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97f2a2213e
* Move some code outside dbms/src folder * Fix paths
501 lines
18 KiB
C++
501 lines
18 KiB
C++
#pragma once
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#include <atomic>
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#include <chrono>
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#include <cmath>
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#include <map>
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#include <mutex>
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#include <shared_mutex>
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#include <utility>
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#include <variant>
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#include <vector>
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#include <common/logger_useful.h>
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#include <Columns/ColumnDecimal.h>
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#include <Columns/ColumnString.h>
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#include <Common/ThreadPool.h>
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#include <Common/ConcurrentBoundedQueue.h>
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#include <pcg_random.hpp>
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#include <Common/ArenaWithFreeLists.h>
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#include <Common/CurrentMetrics.h>
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#include <ext/bit_cast.h>
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#include "DictionaryStructure.h"
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#include "IDictionary.h"
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#include "IDictionarySource.h"
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namespace CurrentMetrics
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{
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extern const Metric CacheDictionaryUpdateQueueBatches;
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extern const Metric CacheDictionaryUpdateQueueKeys;
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}
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namespace DB
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{
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namespace ErrorCodes
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{
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}
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/*
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*
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* This dictionary is stored in a cache that has a fixed number of cells.
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* These cells contain frequently used elements.
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* When searching for a dictionary, the cache is searched first and special heuristic is used:
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* while looking for the key, we take a look only at max_collision_length elements.
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* So, our cache is not perfect. It has errors like "the key is in cache, but the cache says that it does not".
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* And in this case we simply ask external source for the key which is faster.
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* You have to keep this logic in mind.
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* */
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class CacheDictionary final : public IDictionary
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{
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public:
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CacheDictionary(
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const std::string & database_,
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const std::string & name_,
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const DictionaryStructure & dict_struct_,
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DictionarySourcePtr source_ptr_,
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DictionaryLifetime dict_lifetime_,
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size_t size_,
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bool allow_read_expired_keys_,
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size_t max_update_queue_size_,
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size_t update_queue_push_timeout_milliseconds_,
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size_t max_threads_for_updates);
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~CacheDictionary() override;
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const std::string & getDatabase() const override { return database; }
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const std::string & getName() const override { return name; }
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const std::string & getFullName() const override { return full_name; }
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std::string getTypeName() const override { return "Cache"; }
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size_t getBytesAllocated() const override { return bytes_allocated + (string_arena ? string_arena->size() : 0); }
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size_t getQueryCount() const override { return query_count.load(std::memory_order_relaxed); }
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double getHitRate() const override
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{
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return static_cast<double>(hit_count.load(std::memory_order_acquire)) / query_count.load(std::memory_order_relaxed);
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}
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size_t getElementCount() const override { return element_count.load(std::memory_order_relaxed); }
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double getLoadFactor() const override { return static_cast<double>(element_count.load(std::memory_order_relaxed)) / size; }
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bool supportUpdates() const override { return false; }
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std::shared_ptr<const IExternalLoadable> clone() const override
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{
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return std::make_shared<CacheDictionary>(
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database, name, dict_struct, source_ptr->clone(), dict_lifetime, size,
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allow_read_expired_keys, max_update_queue_size,
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update_queue_push_timeout_milliseconds, max_threads_for_updates);
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}
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const IDictionarySource * getSource() const override { return source_ptr.get(); }
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const DictionaryLifetime & getLifetime() const override { return dict_lifetime; }
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const DictionaryStructure & getStructure() const override { return dict_struct; }
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bool isInjective(const std::string & attribute_name) const override
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{
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return dict_struct.attributes[&getAttribute(attribute_name) - attributes.data()].injective;
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}
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bool hasHierarchy() const override { return hierarchical_attribute; }
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void toParent(const PaddedPODArray<Key> & ids, PaddedPODArray<Key> & out) const override;
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void isInVectorVector(
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const PaddedPODArray<Key> & child_ids, const PaddedPODArray<Key> & ancestor_ids, PaddedPODArray<UInt8> & out) const override;
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void isInVectorConstant(const PaddedPODArray<Key> & child_ids, const Key ancestor_id, PaddedPODArray<UInt8> & out) const override;
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void isInConstantVector(const Key child_id, const PaddedPODArray<Key> & ancestor_ids, PaddedPODArray<UInt8> & out) const override;
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std::exception_ptr getLastException() const override;
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template <typename T>
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using ResultArrayType = std::conditional_t<IsDecimalNumber<T>, DecimalPaddedPODArray<T>, PaddedPODArray<T>>;
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#define DECLARE(TYPE) \
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void get##TYPE(const std::string & attribute_name, const PaddedPODArray<Key> & ids, ResultArrayType<TYPE> & out) const;
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DECLARE(UInt8)
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DECLARE(UInt16)
