ClickHouse/dbms/include/DB/Functions/FunctionsConversion.h
2016-02-01 21:32:34 +03:00

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#pragma once
#include <ext/enumerate.hpp>
#include <ext/collection_cast.hpp>
#include <ext/range.hpp>
#include <type_traits>
#include <DB/IO/WriteBufferFromVector.h>
#include <DB/IO/ReadBufferFromString.h>
#include <DB/DataTypes/DataTypeFactory.h>
#include <DB/DataTypes/DataTypesNumberFixed.h>
#include <DB/DataTypes/DataTypeString.h>
#include <DB/DataTypes/DataTypeFixedString.h>
#include <DB/DataTypes/DataTypeDate.h>
#include <DB/DataTypes/DataTypeDateTime.h>
#include <DB/DataTypes/DataTypeEnum.h>
#include <DB/DataTypes/DataTypeArray.h>
#include <DB/DataTypes/DataTypeTuple.h>
#include <DB/Columns/ColumnString.h>
#include <DB/Columns/ColumnFixedString.h>
#include <DB/Columns/ColumnConst.h>
#include <DB/Columns/ColumnArray.h>
#include <DB/Core/FieldVisitors.h>
#include <DB/Interpreters/ExpressionActions.h>
#include <DB/Functions/IFunction.h>
#include <DB/Functions/FunctionsMiscellaneous.h>
namespace DB
{
namespace ErrorCodes
{
extern const int CANNOT_PARSE_NUMBER;
}
/** Функции преобразования типов.
* toType - преобразование "естественным образом";
*/
/** Преобразование чисел друг в друга, перечислений в числа, дат/дат-с-временем в числа и наоборот: делается обычным присваиванием.
* (дата внутри хранится как количество дней с какого-то, дата-с-временем - как unix timestamp)
*/
template <typename FromDataType, typename ToDataType, typename Name>
struct ConvertImpl
{
typedef typename FromDataType::FieldType FromFieldType;
typedef typename ToDataType::FieldType ToFieldType;
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
if (const ColumnVector<FromFieldType> * col_from
= typeid_cast<const ColumnVector<FromFieldType> *>(&*block.getByPosition(arguments[0]).column))
{
ColumnVector<ToFieldType> * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
const typename ColumnVector<FromFieldType>::Container_t & vec_from = col_from->getData();
typename ColumnVector<ToFieldType>::Container_t & vec_to = col_to->getData();
size_t size = vec_from.size();
vec_to.resize(size);
for (size_t i = 0; i < size; ++i)
vec_to[i] = vec_from[i];
}
else if (const ColumnConst<FromFieldType> * col_from = typeid_cast<const ColumnConst<FromFieldType> *>(&*block.getByPosition(arguments[0]).column))
{
block.getByPosition(result).column = new ColumnConst<ToFieldType>(col_from->size(), col_from->getData());
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
};
/** Преобразование даты в дату-с-временем: добавление нулевого времени.
*/
template <typename Name>
struct ConvertImpl<DataTypeDate, DataTypeDateTime, Name>
{
typedef DataTypeDate::FieldType FromFieldType;
typedef DataTypeDateTime::FieldType ToFieldType;
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
typedef DataTypeDate::FieldType FromFieldType;
const auto & date_lut = DateLUT::instance();
if (const ColumnVector<FromFieldType> * col_from = typeid_cast<const ColumnVector<FromFieldType> *>(&*block.getByPosition(arguments[0]).column))
{
ColumnVector<ToFieldType> * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
const typename ColumnVector<FromFieldType>::Container_t & vec_from = col_from->getData();
typename ColumnVector<ToFieldType>::Container_t & vec_to = col_to->getData();
size_t size = vec_from.size();
vec_to.resize(size);
for (size_t i = 0; i < size; ++i)
{
vec_to[i] = date_lut.fromDayNum(DayNum_t(vec_from[i]));
}
}
else if (const ColumnConst<FromFieldType> * col_from = typeid_cast<const ColumnConst<FromFieldType> *>(&*block.getByPosition(arguments[0]).column))
{
block.getByPosition(result).column = new ColumnConst<ToFieldType>(col_from->size(), date_lut.fromDayNum(DayNum_t(col_from->getData())));
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
};
/// Реализация функции toDate.
namespace details {
template<typename FromType, typename ToType, template <typename, typename> class Transformation>
class Transformer
{
private:
using Op = Transformation<FromType, ToType>;
public:
static void vector_vector(const PODArray<FromType> & vec_from, const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets, PODArray<ToType> & vec_to)
{
ColumnString::Offset_t prev_offset = 0;
for (size_t i = 0; i < vec_from.size(); ++i)
{
ColumnString::Offset_t cur_offset = offsets[i];
const std::string time_zone(reinterpret_cast<const char *>(&data[prev_offset]), cur_offset - prev_offset - 1);
const auto & remote_date_lut = DateLUT::instance(time_zone);
vec_to[i] = Op::execute(vec_from[i], remote_date_lut);
prev_offset = cur_offset;
}
}
static void vector_constant(const PODArray<FromType> & vec_from, const std::string & data,
PODArray<ToType> & vec_to)
{
const auto & remote_date_lut = DateLUT::instance(data);
for (size_t i = 0; i < vec_from.size(); ++i)
vec_to[i] = Op::execute(vec_from[i], remote_date_lut);
}
static void vector_constant(const PODArray<FromType> & vec_from, PODArray<ToType> & vec_to)
{
const auto & local_date_lut = DateLUT::instance();
for (size_t i = 0; i < vec_from.size(); ++i)
vec_to[i] = Op::execute(vec_from[i], local_date_lut);
}
static void constant_vector(const FromType & from, const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets, PODArray<ToType> & vec_to)
{
ColumnString::Offset_t prev_offset = 0;
for (size_t i = 0; i < offsets.size(); ++i)
{
ColumnString::Offset_t cur_offset = offsets[i];
const std::string time_zone(reinterpret_cast<const char *>(&data[prev_offset]), cur_offset - prev_offset - 1);
const auto & remote_date_lut = DateLUT::instance(time_zone);
vec_to[i] = Op::execute(from, remote_date_lut);
prev_offset = cur_offset;
}
}
static void constant_constant(const FromType & from, const std::string & data, ToType & to)
{
const auto & remote_date_lut = DateLUT::instance(data);
to = Op::execute(from, remote_date_lut);
}
static void constant_constant(const FromType & from, ToType & to)
{
const auto & local_date_lut = DateLUT::instance();
to = Op::execute(from, local_date_lut);
}
};
template <typename FromType, template <typename, typename> class Transformation, typename Name>
class ToDateConverter
{
private:
using FromFieldType = typename FromType::FieldType;
using ToFieldType = typename DataTypeDate::FieldType;
using Op = Transformer<FromFieldType, ToFieldType, Transformation>;
public:
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
const ColumnPtr source_col = block.getByPosition(arguments[0]).column;
const auto * sources = typeid_cast<const ColumnVector<FromFieldType> *>(&*source_col);
const auto * const_source = typeid_cast<const ColumnConst<FromFieldType> *>(&*source_col);
if (arguments.size() == 1)
{
if (sources)
{
auto * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
const auto & vec_from = sources->getData();
auto & vec_to = col_to->getData();
size_t size = vec_from.size();
vec_to.resize(size);
Op::vector_constant(vec_from, vec_to);
}
else if (const_source)
{
ToFieldType res;
Op::constant_constant(const_source->getData(), res);
block.getByPosition(result).column = new ColumnConst<ToFieldType>(const_source->size(), res);
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else if (arguments.size() == 2)
{
const ColumnPtr time_zone_col = block.getByPosition(arguments[1]).column;
const auto * time_zones = typeid_cast<const ColumnString *>(&*time_zone_col);
const auto * const_time_zone = typeid_cast<const ColumnConstString *>(&*time_zone_col);
if (sources)
{
auto * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
auto & vec_from = sources->getData();
auto & vec_to = col_to->getData();
vec_to.resize(vec_from.size());
if (time_zones)
Op::vector_vector(vec_from, time_zones->getChars(), time_zones->getOffsets(), vec_to);
else if (const_time_zone)
Op::vector_constant(vec_from, const_time_zone->getData(), vec_to);
else
throw Exception("Illegal column " + block.getByPosition(arguments[1]).column->getName()
+ " of second argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else if (const_source)
{
if (time_zones)
{
auto * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
auto & vec_to = col_to->getData();
vec_to.resize(time_zones->getOffsets().size());
Op::constant_vector(const_source->getData(), time_zones->getChars(), time_zones->getOffsets(), vec_to);
}
else if (const_time_zone)
{
ToFieldType res;
Op::constant_constant(const_source->getData(), const_time_zone->getData(), res);
block.getByPosition(result).column = new ColumnConst<ToFieldType>(const_source->size(), res);
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[1]).column->getName()
+ " of second argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else
throw Exception("FunctionsConversion: Internal error", ErrorCodes::LOGICAL_ERROR);
}
};
template <typename FromType, typename ToType>
struct ToDateTransform
{
static inline ToType execute(const FromType & from, const DateLUTImpl & date_lut)
{
return date_lut.toDayNum(from);
}
};
template <typename FromType, typename ToType>
struct ToDateTransform32Or64
{
static inline ToType execute(const FromType & from, const DateLUTImpl & date_lut)
{
return (from < 0xFFFF) ? from : date_lut.toDayNum(from);
}
};
}
/** Преобразование даты-с-временем в дату: отбрасывание времени.
