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https://github.com/ClickHouse/ClickHouse.git
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4ecfd44015
* do not insert produced value into the cache if the cache has been reset. * less logging * cosmetic fixes
348 lines
8.3 KiB
C++
348 lines
8.3 KiB
C++
#pragma once
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#include <unordered_map>
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#include <list>
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#include <memory>
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#include <chrono>
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#include <mutex>
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#include <common/logger_useful.h>
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namespace DB
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{
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template <typename T>
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struct TrivialWeightFunction
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{
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size_t operator()(const T & x) const
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{
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return 1;
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}
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};
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/// Thread-safe cache that evicts entries which are not used for a long time or are expired.
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/// WeightFunction is a functor that takes Mapped as a parameter and returns "weight" (approximate size)
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/// of that value.
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/// Cache starts to evict entries when their total weight exceeds max_size and when expiration time of these
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/// entries is due.
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/// Value weight should not change after insertion.
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template <typename TKey, typename TMapped, typename HashFunction = std::hash<TMapped>, typename WeightFunction = TrivialWeightFunction<TMapped> >
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class LRUCache
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{
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public:
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using Key = TKey;
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using Mapped = TMapped;
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using MappedPtr = std::shared_ptr<Mapped>;
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using Delay = std::chrono::seconds;
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private:
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using Clock = std::chrono::steady_clock;
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using Timestamp = Clock::time_point;
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public:
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LRUCache(size_t max_size_, const Delay & expiration_delay_ = Delay::zero())
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: max_size(std::max(1ul, max_size_)), expiration_delay(expiration_delay_) {}
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MappedPtr get(const Key & key)
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{
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std::lock_guard<std::mutex> lock(mutex);
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auto res = getImpl(key, lock);
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if (res)
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++hits;
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else
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++misses;
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return res;
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}
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void set(const Key & key, const MappedPtr & mapped)
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{
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std::lock_guard<std::mutex> lock(mutex);
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setImpl(key, mapped, lock);
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}
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/// If the value for the key is in the cache, returns it. If it is not, calls load_func() to
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/// produce it, saves the result in the cache and returns it.
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/// Only one of several concurrent threads calling getOrSet() will call load_func(),
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/// others will wait for that call to complete and will use its result (this helps prevent cache stampede).
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/// Exceptions occuring in load_func will be propagated to the caller. Another thread from the
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/// set of concurrent threads will then try to call its load_func etc.
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///
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/// Returns std::pair of the cached value and a bool indicating whether the value was produced during this call.
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template<typename LoadFunc>
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std::pair<MappedPtr, bool> getOrSet(const Key & key, LoadFunc&& load_func)
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{
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InsertTokenHolder token_holder;
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{
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std::lock_guard<std::mutex> cache_lock(mutex);
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auto val = getImpl(key, cache_lock);
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if (val)
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{
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++hits;
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return std::make_pair(val, false);
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}
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auto & token = insert_tokens[key];
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if (!token)
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token = std::make_shared<InsertToken>(*this);
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token_holder.acquire(&key, token, cache_lock);
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}
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InsertToken * token = token_holder.token.get();
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std::lock_guard<std::mutex> token_lock(token->mutex);
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token_holder.cleaned_up = token->cleaned_up;
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if (token->value)
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{
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/// Another thread already produced the value while we waited for token->mutex.
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++hits;
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return std::make_pair(token->value, false);
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}
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++misses;
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token->value = load_func();
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std::lock_guard<std::mutex> cache_lock(mutex);
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/// Insert the new value only if the token is still in present in insert_tokens.
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/// (The token may be absent because of a concurrent reset() call).
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auto token_it = insert_tokens.find(key);
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if (token_it != insert_tokens.end() && token_it->second.get() == token)
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setImpl(key, token->value, cache_lock);
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if (!token->cleaned_up)
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token_holder.cleanup(token_lock, cache_lock);
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return std::make_pair(token->value, true);
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}
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void getStats(size_t & out_hits, size_t & out_misses) const
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{
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std::lock_guard<std::mutex> lock(mutex);
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out_hits = hits;
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out_misses = misses;
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}
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size_t weight() const
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{
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std::lock_guard<std::mutex> lock(mutex);
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return current_size;
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}
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size_t count() const
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{
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std::lock_guard<std::mutex> lock(mutex);
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return cells.size();
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}
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void reset()
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{
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std::lock_guard<std::mutex> lock(mutex);
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queue.clear();
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cells.clear();
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insert_tokens.clear();
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current_size = 0;
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hits = 0;
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misses = 0;
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current_weight_lost = 0;
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}
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protected:
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/// Total weight of evicted values. This value is reset every time it is sent to profile events.
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size_t current_weight_lost = 0;
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private:
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/// Represents pending insertion attempt.
