protected void evaluateArrayAssignmentWithOperator(
String method, BinaryExpression expression, BinaryExpression leftBinExpr) {
CompileStack compileStack = getController().getCompileStack();
AsmClassGenerator acg = getController().getAcg();
OperandStack os = getController().getOperandStack();
// e.g. x[a] += b
// to avoid loading x and a twice we transform the expression to use
// ExpressionAsVariableSlot
// -> subscript=a, receiver=x, receiver[subscript]+b, =, receiver[subscript]
// -> subscript=a, receiver=x, receiver#getAt(subscript)#plus(b), =, receiver#putAt(subscript)
// -> subscript=a, receiver=x, receiver#putAt(subscript, receiver#getAt(subscript)#plus(b))
// the result of x[a] += b is x[a]+b, thus:
// -> subscript=a, receiver=x, receiver#putAt(subscript, ret=receiver#getAt(subscript)#plus(b)),
// ret
ExpressionAsVariableSlot subscript =
new ExpressionAsVariableSlot(controller, leftBinExpr.getRightExpression(), "subscript");
ExpressionAsVariableSlot receiver =
new ExpressionAsVariableSlot(controller, leftBinExpr.getLeftExpression(), "receiver");
MethodCallExpression getAt =
new MethodCallExpression(receiver, "getAt", new ArgumentListExpression(subscript));
MethodCallExpression operation =
new MethodCallExpression(getAt, method, expression.getRightExpression());
ExpressionAsVariableSlot ret = new ExpressionAsVariableSlot(controller, operation, "ret");
MethodCallExpression putAt =
new MethodCallExpression(receiver, "putAt", new ArgumentListExpression(subscript, ret));
putAt.visit(acg);
os.pop();
os.load(ret.getType(), ret.getIndex());
compileStack.removeVar(ret.getIndex());
compileStack.removeVar(subscript.getIndex());
compileStack.removeVar(receiver.getIndex());
}
private void evaluateElvisOperatorExpression(ElvisOperatorExpression expression) {
MethodVisitor mv = controller.getMethodVisitor();
CompileStack compileStack = controller.getCompileStack();
OperandStack operandStack = controller.getOperandStack();
TypeChooser typeChooser = controller.getTypeChooser();
Expression boolPart = expression.getBooleanExpression().getExpression();
Expression falsePart = expression.getFalseExpression();
ClassNode truePartType = typeChooser.resolveType(boolPart, controller.getClassNode());
ClassNode falsePartType = typeChooser.resolveType(falsePart, controller.getClassNode());
ClassNode common = WideningCategories.lowestUpperBound(truePartType, falsePartType);
// x?:y is equal to x?x:y, which evals to
// var t=x; boolean(t)?t:y
// first we load x, dup it, convert the dupped to boolean, then
// jump depending on the value. For true we are done, for false we
// have to load y, thus we first remove x and then load y.
// But since x and y may have different stack lengths, this cannot work
// Thus we have to have to do the following:
// Be X the type of x, Y the type of y and S the common supertype of
// X and Y, then we have to see x?:y as
// var t=x;boolean(t)?S(t):S(y)
// so we load x, dup it, store the value in a local variable (t), then
// do boolean conversion. In the true part load t and cast it to S,
// in the false part load y and cast y to S
// load x, dup it, store one in $t and cast the remaining one to boolean
int mark = operandStack.getStackLength();
boolPart.visit(controller.getAcg());
operandStack.dup();
if (ClassHelper.isPrimitiveType(truePartType)
&& !ClassHelper.isPrimitiveType(operandStack.getTopOperand())) {
truePartType = ClassHelper.getWrapper(truePartType);
}
int retValueId = compileStack.defineTemporaryVariable("$t", truePartType, true);
operandStack.castToBool(mark, true);
Label l0 = operandStack.jump(IFEQ);
// true part: load $t and cast to S
operandStack.load(truePartType, retValueId);
operandStack.doGroovyCast(common);
Label l1 = new Label();
mv.visitJumpInsn(GOTO, l1);
// false part: load false expression and cast to S
mv.visitLabel(l0);
falsePart.visit(controller.getAcg());
operandStack.doGroovyCast(common);
// finish and cleanup
mv.visitLabel(l1);
compileStack.removeVar(retValueId);
controller.getOperandStack().replace(common, 2);
}
private void evaluatePostfixMethod(
int op, String method, Expression expression, Expression orig) {
CompileStack compileStack = controller.getCompileStack();
final OperandStack operandStack = controller.getOperandStack();
// load Expressions
VariableSlotLoader usesSubscript = loadWithSubscript(expression);
// save copy for later
operandStack.dup();
ClassNode expressionType = operandStack.getTopOperand();
int tempIdx = compileStack.defineTemporaryVariable("postfix_" + method, expressionType, true);
// execute Method
execMethodAndStoreForSubscriptOperator(op, method, expression, usesSubscript, orig);
// remove the result of the method call
operandStack.pop();
// reload saved value
operandStack.load(expressionType, tempIdx);
compileStack.removeVar(tempIdx);
if (usesSubscript != null) compileStack.removeVar(usesSubscript.getIndex());