*/
template <typename Name> struct ConvertImpl<DataTypeDateTime, DataTypeDate, Name> : details::ToDateConverter<DataTypeDateTime, details::ToDateTransform, Name> {};
/** Отдельный случай для преобразования (U)Int32 или (U)Int64 в Date.
* Если число меньше 65536, то оно понимается, как DayNum, а если больше или равно - как unix timestamp.
* Немного нелогично, что мы, по сути, помещаем две разные функции в одну.
* Но зато это позволяет поддержать распространённый случай,
* когда пользователь пишет toDate(UInt32), ожидая, что это - перевод unix timestamp в дату
* (иначе такое использование было бы распространённой ошибкой).
*/
template <typename Name> struct ConvertImpl<DataTypeUInt32, DataTypeDate, Name> : details::ToDateConverter<DataTypeUInt32, details::ToDateTransform32Or64, Name> {};
template <typename Name> struct ConvertImpl<DataTypeUInt64, DataTypeDate, Name> : details::ToDateConverter<DataTypeUInt64, details::ToDateTransform32Or64, Name> {};
template <typename Name> struct ConvertImpl<DataTypeInt32, DataTypeDate, Name> : details::ToDateConverter<DataTypeInt32, details::ToDateTransform32Or64, Name> {};
template <typename Name> struct ConvertImpl<DataTypeInt64, DataTypeDate, Name> : details::ToDateConverter<DataTypeInt64, details::ToDateTransform32Or64, Name> {};
/** Преобразование чисел, дат, дат-с-временем в строки: через форматирование.
*/
template <typename DataType> struct FormatImpl
{
static void execute(const typename DataType::FieldType x, WriteBuffer & wb, const DataType & type = DataType{})
{
writeText(x, wb);
}
};
template <> struct FormatImpl<DataTypeDate>
{
static void execute(const DataTypeDate::FieldType x, WriteBuffer & wb, const DataTypeDate & type = DataTypeDate{})
{
writeDateText(DayNum_t(x), wb);
}
};
template <> struct FormatImpl<DataTypeDateTime>
{
static void execute(const DataTypeDateTime::FieldType x, WriteBuffer & wb, const DataTypeDateTime &type = DataTypeDateTime{})
{
writeDateTimeText(x, wb);
}
};
template <typename FieldType> struct FormatImpl<DataTypeEnum<FieldType>>
{
static void execute(const FieldType x, WriteBuffer & wb, const DataTypeEnum<FieldType> & type)
{
writeString(type.getNameForValue(x), wb);
}
};
/// DataTypeEnum<T> to DataType<T> free conversion
template <typename FieldType, typename Name>
struct ConvertImpl<DataTypeEnum<FieldType>, typename DataTypeFromFieldType<FieldType>::Type, Name>
{
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
block.getByPosition(result).column = block.getByPosition(arguments[0]).column;
}
};
template <typename FromDataType, typename Name>
struct ConvertImpl<FromDataType, DataTypeString, Name>
{
typedef typename FromDataType::FieldType FromFieldType;
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
const auto & col_with_name_and_type = block.getByPosition(arguments[0]);
const auto & type = static_cast<const FromDataType &>(*col_with_name_and_type.type);
if (const auto col_from = typeid_cast<const ColumnVector<FromFieldType> *>(&*col_with_name_and_type.column))
{
ColumnString * col_to = new ColumnString;
block.getByPosition(result).column = col_to;
const typename ColumnVector<FromFieldType>::Container_t & vec_from = col_from->getData();
ColumnString::Chars_t & data_to = col_to->getChars();
ColumnString::Offsets_t & offsets_to = col_to->getOffsets();
size_t size = vec_from.size();
data_to.resize(size * 2);
offsets_to.resize(size);
WriteBufferFromVector<ColumnString::Chars_t> write_buffer(data_to);
for (size_t i = 0; i < size; ++i)
{
FormatImpl<FromDataType>::execute(vec_from[i], write_buffer, type);
writeChar(0, write_buffer);
offsets_to[i] = write_buffer.count();
}
data_to.resize(write_buffer.count());
}
else if (const auto col_from = typeid_cast<const ColumnConst<FromFieldType> *>(&*col_with_name_and_type.column))
{
std::vector<char> buf;
WriteBufferFromVector<std::vector<char> > write_buffer(buf);
FormatImpl<FromDataType>::execute(col_from->getData(), write_buffer, type);
block.getByPosition(result).column = new ColumnConstString(col_from->size(), std::string(&buf[0], write_buffer.count()));
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
};
namespace details { namespace {
/** Пусть source_timestamp представляет дату и время в исходном часовом поясе соответствующем
* объекту from_date_lut. Эта функция возвращает timestamp представлящий те же дату и время
* в часовом поясе соответствующем объекту to_date_lut.
*/
time_t convertTimestamp(time_t source_timestamp, const DateLUTImpl & from_date_lut, const DateLUTImpl & to_date_lut)
{
if (&from_date_lut == &to_date_lut)
return source_timestamp;
else
{
const auto & values = from_date_lut.getValues(source_timestamp);
return to_date_lut.makeDateTime(values.year, values.month, values.day_of_month,
from_date_lut.toHourInaccurate(source_timestamp),
from_date_lut.toMinuteInaccurate(source_timestamp),
from_date_lut.toSecondInaccurate(source_timestamp));
}
}
/** Функции для преобразования даты + времени в строку.
