ClickHouse/src/Functions/FunctionDateOrDateTimeAddInterval.h
2020-10-20 16:11:57 +03:00

494 lines
19 KiB
C++

#pragma once
#include <common/DateLUTImpl.h>
#include <DataTypes/DataTypeDate.h>
#include <DataTypes/DataTypeDateTime.h>
#include <DataTypes/DataTypeDateTime64.h>
#include <Columns/ColumnsNumber.h>
#include <Functions/IFunctionImpl.h>
#include <Functions/FunctionHelpers.h>
#include <Functions/castTypeToEither.h>
#include <Functions/extractTimeZoneFromFunctionArguments.h>
#include <IO/WriteHelpers.h>
namespace DB
{
namespace ErrorCodes
{
extern const int NUMBER_OF_ARGUMENTS_DOESNT_MATCH;
extern const int ILLEGAL_TYPE_OF_ARGUMENT;
extern const int ILLEGAL_COLUMN;
}
/// AddOnDateTime64DefaultImpl provides default implementation of add-X functionality for DateTime64.
///
/// Default implementation is not to change fractional part, but only modify whole part as if it was DateTime.
/// That means large whole values (for scale less than 9) might not fit into UInt32-range,
/// and hence default implementation will produce incorrect results.
template <typename T>
struct AddOnDateTime64DefaultImpl
{
AddOnDateTime64DefaultImpl(UInt32 scale_ = 0)
: scale_multiplier(DecimalUtils::scaleMultiplier<DateTime64::NativeType>(scale_))
{}
// Default implementation for add/sub on DateTime64: do math on whole part (the same way as for DateTime), leave fractional as it is.
inline DateTime64 execute(const DateTime64 & t, Int64 delta, const DateLUTImpl & time_zone) const
{
const auto components = DecimalUtils::splitWithScaleMultiplier(t, scale_multiplier);
const auto whole = static_cast<const T *>(this)->execute(static_cast<UInt32>(components.whole), delta, time_zone);
return DecimalUtils::decimalFromComponentsWithMultiplier<DateTime64>(static_cast<DateTime64::NativeType>(whole), components.fractional, scale_multiplier);
}
UInt32 scale_multiplier = 1;
};
/// Type of first argument of 'execute' function overload defines what INPUT DataType it is used for.
/// Return type defines what is the OUTPUT (return) type of the CH function.
/// Corresponding types:
/// - UInt16 => DataTypeDate
/// - UInt32 => DataTypeDateTime
/// - DateTime64 => DataTypeDateTime64
/// Please note that INPUT and OUTPUT types may differ, e.g.:
/// - 'AddSecondsImpl::execute(UInt32, ...) -> UInt32' is available to the ClickHouse users as 'addSeconds(DateTime, ...) -> DateTime'
/// - 'AddSecondsImpl::execute(UInt16, ...) -> UInt32' is available to the ClickHouse users as 'addSeconds(Date, ...) -> DateTime'
struct AddSecondsImpl : public AddOnDateTime64DefaultImpl<AddSecondsImpl>
{
using Base = AddOnDateTime64DefaultImpl<AddSecondsImpl>;
using Base::Base;
using Base::execute;
static constexpr auto name = "addSeconds";
static inline UInt32 execute(UInt32 t, Int64 delta, const DateLUTImpl &)
{
return t + delta;
}
static inline UInt32 execute(UInt16 d, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.fromDayNum(DayNum(d)) + delta;
}
};
struct AddMinutesImpl : public AddOnDateTime64DefaultImpl<AddMinutesImpl>
{
using Base = AddOnDateTime64DefaultImpl<AddMinutesImpl>;
using Base::Base;
using Base::execute;
static constexpr auto name = "addMinutes";
static inline UInt32 execute(UInt32 t, Int64 delta, const DateLUTImpl &)
{
return t + delta * 60;
}
static inline UInt32 execute(UInt16 d, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.fromDayNum(DayNum(d)) + delta * 60;
}
};
struct AddHoursImpl : public AddOnDateTime64DefaultImpl<AddHoursImpl>
{
using Base = AddOnDateTime64DefaultImpl<AddHoursImpl>;
using Base::Base;
using Base::execute;
static constexpr auto name = "addHours";
static inline UInt32 execute(UInt32 t, Int64 delta, const DateLUTImpl &)
{
return t + delta * 3600;
}
static inline UInt32 execute(UInt16 d, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.fromDayNum(DayNum(d)) + delta * 3600;
}
};
struct AddDaysImpl : public AddOnDateTime64DefaultImpl<AddDaysImpl>
{
using Base = AddOnDateTime64DefaultImpl<AddDaysImpl>;
using Base::Base;
using Base::execute;
static constexpr auto name = "addDays";
// static inline UInt32 execute(UInt64 t, Int64 delta, const DateLUTImpl & time_zone)
// {
// // TODO (nemkov): LUT does not support out-of range date values for now.
// return time_zone.addDays(t, delta);
// }
static inline UInt32 execute(UInt32 t, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.addDays(t, delta);
}
static inline UInt16 execute(UInt16 d, Int64 delta, const DateLUTImpl &)
{
return d + delta;
}
};
struct AddWeeksImpl : public AddOnDateTime64DefaultImpl<AddWeeksImpl>
{
using Base = AddOnDateTime64DefaultImpl<AddWeeksImpl>;
using Base::Base;
using Base::execute;
static constexpr auto name = "addWeeks";
static inline UInt32 execute(UInt32 t, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.addWeeks(t, delta);
}
static inline UInt16 execute(UInt16 d, Int64 delta, const DateLUTImpl &)
{
return d + delta * 7;
}
};
struct AddMonthsImpl : public AddOnDateTime64DefaultImpl<AddMonthsImpl>
{
using Base = AddOnDateTime64DefaultImpl<AddMonthsImpl>;
using Base::Base;
using Base::execute;
static constexpr auto name = "addMonths";
static inline UInt32 execute(UInt32 t, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.addMonths(t, delta);
}
static inline UInt16 execute(UInt16 d, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.addMonths(DayNum(d), delta);
}
};
struct AddQuartersImpl : public AddOnDateTime64DefaultImpl<AddQuartersImpl>
{
using Base = AddOnDateTime64DefaultImpl<AddQuartersImpl>;
using Base::Base;
using Base::execute;
static constexpr auto name = "addQuarters";
static inline UInt32 execute(UInt32 t, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.addQuarters(t, delta);
}
static inline UInt16 execute(UInt16 d, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.addQuarters(DayNum(d), delta);
}
};
struct AddYearsImpl : public AddOnDateTime64DefaultImpl<AddYearsImpl>
{
using Base = AddOnDateTime64DefaultImpl<AddYearsImpl>;
using Base::Base;
using Base::execute;
static constexpr auto name = "addYears";
static inline UInt32 execute(UInt32 t, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.addYears(t, delta);
}
static inline UInt16 execute(UInt16 d, Int64 delta, const DateLUTImpl & time_zone)
{
return time_zone.addYears(DayNum(d), delta);
}
};
template <typename Transform>
struct SubtractIntervalImpl : public Transform
{
using Transform::Transform;
template <typename T>
inline auto execute(T t, Int64 delta, const DateLUTImpl & time_zone) const
{
return Transform::execute(t, -delta, time_zone);
}
};
struct SubtractSecondsImpl : SubtractIntervalImpl<AddSecondsImpl> { static constexpr auto name = "subtractSeconds"; };
struct SubtractMinutesImpl : SubtractIntervalImpl<AddMinutesImpl> { static constexpr auto name = "subtractMinutes"; };
struct SubtractHoursImpl : SubtractIntervalImpl<AddHoursImpl> { static constexpr auto name = "subtractHours"; };
struct SubtractDaysImpl : SubtractIntervalImpl<AddDaysImpl> { static constexpr auto name = "subtractDays"; };
struct SubtractWeeksImpl : SubtractIntervalImpl<AddWeeksImpl> { static constexpr auto name = "subtractWeeks"; };
struct SubtractMonthsImpl : SubtractIntervalImpl<AddMonthsImpl> { static constexpr auto name = "subtractMonths"; };
struct SubtractQuartersImpl : SubtractIntervalImpl<AddQuartersImpl> { static constexpr auto name = "subtractQuarters"; };
struct SubtractYearsImpl : SubtractIntervalImpl<AddYearsImpl> { static constexpr auto name = "subtractYears"; };
template <typename Transform>
struct Adder
{
const Transform transform;
explicit Adder(Transform transform_)
: transform(std::move(transform_))
{}
template <typename FromVectorType, typename ToVectorType>
void NO_INLINE vectorConstant(const FromVectorType & vec_from, ToVectorType & vec_to, Int64 delta, const DateLUTImpl & time_zone) const
{
size_t size = vec_from.size();
vec_to.resize(size);
for (size_t i = 0; i < size; ++i)
vec_to[i] = transform.execute(vec_from[i], delta, time_zone);
}
template <typename FromVectorType, typename ToVectorType>
void vectorVector(const FromVectorType & vec_from, ToVectorType & vec_to, const IColumn & delta, const DateLUTImpl & time_zone) const
{
size_t size = vec_from.size();
vec_to.resize(size);
castTypeToEither<
ColumnUInt8, ColumnUInt16, ColumnUInt32, ColumnUInt64,
ColumnInt8, ColumnInt16, ColumnInt32, ColumnInt64,
ColumnFloat32, ColumnFloat64>(
&delta, [&](const auto & column){ vectorVector(vec_from, vec_to, column, time_zone, size); return true; });
}
template <typename FromType, typename ToVectorType>
