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https://github.com/ClickHouse/ClickHouse.git
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419 lines
14 KiB
C++
419 lines
14 KiB
C++
#pragma once
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#include <sstream>
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#include <optional>
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#include <Interpreters/Set.h>
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#include <Core/SortDescription.h>
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#include <Parsers/ASTExpressionList.h>
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#include <Parsers/ASTSelectQuery.h>
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#include <Parsers/ASTFunction.h>
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#include <Storages/SelectQueryInfo.h>
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namespace DB
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{
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class Context;
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class IFunction;
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using FunctionBasePtr = std::shared_ptr<IFunctionBase>;
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class ExpressionActions;
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using ExpressionActionsPtr = std::shared_ptr<ExpressionActions>;
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/** A field, that can be stored in two representations:
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* - A standalone field.
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* - A field with reference to its position in a block.
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* It's needed for execution of functions on ranges during
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* index analysis. If function was executed once for field,
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* its result would be cached for whole block for which field's reference points to.
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*/
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struct FieldRef : public Field
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{
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FieldRef() = default;
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/// Create as explicit field without block.
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template <typename T>
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FieldRef(T && value) : Field(std::forward<T>(value)) {}
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/// Create as reference to field in block.
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FieldRef(Block * block_, size_t row_idx_, size_t column_idx_)
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: Field((*block_->getByPosition(column_idx_).column)[row_idx_]),
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block(block_), row_idx(row_idx_), column_idx(column_idx_) {}
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bool isExplicit() const { return block == nullptr; }
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Block * block = nullptr;
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size_t row_idx = 0;
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size_t column_idx = 0;
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};
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/** Range with open or closed ends; possibly unbounded.
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*/
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struct Range
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{
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private:
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static bool equals(const Field & lhs, const Field & rhs);
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static bool less(const Field & lhs, const Field & rhs);
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public:
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FieldRef left; /// the left border, if any
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FieldRef right; /// the right border, if any
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bool left_bounded = false; /// bounded at the left
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bool right_bounded = false; /// bounded at the right
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bool left_included = false; /// includes the left border, if any
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bool right_included = false; /// includes the right border, if any
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/// The whole unversum.
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Range() {}
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/// One point.
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Range(const FieldRef & point)
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: left(point), right(point), left_bounded(true), right_bounded(true), left_included(true), right_included(true) {}
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/// A bounded two-sided range.
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Range(const FieldRef & left_, bool left_included_, const FieldRef & right_, bool right_included_)
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: left(left_), right(right_),
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left_bounded(true), right_bounded(true),
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left_included(left_included_), right_included(right_included_)
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{
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shrinkToIncludedIfPossible();
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}
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static Range createRightBounded(const FieldRef & right_point, bool right_included)
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{
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Range r;
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r.right = right_point;
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r.right_bounded = true;
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r.right_included = right_included;
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r.shrinkToIncludedIfPossible();
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return r;
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}
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static Range createLeftBounded(const FieldRef & left_point, bool left_included)
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{
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Range r;
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r.left = left_point;
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r.left_bounded = true;
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r.left_included = left_included;
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r.shrinkToIncludedIfPossible();
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return r;
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}
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/** Optimize the range. If it has an open boundary and the Field type is "loose"
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* - then convert it to closed, narrowing by one.
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* That is, for example, turn (0,2) into [1].
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*/
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void shrinkToIncludedIfPossible()
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{
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if (left.isExplicit() && left_bounded && !left_included)
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{
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if (left.getType() == Field::Types::UInt64 && left.get<UInt64>() != std::numeric_limits<UInt64>::max())
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{
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++left.get<UInt64 &>();
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left_included = true;
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}
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if (left.getType() == Field::Types::Int64 && left.get<Int64>() != std::numeric_limits<Int64>::max())
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{
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++left.get<Int64 &>();
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left_included = true;
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}
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}
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if (right.isExplicit() && right_bounded && !right_included)
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{
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if (right.getType() == Field::Types::UInt64 && right.get<UInt64>() != std::numeric_limits<UInt64>::min())
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{
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--right.get<UInt64 &>();
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right_included = true;
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}
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if (right.getType() == Field::Types::Int64 && right.get<Int64>() != std::numeric_limits<Int64>::min())
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{
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--right.get<Int64 &>();
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right_included = true;
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}
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}
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}
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bool empty() const
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{
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return left_bounded && right_bounded
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&& (less(right, left)
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|| ((!left_included || !right_included) && !less(left, right)));
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}
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/// x contained in the range
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bool contains(const FieldRef & x) const
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{
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return !leftThan(x) && !rightThan(x);
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}
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/// x is to the left
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bool rightThan(const FieldRef & x) const
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{
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return (left_bounded
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? !(less(left, x) || (left_included && equals(x, left)))
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: false);
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}
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/// x is to the right
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bool leftThan(const FieldRef & x) const
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{
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return (right_bounded
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? !(less(x, right) || (right_included && equals(x, right)))
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: false);
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}
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bool intersectsRange(const Range & r) const
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{
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/// r to the left of me.