*/
struct DateTimeToStringConverter
{
using FromFieldType = typename DataTypeDateTime::FieldType;
static void vector_vector(const PODArray<FromFieldType> & vec_from, const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets, ColumnString & vec_to)
{
const auto & local_date_lut = DateLUT::instance();
ColumnString::Chars_t & data_to = vec_to.getChars();
ColumnString::Offsets_t & offsets_to = vec_to.getOffsets();
size_t size = vec_from.size();
data_to.resize(size * 2);
offsets_to.resize(size);
WriteBufferFromVector<ColumnString::Chars_t> write_buffer(data_to);
ColumnString::Offset_t prev_offset = 0;
for (size_t i = 0; i < size; ++i)
{
ColumnString::Offset_t cur_offset = offsets[i];
const std::string time_zone(reinterpret_cast<const char *>(&data[prev_offset]), cur_offset - prev_offset - 1);
const auto & remote_date_lut = DateLUT::instance(time_zone);
auto ti = convertTimestamp(vec_from[i], remote_date_lut, local_date_lut);
FormatImpl<DataTypeDateTime>::execute(ti, write_buffer);
writeChar(0, write_buffer);
offsets_to[i] = write_buffer.count();
prev_offset = cur_offset;
}
data_to.resize(write_buffer.count());
}
static void vector_constant(const PODArray<FromFieldType> & vec_from, const std::string & data,
ColumnString & vec_to)
{
const auto & local_date_lut = DateLUT::instance();
const auto & remote_date_lut = DateLUT::instance(data);
ColumnString::Chars_t & data_to = vec_to.getChars();
ColumnString::Offsets_t & offsets_to = vec_to.getOffsets();
size_t size = vec_from.size();
data_to.resize(size * 2);
offsets_to.resize(size);
WriteBufferFromVector<ColumnString::Chars_t> write_buffer(data_to);
for (size_t i = 0; i < size; ++i)
{
auto ti = convertTimestamp(vec_from[i], remote_date_lut, local_date_lut);
FormatImpl<DataTypeDateTime>::execute(ti, write_buffer);
writeChar(0, write_buffer);
offsets_to[i] = write_buffer.count();
}
data_to.resize(write_buffer.count());
}
static void vector_constant(const PODArray<FromFieldType> & vec_from, ColumnString & vec_to)
{
ColumnString::Chars_t & data_to = vec_to.getChars();
ColumnString::Offsets_t & offsets_to = vec_to.getOffsets();
size_t size = vec_from.size();
data_to.resize(size * 2);
offsets_to.resize(size);
WriteBufferFromVector<ColumnString::Chars_t> write_buffer(data_to);
for (size_t i = 0; i < size; ++i)
{
FormatImpl<DataTypeDateTime>::execute(vec_from[i], write_buffer);
writeChar(0, write_buffer);
offsets_to[i] = write_buffer.count();
}
data_to.resize(write_buffer.count());
}
static void constant_vector(FromFieldType from, const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets,
ColumnString & vec_to)
{
const auto & local_date_lut = DateLUT::instance();
ColumnString::Chars_t & data_to = vec_to.getChars();
ColumnString::Offsets_t & offsets_to = vec_to.getOffsets();
size_t size = offsets.size();
data_to.resize(size * 2);
offsets_to.resize(size);
WriteBufferFromVector<ColumnString::Chars_t> write_buffer(data_to);
ColumnString::Offset_t prev_offset = 0;
for (size_t i = 0; i < size; ++i)
{
ColumnString::Offset_t cur_offset = offsets[i];
const std::string time_zone(reinterpret_cast<const char *>(&data[prev_offset]), cur_offset - prev_offset - 1);
const auto & remote_date_lut = DateLUT::instance(time_zone);
auto ti = convertTimestamp(from, remote_date_lut, local_date_lut);
FormatImpl<DataTypeDateTime>::execute(ti, write_buffer);
writeChar(0, write_buffer);
offsets_to[i] = write_buffer.count();
prev_offset = cur_offset;
}
data_to.resize(write_buffer.count());
}
static void constant_constant(FromFieldType from, const std::string & data, std::string & to)
{
const auto & local_date_lut = DateLUT::instance();
const auto & remote_date_lut = DateLUT::instance(data);
std::vector<char> buf;
WriteBufferFromVector<std::vector<char> > write_buffer(buf);
auto ti = convertTimestamp(from, remote_date_lut, local_date_lut);
FormatImpl<DataTypeDateTime>::execute(ti, write_buffer);
to = std::string(&buf[0], write_buffer.count());
}
static void constant_constant(FromFieldType from, std::string & to)
{
std::vector<char> buf;
WriteBufferFromVector<std::vector<char> > write_buffer(buf);
FormatImpl<DataTypeDateTime>::execute(from, write_buffer);
to = std::string(&buf[0], write_buffer.count());
}
};
}}
template<typename Name>
struct ConvertImpl<DataTypeDateTime, DataTypeString, Name>
{
using Op = details::DateTimeToStringConverter;
using FromFieldType = Op::FromFieldType;
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
const ColumnPtr source_col = block.getByPosition(arguments[0]).column;
const auto * sources = typeid_cast<const ColumnVector<FromFieldType> *>(&*source_col);
const auto * const_source = typeid_cast<const ColumnConst<FromFieldType> *>(&*source_col);
if (arguments.size() == 1)
{
if (sources)
{
ColumnString * col_to = new ColumnString;
block.getByPosition(result).column = col_to;
auto & vec_from = sources->getData();
auto & vec_to = *col_to;
Op::vector_constant(vec_from, vec_to);
}
else if (const_source)
{
std::string res;
Op::constant_constant(const_source->getData(), res);
block.getByPosition(result).column = new ColumnConstString(const_source->size(), res);
}
else
{
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
}
else if (arguments.size() == 2)
{
const ColumnPtr time_zone_col = block.getByPosition(arguments[1]).column;
const auto * time_zones = typeid_cast<const ColumnString *>(&*time_zone_col);
const auto * const_time_zone = typeid_cast<const ColumnConstString *>(&*time_zone_col);
if (sources)
{
ColumnString * col_to = new ColumnString;
block.getByPosition(result).column = col_to;
auto & vec_from = sources->getData();
auto & vec_to = *col_to;
if (time_zones)
Op::vector_vector(vec_from, time_zones->getChars(), time_zones->getOffsets(), vec_to);
else if (const_time_zone)
Op::vector_constant(vec_from, const_time_zone->getData(), vec_to);
else
throw Exception("Illegal column " + block.getByPosition(arguments[1]).column->getName()
+ " of second argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else if (const_source)
{
if (time_zones)
{
ColumnString * col_to = new ColumnString;
block.getByPosition(result).column = col_to;
auto & vec_to = *col_to;
Op::constant_vector(const_source->getData(), time_zones->getChars(), time_zones->getOffsets(), vec_to);
}
else if (const_time_zone)
{
std::string res;
Op::constant_constant(const_source->getData(), const_time_zone->getData(), res);
block.getByPosition(result).column = new ColumnConstString(const_source->size(), res);
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[1]).column->getName()
+ " of second argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else
throw Exception("Internal error.", ErrorCodes::LOGICAL_ERROR);
}
};
/** Преобразование строк в числа, даты, даты-с-временем: через парсинг.
*/
template <typename DataType> void parseImpl(typename DataType::FieldType & x, ReadBuffer & rb) { readText(x,rb); }
template <> inline void parseImpl<DataTypeDate>(DataTypeDate::FieldType & x, ReadBuffer & rb)
{
DayNum_t tmp(0);
readDateText(tmp, rb);
x = tmp;
}
template <> inline void parseImpl<DataTypeDateTime>(DataTypeDateTime::FieldType & x, ReadBuffer & rb)
{
time_t tmp = 0;
readDateTimeText(tmp, rb);
x = tmp;
}
template <typename ToDataType, typename Name>
struct ConvertImpl<DataTypeString, ToDataType, Name>
{
typedef typename ToDataType::FieldType ToFieldType;
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
if (const ColumnString * col_from = typeid_cast<const ColumnString *>(&*block.getByPosition(arguments[0]).column))
{
ColumnVector<ToFieldType> * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
const ColumnString::Chars_t & data_from = col_from->getChars();
typename ColumnVector<ToFieldType>::Container_t & vec_to = col_to->getData();
size_t size = col_from->size();
vec_to.resize(size);
ReadBuffer read_buffer(const_cast<char *>(reinterpret_cast<const char *>(&data_from[0])), data_from.size(), 0);
char zero = 0;
for (size_t i = 0; i < size; ++i)
{
parseImpl<ToDataType>(vec_to[i], read_buffer);
readChar(zero, read_buffer);
if (zero != 0)
throw Exception("Cannot parse from string.", ErrorCodes::CANNOT_PARSE_NUMBER);
}
}
else if (const ColumnConstString * col_from = typeid_cast<const ColumnConstString *>(&*block.getByPosition(arguments[0]).column))
{
const String & s = col_from->getData();
ReadBufferFromString read_buffer(s);
ToFieldType x = 0;
parseImpl<ToDataType>(x, read_buffer);
block.getByPosition(result).column = new ColumnConst<ToFieldType>(col_from->size(), x);
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
};
namespace details { namespace {
/** Функции для преобразования строк в timestamp.
