package org.springframework.expression.spel.ast;
import java.math.BigDecimal;
import java.math.BigInteger;
import org.springframework.asm.MethodVisitor;
import org.springframework.expression.EvaluationException;
import org.springframework.expression.Operation;
import org.springframework.expression.TypedValue;
import org.springframework.expression.spel.CodeFlow;
import org.springframework.expression.spel.ExpressionState;
import org.springframework.util.Assert;
import org.springframework.util.NumberUtils;
public class OpModulus extends Operator {
public OpModulus(int pos, SpelNodeImpl... operands) {
super("%", pos, operands);
}
@Override
public TypedValue getValueInternal(ExpressionState state) throws EvaluationException {
Object leftOperand = getLeftOperand().getValueInternal(state).getValue();
Object rightOperand = getRightOperand().getValueInternal(state).getValue();
if (leftOperand instanceof Number && rightOperand instanceof Number) {
Number leftNumber = (Number) leftOperand;
Number rightNumber = (Number) rightOperand;
if (leftNumber instanceof BigDecimal || rightNumber instanceof BigDecimal) {
BigDecimal leftBigDecimal = NumberUtils.convertNumberToTargetClass(leftNumber, BigDecimal.class);
BigDecimal rightBigDecimal = NumberUtils.convertNumberToTargetClass(rightNumber, BigDecimal.class);
return new TypedValue(leftBigDecimal.remainder(rightBigDecimal));
}
else if (leftNumber instanceof Double || rightNumber instanceof Double) {
this.exitTypeDescriptor = "D";
return new TypedValue(leftNumber.doubleValue() % rightNumber.doubleValue());
}
else if (leftNumber instanceof Float || rightNumber instanceof Float) {
this.exitTypeDescriptor = "F";
return new TypedValue(leftNumber.floatValue() % rightNumber.floatValue());
}
else if (leftNumber instanceof BigInteger || rightNumber instanceof BigInteger) {
BigInteger leftBigInteger = NumberUtils.convertNumberToTargetClass(leftNumber, BigInteger.class);
BigInteger rightBigInteger = NumberUtils.convertNumberToTargetClass(rightNumber, BigInteger.class);
return new TypedValue(leftBigInteger.remainder(rightBigInteger));
}
else if (leftNumber instanceof Long || rightNumber instanceof Long) {
this.exitTypeDescriptor = "J";
return new TypedValue(leftNumber.longValue() % rightNumber.longValue());
}
else if (CodeFlow.isIntegerForNumericOp(leftNumber) || CodeFlow.isIntegerForNumericOp(rightNumber)) {
this.exitTypeDescriptor = "I";
return new TypedValue(leftNumber.intValue() % rightNumber.intValue());
}
else {
return new TypedValue(leftNumber.doubleValue() % rightNumber.doubleValue());
}
}
return state.operate(Operation.MODULUS, leftOperand, rightOperand);
}
@Override
public boolean isCompilable() {
if (!getLeftOperand().isCompilable()) {
return false;
}
if (this.children.length > 1) {
if (!getRightOperand().isCompilable()) {
return false;
}
}
return (this.exitTypeDescriptor != null);
}
@Override
public void generateCode(MethodVisitor mv, CodeFlow cf) {
getLeftOperand().generateCode(mv, cf);
String leftDesc = getLeftOperand().exitTypeDescriptor;
String exitDesc = this.exitTypeDescriptor;
Assert.state(exitDesc != null, "No exit type descriptor");
char targetDesc = exitDesc.charAt(0);
CodeFlow.insertNumericUnboxOrPrimitiveTypeCoercion(mv, leftDesc, targetDesc);
if (this.children.length > 1) {
cf.enterCompilationScope();
getRightOperand().generateCode(mv, cf);
String rightDesc = getRightOperand().exitTypeDescriptor;
cf.exitCompilationScope();
CodeFlow.insertNumericUnboxOrPrimitiveTypeCoercion(mv, rightDesc, targetDesc);
switch (targetDesc) {
case 'I':
mv.visitInsn(IREM);
break;
case 'J':
mv.visitInsn(LREM);
break;
case 'F':
mv.visitInsn(FREM);
break;
case 'D':
mv.visitInsn(DREM);
break;
default:
throw new IllegalStateException(
"Unrecognized exit type descriptor: '" + this.exitTypeDescriptor + "'");
}
}
cf.pushDescriptor(this.exitTypeDescriptor);
}
}