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if (r.right_bounded
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&& left_bounded
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&& (less(r.right, left)
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|| ((!left_included || !r.right_included)
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&& equals(r.right, left))))
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return false;
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/// r to the right of me.
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if (r.left_bounded
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&& right_bounded
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&& (less(right, r.left) /// ...} {...
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|| ((!right_included || !r.left_included) /// ...) [... or ...] (...
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&& equals(r.left, right))))
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return false;
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return true;
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}
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bool containsRange(const Range & r) const
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{
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/// r starts to the left of me.
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if (left_bounded
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&& (!r.left_bounded
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|| less(r.left, left)
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|| (r.left_included
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&& !left_included
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&& equals(r.left, left))))
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return false;
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/// r ends right of me.
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if (right_bounded
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&& (!r.right_bounded
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|| less(right, r.right)
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|| (r.right_included
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&& !right_included
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&& equals(r.right, right))))
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return false;
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return true;
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}
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void swapLeftAndRight()
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{
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std::swap(left, right);
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std::swap(left_bounded, right_bounded);
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std::swap(left_included, right_included);
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}
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String toString() const;
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};
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/** Condition on the index.
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*
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* Consists of the conditions for the key belonging to all possible ranges or sets,
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* as well as logical operators AND/OR/NOT above these conditions.
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*
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* Constructs a reverse polish notation from these conditions
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* and can calculate (interpret) its satisfiability over key ranges.
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*/
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class KeyCondition
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{
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public:
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/// Does not take into account the SAMPLE section. all_columns - the set of all columns of the table.
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KeyCondition(
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const SelectQueryInfo & query_info,
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const Context & context,
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const Names & key_column_names,
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const ExpressionActionsPtr & key_expr);
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/// Whether the condition and its negation are feasible in the direct product of single column ranges specified by `hyperrectangle`.
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BoolMask checkInHyperrectangle(
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const std::vector<Range> & hyperrectangle,
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const DataTypes & data_types) const;
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/// Whether the condition and its negation are (independently) feasible in the key range.
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/// left_key and right_key must contain all fields in the sort_descr in the appropriate order.
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/// data_types - the types of the key columns.
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/// Argument initial_mask is used for early exiting the implementation when we do not care about
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/// one of the resulting mask components (see BoolMask::consider_only_can_be_XXX).
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BoolMask checkInRange(
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size_t used_key_size,
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const FieldRef * left_key,
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const FieldRef* right_key,
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const DataTypes & data_types,
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BoolMask initial_mask = BoolMask(false, false)) const;
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/// Are the condition and its negation valid in a semi-infinite (not limited to the right) key range.
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/// left_key must contain all the fields in the sort_descr in the appropriate order.
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BoolMask checkAfter(
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size_t used_key_size,
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const FieldRef * left_key,
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const DataTypes & data_types,
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BoolMask initial_mask = BoolMask(false, false)) const;
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/// Same as checkInRange, but calculate only may_be_true component of a result.
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/// This is more efficient than checkInRange(...).can_be_true.
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bool mayBeTrueInRange(
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size_t used_key_size,
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const FieldRef * left_key,
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const FieldRef * right_key,
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const DataTypes & data_types) const;
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/// Same as checkAfter, but calculate only may_be_true component of a result.
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/// This is more efficient than checkAfter(...).can_be_true.
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bool mayBeTrueAfter(
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size_t used_key_size,
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const FieldRef * left_key,
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const DataTypes & data_types) const;
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/// Checks that the index can not be used.
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bool alwaysUnknownOrTrue() const;
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/// Get the maximum number of the key element used in the condition.
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size_t getMaxKeyColumn() const;
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bool hasMonotonicFunctionsChain() const;
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/// Impose an additional condition: the value in the column `column` must be in the range `range`.
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/// Returns whether there is such a column in the key.
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bool addCondition(const String & column, const Range & range);
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String toString() const;
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/** A chain of possibly monotone functions.