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DECLARE(UInt32)
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DECLARE(UInt64)
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DECLARE(UInt128)
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DECLARE(Int8)
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DECLARE(Int16)
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DECLARE(Int32)
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DECLARE(Int64)
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DECLARE(Float32)
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DECLARE(Float64)
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DECLARE(Decimal32)
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DECLARE(Decimal64)
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DECLARE(Decimal128)
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#undef DECLARE
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void getString(const std::string & attribute_name, const PaddedPODArray<Key> & ids, ColumnString * out) const;
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#define DECLARE(TYPE) \
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void get##TYPE( \
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const std::string & attribute_name, \
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const PaddedPODArray<Key> & ids, \
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const PaddedPODArray<TYPE> & def, \
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ResultArrayType<TYPE> & out) const;
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DECLARE(UInt8)
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DECLARE(UInt16)
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DECLARE(UInt32)
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DECLARE(UInt64)
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DECLARE(UInt128)
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DECLARE(Int8)
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DECLARE(Int16)
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DECLARE(Int32)
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DECLARE(Int64)
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DECLARE(Float32)
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DECLARE(Float64)
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DECLARE(Decimal32)
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DECLARE(Decimal64)
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DECLARE(Decimal128)
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#undef DECLARE
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void
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getString(const std::string & attribute_name, const PaddedPODArray<Key> & ids, const ColumnString * const def, ColumnString * const out)
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const;
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#define DECLARE(TYPE) \
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void get##TYPE(const std::string & attribute_name, const PaddedPODArray<Key> & ids, const TYPE def, ResultArrayType<TYPE> & out) const;
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DECLARE(UInt8)
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DECLARE(UInt16)
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DECLARE(UInt32)
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DECLARE(UInt64)
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DECLARE(UInt128)
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DECLARE(Int8)
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DECLARE(Int16)
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DECLARE(Int32)
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DECLARE(Int64)
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DECLARE(Float32)
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DECLARE(Float64)
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DECLARE(Decimal32)
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DECLARE(Decimal64)
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DECLARE(Decimal128)
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#undef DECLARE
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void getString(const std::string & attribute_name, const PaddedPODArray<Key> & ids, const String & def, ColumnString * const out) const;
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void has(const PaddedPODArray<Key> & ids, PaddedPODArray<UInt8> & out) const override;
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BlockInputStreamPtr getBlockInputStream(const Names & column_names, size_t max_block_size) const override;
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private:
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template <typename Value>
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using ContainerType = Value[];
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template <typename Value>
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using ContainerPtrType = std::unique_ptr<ContainerType<Value>>;
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struct CellMetadata final
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{
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using time_point_t = std::chrono::system_clock::time_point;
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using time_point_rep_t = time_point_t::rep;
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using time_point_urep_t = std::make_unsigned_t<time_point_rep_t>;
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static constexpr UInt64 EXPIRES_AT_MASK = std::numeric_limits<time_point_rep_t>::max();
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static constexpr UInt64 IS_DEFAULT_MASK = ~EXPIRES_AT_MASK;
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UInt64 id;
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/// Stores both expiration time and `is_default` flag in the most significant bit
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time_point_urep_t data;
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/// Sets expiration time, resets `is_default` flag to false
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time_point_t expiresAt() const { return ext::safe_bit_cast<time_point_t>(data & EXPIRES_AT_MASK); }
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void setExpiresAt(const time_point_t & t) { data = ext::safe_bit_cast<time_point_urep_t>(t); }
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bool isDefault() const { return (data & IS_DEFAULT_MASK) == IS_DEFAULT_MASK; }
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void setDefault() { data |= IS_DEFAULT_MASK; }
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};
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struct Attribute final
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{
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AttributeUnderlyingType type;
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std::variant<
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UInt8,
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UInt16,
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UInt32,
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UInt64,
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UInt128,
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Int8,
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Int16,
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Int32,
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Int64,
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Decimal32,
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Decimal64,
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Decimal128,
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Float32,
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Float64,
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String>
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null_values;
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std::variant<
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ContainerPtrType<UInt8>,
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ContainerPtrType<UInt16>,
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ContainerPtrType<UInt32>,
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ContainerPtrType<UInt64>,
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ContainerPtrType<UInt128>,
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ContainerPtrType<Int8>,
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ContainerPtrType<Int16>,
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ContainerPtrType<Int32>,
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ContainerPtrType<Int64>,
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ContainerPtrType<Decimal32>,
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ContainerPtrType<Decimal64>,
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ContainerPtrType<Decimal128>,
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ContainerPtrType<Float32>,
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ContainerPtrType<Float64>,
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ContainerPtrType<StringRef>>
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arrays;
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};
