org.hibernate.hql.internal.ast.tree.BinaryArithmeticOperatorNode Maven / Gradle / Ivy
/*
* Hibernate, Relational Persistence for Idiomatic Java
*
* Copyright (c) 2008-2011, Red Hat Inc. or third-party contributors as
* indicated by the @author tags or express copyright attribution
* statements applied by the authors. All third-party contributions are
* distributed under license by Red Hat Inc.
*
* This copyrighted material is made available to anyone wishing to use, modify,
* copy, or redistribute it subject to the terms and conditions of the GNU
* Lesser General Public License, as published by the Free Software Foundation.
*
* 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 Lesser General Public License
* for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this distribution; if not, write to:
* Free Software Foundation, Inc.
* 51 Franklin Street, Fifth Floor
* Boston, MA 02110-1301 USA
*/
package org.hibernate.hql.internal.ast.tree;
import antlr.SemanticException;
import org.hibernate.hql.internal.antlr.HqlSqlTokenTypes;
import org.hibernate.hql.internal.ast.util.ColumnHelper;
import org.hibernate.type.StandardBasicTypes;
import org.hibernate.type.Type;
/**
* Nodes which represent binary arithmetic operators.
*
* @author Gavin King
*/
public class BinaryArithmeticOperatorNode extends AbstractSelectExpression implements BinaryOperatorNode, DisplayableNode {
public void initialize() throws SemanticException {
Node lhs = getLeftHandOperand();
Node rhs = getRightHandOperand();
if ( lhs == null ) {
throw new SemanticException( "left-hand operand of a binary operator was null" );
}
if ( rhs == null ) {
throw new SemanticException( "right-hand operand of a binary operator was null" );
}
Type lhType = ( lhs instanceof SqlNode ) ? ( ( SqlNode ) lhs ).getDataType() : null;
Type rhType = ( rhs instanceof SqlNode ) ? ( ( SqlNode ) rhs ).getDataType() : null;
if ( ExpectedTypeAwareNode.class.isAssignableFrom( lhs.getClass() ) && rhType != null ) {
Type expectedType = null;
// we have something like : "? [op] rhs"
if ( isDateTimeType( rhType ) ) {
// more specifically : "? [op] datetime"
// 1) if the operator is MINUS, the param needs to be of
// some datetime type
// 2) if the operator is PLUS, the param needs to be of
// some numeric type
expectedType = getType() == HqlSqlTokenTypes.PLUS ? StandardBasicTypes.DOUBLE : rhType;
}
else {
expectedType = rhType;
}
( ( ExpectedTypeAwareNode ) lhs ).setExpectedType( expectedType );
}
else if ( ParameterNode.class.isAssignableFrom( rhs.getClass() ) && lhType != null ) {
Type expectedType = null;
// we have something like : "lhs [op] ?"
if ( isDateTimeType( lhType ) ) {
// more specifically : "datetime [op] ?"
// 1) if the operator is MINUS, we really cannot determine
// the expected type as either another datetime or
// numeric would be valid
// 2) if the operator is PLUS, the param needs to be of
// some numeric type
if ( getType() == HqlSqlTokenTypes.PLUS ) {
expectedType = StandardBasicTypes.DOUBLE;
}
}
else {
expectedType = lhType;
}
( ( ExpectedTypeAwareNode ) rhs ).setExpectedType( expectedType );
}
}
/**
* Figure out the type of the binary expression by looking at
* the types of the operands. Sometimes we don't know both types,
* if, for example, one is a parameter.
*/
public Type getDataType() {
if ( super.getDataType() == null ) {
super.setDataType( resolveDataType() );
}
return super.getDataType();
}
private Type resolveDataType() {
// TODO : we may also want to check that the types here map to exactly one column/JDBC-type
// can't think of a situation where arithmetic expression between multi-column mappings
// makes any sense.