*/
struct StringToTimestampConverter
{
using ToFieldType = typename DataTypeInt32::FieldType;
static void vector_vector(const ColumnString::Chars_t & vec_from, const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets, PODArray<ToFieldType> & vec_to)
{
const auto & local_date_lut = DateLUT::instance();
ReadBuffer read_buffer(const_cast<char *>(reinterpret_cast<const char *>(&vec_from[0])), vec_from.size(), 0);
ColumnString::Offset_t prev_offset = 0;
char zero = 0;
for (size_t i = 0; i < vec_to.size(); ++i)
{
DataTypeDateTime::FieldType x = 0;
parseImpl<DataTypeDateTime>(x, read_buffer);
ColumnString::Offset_t cur_offset = offsets[i];
const std::string time_zone(reinterpret_cast<const char *>(&data[prev_offset]), cur_offset - prev_offset - 1);
const auto & remote_date_lut = DateLUT::instance(time_zone);
auto ti = convertTimestamp(x, local_date_lut, remote_date_lut);
vec_to[i] = ti;
readChar(zero, read_buffer);
if (zero != 0)
throw Exception("Cannot parse from string.", ErrorCodes::CANNOT_PARSE_NUMBER);
prev_offset = cur_offset;
}
}
static void vector_constant(const ColumnString::Chars_t & vec_from, const std::string & data,
PODArray<ToFieldType> & vec_to)
{
const auto & local_date_lut = DateLUT::instance();
const auto & remote_date_lut = DateLUT::instance(data);
ReadBuffer read_buffer(const_cast<char *>(reinterpret_cast<const char *>(&vec_from[0])), vec_from.size(), 0);
char zero = 0;
for (size_t i = 0; i < vec_to.size(); ++i)
{
DataTypeDateTime::FieldType x = 0;
parseImpl<DataTypeDateTime>(x, read_buffer);
auto ti = convertTimestamp(x, local_date_lut, remote_date_lut);
vec_to[i] = ti;
readChar(zero, read_buffer);
if (zero != 0)
throw Exception("Cannot parse from string.", ErrorCodes::CANNOT_PARSE_NUMBER);
}
}
static void vector_constant(const ColumnString::Chars_t & vec_from, PODArray<ToFieldType> & vec_to)
{
ReadBuffer read_buffer(const_cast<char *>(reinterpret_cast<const char *>(&vec_from[0])), vec_from.size(), 0);
char zero = 0;
for (size_t i = 0; i < vec_to.size(); ++i)
{
DataTypeDateTime::FieldType x = 0;
parseImpl<DataTypeDateTime>(x, read_buffer);
vec_to[i] = x;
readChar(zero, read_buffer);
if (zero != 0)
throw Exception("Cannot parse from string.", ErrorCodes::CANNOT_PARSE_NUMBER);
}
}
static void constant_vector(const std::string & from, const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets, PODArray<ToFieldType> & vec_to)
{
const auto & local_date_lut = DateLUT::instance();
ReadBufferFromString read_buffer(from);
DataTypeDateTime::FieldType x = 0;
parseImpl<DataTypeDateTime>(x, read_buffer);
ColumnString::Offset_t prev_offset = 0;
for (size_t i = 0; i < offsets.size(); ++i)
{
ColumnString::Offset_t cur_offset = offsets[i];
const std::string time_zone(reinterpret_cast<const char *>(&data[prev_offset]), cur_offset - prev_offset - 1);
const auto & remote_date_lut = DateLUT::instance(time_zone);
auto ti = convertTimestamp(x, local_date_lut, remote_date_lut);
vec_to[i] = ti;
prev_offset = cur_offset;
}
}
static void constant_constant(const std::string & from, const std::string & data, ToFieldType & to)
{
const auto & local_date_lut = DateLUT::instance();
const auto & remote_date_lut = DateLUT::instance(data);
ReadBufferFromString read_buffer(from);
DataTypeDateTime::FieldType x = 0;
parseImpl<DataTypeDateTime>(x, read_buffer);
to = convertTimestamp(x, local_date_lut, remote_date_lut);
}
static void constant_constant(const std::string & from, ToFieldType & to)
{
ReadBufferFromString read_buffer(from);
DataTypeDateTime::FieldType x = 0;
parseImpl<DataTypeDateTime>(x, read_buffer);
to = x;
}
};
}}
struct NameToUnixTimestamp { static constexpr auto name = "toUnixTimestamp"; };
template<>
struct ConvertImpl<DataTypeString, DataTypeInt32, NameToUnixTimestamp>
{
using Op = details::StringToTimestampConverter;
using ToFieldType = Op::ToFieldType;
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
const ColumnPtr source_col = block.getByPosition(arguments[0]).column;
const auto * sources = typeid_cast<const ColumnString *>(&*source_col);
const auto * const_source = typeid_cast<const ColumnConstString *>(&*source_col);
if (arguments.size() == 1)
{
if (sources)
{
auto * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
auto & vec_from = sources->getChars();
auto & vec_to = col_to->getData();
size_t size = sources->size();
vec_to.resize(size);
Op::vector_constant(vec_from, vec_to);
}
else if (const_source)
{
ToFieldType res;
Op::constant_constant(const_source->getData(), res);
block.getByPosition(result).column = new ColumnConst<ToFieldType>(const_source->size(), res);
}
else
{
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + NameToUnixTimestamp::name,
ErrorCodes::ILLEGAL_COLUMN);
}
}
else if (arguments.size() == 2)
{
const ColumnPtr time_zone_col = block.getByPosition(arguments[1]).column;
const auto * time_zones = typeid_cast<const ColumnString *>(&*time_zone_col);
const auto * const_time_zone = typeid_cast<const ColumnConstString *>(&*time_zone_col);
if (sources)
{
auto * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
auto & vec_from = sources->getChars();
auto & vec_to = col_to->getData();
size_t size = sources->size();
vec_to.resize(size);
if (time_zones)
Op::vector_vector(vec_from, time_zones->getChars(), time_zones->getOffsets(), vec_to);
else if (const_time_zone)
Op::vector_constant(vec_from, const_time_zone->getData(), vec_to);
else
throw Exception("Illegal column " + block.getByPosition(arguments[1]).column->getName()
+ " of second argument of function " + NameToUnixTimestamp::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else if (const_source)
{
if (time_zones)
{
auto * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
auto & vec_to = col_to->getData();
vec_to.resize(time_zones->getOffsets().size());
Op::constant_vector(const_source->getData(), time_zones->getChars(), time_zones->getOffsets(), vec_to);
}
else if (const_time_zone)
{
ToFieldType res;
Op::constant_constant(const_source->getData(), const_time_zone->getData(), res);
block.getByPosition(result).column = new ColumnConst<ToFieldType>(const_source->size(), res);
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[1]).column->getName()
+ " of second argument of function " + NameToUnixTimestamp::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + NameToUnixTimestamp::name,
ErrorCodes::ILLEGAL_COLUMN);
}
else
throw Exception("Internal error.", ErrorCodes::LOGICAL_ERROR);
}
};
/** Если типы совпадают - просто скопируем ссылку на столбец.
*/
template <typename Name>
struct ConvertImpl<DataTypeString, DataTypeString, Name>
{
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
block.getByPosition(result).column = block.getByPosition(arguments[0]).column;
}
};
/** Преобразование из FixedString.
*/
template <typename ToDataType, typename Name>
struct ConvertImpl<DataTypeFixedString, ToDataType, Name>
{
typedef typename ToDataType::FieldType ToFieldType;
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
if (const ColumnFixedString * col_from = typeid_cast<const ColumnFixedString *>(&*block.getByPosition(arguments[0]).column))
{
ColumnVector<ToFieldType> * col_to = new ColumnVector<ToFieldType>;
block.getByPosition(result).column = col_to;
const ColumnFixedString::Chars_t & data_from = col_from->getChars();
size_t n = col_from->getN();
typename ColumnVector<ToFieldType>::Container_t & vec_to = col_to->getData();
size_t size = col_from->size();
vec_to.resize(size);
for (size_t i = 0; i < size; ++i)
{
char * begin = const_cast<char *>(reinterpret_cast<const char *>(&data_from[i * n]));
char * end = begin + n;
ReadBuffer read_buffer(begin, n, 0);
parseImpl<ToDataType>(vec_to[i], read_buffer);
if (!read_buffer.eof())
{
while (read_buffer.position() < end && *read_buffer.position() == 0)
++read_buffer.position();
if (read_buffer.position() < end)
throw Exception("Cannot parse from fixed string.", ErrorCodes::CANNOT_PARSE_NUMBER);
}
}
}
else if (typeid_cast<const ColumnConstString *>(&*block.getByPosition(arguments[0]).column))
{
ConvertImpl<DataTypeString, ToDataType, Name>::execute(block, arguments, result);
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
};
/** Преобразование из FixedString в String.
* При этом, вырезаются последовательности нулевых байт с конца строк.
