#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace DB { namespace ErrorCodes { extern const int UNKNOWN_SET_DATA_VARIANT; extern const int LOGICAL_ERROR; extern const int SET_SIZE_LIMIT_EXCEEDED; extern const int TYPE_MISMATCH; extern const int ILLEGAL_COLUMN; } static NameSet requiredRightKeys(const Names & key_names, const NamesAndTypesList & columns_added_by_join) { NameSet required; NameSet right_keys; for (const auto & name : key_names) right_keys.insert(name); for (const auto & column : columns_added_by_join) { if (right_keys.count(column.name)) required.insert(column.name); } return required; } Join::Join(const Names & key_names_right_, bool use_nulls_, const SizeLimits & limits, ASTTableJoin::Kind kind_, ASTTableJoin::Strictness strictness_, bool any_take_last_row_) : kind(kind_), strictness(strictness_), key_names_right(key_names_right_), use_nulls(use_nulls_), any_take_last_row(any_take_last_row_), log(&Logger::get("Join")), limits(limits) { } Join::Type Join::chooseMethod(const ColumnRawPtrs & key_columns, Sizes & key_sizes) { size_t keys_size = key_columns.size(); if (keys_size == 0) return Type::CROSS; bool all_fixed = true; size_t keys_bytes = 0; key_sizes.resize(keys_size); for (size_t j = 0; j < keys_size; ++j) { if (!key_columns[j]->isFixedAndContiguous()) { all_fixed = false; break; } key_sizes[j] = key_columns[j]->sizeOfValueIfFixed(); keys_bytes += key_sizes[j]; } /// If there is one numeric key that fits in 64 bits if (keys_size == 1 && key_columns[0]->isNumeric()) { size_t size_of_field = key_columns[0]->sizeOfValueIfFixed(); if (size_of_field == 1) return Type::key8; if (size_of_field == 2) return Type::key16; if (size_of_field == 4) return Type::key32; if (size_of_field == 8) return Type::key64; if (size_of_field == 16) return Type::keys128; throw Exception("Logical error: numeric column has sizeOfField not in 1, 2, 4, 8, 16.", ErrorCodes::LOGICAL_ERROR); } /// If the keys fit in N bits, we will use a hash table for N-bit-packed keys if (all_fixed && keys_bytes <= 16) return Type::keys128; if (all_fixed && keys_bytes <= 32) return Type::keys256; /// If there is single string key, use hash table of it's values. if (keys_size == 1 && (typeid_cast(key_columns[0]) || (key_columns[0]->isColumnConst() && typeid_cast(&static_cast(key_columns[0])->getDataColumn())))) return Type::key_string; if (keys_size == 1 && typeid_cast(key_columns[0])) return Type::key_fixed_string; /// Otherwise, will use set of cryptographic hashes of unambiguously serialized values. return Type::hashed; } template static void initImpl(Maps & maps, Join::Type type) { switch (type) { case Join::Type::EMPTY: break; case Join::Type::CROSS: break; #define M(TYPE) \ case Join::Type::TYPE: maps.TYPE = std::make_unique(); break; APPLY_FOR_JOIN_VARIANTS(M) #undef M } } template static size_t getTotalRowCountImpl(const Maps & maps, Join::Type type) { switch (type) { case Join::Type::EMPTY: return 0; case Join::Type::CROSS: return 0; #define M(NAME) \ case Join::Type::NAME: return maps.NAME ? maps.NAME->size() : 0; APPLY_FOR_JOIN_VARIANTS(M) #undef M } __builtin_unreachable(); } template static size_t getTotalByteCountImpl(const Maps & maps, Join::Type type) { switch (type) { case Join::Type::EMPTY: return 0; case Join::Type::CROSS: return 0; #define M(NAME) \ case Join::Type::NAME: return maps.NAME ? maps.NAME->getBufferSizeInBytes() : 0; APPLY_FOR_JOIN_VARIANTS(M) #undef M } __builtin_unreachable(); } template struct KeyGetterForTypeImpl; template struct KeyGetterForTypeImpl { using Type = ColumnsHashing::HashMethodOneNumber; }; template struct KeyGetterForTypeImpl { using Type = ColumnsHashing::HashMethodOneNumber; }; template struct KeyGetterForTypeImpl { using Type = ColumnsHashing::HashMethodOneNumber; }; template struct KeyGetterForTypeImpl { using Type = ColumnsHashing::HashMethodOneNumber; }; template struct KeyGetterForTypeImpl { using Type = ColumnsHashing::HashMethodString; }; template struct KeyGetterForTypeImpl { using Type = ColumnsHashing::HashMethodFixedString; }; template struct KeyGetterForTypeImpl { using Type = ColumnsHashing::HashMethodKeysFixed; }; template struct KeyGetterForTypeImpl { using Type = ColumnsHashing::HashMethodKeysFixed; }; template struct KeyGetterForTypeImpl { using Type = ColumnsHashing::HashMethodHashed; }; template struct KeyGetterForType { using Value = typename Data::value_type; using Mapped_t = typename Data::mapped_type; using Mapped = std::conditional_t, const Mapped_t, Mapped_t>; using Type = typename KeyGetterForTypeImpl::Type; }; /// Do I need to use the hash table maps_*_full, in which we