ClickHouse/src/DataTypes/NestedUtils.cpp
2020-12-07 22:02:26 +03:00

240 lines
7.2 KiB
C++

#include <string.h>
#include <Common/typeid_cast.h>
#include <Common/assert_cast.h>
#include <Common/StringUtils/StringUtils.h>
#include <DataTypes/DataTypeArray.h>
#include <DataTypes/DataTypeTuple.h>
#include <DataTypes/NestedUtils.h>
#include <DataTypes/DataTypeNested.h>
#include <Columns/ColumnArray.h>
#include <Columns/ColumnTuple.h>
#include <Columns/ColumnConst.h>
#include <Parsers/IAST.h>
namespace DB
{
namespace ErrorCodes
{
extern const int ILLEGAL_COLUMN;
extern const int SIZES_OF_ARRAYS_DOESNT_MATCH;
}
namespace Nested
{
std::string concatenateName(const std::string & nested_table_name, const std::string & nested_field_name)
{
return nested_table_name + "." + nested_field_name;
}
/** Name can be treated as compound if and only if both parts are simple identifiers.
*/
std::pair<std::string, std::string> splitName(const std::string & name)
{
const char * begin = name.data();
const char * pos = begin;
const char * end = begin + name.size();
if (pos >= end || !isValidIdentifierBegin(*pos))
return {name, {}};
++pos;
while (pos < end && isWordCharASCII(*pos))
++pos;
if (pos >= end || *pos != '.')
return {name, {}};
const char * first_end = pos;
++pos;
const char * second_begin = pos;
if (pos >= end || !isValidIdentifierBegin(*pos))
return {name, {}};
++pos;
while (pos < end && isWordCharASCII(*pos))
++pos;
if (pos != end)
return {name, {}};
return {{ begin, first_end }, { second_begin, end }};
}
std::string extractTableName(const std::string & nested_name)
{
auto split = splitName(nested_name);
return split.first;
}
Block flatten(const Block & block)
{
Block res;
for (const auto & elem : block)
{
const DataTypeArray * type_arr = typeid_cast<const DataTypeArray *>(elem.type.get());
if (type_arr)
{
const DataTypeTuple * type_tuple = typeid_cast<const DataTypeTuple *>(type_arr->getNestedType().get());
if (type_tuple && type_tuple->haveExplicitNames())
{
const DataTypes & element_types = type_tuple->getElements();
const Strings & names = type_tuple->getElementNames();
size_t tuple_size = element_types.size();
bool is_const = isColumnConst(*elem.column);
const ColumnArray * column_array;
if (is_const)
column_array = typeid_cast<const ColumnArray *>(&assert_cast<const ColumnConst &>(*elem.column).getDataColumn());
else
column_array = typeid_cast<const ColumnArray *>(elem.column.get());
const ColumnPtr & column_offsets = column_array->getOffsetsPtr();
const ColumnTuple & column_tuple = typeid_cast<const ColumnTuple &>(column_array->getData());
const auto & element_columns = column_tuple.getColumns();
for (size_t i = 0; i < tuple_size; ++i)
{
String nested_name = concatenateName(elem.name, names[i]);
ColumnPtr column_array_of_element = ColumnArray::create(element_columns[i], column_offsets);
res.insert(ColumnWithTypeAndName(
is_const
? ColumnConst::create(std::move(column_array_of_element), block.rows())
: std::move(column_array_of_element),
std::make_shared<DataTypeArray>(element_types[i]),
nested_name));
}
}
else
res.insert(elem);
}
else
res.insert(elem);
}
return res;
}
namespace
{
using NameToDataType = std::map<String, DataTypePtr>;
NameToDataType getSubcolumnsOfNested(const NamesAndTypesList & names_and_types)
{
std::unordered_map<String, NamesAndTypesList> nested;
for (const auto & name_type : names_and_types)
{
const DataTypeArray * type_arr = typeid_cast<const DataTypeArray *>(name_type.type.get());
/// Ignore true Nested type, but try to unite flatten arrays to Nested type.
if (!isNested(name_type.type) && type_arr)
{
auto split = splitName(name_type.name);
if (!split.second.empty())
nested[split.first].emplace_back(split.second, type_arr->getNestedType());
}
}
std::map<String, DataTypePtr> nested_types;
for (const auto & [name, elems] : nested)
nested_types.emplace(name, createNested(elems.getTypes(), elems.getNames()));
return nested_types;
}
}
NamesAndTypesList collect(const NamesAndTypesList & names_and_types)
{
NamesAndTypesList res;
auto nested_types = getSubcolumnsOfNested(names_and_types);
for (const auto & name_type : names_and_types)
if (!nested_types.count(splitName(name_type.name).first))
res.push_back(name_type);
for (const auto & name_type : nested_types)
res.emplace_back(name_type.first, name_type.second);
return res;
}
NamesAndTypesList convertToSubcolumns(const NamesAndTypesList & names_and_types)
{
auto nested_types = getSubcolumnsOfNested(names_and_types);
auto res = names_and_types;
for (auto & name_type : res)
{
auto split = splitName(name_type.name);
if (name_type.isSubcolumn() || split.second.empty())
continue;
auto it = nested_types.find(split.first);
if (it != nested_types.end())
name_type = NameAndTypePair{split.first, split.second, it->second, it->second->getSubcolumnType(split.second)};
}
return res;
}
void validateArraySizes(const Block & block)
{
/// Nested prefix -> position of first column in block.
std::map<std::string, size_t> nested;
for (size_t i = 0, size = block.columns(); i < size; ++i)
{
const auto & elem = block.getByPosition(i);
if (isArray(elem.type))
{
if (!typeid_cast<const ColumnArray *>(elem.column.get()))
throw Exception("Column with Array type is not represented by ColumnArray column: " + elem.column->dumpStructure(), ErrorCodes::ILLEGAL_COLUMN);
auto split = splitName(elem.name);
/// Is it really a column of Nested data structure.
if (!split.second.empty())
{
auto [it, inserted] = nested.emplace(split.first, i);
/// It's not the first column of Nested data structure.
if (!inserted)
{
const ColumnArray & first_array_column = assert_cast<const ColumnArray &>(*block.getByPosition(it->second).column);
const ColumnArray & another_array_column = assert_cast<const ColumnArray &>(*elem.column);
if (!first_array_column.hasEqualOffsets(another_array_column))
throw Exception("Elements '" + block.getByPosition(it->second).name
+ "' and '" + elem.name
+ "' of Nested data structure '" + split.first
+ "' (Array columns) have different array sizes.", ErrorCodes::SIZES_OF_ARRAYS_DOESNT_MATCH);
}
}
}
}
}
}
}