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0050a73a4f
Summary: This change standardizes on a new 16-byte cache key format for block cache (incl compressed and secondary) and persistent cache (but not table cache and row cache). The goal is a really fast cache key with practically ideal stability and uniqueness properties without external dependencies (e.g. from FileSystem). A fixed key size of 16 bytes should enable future optimizations to the concurrent hash table for block cache, which is a heavy CPU user / bottleneck, but there appears to be measurable performance improvement even with no changes to LRUCache. This change replaces a lot of disjointed and ugly code handling cache keys with calls to a simple, clean new internal API (cache_key.h). (Preserving the old cache key logic under an option would be very ugly and likely negate the performance gain of the new approach. Complete replacement carries some inherent risk, but I think that's acceptable with sufficient analysis and testing.) The scheme for encoding new cache keys is complicated but explained in cache_key.cc. Also: EndianSwapValue is moved to math.h to be next to other bit operations. (Explains some new include "math.h".) ReverseBits operation added and unit tests added to hash_test for both. Fixes https://github.com/facebook/rocksdb/issues/7405 (presuming a root cause) Pull Request resolved: https://github.com/facebook/rocksdb/pull/9126 Test Plan: ### Basic correctness Several tests needed updates to work with the new functionality, mostly because we are no longer relying on filesystem for stable cache keys so table builders & readers need more context info to agree on cache keys. This functionality is so core, a huge number of existing tests exercise the cache key functionality. ### Performance Create db with `TEST_TMPDIR=/dev/shm ./db_bench -bloom_bits=10 -benchmarks=fillrandom -num=3000000 -partition_index_and_filters` And test performance with `TEST_TMPDIR=/dev/shm ./db_bench -readonly -use_existing_db -bloom_bits=10 -benchmarks=readrandom -num=3000000 -duration=30 -cache_index_and_filter_blocks -cache_size=250000 -threads=4` using DEBUG_LEVEL=0 and simultaneous before & after runs. Before ops/sec, avg over 100 runs: 121924 After ops/sec, avg over 100 runs: 125385 (+2.8%) ### Collision probability I have built a tool, ./cache_bench -stress_cache_key to broadly simulate host-wide cache activity over many months, by making some pessimistic simplifying assumptions: * Every generated file has a cache entry for every byte offset in the file (contiguous range of cache keys) * All of every file is cached for its entire lifetime We use a simple table with skewed address assignment and replacement on address collision to simulate files coming & going, with quite a variance (super-Poisson) in ages. Some output with `./cache_bench -stress_cache_key -sck_keep_bits=40`: ``` Total cache or DBs size: 32TiB Writing 925.926 MiB/s or 76.2939TiB/day Multiply by 9.22337e+18 to correct for simulation losses (but still assume whole file cached) ``` These come from default settings of 2.5M files per day of 32 MB each, and `-sck_keep_bits=40` means that to represent a single file, we are only keeping 40 bits of the 128-bit cache key. With file size of 2\*\*25 contiguous keys (pessimistic), our simulation is about 2\*\*(128-40-25) or about 9 billion billion times more prone to collision than reality. More default assumptions, relatively pessimistic: * 100 DBs in same process (doesn't matter much) * Re-open DB in same process (new session ID related to old session ID) on average every 100 files generated * Restart process (all new session IDs unrelated to old) 24 times per day After enough data, we get a result at the end: ``` (keep 40 bits) 17 collisions after 2 x 90 days, est 10.5882 days between (9.76592e+19 corrected) ``` If we believe the (pessimistic) simulation and the mathematical generalization, we would need to run a billion machines all for 97 billion days to expect a cache key collision. To help verify that our generalization ("corrected") is robust, we can make our simulation more precise with `-sck_keep_bits=41` and `42`, which takes more running time to get enough data: ``` (keep 41 bits) 16 collisions after 4 x 90 days, est 22.5 days between (1.03763e+20 corrected) (keep 42 bits) 19 collisions after 10 x 90 days, est 47.3684 days between (1.09224e+20 corrected) ``` The generalized prediction still holds. With the `-sck_randomize` option, we can see that we are beating "random" cache keys (except offsets still non-randomized) by a modest amount (roughly 20x less collision prone than random), which should make us reasonably comfortable even in "degenerate" cases: ``` 197 collisions after 1 x 90 days, est 0.456853 days between (4.21372e+18 corrected) ``` I've run other tests to validate other conditions behave as expected, never behaving "worse than random" unless we start chopping off structured data. Reviewed By: zhichao-cao Differential Revision: D33171746 Pulled By: pdillinger fbshipit-source-id: f16a57e369ed37be5e7e33525ace848d0537c88f
133 lines
5.2 KiB
C++
133 lines
5.2 KiB
C++
// Copyright (c) Facebook, Inc. and its affiliates. 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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#pragma once
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#include <cstdint>
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#include "rocksdb/rocksdb_namespace.h"
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#include "rocksdb/slice.h"
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namespace ROCKSDB_NAMESPACE {
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class Cache;
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// A standard holder for fixed-size block cache keys (and for related caches).