*/
template <typename Name>
struct ConvertImpl<DataTypeFixedString, DataTypeString, Name>
{
static void execute(Block & block, const ColumnNumbers & arguments, size_t result)
{
if (const ColumnFixedString * col_from = typeid_cast<const ColumnFixedString *>(&*block.getByPosition(arguments[0]).column))
{
ColumnString * col_to = new ColumnString;
block.getByPosition(result).column = col_to;
const ColumnFixedString::Chars_t & data_from = col_from->getChars();
ColumnString::Chars_t & data_to = col_to->getChars();
ColumnString::Offsets_t & offsets_to = col_to->getOffsets();
size_t size = col_from->size();
size_t n = col_from->getN();
data_to.resize(size * (n + 1)); /// + 1 - нулевой байт
offsets_to.resize(size);
size_t offset_from = 0;
size_t offset_to = 0;
for (size_t i = 0; i < size; ++i)
{
size_t bytes_to_copy = n;
while (bytes_to_copy > 0 && data_from[offset_from + bytes_to_copy - 1] == 0)
--bytes_to_copy;
memcpy(&data_to[offset_to], &data_from[offset_from], bytes_to_copy);
offset_from += n;
offset_to += bytes_to_copy;
data_to[offset_to] = 0;
++offset_to;
offsets_to[i] = offset_to;
}
data_to.resize(offset_to);
}
else if (const ColumnConstString * col_from = typeid_cast<const ColumnConstString *>(&*block.getByPosition(arguments[0]).column))
{
const String & s = col_from->getData();
size_t bytes_to_copy = s.size();
while (bytes_to_copy > 0 && s[bytes_to_copy - 1] == 0)
--bytes_to_copy;
block.getByPosition(result).column = new ColumnConstString(col_from->size(), s.substr(0, bytes_to_copy));
}
else
throw Exception("Illegal column " + block.getByPosition(arguments[0]).column->getName()
+ " of first argument of function " + Name::name,
ErrorCodes::ILLEGAL_COLUMN);
}
};
/// Предварительное объявление.
struct NameToDate { static constexpr auto name = "toDate"; };
template <typename ToDataType, typename Name, typename MonotonicityImpl>
class FunctionConvert : public IFunction
{
public:
using Monotonic = MonotonicityImpl;
static constexpr auto name = Name::name;
static IFunction * create(const Context & context) { return new FunctionConvert; }
/// Получить имя функции.
String getName() const override
{
return name;
}
/// Получить тип результата по типам аргументов. Если функция неприменима для данных аргументов - кинуть исключение.
DataTypePtr getReturnType(const DataTypes & arguments) const override
{
return getReturnTypeImpl(arguments);
}
/// Выполнить функцию над блоком.
void execute(Block & block, const ColumnNumbers & arguments, size_t result) override
{
IDataType * from_type = &*block.getByPosition(arguments[0]).type;
if (typeid_cast<const DataTypeUInt8 * >(from_type)) ConvertImpl<DataTypeUInt8, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeUInt16 * >(from_type)) ConvertImpl<DataTypeUInt16, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeUInt32 * >(from_type)) ConvertImpl<DataTypeUInt32, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeUInt64 * >(from_type)) ConvertImpl<DataTypeUInt64, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeInt8 * >(from_type)) ConvertImpl<DataTypeInt8, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeInt16 * >(from_type)) ConvertImpl<DataTypeInt16, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeInt32 * >(from_type)) ConvertImpl<DataTypeInt32, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeInt64 * >(from_type)) ConvertImpl<DataTypeInt64, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeFloat32 * >(from_type)) ConvertImpl<DataTypeFloat32, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeFloat64 * >(from_type)) ConvertImpl<DataTypeFloat64, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeDate * >(from_type)) ConvertImpl<DataTypeDate, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeDateTime * >(from_type)) ConvertImpl<DataTypeDateTime, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeString * >(from_type)) ConvertImpl<DataTypeString, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeFixedString *>(from_type)) ConvertImpl<DataTypeFixedString, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeEnum8 *>(from_type)) ConvertImpl<DataTypeEnum8, ToDataType, Name>::execute(block, arguments, result);
else if (typeid_cast<const DataTypeEnum16 *>(from_type)) ConvertImpl<DataTypeEnum16, ToDataType, Name>::execute(block, arguments, result);
else
throw Exception("Illegal type " + block.getByPosition(arguments[0]).type->getName() + " of argument of function " + getName(),
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
}
bool hasInformationAboutMonotonicity() const override
{
return Monotonic::has();
}
Monotonicity getMonotonicityForRange(const IDataType & type, const Field & left, const Field & right) const override
{
return Monotonic::get(type, left, right);
}
private:
template<typename ToDataType2 = ToDataType, typename Name2 = Name>
DataTypePtr getReturnTypeImpl(const DataTypes & arguments,
typename std::enable_if<!(std::is_same<ToDataType2, DataTypeString>::value ||
std::is_same<Name2, NameToUnixTimestamp>::value ||
std::is_same<Name2, NameToDate>::value)>::type * = nullptr) const
{
if (arguments.size() != 1)
throw Exception("Number of arguments for function " + getName() + " doesn't match: passed "
+ toString(arguments.size()) + ", should be 1.",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH);
return new ToDataType;
}
template<typename ToDataType2 = ToDataType, typename Name2 = Name>
DataTypePtr getReturnTypeImpl(const DataTypes & arguments,
typename std::enable_if<std::is_same<ToDataType2, DataTypeString>::value>::type * = nullptr) const
{
if ((arguments.size() < 1) || (arguments.size() > 2))
throw Exception("Number of arguments for function " + getName() + " doesn't match: passed "
+ toString(arguments.size()) + ", should be 1 or 2.",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH);
if (typeid_cast<const DataTypeDateTime *>(&*arguments[0]) == nullptr)
{
if (arguments.size() != 1)
throw Exception("Number of arguments for function " + getName() + " doesn't match: passed "
+ toString(arguments.size()) + ", should be 1.",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH);
}
else if ((arguments.size() == 2) && (typeid_cast<const DataTypeString *>(&*arguments[1]) == nullptr))
{
throw Exception{
"Illegal type " + arguments[1]->getName() + " of argument of function " + getName(),
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT
};
}
return new ToDataType2;
}
template<typename ToDataType2 = ToDataType, typename Name2 = Name>
DataTypePtr getReturnTypeImpl(const DataTypes & arguments,
typename std::enable_if<std::is_same<Name2, NameToUnixTimestamp>::value, void>::type * = nullptr) const
{
if ((arguments.size() < 1) || (arguments.size() > 2))
throw Exception("Number of arguments for function " + getName() + " doesn't match: passed "
+ toString(arguments.size()) + ", should be 1 or 2.",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH);
if (typeid_cast<const DataTypeString *>(&*arguments[0]) == nullptr)
{
if (arguments.size() != 1)
throw Exception("Number of arguments for function " + getName() + " doesn't match: passed "
+ toString(arguments.size()) + ", should be 1.",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH);
}
else if ((arguments.size() == 2) && (typeid_cast<const DataTypeString *>(&*arguments[1]) == nullptr))
{
throw Exception{
"Illegal type " + arguments[1]->getName() + " of argument of function " + getName(),
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT
};
}
return new ToDataType2;
}
template<typename ToDataType2 = ToDataType, typename Name2 = Name>
DataTypePtr getReturnTypeImpl(const DataTypes & arguments,
typename std::enable_if<std::is_same<Name2, NameToDate>::value>::type * = nullptr) const
{
if ((arguments.size() < 1) || (arguments.size() > 2))
throw Exception("Number of arguments for function " + getName() + " doesn't match: passed "
+ toString(arguments.size()) + ", should be 1 or 2.",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH);
if ((arguments.size() == 2) && (typeid_cast<const DataTypeString *>(&*arguments[1]) == nullptr))
{
throw Exception{
"Illegal type " + arguments[1]->getName() + " of 2nd argument of function " + getName(),
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT
};
}
return new ToDataType2;
}
};
/** Преобразование в строку фиксированной длины реализовано только из строк.
*/
class FunctionToFixedString : public IFunction
{
public:
static constexpr auto name = "toFixedString";
static IFunction * create(const Context & context) { return new FunctionToFixedString; };
/// Получить имя функции.
String getName() const override
{
return name;
}
/** Получить тип результата по типам аргументов и значениям константных аргументов.
* Если функция неприменима для данных аргументов - кинуть исключение.
* Для неконстантных столбцов arguments[i].column = nullptr.
