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mariadb-columnstore-engine/dbcon/execplan/arithmeticoperator.h
Aleksei Antipovskii 0ab03c7258 chore(codestyle): mark virtual methods as override
2025-02-21 20:01:34 +04:00

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/* Copyright (C) 2014 InfiniDB, Inc.
Copyright (C) 2019 MariaDB Corporation
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; version 2 of
the License.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
MA 02110-1301, USA. */
/***********************************************************************
* $Id$
*
*
***********************************************************************/
/** @file */
#pragma once
#include <string>
#include <iosfwd>
#include <cmath>
#include <sstream>
#include "operator.h"
#include "parsetree.h"
#include "mcs_datatype.h"
namespace messageqcpp
{
class ByteStream;
}
namespace execplan
{
class ArithmeticOperator : public Operator
{
using cscType = execplan::CalpontSystemCatalog::ColType;
public:
ArithmeticOperator();
explicit ArithmeticOperator(const std::string& operatorName);
ArithmeticOperator(const ArithmeticOperator& rhs);
~ArithmeticOperator() override;
/** return a copy of this pointer
*
* deep copy of this pointer and return the copy
*/
inline ArithmeticOperator* clone() const override
{
return new ArithmeticOperator(*this);
}
inline long timeZone() const
{
return fTimeZone;
}
inline void timeZone(const long timeZone)
{
fTimeZone = timeZone;
}
/**
* The serialization interface
*/
void serialize(messageqcpp::ByteStream&) const override;
void unserialize(messageqcpp::ByteStream&) override;
/** @brief Do a deep, strict (as opposed to semantic) equivalence test
*
* Do a deep, strict (as opposed to semantic) equivalence test.
* @return true iff every member of t is a duplicate copy of every member of this; false otherwise
*/
bool operator==(const TreeNode* t) const override;
/** @brief Do a deep, strict (as opposed to semantic) equivalence test
*
* Do a deep, strict (as opposed to semantic) equivalence test.
* @return true iff every member of t is a duplicate copy of every member of this; false otherwise
*/
bool operator==(const ArithmeticOperator& t) const;
/** @brief Do a deep, strict (as opposed to semantic) equivalence test
*
* Do a deep, strict (as opposed to semantic) equivalence test.
* @return false iff every member of t is a duplicate copy of every member of this; true otherwise
*/
bool operator!=(const TreeNode* t) const override;
/** @brief Do a deep, strict (as opposed to semantic) equivalence test
*
* Do a deep, strict (as opposed to semantic) equivalence test.
* @return false iff every member of t is a duplicate copy of every member of this; true otherwise
*/
bool operator!=(const ArithmeticOperator& t) const;
/***********************************************************
* F&E framework *
***********************************************************/
using Operator::evaluate;
inline void evaluate(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override;
using Operator::getStrVal;
const utils::NullString& getStrVal(rowgroup::Row& row, bool& isNull, ParseTree* lop,
ParseTree* rop) override
{
bool localIsNull = false;
evaluate(row, localIsNull, lop, rop);
isNull = isNull || localIsNull;
return localIsNull ? fResult.strVal.dropString() : TreeNode::getStrVal(fTimeZone);
}
using Operator::getIntVal;
int64_t getIntVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getIntVal();
}
using Operator::getUintVal;
uint64_t getUintVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getUintVal();
}
using Operator::getFloatVal;
float getFloatVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getFloatVal();
}
using Operator::getDoubleVal;
double getDoubleVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getDoubleVal();
}
using Operator::getLongDoubleVal;
long double getLongDoubleVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getLongDoubleVal();
}
using Operator::getDecimalVal;
IDB_Decimal getDecimalVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
// @bug5736, double type with precision -1 indicates that this type is for decimal math,
// the original decimal scale is stored in scale field, which is no use for double.
