}
|
|
|
|
template <class Table>
|
|
size_t ClockCacheShard<Table>::GetTableAddressCount() const {
|
|
return table_.GetTableSize();
|
|
}
|
|
|
|
// Explicit instantiation
|
|
template class ClockCacheShard<HyperClockTable>;
|
|
|
|
HyperClockCache::HyperClockCache(
|
|
size_t capacity, size_t estimated_value_size, int num_shard_bits,
|
|
bool strict_capacity_limit,
|
|
CacheMetadataChargePolicy metadata_charge_policy,
|
|
std::shared_ptr<MemoryAllocator> memory_allocator)
|
|
: ShardedCache(capacity, num_shard_bits, strict_capacity_limit,
|
|
std::move(memory_allocator)) {
|
|
assert(estimated_value_size > 0 ||
|
|
metadata_charge_policy != kDontChargeCacheMetadata);
|
|
// TODO: should not need to go through two levels of pointer indirection to
|
|
// get to table entries
|
|
size_t per_shard = GetPerShardCapacity();
|
|
MemoryAllocator* alloc = this->memory_allocator();
|
|
InitShards([=](Shard* cs) {
|
|
HyperClockTable::Opts opts;
|
|
opts.estimated_value_size = estimated_value_size;
|
|
new (cs) Shard(per_shard, strict_capacity_limit, metadata_charge_policy,
|
|
alloc, opts);
|
|
});
|
|
}
|
|
|
|
Cache::ObjectPtr HyperClockCache::Value(Handle* handle) {
|
|
return reinterpret_cast<const HandleImpl*>(handle)->value;
|
|
}
|
|
|
|
size_t HyperClockCache::GetCharge(Handle* handle) const {
|
|
return reinterpret_cast<const HandleImpl*>(handle)->GetTotalCharge();
|
|
}
|
|
|
|
const Cache::CacheItemHelper* HyperClockCache::GetCacheItemHelper(
|
|
Handle* handle) const {
|
|
auto h = reinterpret_cast<const HandleImpl*>(handle);
|
|
return h->helper;
|
|
}
|
|
|
|
namespace {
|
|
|
|
// For each cache shard, estimate what the table load factor would be if
|
|
// cache filled to capacity with average entries. This is considered
|
|
// indicative of a potential problem if the shard is essentially operating
|
|
// "at limit", which we define as high actual usage (>80% of capacity)
|
|
// or actual occupancy very close to limit (>95% of limit).
|
|
// Also, for each shard compute the recommended estimated_entry_charge,
|
|
// and keep the minimum one for use as overall recommendation.
|
|
void AddShardEvaluation(const HyperClockCache::Shard& shard,
|
|
std::vector<double>& predicted_load_factors,
|
|
size_t& min_recommendation) {
|
|
size_t usage = shard.GetUsage() - shard.GetDetachedUsage();
|
|
size_t capacity = shard.GetCapacity();
|
|
double usage_ratio = 1.0 * usage / capacity;
|
|
|
|
size_t occupancy = shard.GetOccupancyCount();
|
|
size_t occ_limit = shard.GetOccupancyLimit();
|
|
double occ_ratio = 1.0 * occupancy / occ_limit;
|
|
if (usage == 0 || occupancy == 0 || (usage_ratio < 0.8 && occ_ratio < 0.95)) {
|
|
// Skip as described above
|
|
return;
|
|
}
|
|
|
|
// If filled to capacity, what would the occupancy ratio be?
|
|
double ratio = occ_ratio / usage_ratio;
|
|
// Given max load factor, what that load factor be?
|
|
double lf = ratio * kStrictLoadFactor;
|
|
predicted_load_factors.push_back(lf);
|
|
|
|
// Update min_recommendation also
|
|
size_t recommendation = usage / occupancy;
|
|
min_recommendation = std::min(min_recommendation, recommendation);
|
|
}
|
|
|
|
} // namespace
|
|
|
|
void HyperClockCache::ReportProblems(
|
|
const std::shared_ptr<Logger>& info_log) const {
|
|
uint32_t shard_count = GetNumShards();
|
|
std::vector<double> predicted_load_factors;
|
|
size_t min_recommendation = SIZE_MAX;
|
|
const_cast<HyperClockCache*>(this)->ForEachShard(
|
|
[&](HyperClockCache::Shard* shard) {
|
|
AddShardEvaluation(*shard, predicted_load_factors, min_recommendation);
|
|
});
|
|
|
|
if (predicted_load_factors.empty()) {
|
|
// None operating "at limit" -> nothing to report
|
|
return;
|
|
}
|
|
std::sort(predicted_load_factors.begin(), predicted_load_factors.end());
|
|
|
|
// First, if the average load factor is within spec, we aren't going to
|
|
// complain about a few shards being out of spec.
|
|
// NOTE: this is only the average among cache shards operating "at limit,"
|
|
// which should be representative of what we care about. It it normal, even
|
|
// desirable, for a cache to operate "at limit" so this should not create
|
|
// selection bias. See AddShardEvaluation().