remember whether the row was joined. static bool getFullness(ASTTableJoin::Kind kind) { return kind == ASTTableJoin::Kind::Right || kind == ASTTableJoin::Kind::Full; } void Join::init(Type type_) { type = type_; if (kind == ASTTableJoin::Kind::Cross) return; dispatch(MapInitTag()); dispatch([&](auto, auto, auto & map) { initImpl(map, type); }); } size_t Join::getTotalRowCount() const { size_t res = 0; if (type == Type::CROSS) { for (const auto & block : blocks) res += block.rows(); } else { dispatch([&](auto, auto, auto & map) { res += getTotalRowCountImpl(map, type); }); } return res; } size_t Join::getTotalByteCount() const { size_t res = 0; if (type == Type::CROSS) { for (const auto & block : blocks) res += block.bytes(); } else { dispatch([&](auto, auto, auto & map) { res += getTotalByteCountImpl(map, type); }); res += pool.size(); } return res; } static void convertColumnToNullable(ColumnWithTypeAndName & column) { column.type = makeNullable(column.type); if (column.column) column.column = makeNullable(column.column); } void Join::setSampleBlock(const Block & block) { std::unique_lock lock(rwlock); if (!empty()) return; size_t keys_size = key_names_right.size(); ColumnRawPtrs key_columns(keys_size); Columns materialized_columns; for (size_t i = 0; i < keys_size; ++i) { auto & column = block.getByName(key_names_right[i]).column; key_columns[i] = column.get(); auto column_no_lc = recursiveRemoveLowCardinality(column); if (column.get() != column_no_lc.get()) { materialized_columns.emplace_back(std::move(column_no_lc)); key_columns[i] = materialized_columns[i].get(); } /// We will join only keys, where all components are not NULL. if (key_columns[i]->isColumnNullable()) key_columns[i] = &static_cast(*key_columns[i]).getNestedColumn(); } /// Choose data structure to use for JOIN. init(chooseMethod(key_columns, key_sizes)); sample_block_with_columns_to_add = materializeBlock(block); /// Move from `sample_block_with_columns_to_add` key columns to `sample_block_with_keys`, keeping the order. size_t pos = 0; while (pos < sample_block_with_columns_to_add.columns()) { const auto & name = sample_block_with_columns_to_add.getByPosition(pos).name; if (key_names_right.end() != std::find(key_names_right.begin(), key_names_right.end(), name)) { auto & col = sample_block_with_columns_to_add.getByPosition(pos); col.column = recursiveRemoveLowCardinality(col.column); col.type = recursiveRemoveLowCardinality(col.type); sample_block_with_keys.insert(col); sample_block_with_columns_to_add.erase(pos); } else ++pos; } size_t num_columns_to_add = sample_block_with_columns_to_add.columns(); for (size_t i = 0; i < num_columns_to_add; ++i) { auto & column = sample_block_with_columns_to_add.getByPosition(i); if (!column.column) column.column = column.type->createColumn(); } /// In case of LEFT and FULL joins, if use_nulls, convert joined columns to Nullable. if (use_nulls && (kind == ASTTableJoin::Kind::Left || kind == ASTTableJoin::Kind::Full)) for (size_t i = 0; i < num_columns_to_add; ++i) convertColumnToNullable(sample_block_with_columns_to_add.getByPosition(i)); } namespace { /// Inserting an element into a hash table of the form `key -> reference to a string`, which will then be used by JOIN. template struct Inserter { static void insert(Map & map, KeyGetter & key_getter, Block * stored_block, size_t i, Arena & pool); }; template struct Inserter { static void insert(Map & map, KeyGetter & key_getter, Block * stored_block, size_t i, Arena & pool) { auto emplace_result = key_getter.emplaceKey(map, i, pool); if (emplace_result.isInserted() || emplace_result.getMapped().overwrite) new (&emplace_result.getMapped()) typename Map::mapped_type(stored_block, i); } }; template struct Inserter { static void insert(Map & map, KeyGetter & key_getter, Block * stored_block, size_t i, Arena & pool) { auto emplace_result = key_getter.emplaceKey(map, i, pool); if (emplace_result.isInserted()) new (&emplace_result.getMapped()) typename Map::mapped_type(stored_block, i); else { /** The first element of the list is stored in the value of the hash table, the rest in the pool. * We will insert each time the element into the second place. * That is, the former second element, if it was, will be the third, and so on. */ auto elem = pool.alloc(); auto & mapped = emplace_result.getMapped(); elem->next = mapped.next; mapped.next = elem; elem->block = stored_block; elem->row_num = i; } } }; template void NO_INLINE insertFromBlockImplTypeCase( Map & map, size_t rows, const ColumnRawPtrs & key_columns, const Sizes & key_sizes, Block * stored_block, ConstNullMapPtr null_map, Arena & pool) { KeyGetter key_getter(key_columns, key_sizes, nullptr); for (size_t i = 0; i < rows; ++i) { if (has_null_map && (*null_map)[i]) continue; Inserter::insert(map, key_getter, stored_block, i, pool); } } template void insertFromBlockImplType( Map & map, size_t rows, const ColumnRawPtrs & key_columns, const Sizes & key_sizes, Block * stored_block, ConstNullMapPtr null_map, Arena & pool) { if (null_map) insertFromBlockImplTypeCase(map, rows, key_columns, key_sizes, stored_block, null_map, pool); else insertFromBlockImplTypeCase(map, rows, key_columns, key_sizes, stored_block, null_map, pool); } template void insertFromBlockImpl( Join::Type type, Maps & maps, size_t rows, const ColumnRawPtrs & key_columns, const Sizes & key_sizes, Block * stored_block, ConstNullMapPtr null_map, Arena & pool) { switch (type) { case Join::Type::EMPTY: break; case Join::Type::CROSS: break; /// Do nothing. We have already saved block, and it is enough. #define M(TYPE) \ case Join::Type::TYPE: \ insertFromBlockImplType>::Type>(\ *maps.TYPE, rows, key_columns, key_sizes, stored_block, null_map, pool); \ break; APPLY_FOR_JOIN_VARIANTS(M) #undef M } } } bool Join::insertFromBlock(const Block & block) { std::unique_lock lock(rwlock); if (empty()) throw Exception("Logical error: Join was not initialized", ErrorCodes::LOGICAL_ERROR); size_t keys_size = key_names_right.size(); ColumnRawPtrs key_columns(keys_size); /// Rare case, when keys are constant. To avoid code bloat, simply materialize them. Columns materialized_columns; materialized_columns.reserve(keys_size); /// Memoize key columns to work. for (size_t i = 0; i < keys_size; ++i) { materialized_columns.emplace_back(recursiveRemoveLowCardinality(block.getByName(key_names_right[i]).column->convertToFullColumnIfConst())); key_columns[i] = materialized_columns.back().get(); } /// We will insert to the map only keys, where all components are not NULL. ColumnPtr null_map_holder; ConstNullMapPtr null_map{}; extractNestedColumnsAndNullMap(key_columns, null_map_holder, null_map); size_t rows = block.rows(); blocks.push_back(block); Block * stored_block = &blocks.back(); if (getFullness(kind)) { /** Move the key columns to the beginning of the block. * This is where NonJoinedBlockInputStream will expect. */ size_t key_num = 0; for (const auto & name : key_names_right) { size_t pos = stored_block->getPositionByName(name); ColumnWithTypeAndName col = stored_block->safeGetByPosition(pos); stored_block->erase(pos); stored_block->insert(key_num, std::move(col)); ++key_num; } } else { /// Remove the key columns from stored_block, as they are not needed. for (const auto & name : key_names_right) stored_block->erase(stored_block->getPositionByName(name)); } size_t size = stored_block->columns(); /// Rare case, when joined columns are constant. To avoid code bloat, simply materialize them. for (size_t i = 0; i < size; ++i) stored_block->safeGetByPosition(i).column = stored_block->safeGetByPosition(i).column->convertToFullColumnIfConst(); /// In case of LEFT and FULL joins, if use_nulls, convert joined columns to Nullable. if (use_nulls && (kind == ASTTableJoin::Kind::Left || kind == ASTTableJoin::Kind::Full)) { for (size_t i = getFullness(kind) ? keys_size : 0; i < size; ++i) { convertColumnToNullable(stored_block->getByPosition(i)); } } if (kind != ASTTableJoin::Kind::Cross) { dispatch([&](auto, auto strictness_, auto & map) { insertFromBlockImpl(type, map, rows, key_columns, key_sizes, stored_block, null_map, pool); }); } return limits.check(getTotalRowCount(), getTotalByteCount(), "JOIN", ErrorCodes::SET_SIZE_LIMIT_EXCEEDED); } namespace { template struct Adder; template struct Adder { static void addFound(const typename Map::mapped_type & mapped, size_t num_columns_to_add, MutableColumns & added_columns, size_t i, IColumn::Filter & filter, IColumn::Offset & /*current_offset*/, IColumn::Offsets * /*offsets*/, const std::vector & right_indexes) { filter[i] = 1; for (size_t j = 0; j < num_columns_to_add; ++j) added_columns[j]->insertFrom(*mapped.block->getByPosition(right_indexes[j]).column, mapped.row_num); } static void addNotFound(size_t num_columns_to_add, MutableColumns & added_columns, size_t i, IColumn::Filter & filter, IColumn::Offset & /*current_offset*/, IColumn::Offsets * /*offsets*/) { filter[i] = 0; for (size_t j = 0; j < num_columns_to_add; ++j) added_columns[j]->insertDefault(); } }; template struct Adder { static void addFound(const typename Map::mapped_type & mapped, size_t num_columns_to_add, MutableColumns & added_columns, size_t i, IColumn::Filter & filter, IColumn::Offset & /*current_offset*/, IColumn::Offsets * /*offsets*/, const std::vector & right_indexes) { filter[i] = 1; for (size_t j = 0; j < num_columns_to_add; ++j) added_columns[j]->insertFrom(*mapped.block->getByPosition(right_indexes[j]).column, mapped.row_num); } static void addNotFound(size_t /*num_columns_to_add*/, MutableColumns & /*added_columns*/, size_t i, IColumn::Filter & filter, IColumn::Offset & /*current_offset*/, IColumn::Offsets * /*offsets*/) { filter[i] = 0; } }; template struct Adder { static void addFound(const typename Map::mapped_type & mapped, size_t num_columns_to_add, MutableColumns & added_columns, size_t i, IColumn::Filter & filter, IColumn::Offset & current_offset, IColumn::Offsets * offsets, const std::vector & right_indexes) { filter[i] = 1; size_t rows_joined = 0; for (auto current = &static_cast(mapped); current != nullptr; current = current->next) { for (size_t j = 0; j < num_columns_to_add; ++j) added_columns[j]->insertFrom(*current->block->getByPosition(right_indexes[j]).column.get(), current->row_num); ++rows_joined; } current_offset += rows_joined; (*offsets)[i] = current_offset; } static void addNotFound(size_t num_columns_to_add, MutableColumns & added_columns, size_t i, IColumn::Filter & filter, IColumn::Offset & current_offset, IColumn::Offsets * offsets) { filter[i] = 0; if (!fill_left) { (*offsets)[i] = current_offset; } else { ++current_offset; (*offsets)[i] = current_offset; for (size_t j = 0; j < num_columns_to_add; ++j) added_columns[j]->insertDefault(); } } }; template void NO_INLINE joinBlockImplTypeCase( const Map & map, size_t rows, const ColumnRawPtrs & key_columns, const Sizes & key_sizes, MutableColumns & added_columns, ConstNullMapPtr null_map, IColumn::Filter & filter, std::unique_ptr & offsets_to_replicate, const std::vector & right_indexes) { IColumn::Offset current_offset = 0; size_t num_columns_to_add = right_indexes.size(); Arena pool; KeyGetter key_getter(key_columns, key_sizes, nullptr); for (size_t i = 0; i < rows; ++i) { if (has_null_map && (*null_map)[i]) { Adder::fill_left, STRICTNESS, Map>::addNotFound( num_columns_to_add, added_columns, i, filter, current_offset, offsets_to_replicate.get()); } else { auto find_result = key_getter.findKey(map, i, pool); if (find_result.isFound()) { auto & mapped = find_result.getMapped(); mapped.setUsed(); Adder::fill_left, STRICTNESS, Map>::addFound( mapped, num_columns_to_add, added_columns, i, filter, current_offset, offsets_to_replicate.get(), right_indexes); } else Adder::fill_left, STRICTNESS, Map>::addNotFound( num_columns_to_add, added_columns, i, filter, current_offset, offsets_to_replicate.get()); } } } using BlockFilterData = std::pair< std::unique_ptr, std::unique_ptr>; template BlockFilterData joinBlockImplType( const Map & map, size_t rows, const ColumnRawPtrs & key_columns, const Sizes & key_sizes, MutableColumns & added_columns, ConstNullMapPtr null_map, const std::vector & right_indexes) { std::unique_ptr filter = std::make_unique(rows); std::unique_ptr offsets_to_replicate; if (STRICTNESS == ASTTableJoin::Strictness::All) offsets_to_replicate = std::make_unique(rows); if (null_map) joinBlockImplTypeCase( map, rows, key_columns, key_sizes, added_columns, null_map, *filter, offsets_to_replicate, right_indexes); else joinBlockImplTypeCase( map, rows, key_columns, key_sizes, added_columns, null_map, *filter, offsets_to_replicate, right_indexes); return {std::move(filter), std::move(offsets_to_replicate)}; } } template void Join::joinBlockImpl( Block & block, const Names & key_names_left, const NamesAndTypesList & columns_added_by_join, const Block & block_with_columns_to_add, const Maps & maps_) const { size_t keys_size = key_names_left.size(); ColumnRawPtrs key_columns(keys_size); /// Rare case, when keys are constant. To avoid code bloat, simply materialize them. Columns materialized_columns; materialized_columns.reserve(keys_size); /// Memoize key columns to work with. for (size_t i = 0; i < keys_size; ++i) { materialized_columns.emplace_back(recursiveRemoveLowCardinality(block.getByName(key_names_left[i]).column->convertToFullColumnIfConst())); key_columns[i] = materialized_columns.back().get(); } /// Keys with NULL value in any column won't join to anything. ColumnPtr null_map_holder; ConstNullMapPtr null_map{}; extractNestedColumnsAndNullMap(key_columns, null_map_holder, null_map); size_t existing_columns = block.columns(); /** If you use FULL or RIGHT JOIN, then the columns from the "left" table must be materialized. * Because if they are constants, then in the "not joined" rows, they may have different values * - default values, which can differ from the values of these constants. */ if (getFullness(kind)) { for (size_t i = 0; i < existing_columns; ++i) { block.getByPosition(i).column = block.getByPosition(i).column->convertToFullColumnIfConst(); /// If use_nulls, convert left columns (except keys) to Nullable. if (use_nulls) { if (std::end(key_names_left) == std::find(key_names_left.begin(), key_names_left.end(), block.getByPosition(i).name)) convertColumnToNullable(block.getByPosition(i)); } } } /** For LEFT/INNER JOIN, the saved blocks do not contain keys. * For FULL/RIGHT JOIN, the saved blocks contain keys; * but they will not be used at this stage of joining (and will be in `AdderNonJoined`), and they need to be skipped. */ size_t num_columns_to_skip = 0; if (getFullness(kind)) num_columns_to_skip = keys_size; /// Add new columns to the block. size_t num_columns_to_add = sample_block_with_columns_to_add.columns(); MutableColumns added_columns; added_columns.reserve(num_columns_to_add); std::vector> added_type_name; added_type_name.reserve(num_columns_to_add); std::vector right_indexes; right_indexes.reserve(num_columns_to_add); for (size_t i = 0; i < num_columns_to_add; ++i) { const ColumnWithTypeAndName & src_column = sample_block_with_columns_to_add.safeGetByPosition(i); /// Don't insert column if it's in left block or not explicitly required. if (!block.has(src_column.name) && block_with_columns_to_add.has(src_column.name)) { added_columns.push_back(src_column.column->cloneEmpty()); added_columns.back()->reserve(src_column.column->size()); added_type_name.emplace_back(src_column.type, src_column.name); right_indexes.push_back(num_columns_to_skip + i); } } std::unique_ptr filter; std::unique_ptr offsets_to_replicate; switch (type) { #define M(TYPE) \ case Join::Type::TYPE: \ std::tie(filter, offsets_to_replicate) = \ joinBlockImplType>::Type>(\ *maps_.TYPE, block.rows(), key_columns, key_sizes, added_columns, null_map, right_indexes); \ break; APPLY_FOR_JOIN_VARIANTS(M) #undef M default: throw Exception("Unknown JOIN keys variant.", ErrorCodes::UNKNOWN_SET_DATA_VARIANT); } const auto added_columns_size = added_columns.size(); for (size_t i = 0; i < added_columns_size; ++i) block.insert(ColumnWithTypeAndName(std::move(added_columns[i]), added_type_name[i].first, added_type_name[i].second)); if (!filter) throw Exception("No data to filter columns", ErrorCodes::LOGICAL_ERROR); NameSet needed_key_names_right = requiredRightKeys(key_names_right, columns_added_by_join); if (strictness == ASTTableJoin::Strictness::Any) { if (kind == ASTTableJoin::Kind::Inner || kind == ASTTableJoin::Kind::Right) { /// If ANY INNER | RIGHT JOIN - filter all the columns except the new ones. for (size_t i = 0; i < existing_columns; ++i) block.safeGetByPosition(i).column = block.safeGetByPosition(i).column->filter(*filter, -1); /// Add join key columns from right block if they has different name. for (size_t i = 0; i < key_names_right.size(); ++i) { auto & right_name = key_names_right[i]; auto & left_name = key_names_left[i]; if (needed_key_names_right.count(right_name) && !block.has(right_name)) { const auto & col = block.getByName(left_name); block.insert({col.column, col.type, right_name}); } } } else { /// Add join key columns from right block if they has different name. for (size_t i = 0; i < key_names_right.size(); ++i) { auto & right_name = key_names_right[i]; auto & left_name = key_names_left[i]; if (needed_key_names_right.count(right_name) && !block.has(right_name)) { const auto & col = block.getByName(left_name); auto & column = col.column; MutableColumnPtr mut_column = column->cloneEmpty(); for (size_t col_no = 0; col_no < filter->size(); ++col_no) { if ((*filter)[col_no]) mut_column->insertFrom(*column, col_no); else mut_column->insertDefault(); } block.insert({std::move(mut_column), col.type, right_name}); } } } } else { if (!offsets_to_replicate) throw Exception("No data to filter columns", ErrorCodes::LOGICAL_ERROR); /// Add join key columns from right block if they has different name. for (size_t i = 0; i < key_names_right.size(); ++i) { auto & right_name = key_names_right[i]; auto & left_name = key_names_left[i]; if (needed_key_names_right.count(right_name) && !block.has(right_name)) { const auto & col = block.getByName(left_name); auto & column = col.column; MutableColumnPtr mut_column = column->cloneEmpty(); size_t last_offset = 0; for (size_t col_no = 0; col_no < column->size(); ++col_no) { if (size_t to_insert = (*offsets_to_replicate)[col_no] - last_offset) { if (!