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* If the key column is wrapped in functions that can be monotonous in some value ranges
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* (for example: -toFloat64(toDayOfWeek(date))), then here the functions will be located: toDayOfWeek, toFloat64, negate.
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*/
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using MonotonicFunctionsChain = std::vector<FunctionBasePtr>;
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/** Computes value of constant expression and its data type.
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* Returns false, if expression isn't constant.
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*/
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static bool getConstant(
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const ASTPtr & expr, Block & block_with_constants, Field & out_value, DataTypePtr & out_type);
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static Block getBlockWithConstants(
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const ASTPtr & query, const SyntaxAnalyzerResultPtr & syntax_analyzer_result, const Context & context);
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static std::optional<Range> applyMonotonicFunctionsChainToRange(
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Range key_range,
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const MonotonicFunctionsChain & functions,
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DataTypePtr current_type);
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bool matchesExactContinuousRange() const;
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private:
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/// The expression is stored as Reverse Polish Notation.
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struct RPNElement
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{
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enum Function
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{
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/// Atoms of a Boolean expression.
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FUNCTION_IN_RANGE,
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FUNCTION_NOT_IN_RANGE,
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FUNCTION_IN_SET,
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FUNCTION_NOT_IN_SET,
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FUNCTION_UNKNOWN, /// Can take any value.
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/// Operators of the logical expression.
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FUNCTION_NOT,
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FUNCTION_AND,
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FUNCTION_OR,
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/// Constants
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ALWAYS_FALSE,
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ALWAYS_TRUE,
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};
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RPNElement() {}
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RPNElement(Function function_) : function(function_) {}
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RPNElement(Function function_, size_t key_column_) : function(function_), key_column(key_column_) {}
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RPNElement(Function function_, size_t key_column_, const Range & range_)
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: function(function_), range(range_), key_column(key_column_) {}
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String toString() const;
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Function function = FUNCTION_UNKNOWN;
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/// For FUNCTION_IN_RANGE and FUNCTION_NOT_IN_RANGE.
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Range range;
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size_t key_column = 0;
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/// For FUNCTION_IN_SET, FUNCTION_NOT_IN_SET
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using MergeTreeSetIndexPtr = std::shared_ptr<const MergeTreeSetIndex>;
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MergeTreeSetIndexPtr set_index;
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MonotonicFunctionsChain monotonic_functions_chain;
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};
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using RPN = std::vector<RPNElement>;
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using ColumnIndices = std::map<String, size_t>;
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using AtomMap = std::unordered_map<std::string, bool(*)(RPNElement & out, const Field & value)>;
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public:
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static const AtomMap atom_map;
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private:
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BoolMask checkInRange(
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size_t used_key_size,
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const FieldRef * left_key,
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const FieldRef * right_key,
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const DataTypes & data_types,
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bool right_bounded,
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BoolMask initial_mask) const;
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void traverseAST(const ASTPtr & node, const Context & context, Block & block_with_constants);
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bool tryParseAtomFromAST(const ASTPtr & node, const Context & context, Block & block_with_constants, RPNElement & out);
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static bool tryParseLogicalOperatorFromAST(const ASTFunction * func, RPNElement & out);
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/** Is node the key column
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* or expression in which column of key is wrapped by chain of functions,
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* that can be monotonic on certain ranges?
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* If these conditions are true, then returns number of column in key, type of resulting expression
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* and fills chain of possibly-monotonic functions.
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*/
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bool isKeyPossiblyWrappedByMonotonicFunctions(
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const ASTPtr & node,
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const Context & context,
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size_t & out_key_column_num,
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DataTypePtr & out_key_res_column_type,
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MonotonicFunctionsChain & out_functions_chain);
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bool isKeyPossiblyWrappedByMonotonicFunctionsImpl(
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const ASTPtr & node,
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size_t & out_key_column_num,
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DataTypePtr & out_key_column_type,
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std::vector<const ASTFunction *> & out_functions_chain);
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bool canConstantBeWrappedByMonotonicFunctions(
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const ASTPtr & node,
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size_t & out_key_column_num,
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DataTypePtr & out_key_column_type,
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Field & out_value,
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DataTypePtr & out_type);
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/// If it's possible to make an RPNElement
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/// that will filter values (possibly tuples) by the content of 'prepared_set',
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/// do it and return true.
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bool tryPrepareSetIndex(
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const ASTs & args,
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const Context & context,
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RPNElement & out,
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size_t & out_key_column_num);
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RPN rpn;
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ColumnIndices key_columns;
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ExpressionActionsPtr key_expr;
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PreparedSets prepared_sets;
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};
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}
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