void constantVector(const FromType & from, ToVectorType & vec_to, const IColumn & delta, const DateLUTImpl & time_zone) const
{
size_t size = delta.size();
vec_to.resize(size);
castTypeToEither<
ColumnUInt8, ColumnUInt16, ColumnUInt32, ColumnUInt64,
ColumnInt8, ColumnInt16, ColumnInt32, ColumnInt64,
ColumnFloat32, ColumnFloat64>(
&delta, [&](const auto & column){ constantVector(from, vec_to, column, time_zone, size); return true; });
}
private:
template <typename FromVectorType, typename ToVectorType, typename DeltaColumnType>
void NO_INLINE vectorVector(const FromVectorType & vec_from, ToVectorType & vec_to, const DeltaColumnType & delta, const DateLUTImpl & time_zone, size_t size) const
{
for (size_t i = 0; i < size; ++i)
vec_to[i] = transform.execute(vec_from[i], delta.getData()[i], time_zone);
}
template <typename FromType, typename ToVectorType, typename DeltaColumnType>
void NO_INLINE constantVector(const FromType & from, ToVectorType & vec_to, const DeltaColumnType & delta, const DateLUTImpl & time_zone, size_t size) const
{
for (size_t i = 0; i < size; ++i)
vec_to[i] = transform.execute(from, delta.getData()[i], time_zone);
}
};
template <typename FromDataType, typename ToDataType, typename Transform>
struct DateTimeAddIntervalImpl
{
static ColumnPtr execute(Transform transform, ColumnsWithTypeAndName & arguments, const DataTypePtr & result_type)
{
using FromValueType = typename FromDataType::FieldType;
using FromColumnType = typename FromDataType::ColumnType;
using ToColumnType = typename ToDataType::ColumnType;
auto op = Adder<Transform>{std::move(transform)};
const DateLUTImpl & time_zone = extractTimeZoneFromFunctionArguments(arguments, 2, 0);
const ColumnPtr source_col = arguments[0].column;
auto result_col = result_type->createColumn();
auto col_to = assert_cast<ToColumnType *>(result_col.get());
if (const auto * sources = checkAndGetColumn<FromColumnType>(source_col.get()))
{
const IColumn & delta_column = *arguments[1].column;
if (const auto * delta_const_column = typeid_cast<const ColumnConst *>(&delta_column))
op.vectorConstant(sources->getData(), col_to->getData(), delta_const_column->getInt(0), time_zone);
else
op.vectorVector(sources->getData(), col_to->getData(), delta_column, time_zone);
}
else if (const auto * sources_const = checkAndGetColumnConst<FromColumnType>(source_col.get()))
{
op.constantVector(
sources_const->template getValue<FromValueType>(),
col_to->getData(),
*arguments[1].column, time_zone);
}
else
{
throw Exception("Illegal column " + arguments[0].column->getName()
+ " of first argument of function " + Transform::name,
ErrorCodes::ILLEGAL_COLUMN);
}
return result_col;
}
};
namespace date_and_time_type_details
{
// Compile-time mapping of value (DataType::FieldType) types to corresponding DataType
template <typename FieldType> struct ResultDataTypeMap {};
template <> struct ResultDataTypeMap<UInt16> { using ResultDataType = DataTypeDate; };
template <> struct ResultDataTypeMap<Int16> { using ResultDataType = DataTypeDate; };
template <> struct ResultDataTypeMap<UInt32> { using ResultDataType = DataTypeDateTime; };
template <> struct ResultDataTypeMap<Int32> { using ResultDataType = DataTypeDateTime; };
template <> struct ResultDataTypeMap<DateTime64> { using ResultDataType = DataTypeDateTime64; };
}
template <typename Transform>
class FunctionDateOrDateTimeAddInterval : public IFunction
{
public:
static constexpr auto name = Transform::name;
static FunctionPtr create(const Context &) { return std::make_shared<FunctionDateOrDateTimeAddInterval>(); }
String getName() const override
{
return name;
}
bool isVariadic() const override { return true; }
size_t getNumberOfArguments() const override { return 0; }
DataTypePtr getReturnTypeImpl(const ColumnsWithTypeAndName & arguments) const override
{
if (arguments.size() != 2 && arguments.size() != 3)
throw Exception("Number of arguments for function " + getName() + " doesn't match: passed "
+ toString(arguments.size()) + ", should be 2 or 3",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH);
if (!isNativeNumber(arguments[1].type))
throw Exception("Second argument for function " + getName() + " (delta) must be number",
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
if (arguments.size() == 2)
{