*/
void getReturnTypeAndPrerequisites(const ColumnsWithTypeAndName & arguments,
DataTypePtr & out_return_type,
std::vector<ExpressionAction> & out_prerequisites) override
{
if (arguments.size() != 2)
throw Exception("Number of arguments for function " + getName() + " doesn't match: passed "
+ toString(arguments.size()) + ", should be 2.",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH);
if (!arguments[1].column)
throw Exception("Second argument for function " + getName() + " must be constant", ErrorCodes::ILLEGAL_COLUMN);
if (!typeid_cast<const DataTypeString *>(arguments[0].type.get()) &&
!typeid_cast<const DataTypeFixedString *>(arguments[0].type.get()))
throw Exception(getName() + " is only implemented for types String and FixedString", ErrorCodes::NOT_IMPLEMENTED);
const size_t n = getSize(arguments[1]);
out_return_type = new DataTypeFixedString(n);
}
/// Выполнить функцию над блоком.
void execute(Block & block, const ColumnNumbers & arguments, const size_t result) override
{
const auto n = getSize(block.getByPosition(arguments[1]));
return execute(block, arguments, result, n);
}
static void execute(Block & block, const ColumnNumbers & arguments, const size_t result, const size_t n)
{
const auto & column = block.getByPosition(arguments[0]).column;
if (const auto column_const = typeid_cast<const ColumnConstString *>(&*column))
{
if (column_const->getData().size() > n)
throw Exception("String too long for type FixedString(" + toString(n) + ")",
ErrorCodes::TOO_LARGE_STRING_SIZE);
auto resized_string = column_const->getData();
resized_string.resize(n);
block.getByPosition(result).column = new ColumnConst<String>{
column_const->size(), std::move(resized_string), new DataTypeFixedString(n)
};
}
else if (const auto column_string = typeid_cast<const ColumnString *>(&*column))
{
const auto column_fixed = new ColumnFixedString(n);
ColumnPtr result_ptr = column_fixed;
auto & out_chars = column_fixed->getChars();
const auto & in_chars = column_string->getChars();
const auto & in_offsets = column_string->getOffsets();
out_chars.resize_fill(in_offsets.size() * n);
for (size_t i = 0; i < in_offsets.size(); ++i)
{
const size_t off = i ? in_offsets[i - 1] : 0;
const size_t len = in_offsets[i] - off - 1;
if (len > n)
throw Exception("String too long for type FixedString(" + toString(n) + ")",
ErrorCodes::TOO_LARGE_STRING_SIZE);
memcpy(&out_chars[i * n], &in_chars[off], len);
}
block.getByPosition(result).column = result_ptr;
}
else if (const auto column_fixed_string = typeid_cast<const ColumnFixedString *>(column.get()))
{
const auto src_n = column_fixed_string->getN();
if (src_n > n)
throw Exception{
"String too long for type FixedString(" + toString(n) + ")",
ErrorCodes::TOO_LARGE_STRING_SIZE
};
const auto column_fixed = new ColumnFixedString{n};
block.getByPosition(result).column = column_fixed;
auto & out_chars = column_fixed->getChars();
const auto & in_chars = column_fixed_string->getChars();
const auto size = column_fixed_string->size();
out_chars.resize_fill(size * n);
for (const auto i : ext::range(0, size))
memcpy(&out_chars[i * n], &in_chars[i * src_n], src_n);
}
else
throw Exception("Unexpected column: " + column->getName(), ErrorCodes::ILLEGAL_COLUMN);
}
private:
template <typename T>
bool getSizeTyped(const ColumnWithTypeAndName & column, size_t & out_size)
{
if (!typeid_cast<const typename DataTypeFromFieldType<T>::Type *>(&*column.type))
return false;
const ColumnConst<T> * column_const = typeid_cast<const ColumnConst<T> *>(&*column.column);
if (!column_const)
throw Exception("Unexpected type of column for FixedString length: " + column.column->getName(), ErrorCodes::ILLEGAL_COLUMN);
T s = column_const->getData();
if (s <= 0)
throw Exception("FixedString length must be positive (unlike " + toString(s) + ")", ErrorCodes::ILLEGAL_COLUMN);
out_size = static_cast<size_t>(s);
return true;
}
size_t getSize(const ColumnWithTypeAndName & column)
{
size_t res;
if (getSizeTyped<UInt8>(column, res) ||
getSizeTyped<UInt16>(column, res) ||
getSizeTyped<UInt32>(column, res) ||
getSizeTyped<UInt64>(column, res) ||
getSizeTyped< Int8 >(column, res) ||
getSizeTyped< Int16>(column, res) ||
getSizeTyped< Int32>(column, res) ||
getSizeTyped< Int64>(column, res))
return res;
throw Exception("Length of FixedString must be integer; got " + column.type->getName(), ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
}
};
/// Монотонность.
struct PositiveMonotonicity
{
static bool has() { return true; }
static IFunction::Monotonicity get(const IDataType & type, const Field & left, const Field & right)
{
return { true };
}
};
template <typename T>
struct ToIntMonotonicity
{
static bool has() { return true; }
template <typename T2 = T>
static UInt64 divideByRangeOfType(typename std::enable_if_t<sizeof(T2) != sizeof(UInt64), UInt64> x) { return x >> (sizeof(T) * 8); };
template <typename T2 = T>
static UInt64 divideByRangeOfType(typename std::enable_if_t<sizeof(T2) == sizeof(UInt64), UInt64> x) { return 0; };
static IFunction::Monotonicity get(const IDataType & type, const Field & left, const Field & right)
{
size_t size_of_type = type.getSizeOfField();
/// Если тип расширяется, то функция монотонна.
if (sizeof(T) > size_of_type)
return { true };
/// Если тип совпадает - тоже. (Enum обрабатываем отдельно, так как он имеет другой тип)
if (typeid_cast<const typename DataTypeFromFieldType<T>::Type *>(&type) ||
typeid_cast<const DataTypeEnum<T> *>(&type))
return { true };
/// В других случаях, для неограниченного диапазона не знаем, будет ли функция монотонной.
if (left.isNull() || right.isNull())
return {};
/// Если преобразуем из float, то аргументы должны помещаться в тип результата.
if (typeid_cast<const DataTypeFloat32 *>(&type)
|| typeid_cast<const DataTypeFloat64 *>(&type))
{
Float64 left_float = left.get<Float64>();
Float64 right_float = right.get<Float64>();
if (left_float >= std::numeric_limits<T>::min() && left_float <= std::numeric_limits<T>::max()
&& right_float >= std::numeric_limits<T>::min() && right_float <= std::numeric_limits<T>::max())
return { true };
return {};
}
/// Если меняем знаковость типа или преобразуем из даты, даты-времени, то аргумент должен быть из одной половинки.
/// На всякий случай, в остальных случаях тоже будем этого требовать.
if ((left.get<Int64>() >= 0) != (right.get<Int64>() >= 0))
return {};
/// Если уменьшаем тип, то все биты кроме тех, которые в него помещаются, должны совпадать.
if (divideByRangeOfType(left.get<UInt64>()) != divideByRangeOfType(right.get<UInt64>()))
return {};
return { true };
}
};
/** Монотонность для функции toString определяем, в основном, для тестовых целей.
* Всерьёз вряд ли кто-нибудь рассчитывает на оптимизацию запросов с условиями toString(CounterID) = 34.
*/
struct ToStringMonotonicity
{
static bool has() { return true; }
static IFunction::Monotonicity get(const IDataType & type, const Field & left, const Field & right)
{
IFunction::Monotonicity positive = { .is_monotonic = true, .is_positive = true };
IFunction::Monotonicity not_monotonic;
/// Функция toString монотонна, если аргумент - Date или DateTime, или неотрицательные числа с одинаковым количеством знаков.