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void createAttributes();
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Attribute createAttributeWithType(const AttributeUnderlyingType type, const Field & null_value);
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template <typename AttributeType, typename OutputType, typename DefaultGetter>
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void getItemsNumberImpl(
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Attribute & attribute, const PaddedPODArray<Key> & ids, ResultArrayType<OutputType> & out, DefaultGetter && get_default) const;
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template <typename DefaultGetter>
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void getItemsString(Attribute & attribute, const PaddedPODArray<Key> & ids, ColumnString * out, DefaultGetter && get_default) const;
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PaddedPODArray<Key> getCachedIds() const;
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bool isEmptyCell(const UInt64 idx) const;
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size_t getCellIdx(const Key id) const;
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void setDefaultAttributeValue(Attribute & attribute, const Key idx) const;
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void setAttributeValue(Attribute & attribute, const Key idx, const Field & value) const;
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Attribute & getAttribute(const std::string & attribute_name) const;
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struct FindResult
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{
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const size_t cell_idx;
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const bool valid;
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const bool outdated;
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};
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FindResult findCellIdx(const Key & id, const CellMetadata::time_point_t now) const;
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template <typename AncestorType>
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void isInImpl(const PaddedPODArray<Key> & child_ids, const AncestorType & ancestor_ids, PaddedPODArray<UInt8> & out) const;
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const std::string database;
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const std::string name;
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const std::string full_name;
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const DictionaryStructure dict_struct;
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mutable DictionarySourcePtr source_ptr;
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const DictionaryLifetime dict_lifetime;
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const bool allow_read_expired_keys;
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const size_t max_update_queue_size;
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const size_t update_queue_push_timeout_milliseconds;
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const size_t max_threads_for_updates;
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Logger * const log;
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mutable std::shared_mutex rw_lock;
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/// Actual size will be increased to match power of 2
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const size_t size;
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/// all bits to 1 mask (size - 1) (0b1000 - 1 = 0b111)
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const size_t size_overlap_mask;
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/// Max tries to find cell, overlaped with mask: if size = 16 and start_cell=10: will try cells: 10,11,12,13,14,15,0,1,2,3
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static constexpr size_t max_collision_length = 10;
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const size_t zero_cell_idx{getCellIdx(0)};
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std::map<std::string, size_t> attribute_index_by_name;
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mutable std::vector<Attribute> attributes;
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mutable std::vector<CellMetadata> cells;
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Attribute * hierarchical_attribute = nullptr;
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std::unique_ptr<ArenaWithFreeLists> string_arena;
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mutable std::exception_ptr last_exception;
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mutable std::atomic<size_t> error_count = 0;
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mutable std::atomic<std::chrono::system_clock::time_point> backoff_end_time{std::chrono::system_clock::time_point{}};
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mutable pcg64 rnd_engine;
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mutable size_t bytes_allocated = 0;
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mutable std::atomic<size_t> element_count{0};
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mutable std::atomic<size_t> hit_count{0};
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mutable std::atomic<size_t> query_count{0};
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/// Field and methods correlated with update expired and not found keys
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using PresentIdHandler = std::function<void(Key, size_t)>;
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using AbsentIdHandler = std::function<void(Key, size_t)>;
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/*
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* Disclaimer: this comment is written not for fun.
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*
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* How the update goes: we basically have a method like get(keys)->values. Values are cached, so sometimes we
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* can return them from the cache. For values not in cache, we query them from the dictionary, and add to the
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* cache. The cache is lossy, so we can't expect it to store all the keys, and we store them separately. Normally,
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* they would be passed as a return value of get(), but for Unknown Reasons the dictionaries use a baroque
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* interface where get() accepts two callback, one that it calls for found values, and one for not found.
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*
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* Now we make it even uglier by doing this from multiple threads. The missing values are retreived from the
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* dictionary in a background thread, and this thread calls the provided callback. So if you provide the callbacks,
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* you MUST wait until the background update finishes, or god knows what happens. Unfortunately, we have no
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* way to check that you did this right, so good luck.
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*/
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struct UpdateUnit
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{
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UpdateUnit(std::vector<Key> requested_ids_,
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PresentIdHandler present_id_handler_,
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AbsentIdHandler absent_id_handler_) :
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requested_ids(std::move(requested_ids_)),
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present_id_handler(present_id_handler_),
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absent_id_handler(absent_id_handler_),
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alive_keys(CurrentMetrics::CacheDictionaryUpdateQueueKeys, requested_ids.size()){}
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explicit UpdateUnit(std::vector<Key> requested_ids_) :
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requested_ids(std::move(requested_ids_)),
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present_id_handler([](Key, size_t){}),
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absent_id_handler([](Key, size_t){}),
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alive_keys(CurrentMetrics::CacheDictionaryUpdateQueueKeys, requested_ids.size()){}
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std::vector<Key> requested_ids;
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PresentIdHandler present_id_handler;
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AbsentIdHandler absent_id_handler;
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std::atomic<bool> is_done{false};
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std::exception_ptr current_exception{nullptr};
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/// While UpdateUnit is alive, it is accounted in update_queue size.
