#pragma once #include #include #include #include #include #include #include #include namespace DB { struct Range; class Context; class IFunctionBase; using FunctionBasePtr = std::shared_ptr; class Chunk; /** Data structure for implementation of IN expression. */ class Set { public: /// 'fill_set_elements': in addition to hash table /// (that is useful only for checking that some value is in the set and may not store the original values), /// store all set elements in explicit form. /// This is needed for subsequent use for index. Set(const SizeLimits & limits_, bool fill_set_elements_, bool transform_null_in_) : log(&Poco::Logger::get("Set")), limits(limits_), fill_set_elements(fill_set_elements_), transform_null_in(transform_null_in_) { } /** Set can be created either from AST or from a stream of data (subquery result). */ /** Create a Set from stream. * Call setHeader, then call insertFromBlock for each block. */ void setHeader(const ColumnsWithTypeAndName & header); /// Returns false, if some limit was exceeded and no need to insert more data. bool insertFromBlock(const Columns & columns); bool insertFromBlock(const ColumnsWithTypeAndName & columns); /// Call after all blocks were inserted. To get the information that set is already created. void finishInsert() { is_created = true; } /// finishInsert and isCreated are thread-safe bool isCreated() const { return is_created.load(); } /** For columns of 'block', check belonging of corresponding rows to the set. * Return UInt8 column with the result. */ ColumnPtr execute(const ColumnsWithTypeAndName & columns, bool negative) const; bool empty() const; size_t getTotalRowCount() const; size_t getTotalByteCount() const; const DataTypes & getDataTypes() const { return data_types; } const DataTypes & getElementsTypes() const { return set_elements_types; } bool hasExplicitSetElements() const { return fill_set_elements; } Columns getSetElements() const { return { set_elements.begin(), set_elements.end() }; } void checkColumnsNumber(size_t num_key_columns) const; bool areTypesEqual(size_t set_type_idx, const DataTypePtr & other_type) const; void checkTypesEqual(size_t set_type_idx, const DataTypePtr & other_type) const; private: size_t keys_size = 0; Sizes key_sizes; SetVariants data; /** How IN works with Nullable types. * * For simplicity reasons, all NULL values and any tuples with at least one NULL element are ignored in the Set. * And for left hand side values, that are NULLs or contain any NULLs, we return 0 (means that element is not in Set). * * If we want more standard compliant behaviour, we must return NULL * if lhs is NULL and set is not empty or if lhs is not in set, but set contains at least one NULL. * It is more complicated with tuples. * For example, * (1, NULL, 2) IN ((1, NULL, 3)) must return 0, * but (1, NULL, 2) IN ((1, 1111, 2)) must return NULL. * * We have not implemented such sophisticated behaviour. */ /** The data types from which the set was created. * When checking for belonging to a set, the types of columns to be checked must match with them. */ DataTypes data_types; /// Types for set_elements. DataTypes set_elements_types; Poco::Logger * log; /// Limitations on the maximum size of the set SizeLimits limits; /// Do we need to additionally store all elements of the set in explicit form for subsequent use for index. bool fill_set_elements; /// If true, insert NULL values to set. bool transform_null_in; /// Check if set contains all the data. std::atomic is_created = false; /// If in the left part columns contains the same types as the elements of the set. void executeOrdinary( const ColumnRawPtrs & key_columns, ColumnUInt8::Container & vec_res, bool negative, const PaddedPODArray * null_map) const; /// Collected elements of `Set`. /// It is necessary for the index to work on the primary key in the IN statement. std::vector set_elements; /** Protects work with the set in the functions `insertFromBlock` and `execute`. * These functions can be called simultaneously from different threads only when using StorageSet, */ mutable DB::FastSharedMutex rwlock; template void insertFromBlockImpl( Method & method, const ColumnRawPtrs & key_columns, size_t rows, SetVariants & variants, ConstNullMapPtr null_map, ColumnUInt8::Container * out_filter); template void insertFromBlockImplCase( Method & method, const ColumnRawPtrs & key_columns, size_t rows, SetVariants & variants, ConstNullMapPtr null_map, ColumnUInt8::Container * out_filter); template void executeImpl( Method & method, const ColumnRawPtrs & key_columns, ColumnUInt8::Container & vec_res, bool negative, size_t rows, ConstNullMapPtr null_map) const; template void executeImplCase( Method & method, const ColumnRawPtrs & key_columns, ColumnUInt8::Container & vec_res, bool negative, size_t rows, ConstNullMapPtr null_map) const; }; using SetPtr = std::shared_ptr; using ConstSetPtr = std::shared_ptr; using Sets = std::vector; class IFunction; using FunctionPtr = std::shared_ptr; /** Class that represents single value with possible infinities. * Single field is stored in column for more optimal inplace comparisons with other regular columns. * Extracting fields from columns and further their comparison is suboptimal and requires extra copying. */ struct FieldValue { FieldValue(MutableColumnPtr && column_) : column(std::move(column_)) {} void update(const Field & x); bool isNormal() const { return !value.isPositiveInfinity() && !value.isNegativeInfinity(); } bool isPositiveInfinity() const { return value.isPositiveInfinity(); } bool isNegativeInfinity() const { return value.isNegativeInfinity(); } Field value; // Null, -Inf, +Inf // If value is Null, uses the actual value in column MutableColumnPtr column; }; /// Class for checkInRange function. class MergeTreeSetIndex { public: /** Mapping for tuple positions from Set::set_elements to * position of pk index and functions chain applied to this column. */ struct KeyTuplePositionMapping { size_t tuple_index; size_t key_index; std::vector functions; }; MergeTreeSetIndex(const Columns & set_elements, std::vector && indexes_mapping_); size_t size() const { return ordered_set.at(0)->size(); } bool hasMonotonicFunctionsChain() const; BoolMask checkInRange(const std::vector & key_ranges, const DataTypes & data_types, bool single_point = false) const; private: // If all arguments in tuple are key columns, we can optimize NOT IN when there is only one element. bool has_all_keys; Columns ordered_set; std::vector indexes_mapping; using FieldValues = std::vector; }; }