if (fResultType.colDataType == CalpontSystemCatalog::DOUBLE && fResultType.precision == -1)
{
IDB_Decimal rv;
rv.scale = fResultType.scale;
rv.precision = 15;
rv.value = (int64_t)(TreeNode::getDoubleVal() * IDB_pow[rv.scale]);
return rv;
}
return TreeNode::getDecimalVal();
}
using Operator::getDateIntVal;
int32_t getDateIntVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getDateIntVal();
}
using Operator::getDatetimeIntVal;
int64_t getDatetimeIntVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getDatetimeIntVal();
}
using Operator::getTimestampIntVal;
int64_t getTimestampIntVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getTimestampIntVal();
}
using Operator::getTimeIntVal;
int64_t getTimeIntVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getTimeIntVal();
}
using Operator::getBoolVal;
bool getBoolVal(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop) override
{
evaluate(row, isNull, lop, rop);
return TreeNode::getBoolVal();
}
void adjustResultType(const CalpontSystemCatalog::ColType& m);
inline bool getOverflowCheck() const
{
return fDecimalOverflowCheck;
}
inline void setOverflowCheck(bool check)
{
fDecimalOverflowCheck = check;
}
inline std::string toCppCode(IncludeSet& includes) const override
{
includes.insert("arithmeticoperator.h");
std::stringstream ss;
ss << "ArithmeticOperator(" << std::quoted(fData) << ")";
return ss.str();
}
private:
template <typename result_t>
inline result_t execute(result_t op1, result_t op2, bool& isNull);
inline void execute(IDB_Decimal& result, IDB_Decimal op1, IDB_Decimal op2, bool& isNull);
long fTimeZone;
bool fDecimalOverflowCheck;
};
#include "parsetree.h"
inline void ArithmeticOperator::evaluate(rowgroup::Row& row, bool& isNull, ParseTree* lop, ParseTree* rop)
{
// fOpType should have already been set on the connector during parsing
switch (fOperationType.colDataType)
{
case execplan::CalpontSystemCatalog::BIGINT:
case execplan::CalpontSystemCatalog::INT:
case execplan::CalpontSystemCatalog::MEDINT:
case execplan::CalpontSystemCatalog::SMALLINT:
case execplan::CalpontSystemCatalog::TINYINT:
fResult.intVal = execute(lop->getIntVal(row, isNull), rop->getIntVal(row, isNull), isNull);
if (isNull)
{
fResult.intVal = joblist::INTNULL;
}
break;
case execplan::CalpontSystemCatalog::UBIGINT:
{
// XXX: this is bandaid solution for specific customer case (MCOL-5568).
// Despite that I tried to implement a proper solution: to have operations
// performed using int128_t amd then check the result.
int128_t x, y;
bool signedLeft = lop->data()->resultType().isSignedInteger();
bool signedRight = rop->data()->resultType().isSignedInteger();
if (signedLeft)
{
x = static_cast<int128_t>(lop->getIntVal(row, isNull));
}
else
{
x = static_cast<int128_t>(lop->getUintVal(row, isNull));
}
if (signedRight)
{
y = static_cast<int128_t>(rop->getIntVal(row, isNull));
}
else
{
y = static_cast<int128_t>(rop->getUintVal(row, isNull));
}
int128_t result = execute(x, y, isNull);
if (!isNull && (result > MAX_UBIGINT || result < 0))
{
logging::Message::Args args;
std::string func = "<unknown>";
switch (fOp)
{
case OP_ADD: func = "\"+\""; break;
case OP_SUB: func = "\"-\""; break;
case OP_MUL: func = "\"*\""; break;
case OP_DIV: func = "\"/\""; break;
default: break;
}
args.add(func);
args.add(static_cast<double>(x));
args.add(static_cast<double>(y));
unsigned errcode = logging::ERR_FUNC_OUT_OF_RANGE_RESULT;
throw logging::IDBExcept(logging::IDBErrorInfo::instance()->errorMsg(errcode, args), errcode);
}
fResult.uintVal = static_cast<uint64_t>(result);
}
break;
case execplan::CalpontSystemCatalog::UINT:
case execplan::CalpontSystemCatalog::UMEDINT:
case execplan::CalpontSystemCatalog::USMALLINT:
case execplan::CalpontSystemCatalog::UTINYINT:
fResult.uintVal = execute(lop->getUintVal(row, isNull), rop->getUintVal(row, isNull), isNull);
if (isNull)
{
fResult.uintVal = joblist::UBIGINTNULL;
}
break;
case execplan::CalpontSystemCatalog::DOUBLE:
case execplan::CalpontSystemCatalog::FLOAT:
case execplan::CalpontSystemCatalog::UDOUBLE:
case execplan::CalpontSystemCatalog::UFLOAT:
fResult.doubleVal = execute(lop->getDoubleVal(row, isNull), rop->getDoubleVal(row, isNull), isNull);
break;
case execplan::CalpontSystemCatalog::LONGDOUBLE:
fResult.longDoubleVal =
execute(lop->getLongDoubleVal(row, isNull), rop->getLongDoubleVal(row, isNull), isNull);
break;
case execplan::CalpontSystemCatalog::DECIMAL:
case execplan::CalpontSystemCatalog::UDECIMAL:
execute(fResult.decimalVal, lop->getDecimalVal(row, isNull), rop->getDecimalVal(row, isNull), isNull);
break;
default:
{
std::ostringstream oss;
oss << "invalid arithmetic operand type: " << fOperationType.colDataType;
throw logging::InvalidArgumentExcept(oss.str());
}
}
}
template <typename result_t>
inline result_t ArithmeticOperator::execute(result_t op1, result_t op2, bool& isNull)
{
if (isNull)
{
// at least one operand is NULL.