Node lhs = getLeftHandOperand();
Node rhs = getRightHandOperand();
Type lhType = ( lhs instanceof SqlNode ) ? ( ( SqlNode ) lhs ).getDataType() : null;
Type rhType = ( rhs instanceof SqlNode ) ? ( ( SqlNode ) rhs ).getDataType() : null;
if ( isDateTimeType( lhType ) || isDateTimeType( rhType ) ) {
return resolveDateTimeArithmeticResultType( lhType, rhType );
}
else {
if ( lhType == null ) {
if ( rhType == null ) {
// we do not know either type
return StandardBasicTypes.DOUBLE; //BLIND GUESS!
}
else {
// we know only the rhs-hand type, so use that
return rhType;
}
}
else {
if ( rhType == null ) {
// we know only the lhs-hand type, so use that
return lhType;
}
else {
if ( lhType== StandardBasicTypes.DOUBLE || rhType==StandardBasicTypes.DOUBLE ) {
return StandardBasicTypes.DOUBLE;
}
if ( lhType==StandardBasicTypes.FLOAT || rhType==StandardBasicTypes.FLOAT ) {
return StandardBasicTypes.FLOAT;
}
if ( lhType==StandardBasicTypes.BIG_DECIMAL || rhType==StandardBasicTypes.BIG_DECIMAL ) {
return StandardBasicTypes.BIG_DECIMAL;
}
if ( lhType==StandardBasicTypes.BIG_INTEGER || rhType==StandardBasicTypes.BIG_INTEGER ) {
return StandardBasicTypes.BIG_INTEGER;
}
if ( lhType==StandardBasicTypes.LONG || rhType==StandardBasicTypes.LONG ) {
return StandardBasicTypes.LONG;
}
if ( lhType==StandardBasicTypes.INTEGER || rhType==StandardBasicTypes.INTEGER ) {
return StandardBasicTypes.INTEGER;
}
return lhType;
}
}
}
}
private boolean isDateTimeType(Type type) {
if ( type == null ) {
return false;
}
return java.util.Date.class.isAssignableFrom( type.getReturnedClass() ) ||
java.util.Calendar.class.isAssignableFrom( type.getReturnedClass() );
}
private Type resolveDateTimeArithmeticResultType(Type lhType, Type rhType) {
// here, we work under the following assumptions:
// ------------ valid cases --------------------------------------
// 1) datetime + {something other than datetime} : always results
// in a datetime ( db will catch invalid conversions )
// 2) datetime - datetime : always results in a DOUBLE
// 3) datetime - {something other than datetime} : always results
// in a datetime ( db will catch invalid conversions )
// ------------ invalid cases ------------------------------------
// 4) datetime + datetime
// 5) {something other than datetime} - datetime
// 6) datetime * {any type}
// 7) datetime / {any type}
// 8) {any type} / datetime
// doing so allows us to properly handle parameters as either the left
// or right side here in the majority of cases
boolean lhsIsDateTime = isDateTimeType( lhType );
boolean rhsIsDateTime = isDateTimeType( rhType );
// handle the (assumed) valid cases:
// #1 - the only valid datetime addition synatx is one or the other is a datetime (but not both)
if ( getType() == HqlSqlTokenTypes.PLUS ) {
// one or the other needs to be a datetime for us to get into this method in the first place...
return lhsIsDateTime ? lhType : rhType;
}
else if ( getType() == HqlSqlTokenTypes.MINUS ) {
// #3 - note that this is also true of "datetime - :param"...
if ( lhsIsDateTime && !rhsIsDateTime ) {
return lhType;
}
// #2
if ( lhsIsDateTime && rhsIsDateTime ) {
return StandardBasicTypes.DOUBLE;
}
}
return null;
}
public void setScalarColumnText(int i) throws SemanticException {
ColumnHelper.generateSingleScalarColumn( this, i );
}
/**
* Retrieves the left-hand operand of the operator.
*
* @return The left-hand operand
*/
public Node getLeftHandOperand() {
return ( Node ) getFirstChild();
}
/**
* Retrieves the right-hand operand of the operator.
*
* @return The right-hand operand
*/
public Node getRightHandOperand() {
return ( Node ) getFirstChild().getNextSibling();
}
public String getDisplayText() {
return "{dataType=" + getDataType() + "}";
}
}