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CurrentMetrics::Increment alive_batch{CurrentMetrics::CacheDictionaryUpdateQueueBatches};
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CurrentMetrics::Increment alive_keys;
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};
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using UpdateUnitPtr = std::shared_ptr<UpdateUnit>;
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using UpdateQueue = ConcurrentBoundedQueue<UpdateUnitPtr>;
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/*
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* This class is used to concatenate requested_keys.
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*
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* Imagine that we have several UpdateUnit with different vectors of keys and callbacks for that keys.
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* We concatenate them into a long vector of keys that looks like:
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*
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* a1...ak_a b1...bk_2 c1...ck_3,
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*
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* where a1...ak_a are requested_keys from the first UpdateUnit.
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* In addition we have the same number (three in this case) of callbacks.
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* This class helps us to find a callback (or many callbacks) for a special key.
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* */
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class BunchUpdateUnit
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{
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public:
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explicit BunchUpdateUnit(std::vector<UpdateUnitPtr> & update_request)
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{
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/// Here we prepare total count of all requested ids
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/// not to do useless allocations later.
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size_t total_requested_keys_count = 0;
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for (auto & unit_ptr: update_request)
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{
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total_requested_keys_count += unit_ptr->requested_ids.size();
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if (helper.empty())
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helper.push_back(unit_ptr->requested_ids.size());
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else
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helper.push_back(unit_ptr->requested_ids.size() + helper.back());
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present_id_handlers.emplace_back(unit_ptr->present_id_handler);
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absent_id_handlers.emplace_back(unit_ptr->absent_id_handler);
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}
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concatenated_requested_ids.reserve(total_requested_keys_count);
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for (auto & unit_ptr: update_request)
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std::for_each(std::begin(unit_ptr->requested_ids), std::end(unit_ptr->requested_ids),
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[&] (const Key & key) {concatenated_requested_ids.push_back(key);});
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}
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const std::vector<Key> & getRequestedIds()
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{
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return concatenated_requested_ids;
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}
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void informCallersAboutPresentId(Key id, size_t cell_idx)
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{
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for (size_t i = 0; i < concatenated_requested_ids.size(); ++i)
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{
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auto & curr = concatenated_requested_ids[i];
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if (curr == id)
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getPresentIdHandlerForPosition(i)(id, cell_idx);
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}
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}
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void informCallersAboutAbsentId(Key id, size_t cell_idx)
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{
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for (size_t i = 0; i < concatenated_requested_ids.size(); ++i)
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if (concatenated_requested_ids[i] == id)
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getAbsentIdHandlerForPosition(i)(id, cell_idx);
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}
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private:
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PresentIdHandler & getPresentIdHandlerForPosition(size_t position)
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{
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return present_id_handlers[getUpdateUnitNumberForRequestedIdPosition(position)];
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}
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AbsentIdHandler & getAbsentIdHandlerForPosition(size_t position)
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{
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return absent_id_handlers[getUpdateUnitNumberForRequestedIdPosition((position))];
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}
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size_t getUpdateUnitNumberForRequestedIdPosition(size_t position)
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{
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return std::lower_bound(helper.begin(), helper.end(), position) - helper.begin();
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}
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std::vector<Key> concatenated_requested_ids;
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std::vector<PresentIdHandler> present_id_handlers;
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std::vector<AbsentIdHandler> absent_id_handlers;
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std::vector<size_t> helper;
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};
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mutable UpdateQueue update_queue;
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ThreadPool update_pool;
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/*
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* Actually, we can divide all requested keys into two 'buckets'. There are only four possible states and they
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* are described in the table.
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*
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* cache_not_found_ids |0|0|1|1|
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* cache_expired_ids |0|1|0|1|
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*
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* 0 - if set is empty, 1 - otherwise
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*
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* Only if there are no cache_not_found_ids and some cache_expired_ids
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* (with allow_read_expired_keys_from_cache_dictionary setting) we can perform async update.
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* Otherwise we have no concatenate ids and update them sync.
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*
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*/
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void updateThreadFunction();
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void update(BunchUpdateUnit & bunch_update_unit) const;
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void tryPushToUpdateQueueOrThrow(UpdateUnitPtr & update_unit_ptr) const;
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void waitForCurrentUpdateFinish(UpdateUnitPtr & update_unit_ptr) const;
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mutable std::mutex update_mutex;
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mutable std::condition_variable is_update_finished;
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std::atomic<bool> finished{false};
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};
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}
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