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struct InsertToken
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{
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InsertToken(LRUCache & cache_) : cache(cache_) {}
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std::mutex mutex;
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bool cleaned_up = false; /// Protected by the token mutex
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MappedPtr value; /// Protected by the token mutex
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LRUCache & cache;
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size_t refcount = 0; /// Protected by the cache mutex
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};
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using InsertTokenById = std::unordered_map<Key, std::shared_ptr<InsertToken>, HashFunction>;
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/// This class is responsible for removing used insert tokens from the insert_tokens map.
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/// Among several concurrent threads the first successful one is responsible for removal. But if they all
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/// fail, then the last one is responsible.
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struct InsertTokenHolder
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{
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const Key * key = nullptr;
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std::shared_ptr<InsertToken> token;
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bool cleaned_up = false;
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InsertTokenHolder() = default;
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void acquire(const Key * key_, const std::shared_ptr<InsertToken> & token_, std::lock_guard<std::mutex> & cache_lock)
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{
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key = key_;
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token = token_;
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++token->refcount;
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}
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void cleanup(std::lock_guard<std::mutex> & token_lock, std::lock_guard<std::mutex> & cache_lock)
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{
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token->cache.insert_tokens.erase(*key);
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token->cleaned_up = true;
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cleaned_up = true;
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}
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~InsertTokenHolder()
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{
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if (!token)
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return;
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if (cleaned_up)
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return;
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std::lock_guard<std::mutex> token_lock(token->mutex);
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if (token->cleaned_up)
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return;
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std::lock_guard<std::mutex> cache_lock(token->cache.mutex);
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--token->refcount;
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if (token->refcount == 0)
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cleanup(token_lock, cache_lock);
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}
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};
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friend struct InsertTokenHolder;
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using LRUQueue = std::list<Key>;
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using LRUQueueIterator = typename LRUQueue::iterator;
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struct Cell
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{
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bool expired(const Timestamp & last_timestamp, const Delay & expiration_delay) const
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{
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return (expiration_delay == Delay::zero()) ||
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((last_timestamp > timestamp) && ((last_timestamp - timestamp) > expiration_delay));
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}
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MappedPtr value;
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size_t size;
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LRUQueueIterator queue_iterator;
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Timestamp timestamp;
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};
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using Cells = std::unordered_map<Key, Cell, HashFunction>;
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InsertTokenById insert_tokens;
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LRUQueue queue;
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Cells cells;
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/// Total weight of values.
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size_t current_size = 0;
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const size_t max_size;
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const Delay expiration_delay;
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mutable std::mutex mutex;
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size_t hits = 0;
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size_t misses = 0;
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WeightFunction weight_function;
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MappedPtr getImpl(const Key & key, std::lock_guard<std::mutex> & cache_lock)
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{
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auto it = cells.find(key);
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if (it == cells.end())
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{
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return MappedPtr();
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}
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Cell & cell = it->second;
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updateCellTimestamp(cell);
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/// Move the key to the end of the queue. The iterator remains valid.
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queue.splice(queue.end(), queue, cell.queue_iterator);
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return cell.value;
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}
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void setImpl(const Key & key, const MappedPtr & mapped, std::lock_guard<std::mutex> & cache_lock)
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{
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auto res = cells.emplace(std::piecewise_construct,
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std::forward_as_tuple(key),
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std::forward_as_tuple());
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Cell & cell = res.first->second;
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bool inserted = res.second;
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if (inserted)
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{
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cell.queue_iterator = queue.insert(queue.end(), key);
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}
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else
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{
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current_size -= cell.size;
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queue.splice(queue.end(), queue, cell.queue_iterator);
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}
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cell.value = mapped;
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cell.size = cell.value ? weight_function(*cell.value) : 0;
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current_size += cell.size;
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updateCellTimestamp(cell);
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removeOverflow(cell.timestamp);
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}
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void updateCellTimestamp(Cell & cell)
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{
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if (expiration_delay != Delay::zero())
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cell.timestamp = Clock::now();
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}
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void removeOverflow(const Timestamp & last_timestamp)
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{
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size_t queue_size = cells.size();
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while ((current_size > max_size) && (queue_size > 1))
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{
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const Key & key = queue.front();
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auto it = cells.find(key);
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if (it == cells.end())
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{
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LOG_ERROR(&Logger::get("LRUCache"), "LRUCache became inconsistent. There must be a bug in it.");
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abort();
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}
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const auto & cell = it->second;
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if (!cell.expired(last_timestamp, expiration_delay))
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break;
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current_size -= cell.size;
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current_weight_lost += cell.size;
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cells.erase(it);
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queue.pop_front();
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--queue_size;
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}
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if (current_size > (1ull << 63))
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{
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LOG_ERROR(&Logger::get("LRUCache"), "LRUCache became inconsistent. There must be a bug in it.");
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abort();
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}
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}
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};
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}
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