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286 lines
9.6 KiB
C++
286 lines
9.6 KiB
C++
#pragma once
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#include <Interpreters/AggregationCommon.h>
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#include <Common/ColumnsHashing.h>
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#include <Common/assert_cast.h>
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#include <Common/Arena.h>
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#include <Common/HashTable/HashSet.h>
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#include <Common/HashTable/ClearableHashSet.h>
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#include <Common/HashTable/FixedClearableHashSet.h>
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#include <Common/HashTable/FixedHashSet.h>
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namespace DB
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{
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namespace ErrorCodes
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{
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extern const int LOGICAL_ERROR;
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}
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/** Methods for different implementations of sets (used in right hand side of IN or for DISTINCT).
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* To use as template parameter.
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*/
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/// For the case where there is one numeric key.
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template <typename FieldType, typename TData, bool use_cache = true> /// UInt8/16/32/64 for any types with corresponding bit width.
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struct SetMethodOneNumber
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{
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using Data = TData;
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using Key = typename Data::key_type;
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Data data;
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using State = ColumnsHashing::HashMethodOneNumber<typename Data::value_type,
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void, FieldType, use_cache>;
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};
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/// For the case where there is one string key.
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template <typename TData>
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struct SetMethodString
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{
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using Data = TData;
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using Key = typename Data::key_type;
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Data data;
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using State = ColumnsHashing::HashMethodString<typename Data::value_type, void, true, false>;
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};
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/// For the case when there is one fixed-length string key.
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template <typename TData>
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struct SetMethodFixedString
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{
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using Data = TData;
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using Key = typename Data::key_type;
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Data data;
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using State = ColumnsHashing::HashMethodFixedString<typename Data::value_type, void, true, false>;
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};
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namespace set_impl
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{
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/// This class is designed to provide the functionality that is required for
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/// supporting nullable keys in SetMethodKeysFixed. If there are
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/// no nullable keys, this class is merely implemented as an empty shell.
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template <typename Key, bool has_nullable_keys>
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class BaseStateKeysFixed;
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/// Case where nullable keys are supported.
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template <typename Key>
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class BaseStateKeysFixed<Key, true>
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{
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protected:
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void init(const ColumnRawPtrs & key_columns)
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{
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null_maps.reserve(key_columns.size());
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actual_columns.reserve(key_columns.size());
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for (const auto & col : key_columns)
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{
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if (auto * nullable = checkAndGetColumn<ColumnNullable>(*col))
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{
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actual_columns.push_back(&nullable->getNestedColumn());
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null_maps.push_back(&nullable->getNullMapColumn());
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}
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else
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{
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actual_columns.push_back(col);
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null_maps.push_back(nullptr);
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}
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}
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}
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/// Return the columns which actually contain the values of the keys.
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/// For a given key column, if it is nullable, we return its nested
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/// column. Otherwise we return the key column itself.
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inline const ColumnRawPtrs & getActualColumns() const
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{
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return actual_columns;
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}
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/// Create a bitmap that indicates whether, for a particular row,
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/// a key column bears a null value or not.
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KeysNullMap<Key> createBitmap(size_t row) const
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{
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KeysNullMap<Key> bitmap{};
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for (size_t k = 0; k < null_maps.size(); ++k)
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{
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if (null_maps[k] != nullptr)
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{
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const auto & null_map = assert_cast<const ColumnUInt8 &>(*null_maps[k]).getData();
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if (null_map[row] == 1)
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{
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size_t bucket = k / 8;
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size_t offset = k % 8;
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bitmap[bucket] |= UInt8(1) << offset;
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}
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}
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}
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return bitmap;
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}
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private:
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ColumnRawPtrs actual_columns;
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ColumnRawPtrs null_maps;
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};
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/// Case where nullable keys are not supported.
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template <typename Key>
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class BaseStateKeysFixed<Key, false>
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{
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protected:
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void init(const ColumnRawPtrs &)
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{
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throw Exception{"Internal error: calling init() for non-nullable"
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" keys is forbidden", ErrorCodes::LOGICAL_ERROR};
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}
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const ColumnRawPtrs & getActualColumns() const
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{
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throw Exception{"Internal error: calling getActualColumns() for non-nullable"
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" keys is forbidden", ErrorCodes::LOGICAL_ERROR};
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}
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KeysNullMap<Key> createBitmap(size_t) const
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{
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throw Exception{"Internal error: calling createBitmap() for non-nullable keys"
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" is forbidden", ErrorCodes::LOGICAL_ERROR};
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}
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};
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}
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/// For the case when all keys are of fixed length, and they fit in N (for example, 128) bits.
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template <typename TData, bool has_nullable_keys_ = false>
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struct SetMethodKeysFixed
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{
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using Data = TData;
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using Key = typename Data::key_type;
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static constexpr bool has_nullable_keys = has_nullable_keys_;
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Data data;
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using State = ColumnsHashing::HashMethodKeysFixed<typename Data::value_type, Key, void, has_nullable_keys, false>;
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};
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/// For other cases. 128 bit hash from the key.
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template <typename TData>
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struct SetMethodHashed
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{
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using Data = TData;
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using Key = typename Data::key_type;
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Data data;
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using State = ColumnsHashing::HashMethodHashed<typename Data::value_type, void>;
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};
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/** Different implementations of the set.