// do nothing, return 0.
if constexpr (std::is_same<result_t, datatypes::TSInt128>::value)
{
return datatypes::TSInt128(); // returns 0
}
else
{
return 0;
}
}
switch (fOp)
{
case OP_ADD: return op1 + op2;
case OP_SUB: return op1 - op2;
case OP_MUL: return op1 * op2;
case OP_DIV:
if (op2)
return op1 / op2;
else
isNull = true;
return 0;
default:
{
std::ostringstream oss;
oss << "invalid arithmetic operation: " << fOp;
throw logging::InvalidOperationExcept(oss.str());
}
}
}
inline void ArithmeticOperator::execute(IDB_Decimal& result, IDB_Decimal op1, IDB_Decimal op2, bool& isNull)
{
switch (fOp)
{
case OP_ADD:
if (fOperationType.colWidth == datatypes::MAXDECIMALWIDTH)
{
if (LIKELY(!fDecimalOverflowCheck))
{
datatypes::Decimal::addition<decltype(result.s128Value), false>(op1, op2, result);
}
else
{
datatypes::Decimal::addition<decltype(result.s128Value), true>(op1, op2, result);
}
}
else if (fOperationType.colWidth == utils::MAXLEGACYWIDTH)
{
if (LIKELY(!fDecimalOverflowCheck))
{
datatypes::Decimal::addition<decltype(result.value), false>(op1, op2, result);
}
else
{
datatypes::Decimal::addition<decltype(result.value), true>(op1, op2, result);
}
}
else
{
throw logging::InvalidArgumentExcept("Unexpected result width");
}
break;
case OP_SUB:
if (fOperationType.colWidth == datatypes::MAXDECIMALWIDTH)
{
if (LIKELY(!fDecimalOverflowCheck))
{
datatypes::Decimal::subtraction<decltype(result.s128Value), false>(op1, op2, result);
}
else
{
datatypes::Decimal::subtraction<decltype(result.s128Value), true>(op1, op2, result);
}
}
else if (fOperationType.colWidth == utils::MAXLEGACYWIDTH)
{
if (LIKELY(!fDecimalOverflowCheck))
{
datatypes::Decimal::subtraction<decltype(result.value), false>(op1, op2, result);
}
else
{
datatypes::Decimal::subtraction<decltype(result.value), true>(op1, op2, result);
}
}
else
{
throw logging::InvalidArgumentExcept("Unexpected result width");
}
break;
case OP_MUL:
if (fOperationType.colWidth == datatypes::MAXDECIMALWIDTH)
{
if (LIKELY(!fDecimalOverflowCheck))
{
datatypes::Decimal::multiplication<decltype(result.s128Value), false>(op1, op2, result);
}
else
{
datatypes::Decimal::multiplication<decltype(result.s128Value), true>(op1, op2, result);
}
}
else if (fOperationType.colWidth == utils::MAXLEGACYWIDTH)
{
if (LIKELY(!fDecimalOverflowCheck))
{
datatypes::Decimal::multiplication<decltype(result.value), false>(op1, op2, result);
}
else
{
datatypes::Decimal::multiplication<decltype(result.value), true>(op1, op2, result);
}
}
else
{
throw logging::InvalidArgumentExcept("Unexpected result width");
}
break;
case OP_DIV:
if (fOperationType.colWidth == datatypes::MAXDECIMALWIDTH)
{
if ((datatypes::Decimal::isWideDecimalTypeByPrecision(op2.precision) && op2.s128Value == 0) ||
(!datatypes::Decimal::isWideDecimalTypeByPrecision(op2.precision) && op2.value == 0))
{
isNull = true;
break;
}
if (LIKELY(!fDecimalOverflowCheck))
{
datatypes::Decimal::division<decltype(result.s128Value), false>(op1, op2, result);
}
else
{
datatypes::Decimal::division<decltype(result.s128Value), true>(op1, op2, result);
}
}
else if (fOperationType.colWidth == utils::MAXLEGACYWIDTH)
{
if (op2.value == 0)
{
isNull = true;
break;
}
if (LIKELY(!fDecimalOverflowCheck))
{
datatypes::Decimal::division<decltype(result.value), false>(op1, op2, result);
}
else
{
datatypes::Decimal::division<decltype(result.value), true>(op1, op2, result);
}
}
else
{
throw logging::InvalidArgumentExcept("Unexpected result width");
}
break;
default:
{
std::ostringstream oss;
oss << "invalid arithmetic operation: " << fOp;
throw logging::InvalidOperationExcept(oss.str());
}
}
}
std::ostream& operator<<(std::ostream& os, const ArithmeticOperator& rhs);
} // namespace execplan
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