(*filter)[col_no]) mut_column->insertDefault(); else for (size_t dup = 0; dup < to_insert; ++dup) mut_column->insertFrom(*column, col_no); } last_offset = (*offsets_to_replicate)[col_no]; } block.insert({std::move(mut_column), col.type, right_name}); } } /// If ALL ... JOIN - we replicate all the columns except the new ones. for (size_t i = 0; i < existing_columns; ++i) block.safeGetByPosition(i).column = block.safeGetByPosition(i).column->replicate(*offsets_to_replicate); } } void Join::joinBlockImplCross(Block & block) const { /// Add new columns to the block. size_t num_existing_columns = block.columns(); size_t num_columns_to_add = sample_block_with_columns_to_add.columns(); size_t rows_left = block.rows(); ColumnRawPtrs src_left_columns(num_existing_columns); MutableColumns dst_columns(num_existing_columns + num_columns_to_add); for (size_t i = 0; i < num_existing_columns; ++i) { src_left_columns[i] = block.getByPosition(i).column.get(); dst_columns[i] = src_left_columns[i]->cloneEmpty(); } for (size_t i = 0; i < num_columns_to_add; ++i) { const ColumnWithTypeAndName & src_column = sample_block_with_columns_to_add.getByPosition(i); dst_columns[num_existing_columns + i] = src_column.column->cloneEmpty(); block.insert(src_column); } /// NOTE It would be better to use `reserve`, as well as `replicate` methods to duplicate the values of the left block. for (size_t i = 0; i < rows_left; ++i) { for (const Block & block_right : blocks) { size_t rows_right = block_right.rows(); for (size_t col_num = 0; col_num < num_existing_columns; ++col_num) for (size_t j = 0; j < rows_right; ++j) dst_columns[col_num]->insertFrom(*src_left_columns[col_num], i); for (size_t col_num = 0; col_num < num_columns_to_add; ++col_num) { const IColumn * column_right = block_right.getByPosition(col_num).column.get(); for (size_t j = 0; j < rows_right; ++j) dst_columns[num_existing_columns + col_num]->insertFrom(*column_right, j); } } } block = block.cloneWithColumns(std::move(dst_columns)); } void Join::checkTypesOfKeys(const Block & block_left, const Names & key_names_left, const Block & block_right) const { size_t keys_size = key_names_left.size(); for (size_t i = 0; i < keys_size; ++i) { /// Compare up to Nullability. DataTypePtr left_type = removeNullable(recursiveRemoveLowCardinality(block_left.getByName(key_names_left[i]).type)); DataTypePtr right_type = removeNullable(recursiveRemoveLowCardinality(block_right.getByName(key_names_right[i]).type)); if (!left_type->equals(*right_type)) throw Exception("Type mismatch of columns to JOIN by: " + key_names_left[i] + " " + left_type->getName() + " at left, " + key_names_right[i] + " " + right_type->getName() + " at right", ErrorCodes::TYPE_MISMATCH); } } static void checkTypeOfKey(const Block & block_left, const Block & block_right) { auto & [c1, left_type_origin, left_name] = block_left.safeGetByPosition(0); auto & [c2, right_type_origin, right_name] = block_right.safeGetByPosition(0); auto left_type = removeNullable(left_type_origin); auto right_type = removeNullable(right_type_origin); if (!left_type->equals(*right_type)) throw Exception("Type mismatch of columns to joinGet by: " + left_name + " " + left_type->getName() + " at left, " + right_name + " " + right_type->getName() + " at right", ErrorCodes::TYPE_MISMATCH); } DataTypePtr Join::joinGetReturnType(const String & column_name) const { std::shared_lock lock(rwlock); if (!sample_block_with_columns_to_add.has(column_name)) throw Exception("StorageJoin doesn't contain column " + column_name, ErrorCodes::LOGICAL_ERROR); return sample_block_with_columns_to_add.getByName(column_name).type; } template void Join::joinGetImpl(Block & block, const String & column_name, const Maps & maps_) const { joinBlockImpl( block, {block.getByPosition(0).name}, {}, {sample_block_with_columns_to_add.getByName(column_name)}, maps_); } // TODO: support composite key // TODO: return multiple columns as named tuple // TODO: return array of values when strictness == ASTTableJoin::Strictness::All void Join::joinGet(Block & block, const String & column_name) const { std::shared_lock lock(rwlock); if (key_names_right.size() != 1) throw Exception("joinGet only supports StorageJoin containing exactly one key", ErrorCodes::LOGICAL_ERROR); checkTypeOfKey(block, sample_block_with_keys); if (kind == ASTTableJoin::Kind::Left && strictness == ASTTableJoin::Strictness::Any) { if (any_take_last_row) joinGetImpl(block, column_name, std::get(maps)); else joinGetImpl(block, column_name, std::get(maps)); } else throw Exception("joinGet only supports StorageJoin of type Left Any", ErrorCodes::LOGICAL_ERROR); } void Join::joinBlock(Block & block, const Names & key_names_left, const NamesAndTypesList & columns_added_by_join) const { // std::cerr << "joinBlock: " << block.dumpStructure() << "\n"; std::shared_lock lock(rwlock); checkTypesOfKeys(block, key_names_left, sample_block_with_keys); if (dispatch([&](auto kind_, auto strictness_, auto & map) { joinBlockImpl(block, key_names_left, columns_added_by_join, sample_block_with_columns_to_add, map); })) { /// Joined } else if (kind == ASTTableJoin::Kind::Cross) joinBlockImplCross(block); else throw Exception("Logical error: unknown combination of JOIN", ErrorCodes::LOGICAL_ERROR); } void Join::joinTotals(Block & block) const { Block totals_without_keys = totals; if (totals_without_keys) { for (const auto & name : key_names_right) totals_without_keys.erase(totals_without_keys.getPositionByName(name)); for (size_t i = 0; i < totals_without_keys.columns(); ++i) block.insert(totals_without_keys.safeGetByPosition(i)); } else { /// We will join empty `totals` - from one row with the default values. for (size_t i = 0; i < sample_block_with_columns_to_add.columns(); ++i) { const auto & col = sample_block_with_columns_to_add.getByPosition(i); block.insert({ col.type->createColumnConstWithDefaultValue(1)->convertToFullColumnIfConst(), col.type, col.name}); } } } template struct AdderNonJoined; template struct AdderNonJoined { static void add(const Mapped & mapped, size_t & rows_added, MutableColumns & columns_left, MutableColumns & columns_right) { for (size_t j = 0; j < columns_left.size(); ++j) columns_left[j]->insertDefault(); for (size_t j = 0; j < columns_right.size(); ++j) columns_right[j]->insertFrom(*mapped.block->getByPosition(j).column.get(), mapped.row_num); ++rows_added; } }; template struct AdderNonJoined { static void add(const Mapped & mapped, size_t & rows_added, MutableColumns & columns_left, MutableColumns & columns_right) { for (auto current = &static_cast(mapped); current != nullptr; current = current->next) { for (size_t j = 0; j < columns_left.size(); ++j) columns_left[j]->insertDefault(); for (size_t j = 0; j < columns_right.size(); ++j) columns_right[j]->insertFrom(*current->block->getByPosition(j).column.get(), current->row_num); ++rows_added; } } }; /// Stream from not joined earlier rows of the right table. class NonJoinedBlockInputStream : public IBlockInputStream { public: NonJoinedBlockInputStream(const Join & parent_, const Block & left_sample_block, const Names & key_names_left, const NamesAndTypesList & columns_added_by_join, size_t max_block_size_) : parent(parent_), max_block_size(max_block_size_) { /** left_sample_block contains keys and "left" columns. * result_sample_block - keys, "left" columns, and "right" columns. */ std::unordered_map key_renames; makeResultSampleBlock(left_sample_block, key_names_left, columns_added_by_join, key_renames); const Block & right_sample_block = parent.sample_block_with_columns_to_add; size_t num_keys = key_names_left.size(); size_t num_columns_left = left_sample_block.columns() - num_keys; size_t num_columns_right = right_sample_block.columns(); column_indices_left.reserve(num_columns_left); column_indices_keys_and_right.reserve(num_keys + num_columns_right); std::vector is_left_key(left_sample_block.columns(), false); for (const std::string & key : key_names_left) { size_t key_pos = left_sample_block.getPositionByName(key); is_left_key[key_pos] = true; /// Here we establish the mapping between key columns of the left- and right-side tables. /// key_pos index is inserted in the position corresponding to key column in parent.blocks /// (saved blocks of the right-side table) and points to the same key column /// in the left_sample_block and thus in the result_sample_block. column_indices_keys_and_right.push_back(key_pos); auto it = key_renames.find(key); if (it != key_renames.end()) key_renames_indices[key_pos] = result_sample_block.getPositionByName(it->second); } size_t num_src_columns = left_sample_block.columns() + right_sample_block.columns(); for (size_t i = 0; i < result_sample_block.columns(); ++i) { if (i < left_sample_block.columns()) { if (!is_left_key[i]) { column_indices_left.emplace_back(i); /// If use_nulls, convert left columns to Nullable. if (parent.use_nulls) convertColumnToNullable(result_sample_block.getByPosition(i)); } } else if (i < num_src_columns) column_indices_keys_and_right.emplace_back(i); } } String getName() const override { return "NonJoined"; } Block getHeader() const override { return result_sample_block; } protected: Block readImpl() override { if (parent.blocks.empty()) return Block(); Block block; if (parent.dispatch([&](auto, auto strictness, auto & map) { block = createBlock(map); })) ; else