if (typeid_cast<const DataTypeDate *>(&type)
|| typeid_cast<const DataTypeDateTime *>(&type))
return positive;
if (left.isNull() || right.isNull())
return {};
if (left.getType() == Field::Types::UInt64
&& right.getType() == Field::Types::UInt64)
{
return (left.get<Int64>() == 0 && right.get<Int64>() == 0)
|| (floor(log10(left.get<UInt64>())) == floor(log10(right.get<UInt64>())))
? positive : not_monotonic;
}
if (left.getType() == Field::Types::Int64
&& right.getType() == Field::Types::Int64)
{
return (left.get<Int64>() == 0 && right.get<Int64>() == 0)
|| (left.get<Int64>() > 0 && right.get<Int64>() > 0 && floor(log10(left.get<Int64>())) == floor(log10(right.get<Int64>())))
? positive : not_monotonic;
}
return not_monotonic;
}
};
struct NameToUInt8 { static constexpr auto name = "toUInt8"; };
struct NameToUInt16 { static constexpr auto name = "toUInt16"; };
struct NameToUInt32 { static constexpr auto name = "toUInt32"; };
struct NameToUInt64 { static constexpr auto name = "toUInt64"; };
struct NameToInt8 { static constexpr auto name = "toInt8"; };
struct NameToInt16 { static constexpr auto name = "toInt16"; };
struct NameToInt32 { static constexpr auto name = "toInt32"; };
struct NameToInt64 { static constexpr auto name = "toInt64"; };
struct NameToFloat32 { static constexpr auto name = "toFloat32"; };
struct NameToFloat64 { static constexpr auto name = "toFloat64"; };
struct NameToDateTime { static constexpr auto name = "toDateTime"; };
struct NameToString { static constexpr auto name = "toString"; };
typedef FunctionConvert<DataTypeUInt8, NameToUInt8, ToIntMonotonicity<UInt8>> FunctionToUInt8;
typedef FunctionConvert<DataTypeUInt16, NameToUInt16, ToIntMonotonicity<UInt16>> FunctionToUInt16;
typedef FunctionConvert<DataTypeUInt32, NameToUInt32, ToIntMonotonicity<UInt32>> FunctionToUInt32;
typedef FunctionConvert<DataTypeUInt64, NameToUInt64, ToIntMonotonicity<UInt64>> FunctionToUInt64;
typedef FunctionConvert<DataTypeInt8, NameToInt8, ToIntMonotonicity<Int8>> FunctionToInt8;
typedef FunctionConvert<DataTypeInt16, NameToInt16, ToIntMonotonicity<Int16>> FunctionToInt16;
typedef FunctionConvert<DataTypeInt32, NameToInt32, ToIntMonotonicity<Int32>> FunctionToInt32;
typedef FunctionConvert<DataTypeInt64, NameToInt64, ToIntMonotonicity<Int64>> FunctionToInt64;
typedef FunctionConvert<DataTypeFloat32, NameToFloat32, PositiveMonotonicity> FunctionToFloat32;
typedef FunctionConvert<DataTypeFloat64, NameToFloat64, PositiveMonotonicity> FunctionToFloat64;
typedef FunctionConvert<DataTypeDate, NameToDate, ToIntMonotonicity<UInt16>> FunctionToDate;
typedef FunctionConvert<DataTypeDateTime, NameToDateTime, ToIntMonotonicity<UInt32>> FunctionToDateTime;
typedef FunctionConvert<DataTypeString, NameToString, ToStringMonotonicity> FunctionToString;
typedef FunctionConvert<DataTypeInt32, NameToUnixTimestamp, ToIntMonotonicity<UInt32>> FunctionToUnixTimestamp;
template <typename DataType> struct FunctionTo;
template <> struct FunctionTo<DataTypeUInt8> { using Type = FunctionToUInt8; };
template <> struct FunctionTo<DataTypeUInt16> { using Type = FunctionToUInt16; };
template <> struct FunctionTo<DataTypeUInt32> { using Type = FunctionToUInt32; };
template <> struct FunctionTo<DataTypeUInt64> { using Type = FunctionToUInt64; };
template <> struct FunctionTo<DataTypeInt8> { using Type = FunctionToInt8; };
template <> struct FunctionTo<DataTypeInt16> { using Type = FunctionToInt16; };
template <> struct FunctionTo<DataTypeInt32> { using Type = FunctionToInt32; };
template <> struct FunctionTo<DataTypeInt64> { using Type = FunctionToInt64; };
template <> struct FunctionTo<DataTypeFloat32> { using Type = FunctionToFloat32; };
template <> struct FunctionTo<DataTypeFloat64> { using Type = FunctionToFloat64; };
template <> struct FunctionTo<DataTypeDate> { using Type = FunctionToDate; };
template <> struct FunctionTo<DataTypeDateTime> { using Type = FunctionToDateTime; };
template <> struct FunctionTo<DataTypeString> { using Type = FunctionToString; };
template <> struct FunctionTo<DataTypeFixedString> { using Type = FunctionToFixedString; };
template <typename FieldType> struct FunctionTo<DataTypeEnum<FieldType>>
: FunctionTo<typename DataTypeFromFieldType<FieldType>::Type>
{
};
class FunctionCast final : public IFunction
{
using WrapperType = std::function<void(Block &, const ColumnNumbers &, size_t)>;
const Context & context;
WrapperType wrapper_function;
std::function<Monotonicity(const IDataType &, const Field &, const Field &)> monotonicity_for_range;
FunctionCast(const Context & context) : context(context) {}
template <typename DataType> auto createWrapper(const DataTypePtr & from_type, const DataType * const)
{
using FunctionType = typename FunctionTo<DataType>::Type;
std::shared_ptr<FunctionType> function{static_cast<FunctionType *>(FunctionType::create(context))};
/// Check conversion using underlying function
(void) function->getReturnType({ from_type });
return [function] (Block & block, const ColumnNumbers & arguments, const size_t result) {
function->execute(block, arguments, result);
};
}
static auto createFixedStringWrapper(const DataTypePtr & from_type, const size_t N)
{
if (!typeid_cast<const DataTypeString *>(from_type.get()) &&
!typeid_cast<const DataTypeFixedString *>(from_type.get()))
throw Exception{
"CAST AS FixedString is only implemented for types String and FixedString",
ErrorCodes::NOT_IMPLEMENTED
};
return [N] (Block & block, const ColumnNumbers & arguments, const size_t result)
{
FunctionToFixedString::execute(block, arguments, result, N);
};
}
auto createArrayWrapper(const DataTypePtr & from_type_untyped, const DataTypeArray * to_type)
{
DataTypePtr from_nested_type, to_nested_type;
auto from_type = typeid_cast<const DataTypeArray *>(from_type_untyped.get());
/// get the most nested type
while (from_type && to_type)
{
from_nested_type = from_type->getNestedType();
to_nested_type = to_type->getNestedType();
from_type = typeid_cast<const DataTypeArray *>(from_nested_type.get());
to_type = typeid_cast<const DataTypeArray *>(to_nested_type.get());
}
/// both from_type and to_type should be nullptr now is array types had same dimensions
if (from_type || to_type)
throw Exception{
"CAST AS Array can only be performed between same-dimensional array types",
ErrorCodes::TYPE_MISMATCH
};
/// Prepare nested type conversion
const auto nested_function = prepare(from_nested_type, to_nested_type.get());
return [nested_function, from_nested_type, to_nested_type] (
Block & block, const ColumnNumbers & arguments, const size_t result)
{
auto array_arg = block.getByPosition(arguments.front());
/// @todo add const variant which retains array constness
if (const auto col_const_array = typeid_cast<const ColumnConstArray *>(array_arg.column.get()))
array_arg.column = col_const_array->convertToFullColumn();
if (auto col_array = typeid_cast<const ColumnArray *>(array_arg.column.get()))
{
auto res = new ColumnArray{nullptr, col_array->getOffsetsColumn()};
block.getByPosition(result).column = res;
/// get the most nested column
while (const auto nested_col_array = typeid_cast<const ColumnArray *>(col_array->getDataPtr().get()))
{
/// create new level of array, copy offsets
res->getDataPtr() = new ColumnArray{nullptr, nested_col_array->getOffsetsColumn()};
res = static_cast<ColumnArray *>(res->getDataPtr().get());
col_array = nested_col_array;
}
/// create block for converting nested column containing original and result columns
Block nested_block{
{ col_array->getDataPtr(), from_nested_type, "" },
{ nullptr, to_nested_type, "" }
};
const auto nested_result = 1;
/// convert nested column
nested_function(nested_block, {0 }, nested_result);
/// set converted nested column to result
res->getDataPtr() = nested_block.getByPosition(nested_result).column;
}
else
throw Exception{
"Illegal column " + array_arg.column->getName() + " for function CAST AS Array",
ErrorCodes::LOGICAL_ERROR
};
};
}
auto createTupleWrapper(const DataTypePtr & from_type_untyped, const DataTypeTuple * to_type)
{
const auto from_type = typeid_cast<const DataTypeTuple *>(from_type_untyped.get());
if (!from_type)
throw Exception{
"CAST AS Tuple can only be performed between tuple types.\nLeft type: " + from_type_untyped->getName() +
", right type: " + to_type->getName(),
ErrorCodes::TYPE_MISMATCH
};
if (from_type->getElements().size() != to_type->getElements().size())
throw Exception{
"CAST AS Tuple can only be performed between tuple types with the same number of elements.\n"
"Left type: " + from_type->getName() + ", right type: " + to_type->getName(),
ErrorCodes::TYPE_MISMATCH
};
const auto & from_element_types = from_type->getElements();
const auto & to_element_types = to_type->getElements();
std::vector<WrapperType> element_wrappers;
element_wrappers.reserve(from_element_types.size());
/// Create conversion wrapper for each element in tuple
for (const auto & idx_type : ext::enumerate(from_type->getElements()))
element_wrappers.push_back(prepare(idx_type.second, to_element_types[idx_type.first].get()));
std::shared_ptr<FunctionTuple> function_tuple{static_cast<FunctionTuple *>(FunctionTuple::create(context))};
return [element_wrappers, function_tuple, from_element_types, to_element_types]
(Block & block, const ColumnNumbers & arguments, const size_t result)
{
const auto col = block.getByPosition(arguments.front()).column.get();
/// copy tuple elements to a separate block
Block element_block;
/// @todo retain constness
if (const auto column_tuple = typeid_cast<const ColumnTuple *>(col))
element_block = column_tuple->getData();
else if (const auto column_const_tuple = typeid_cast<const ColumnConstTuple *>(col))