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*/
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struct NonClearableSet
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{
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/*
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* As in Aggregator, using consecutive keys cache doesn't improve performance
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* for FixedHashTables.
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*/
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std::unique_ptr<SetMethodOneNumber<UInt8, FixedHashSet<UInt8>, false /* use_cache */>> key8;
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std::unique_ptr<SetMethodOneNumber<UInt16, FixedHashSet<UInt16>, false /* use_cache */>> key16;
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/** Also for the experiment was tested the ability to use SmallSet,
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* as long as the number of elements in the set is small (and, if necessary, converted to a full-fledged HashSet).
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* But this experiment showed that there is an advantage only in rare cases.
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*/
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std::unique_ptr<SetMethodOneNumber<UInt32, HashSet<UInt32, HashCRC32<UInt32>>>> key32;
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std::unique_ptr<SetMethodOneNumber<UInt64, HashSet<UInt64, HashCRC32<UInt64>>>> key64;
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std::unique_ptr<SetMethodString<HashSetWithSavedHash<StringRef>>> key_string;
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std::unique_ptr<SetMethodFixedString<HashSetWithSavedHash<StringRef>>> key_fixed_string;
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std::unique_ptr<SetMethodKeysFixed<HashSet<UInt128, UInt128HashCRC32>>> keys128;
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std::unique_ptr<SetMethodKeysFixed<HashSet<UInt256, UInt256HashCRC32>>> keys256;
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std::unique_ptr<SetMethodHashed<HashSet<UInt128, UInt128TrivialHash>>> hashed;
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/// Support for nullable keys (for DISTINCT implementation).
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std::unique_ptr<SetMethodKeysFixed<HashSet<UInt128, UInt128HashCRC32>, true>> nullable_keys128;
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std::unique_ptr<SetMethodKeysFixed<HashSet<UInt256, UInt256HashCRC32>, true>> nullable_keys256;
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/** Unlike Aggregator, `concat` method is not used here.
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* This is done because `hashed` method, although slower, but in this case, uses less RAM.
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* since when you use it, the key values themselves are not stored.
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*/
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};
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struct ClearableSet
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{
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std::unique_ptr<SetMethodOneNumber<UInt8, FixedClearableHashSet<UInt8>, false /* use_cache */>> key8;
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std::unique_ptr<SetMethodOneNumber<UInt16, FixedClearableHashSet<UInt16>, false /*use_cache */>> key16;
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std::unique_ptr<SetMethodOneNumber<UInt32, ClearableHashSet<UInt32, HashCRC32<UInt32>>>> key32;
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std::unique_ptr<SetMethodOneNumber<UInt64, ClearableHashSet<UInt64, HashCRC32<UInt64>>>> key64;
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std::unique_ptr<SetMethodString<ClearableHashSetWithSavedHash<StringRef>>> key_string;
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std::unique_ptr<SetMethodFixedString<ClearableHashSetWithSavedHash<StringRef>>> key_fixed_string;
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std::unique_ptr<SetMethodKeysFixed<ClearableHashSet<UInt128, UInt128HashCRC32>>> keys128;
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std::unique_ptr<SetMethodKeysFixed<ClearableHashSet<UInt256, UInt256HashCRC32>>> keys256;
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std::unique_ptr<SetMethodHashed<ClearableHashSet<UInt128, UInt128TrivialHash>>> hashed;
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/// Support for nullable keys (for DISTINCT implementation).
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std::unique_ptr<SetMethodKeysFixed<ClearableHashSet<UInt128, UInt128HashCRC32>, true>> nullable_keys128;
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std::unique_ptr<SetMethodKeysFixed<ClearableHashSet<UInt256, UInt256HashCRC32>, true>> nullable_keys256;
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/** Unlike Aggregator, `concat` method is not used here.
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* This is done because `hashed` method, although slower, but in this case, uses less RAM.
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* since when you use it, the key values themselves are not stored.
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*/
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};
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template <typename Variant>
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struct SetVariantsTemplate: public Variant
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{
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Arena string_pool;
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#define APPLY_FOR_SET_VARIANTS(M) \
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M(key8) \
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M(key16) \
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M(key32) \
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M(key64) \
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M(key_string) \
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M(key_fixed_string) \
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M(keys128) \
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M(keys256) \
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M(nullable_keys128) \
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M(nullable_keys256) \
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M(hashed)
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#define M(NAME) using Variant::NAME;
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APPLY_FOR_SET_VARIANTS(M)
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#undef M
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enum class Type
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{
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EMPTY,
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#define M(NAME) NAME,
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APPLY_FOR_SET_VARIANTS(M)
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#undef M
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};
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Type type = Type::EMPTY;
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bool empty() const { return type == Type::EMPTY; }
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static Type chooseMethod(const ColumnRawPtrs & key_columns, Sizes & key_sizes);
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void init(Type type_);
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size_t getTotalRowCount() const;
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/// Counts the size in bytes of the Set buffer and the size of the `string_pool`
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size_t getTotalByteCount() const;
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};
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using SetVariants = SetVariantsTemplate<NonClearableSet>;
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using ClearableSetVariants = SetVariantsTemplate<ClearableSet>;
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}
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