throw Exception("Logical error: unknown JOIN strictness (must be ANY or ALL)", ErrorCodes::LOGICAL_ERROR); return block; } private: const Join & parent; size_t max_block_size; Block result_sample_block; /// Indices of columns in result_sample_block that come from the left-side table (except key columns). ColumnNumbers column_indices_left; /// Indices of key columns in result_sample_block or columns that come from the right-side table. /// Order is significant: it is the same as the order of columns in the blocks of the right-side table that are saved in parent.blocks. ColumnNumbers column_indices_keys_and_right; std::unordered_map key_renames_indices; std::unique_ptr> position; /// type erasure void makeResultSampleBlock(const Block & left_sample_block, const Names & key_names_left, const NamesAndTypesList & columns_added_by_join, std::unordered_map & key_renames) { const Block & right_sample_block = parent.sample_block_with_columns_to_add; result_sample_block = materializeBlock(left_sample_block); /// Add columns from the right-side table to the block. for (size_t i = 0; i < right_sample_block.columns(); ++i) { const ColumnWithTypeAndName & src_column = right_sample_block.getByPosition(i); result_sample_block.insert(src_column.cloneEmpty()); } const auto & key_names_right = parent.key_names_right; NameSet needed_key_names_right = requiredRightKeys(key_names_right, columns_added_by_join); /// Add join key columns from right block if they has different name. for (size_t i = 0; i < key_names_right.size(); ++i) { auto & right_name = key_names_right[i]; auto & left_name = key_names_left[i]; if (needed_key_names_right.count(right_name) && !result_sample_block.has(right_name)) { const auto & col = result_sample_block.getByName(left_name); result_sample_block.insert({col.column, col.type, right_name}); key_renames[left_name] = right_name; } } } template Block createBlock(const Maps & maps) { MutableColumns columns_left = columnsForIndex(result_sample_block, column_indices_left); MutableColumns columns_keys_and_right = columnsForIndex(result_sample_block, column_indices_keys_and_right); size_t rows_added = 0; switch (parent.type) { #define M(TYPE) \ case Join::Type::TYPE: \ rows_added = fillColumns(*maps.TYPE, columns_left, columns_keys_and_right); \ break; APPLY_FOR_JOIN_VARIANTS(M) #undef M default: throw Exception("Unknown JOIN keys variant.", ErrorCodes::UNKNOWN_SET_DATA_VARIANT); } if (!rows_added) return {}; Block res = result_sample_block.cloneEmpty(); for (size_t i = 0; i < columns_left.size(); ++i) res.getByPosition(column_indices_left[i]).column = std::move(columns_left[i]); if (key_renames_indices.empty()) { for (size_t i = 0; i < columns_keys_and_right.size(); ++i) res.getByPosition(column_indices_keys_and_right[i]).column = std::move(columns_keys_and_right[i]); } else { for (size_t i = 0; i < columns_keys_and_right.size(); ++i) { size_t key_idx = column_indices_keys_and_right[i]; auto it = key_renames_indices.find(key_idx); if (it != key_renames_indices.end()) { auto & key_column = res.getByPosition(key_idx).column; if (key_column->empty()) key_column = key_column->cloneResized(columns_keys_and_right[i]->size()); res.getByPosition(it->second).column = std::move(columns_keys_and_right[i]); } else res.getByPosition(key_idx).column = std::move(columns_keys_and_right[i]); } } return res; } static MutableColumns columnsForIndex(const Block & block, const ColumnNumbers & indices) { size_t num_columns = indices.size(); MutableColumns columns; columns.resize(num_columns); for (size_t i = 0; i < num_columns; ++i) { const auto & src_col = block.safeGetByPosition(indices[i]); columns[i] = src_col.type->createColumn(); } return columns; } template size_t fillColumns(const Map & map, MutableColumns & columns_left, MutableColumns & columns_keys_and_right) { size_t rows_added = 0; if (!position) position = decltype(position)( static_cast(new typename Map::const_iterator(map.begin())), //-V572 [](void * ptr) { delete reinterpret_cast(ptr); }); auto & it = *reinterpret_cast(position.get()); auto end = map.end(); for (; it != end; ++it) { if (it->second.getUsed()) continue; AdderNonJoined::add(it->second, rows_added, columns_left, columns_keys_and_right); if (rows_added >= max_block_size) { ++it; break; } } return rows_added; } }; BlockInputStreamPtr Join::createStreamWithNonJoinedRows(const Block & left_sample_block, const Names & key_names_left, const NamesAndTypesList & columns_added_by_join, size_t max_block_size) const { return std::make_shared(*this, left_sample_block, key_names_left, columns_added_by_join, max_block_size); } }