element_block = static_cast<const ColumnTuple &>(*column_const_tuple->convertToFullColumn()).getData();
/// create columns for converted elements
for (const auto & to_element_type : to_element_types)
element_block.insert({ nullptr, to_element_type, "" });
/// store position for converted tuple
const auto converted_tuple_pos = element_block.columns();
/// insert column for converted tuple
element_block.insert({ nullptr, new DataTypeTuple{to_element_types}, "" });
const auto converted_element_offset = from_element_types.size();
/// invoke conversion for each element
for (const auto & idx_element_wrapper : ext::enumerate(element_wrappers))
idx_element_wrapper.second(element_block, { idx_element_wrapper.first },
converted_element_offset + idx_element_wrapper.first);
/// form tuple from converted elements using FunctionTuple
function_tuple->execute(element_block,
ext::collection_cast<ColumnNumbers>(ext::range(converted_element_offset, 2 * converted_element_offset)),
converted_tuple_pos);
/// copy FunctionTuple's result from element_block to resulting block
block.getByPosition(result).column = element_block.getByPosition(converted_tuple_pos).column;
};
}
template <typename FieldType>
WrapperType createEnumWrapper(const DataTypePtr & from_type, const DataTypeEnum<FieldType> * to_type)
{
using EnumType = DataTypeEnum<FieldType>;
using Function = typename FunctionTo<EnumType>::Type;
if (const auto from_enum8 = typeid_cast<const DataTypeEnum8 *>(from_type.get()))
checkEnumToEnumConversion(from_enum8, to_type);
else if (const auto from_enum16 = typeid_cast<const DataTypeEnum16 *>(from_type.get()))
checkEnumToEnumConversion(from_enum16, to_type);
if (typeid_cast<const DataTypeString *>(from_type.get()))
return createStringToEnumWrapper<ColumnString, EnumType>();
else if (typeid_cast<const DataTypeFixedString *>(from_type.get()))
return createStringToEnumWrapper<ColumnFixedString, EnumType>();
else if (from_type->behavesAsNumber())
{
std::shared_ptr<Function> function{static_cast<Function *>(Function::create(context))};
/// Check conversion using underlying function
(void) function->getReturnType({ from_type });
return [function] (Block & block, const ColumnNumbers & arguments, const size_t result) {
function->execute(block, arguments, result);
};
}
else
throw Exception{
"Conversion from " + from_type->getName() + " to " + to_type->getName() +
" is not supported",
ErrorCodes::CANNOT_CONVERT_TYPE
};
}
template <typename EnumTypeFrom, typename EnumTypeTo>
void checkEnumToEnumConversion(const EnumTypeFrom * const from_type, const EnumTypeTo * const to_type)
{
const auto & from_values = from_type->getValues();
const auto & to_values = to_type->getValues();
using ValueType = std::common_type_t<typename EnumTypeFrom::FieldType, typename EnumTypeTo::FieldType>;
using NameValuePair = std::pair<std::string, ValueType>;
using EnumValues = std::vector<NameValuePair>;
EnumValues name_intersection;
std::set_intersection(std::begin(from_values), std::end(from_values),
std::begin(to_values), std::end(to_values), std::back_inserter(name_intersection),
[] (auto && from, auto && to) { return from.first < to.first; });
for (const auto & name_value : name_intersection)
{
const auto & old_value = name_value.second;
const auto & new_value = to_type->getValue(name_value.first);
if (old_value != new_value)
throw Exception{
"Enum conversion changes value for element '" + name_value.first +
"' from " + toString(old_value) + " to " + toString(new_value),
ErrorCodes::CANNOT_CONVERT_TYPE
};
}
};
template <typename ColumnStringType, typename EnumType>
auto createStringToEnumWrapper()
{
return [] (Block & block, const ColumnNumbers & arguments, const size_t result)
{
const auto first_col = block.getByPosition(arguments.front()).column.get();
auto & col_with_type_and_name = block.getByPosition(result);
auto & result_col = col_with_type_and_name.column;
const auto & result_type = typeid_cast<EnumType &>(*col_with_type_and_name.type);
if (const auto col = typeid_cast<const ColumnStringType *>(first_col))
{
const auto size = col->size();
auto res = result_type.createColumn();
auto & out_data = static_cast<typename EnumType::ColumnType &>(*res).getData();
out_data.resize(size);
for (const auto i : ext::range(0, size))
out_data[i] = result_type.getValue(col->getDataAt(i));
result_col = res;
}
else if (const auto const_col = typeid_cast<const ColumnConstString *>(first_col))
{
result_col = result_type.createConstColumn(const_col->size(),
nearestFieldType(result_type.getValue(const_col->getData())));
}
else
throw Exception{
"Unexpected column " + first_col->getName() + " as first argument of function " +
name,
ErrorCodes::LOGICAL_ERROR
};
};
}
WrapperType prepare(const DataTypePtr & from_type, const IDataType * const to_type)
{
if (const auto to_actual_type = typeid_cast<const DataTypeUInt8 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeUInt16 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeUInt32 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeUInt64 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeInt8 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeInt16 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeInt32 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeInt64 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeFloat32 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeFloat64 *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeDate *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeDateTime *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto to_actual_type = typeid_cast<const DataTypeString *>(to_type))
return createWrapper(from_type, to_actual_type);
else if (const auto type_fixed_string = typeid_cast<const DataTypeFixedString *>(to_type))
return createFixedStringWrapper(from_type, type_fixed_string->getN());
else if (const auto type_array = typeid_cast<const DataTypeArray *>(to_type))
return createArrayWrapper(from_type, type_array);
else if (const auto type_tuple = typeid_cast<const DataTypeTuple *>(to_type))
return createTupleWrapper(from_type, type_tuple);
else if (const auto type_enum = typeid_cast<const DataTypeEnum8 *>(to_type))
return createEnumWrapper(from_type, type_enum);
else if (const auto type_enum = typeid_cast<const DataTypeEnum16 *>(to_type))
return createEnumWrapper(from_type, type_enum);
throw Exception{
"Conversion from " + from_type->getName() + " to " + to_type->getName() +
" is not supported",
ErrorCodes::CANNOT_CONVERT_TYPE
};
}
template <typename DataType> static auto monotonicityForType(const DataType * const)
{
return FunctionTo<DataType>::Type::Monotonic::get;
}
void prepareMonotonicityInformation(const DataTypePtr & from_type, const IDataType * to_type)
{
if (const auto type = typeid_cast<const DataTypeUInt8 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeUInt16 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeUInt32 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeUInt64 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeInt8 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeInt16 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeInt32 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeInt64 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeFloat32 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeFloat64 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeDate *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeDateTime *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeString *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (from_type->isNumeric())
{
if (const auto type = typeid_cast<const DataTypeEnum8 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
else if (const auto type = typeid_cast<const DataTypeEnum16 *>(to_type))
monotonicity_for_range = monotonicityForType(type);
}
/// other types like FixedString, Array and Tuple have no monotonicity defined
}
public:
static constexpr auto name = "CAST";
static IFunction * create(const Context & context) { return new FunctionCast{context}; }
String getName() const override { return name; }
void getReturnTypeAndPrerequisites(
const ColumnsWithTypeAndName & arguments, DataTypePtr & out_return_type,
std::vector<ExpressionAction> & out_prerequisites) override
{
if (arguments.size() != 2)
throw Exception("Number of arguments for function " + getName() + " doesn't match: passed "
+ toString(arguments.size()) + ", should be 2.",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH);
const auto type_col = typeid_cast<const ColumnConstString *>(arguments.back().column.get());
if (!type_col)
throw Exception("Second argument to " + getName() + " must be a constant string describing type",
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
out_return_type = DataTypeFactory::instance().get(type_col->getData());
wrapper_function = prepare(arguments.front().type, out_return_type.get());
prepareMonotonicityInformation(arguments.front().type, out_return_type.get());
}
void execute(Block & block, const ColumnNumbers & arguments, const size_t result) override
{
/// drop second argument, pass others
ColumnNumbers new_arguments{arguments.front()};
if (arguments.size() > 2)
new_arguments.insert(std::end(new_arguments), std::next(std::begin(arguments), 2), std::end(arguments));
wrapper_function(block, new_arguments, result);
}
bool hasInformationAboutMonotonicity() const override
{
return static_cast<bool>(monotonicity_for_range);
}
Monotonicity getMonotonicityForRange(const IDataType & type, const Field & left, const Field & right) const override
{
return monotonicity_for_range(type, left, right);
}
};
}