|
|
// TODO: Consider detecting cases where decreasing the number of shards
|
|
// would be good, e.g. serious imbalance among shards.
|
|
double average_load_factor =
|
|
std::accumulate(predicted_load_factors.begin(),
|
|
predicted_load_factors.end(), 0.0) /
|
|
shard_count;
|
|
|
|
constexpr double kLowSpecLoadFactor = kLoadFactor / 2;
|
|
constexpr double kMidSpecLoadFactor = kLoadFactor / 1.414;
|
|
if (average_load_factor > kLoadFactor) {
|
|
// Out of spec => Consider reporting load factor too high
|
|
// Estimate effective overall capacity loss due to enforcing occupancy limit
|
|
double lost_portion = 0.0;
|
|
int over_count = 0;
|
|
for (double lf : predicted_load_factors) {
|
|
if (lf > kStrictLoadFactor) {
|
|
++over_count;
|
|
lost_portion += (lf - kStrictLoadFactor) / lf / shard_count;
|
|
}
|
|
}
|
|
// >= 20% loss -> error
|
|
// >= 10% loss -> consistent warning
|
|
// >= 1% loss -> intermittent warning
|
|
InfoLogLevel level = InfoLogLevel::INFO_LEVEL;
|
|
bool report = true;
|
|
if (lost_portion > 0.2) {
|
|
level = InfoLogLevel::ERROR_LEVEL;
|
|
} else if (lost_portion > 0.1) {
|
|
level = InfoLogLevel::WARN_LEVEL;
|
|
} else if (lost_portion > 0.01) {
|
|
int report_percent = static_cast<int>(lost_portion * 100.0);
|
|
if (Random::GetTLSInstance()->PercentTrue(report_percent)) {
|
|
level = InfoLogLevel::WARN_LEVEL;
|
|
}
|
|
} else {
|
|
// don't report
|
|
report = false;
|
|
}
|
|
if (report) {
|
|
ROCKS_LOG_AT_LEVEL(
|
|
info_log, level,
|
|
"HyperClockCache@%p unable to use estimated %.1f%% capacity because "
|
|
"of "
|
|
"full occupancy in %d/%u cache shards (estimated_entry_charge too "
|
|
"high). Recommend estimated_entry_charge=%zu",
|
|
this, lost_portion * 100.0, over_count, (unsigned)shard_count,
|
|
min_recommendation);
|
|
}
|
|
} else if (average_load_factor < kLowSpecLoadFactor) {
|
|
// Out of spec => Consider reporting load factor too low
|
|
// But cautiously because low is not as big of a problem.
|
|
|
|
// Only report if highest occupancy shard is also below
|
|
// spec and only if average is substantially out of spec
|
|
if (predicted_load_factors.back() < kLowSpecLoadFactor &&
|
|
average_load_factor < kLowSpecLoadFactor / 1.414) {
|
|
InfoLogLevel level = InfoLogLevel::INFO_LEVEL;
|
|
if (average_load_factor < kLowSpecLoadFactor / 2) {
|
|
level = InfoLogLevel::WARN_LEVEL;
|
|
}
|
|
ROCKS_LOG_AT_LEVEL(
|
|
info_log, level,
|
|
"HyperClockCache@%p table has low occupancy at full capacity. Higher "
|
|
"estimated_entry_charge (about %.1fx) would likely improve "
|
|
"performance. Recommend estimated_entry_charge=%zu",
|
|
this, kMidSpecLoadFactor / average_load_factor, min_recommendation);
|
|
}
|
|
}
|
|
}
|
|
|
|
} // namespace clock_cache
|
|
|
|
// DEPRECATED (see public API)
|
|
std::shared_ptr<Cache> NewClockCache(
|
|
size_t capacity, int num_shard_bits, bool strict_capacity_limit,
|
|
CacheMetadataChargePolicy metadata_charge_policy) {
|
|
return NewLRUCache(capacity, num_shard_bits, strict_capacity_limit,
|
|
/* high_pri_pool_ratio */ 0.5, nullptr,
|
|
kDefaultToAdaptiveMutex, metadata_charge_policy,
|
|
/* low_pri_pool_ratio */ 0.0);
|
|
}
|
|
|
|
std::shared_ptr<Cache> HyperClockCacheOptions::MakeSharedCache() const {
|
|
auto my_num_shard_bits = num_shard_bits;
|
|
if (my_num_shard_bits >= 20) {
|
|
return nullptr; // The cache cannot be sharded into too many fine pieces.
|
|
}
|
|
if (my_num_shard_bits < 0) {
|
|
// Use larger shard size to reduce risk of large entries clustering
|
|
// or skewing individual shards.
|
|
constexpr size_t min_shard_size = 32U * 1024U * 1024U;
|
|
my_num_shard_bits = GetDefaultCacheShardBits(capacity, min_shard_size);
|
|
}
|
|
return std::make_shared<clock_cache::HyperClockCache>(
|
|
capacity, estimated_entry_charge, my_num_shard_bits,
|
|
strict_capacity_limit, metadata_charge_policy, memory_allocator);
|
|
}
|
|
|
|
} // namespace ROCKSDB_NAMESPACE
|