if (!isDateOrDateTime(arguments[0].type))
throw Exception{"Illegal type " + arguments[0].type->getName() + " of first argument of function " + getName() +
". Should be a date or a date with time", ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT};
}
else
{
if (!WhichDataType(arguments[0].type).isDateTime()
|| !WhichDataType(arguments[2].type).isString())
{
throw Exception(
"Function " + getName() + " supports 2 or 3 arguments. The 1st argument "
"must be of type Date or DateTime. The 2nd argument must be number. "
"The 3rd argument (optional) must be "
"a constant string with timezone name. The timezone argument is allowed "
"only when the 1st argument has the type DateTime",
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
}
}
switch (arguments[0].type->getTypeId())
{
case TypeIndex::Date:
return resolveReturnType<DataTypeDate>(arguments);
case TypeIndex::DateTime:
return resolveReturnType<DataTypeDateTime>(arguments);
case TypeIndex::DateTime64:
return resolveReturnType<DataTypeDateTime64>(arguments);
default:
{
throw Exception("Invalid type of 1st argument of function " + getName() + ": "
+ arguments[0].type->getName() + ", expected: Date, DateTime or DateTime64.",
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
}
}
}
/// Helper templates to deduce return type based on argument type, since some overloads may promote or denote types,
/// e.g. addSeconds(Date, 1) => DateTime
template <typename FieldType>
using TransformExecuteReturnType = decltype(std::declval<Transform>().execute(FieldType(), 0, std::declval<DateLUTImpl>()));
// Deduces RETURN DataType from INPUT DataType, based on return type of Transform{}.execute(INPUT_TYPE, UInt64, DateLUTImpl).
// e.g. for Transform-type that has execute()-overload with 'UInt16' input and 'UInt32' return,
// argument type is expected to be 'Date', and result type is deduced to be 'DateTime'.
template <typename FromDataType>
using TransformResultDataType = typename date_and_time_type_details::ResultDataTypeMap<TransformExecuteReturnType<typename FromDataType::FieldType>>::ResultDataType;
template <typename FromDataType>
DataTypePtr resolveReturnType(const ColumnsWithTypeAndName & arguments) const
{
using ResultDataType = TransformResultDataType<FromDataType>;
if constexpr (std::is_same_v<ResultDataType, DataTypeDate>)
return std::make_shared<DataTypeDate>();
else if constexpr (std::is_same_v<ResultDataType, DataTypeDateTime>)
{
return std::make_shared<DataTypeDateTime>(extractTimeZoneNameFromFunctionArguments(arguments, 2, 0));
}
else if constexpr (std::is_same_v<ResultDataType, DataTypeDateTime64>)
{
// TODO (vnemkov): what if there is an overload of Transform::execute() that returns DateTime64 from DateTime or Date ?
// Shall we use the default scale or one from optional argument ?
const auto & datetime64_type = assert_cast<const DataTypeDateTime64 &>(*arguments[0].type);
return std::make_shared<DataTypeDateTime64>(datetime64_type.getScale(), extractTimeZoneNameFromFunctionArguments(arguments, 2, 0));
}
else
{
static_assert("Failed to resolve return type.");
}
//to make PVS and GCC happy.
return nullptr;
}
bool useDefaultImplementationForConstants() const override { return true; }
ColumnNumbers getArgumentsThatAreAlwaysConstant() const override { return {2}; }
ColumnPtr executeImpl(ColumnsWithTypeAndName & arguments, const DataTypePtr & result_type, size_t /*input_rows_count*/) const override
{
const IDataType * from_type = arguments[0].type.get();
WhichDataType which(from_type);
if (which.isDate())
{
return DateTimeAddIntervalImpl<DataTypeDate, TransformResultDataType<DataTypeDate>, Transform>::execute(
Transform{}, arguments, result_type);
}
else if (which.isDateTime())
{
return DateTimeAddIntervalImpl<DataTypeDateTime, TransformResultDataType<DataTypeDateTime>, Transform>::execute(
Transform{}, arguments, result_type);
}
else if (const auto * datetime64_type = assert_cast<const DataTypeDateTime64 *>(from_type))
{
return DateTimeAddIntervalImpl<DataTypeDateTime64, TransformResultDataType<DataTypeDateTime64>, Transform>::execute(
Transform{datetime64_type->getScale()}, arguments, result_type);
}
else
throw Exception("Illegal type " + arguments[0].type->getName() + " of first argument of function " + getName(),
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
}
};
}