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// They are created through one of these, each using its own range of values:
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// * CacheKey::CreateUniqueForCacheLifetime
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// * CacheKey::CreateUniqueForProcessLifetime
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// * Default ctor ("empty" cache key)
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// * OffsetableCacheKey->WithOffset
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//
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// The first two use atomic counters to guarantee uniqueness over the given
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// lifetime and the last uses a form of universally unique identifier for
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// uniqueness with very high probabilty (and guaranteed for files generated
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// during a single process lifetime).
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//
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// CacheKeys are currently used by calling AsSlice() to pass as a key to
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// Cache. For performance, the keys are endianness-dependent (though otherwise
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// portable). (Persistable cache entries are not intended to cross platforms.)
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class CacheKey {
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public:
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// For convenience, constructs an "empty" cache key that is never returned
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// by other means.
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inline CacheKey() : session_etc64_(), offset_etc64_() {}
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inline bool IsEmpty() const {
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return (session_etc64_ == 0) & (offset_etc64_ == 0);
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}
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// Use this cache key as a Slice (byte order is endianness-dependent)
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inline Slice AsSlice() const {
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static_assert(sizeof(*this) == 16, "Standardized on 16-byte cache key");
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assert(!IsEmpty());
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return Slice(reinterpret_cast<const char *>(this), sizeof(*this));
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}
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// Create a CacheKey that is unique among others associated with this Cache
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// instance. Depends on Cache::NewId. This is useful for block cache
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// "reservations".
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static CacheKey CreateUniqueForCacheLifetime(Cache *cache);
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// Create a CacheKey that is unique among others for the lifetime of this
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// process. This is useful for saving in a static data member so that
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// different DB instances can agree on a cache key for shared entities,
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// such as for CacheEntryStatsCollector.
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static CacheKey CreateUniqueForProcessLifetime();
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protected:
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friend class OffsetableCacheKey;
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CacheKey(uint64_t session_etc64, uint64_t offset_etc64)
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: session_etc64_(session_etc64), offset_etc64_(offset_etc64) {}
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uint64_t session_etc64_;
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uint64_t offset_etc64_;
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};
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// A file-specific generator of cache keys, sometimes referred to as the
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// "base" cache key for a file because all the cache keys for various offsets
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// within the file are computed using simple arithmetic. The basis for the
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// general approach is dicussed here: https://github.com/pdillinger/unique_id
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// Heavily related to GetUniqueIdFromTableProperties.
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//
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// If the db_id, db_session_id, and file_number come from the file's table
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// properties, then the keys will be stable across DB::Open/Close, backup/
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// restore, import/export, etc.
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//
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// This class "is a" CacheKey only privately so that it is not misused as
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// a ready-to-use CacheKey.
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class OffsetableCacheKey : private CacheKey {
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public:
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// For convenience, constructs an "empty" cache key that should not be used.
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inline OffsetableCacheKey() : CacheKey() {}
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// Constructs an OffsetableCacheKey with the given information about a file.
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// max_offset is based on file size (see WithOffset) and is required here to
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// choose an appropriate (sub-)encoding. This constructor never generates an
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// "empty" base key.
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OffsetableCacheKey(const std::string &db_id, const std::string &db_session_id,
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uint64_t file_number, uint64_t max_offset);
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inline bool IsEmpty() const {
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bool result = session_etc64_ == 0;
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assert(!(offset_etc64_ > 0 && result));
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return result;
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}
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// Construct a CacheKey for an offset within a file, which must be
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// <= max_offset provided in constructor. An offset is not necessarily a
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// byte offset if a smaller unique identifier of keyable offsets is used.
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//
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// This class was designed to make this hot code extremely fast.
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inline CacheKey WithOffset(uint64_t offset) const {
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assert(!IsEmpty());
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assert(offset <= max_offset_);
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return CacheKey(session_etc64_, offset_etc64_ ^ offset);
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}
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// The "common prefix" is a shared prefix for all the returned CacheKeys,
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// that also happens to usually be the same among many files in the same DB,
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// so is efficient and highly accurate (not perfectly) for DB-specific cache
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// dump selection (but not file-specific).
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static constexpr size_t kCommonPrefixSize = 8;
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inline Slice CommonPrefixSlice() const {
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static_assert(sizeof(session_etc64_) == kCommonPrefixSize,
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"8 byte common prefix expected");
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assert(!IsEmpty());
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assert(&this->session_etc64_ == static_cast<const void *>(this));
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return Slice(reinterpret_cast<const char *>(this), kCommonPrefixSize);
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}
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// For any max_offset <= this value, the same encoding scheme is guaranteed.
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static constexpr uint64_t kMaxOffsetStandardEncoding = 0xffffffffffU;
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private:
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#ifndef NDEBUG
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uint64_t max_offset_ = 0;
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#endif
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};
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} // namespace ROCKSDB_NAMESPACE
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