}
private void execMethodAndStoreForSubscriptOperator(
int op,
String method,
Expression expression,
VariableSlotLoader usesSubscript,
Expression orig) {
final OperandStack operandStack = controller.getOperandStack();
writePostOrPrefixMethod(op, method, expression, orig);
// we need special code for arrays to store the result (like for a[1]++)
if (usesSubscript != null) {
CompileStack compileStack = controller.getCompileStack();
BinaryExpression be = (BinaryExpression) expression;
ClassNode methodResultType = operandStack.getTopOperand();
final int resultIdx =
compileStack.defineTemporaryVariable("postfix_" + method, methodResultType, true);
BytecodeExpression methodResultLoader =
new VariableSlotLoader(methodResultType, resultIdx, operandStack);
// execute the assignment, this will leave the right side
// (here the method call result) on the stack
assignToArray(be, be.getLeftExpression(), usesSubscript, methodResultLoader);
compileStack.removeVar(resultIdx);
}
// here we handle a.b++ and a++
else if (expression instanceof VariableExpression
|| expression instanceof FieldExpression
|| expression instanceof PropertyExpression) {
operandStack.dup();
controller.getCompileStack().pushLHS(true);
expression.visit(controller.getAcg());
controller.getCompileStack().popLHS();
}
// other cases don't need storing, so nothing to be done for them
}
public void evaluateEqual(BinaryExpression expression, boolean defineVariable) {
AsmClassGenerator acg = controller.getAcg();
CompileStack compileStack = controller.getCompileStack();
OperandStack operandStack = controller.getOperandStack();
Expression rightExpression = expression.getRightExpression();
Expression leftExpression = expression.getLeftExpression();
ClassNode lhsType =
controller.getTypeChooser().resolveType(leftExpression, controller.getClassNode());
if (defineVariable
&& rightExpression instanceof EmptyExpression
&& !(leftExpression instanceof TupleExpression)) {
VariableExpression ve = (VariableExpression) leftExpression;
BytecodeVariable var =
compileStack.defineVariable(
ve, controller.getTypeChooser().resolveType(ve, controller.getClassNode()), false);
operandStack.loadOrStoreVariable(var, false);
return;
}
// let's evaluate the RHS and store the result
ClassNode rhsType;
if (rightExpression instanceof ListExpression && lhsType.isArray()) {
ListExpression list = (ListExpression) rightExpression;
ArrayExpression array =
new ArrayExpression(lhsType.getComponentType(), list.getExpressions());
array.setSourcePosition(list);
array.visit(acg);
} else if (rightExpression instanceof EmptyExpression) {
rhsType = leftExpression.getType();
loadInitValue(rhsType);
} else {
rightExpression.visit(acg);
}
rhsType = operandStack.getTopOperand();
boolean directAssignment = defineVariable && !(leftExpression instanceof TupleExpression);
int rhsValueId;
if (directAssignment) {
VariableExpression var = (VariableExpression) leftExpression;
if (var.isClosureSharedVariable() && ClassHelper.isPrimitiveType(rhsType)) {
// GROOVY-5570: if a closure shared variable is a primitive type, it must be boxed
rhsType = ClassHelper.getWrapper(rhsType);
operandStack.box();
}
// ensure we try to unbox null to cause a runtime NPE in case we assign
// null to a primitive typed variable, even if it is used only in boxed
// form as it is closure shared
if (var.isClosureSharedVariable()
&& ClassHelper.isPrimitiveType(var.getOriginType())
&& isNull(rightExpression)) {
operandStack.doGroovyCast(var.getOriginType());
// these two are never reached in bytecode and only there
// to avoid verifyerrors and compiler infrastructure hazzle
operandStack.box();
operandStack.doGroovyCast(lhsType);
}
// normal type transformation
if (!ClassHelper.isPrimitiveType(lhsType) && isNull(rightExpression)) {
operandStack.replace(lhsType);
} else {
operandStack.doGroovyCast(lhsType);
}
rhsType = lhsType;
rhsValueId = compileStack.defineVariable(var, lhsType, true).getIndex();
} else {
rhsValueId = compileStack.defineTemporaryVariable("$rhs", rhsType, true);
}
// TODO: if rhs is VariableSlotLoader already, then skip crating a new one
BytecodeExpression rhsValueLoader = new VariableSlotLoader(rhsType, rhsValueId, operandStack);
// assignment for subscript
if (leftExpression instanceof BinaryExpression) {
BinaryExpression leftBinExpr = (BinaryExpression) leftExpression;
if (leftBinExpr.getOperation().getType() == Types.LEFT_SQUARE_BRACKET) {
assignToArray(
expression,
leftBinExpr.getLeftExpression(),
leftBinExpr.getRightExpression(),
rhsValueLoader);
}
compileStack.removeVar(rhsValueId);
return;
}
compileStack.pushLHS(true);
// multiple declaration
if (leftExpression instanceof TupleExpression) {
TupleExpression tuple = (TupleExpression) leftExpression;
int i = 0;
for (Expression e : tuple.getExpressions()) {
VariableExpression var = (VariableExpression) e;
MethodCallExpression call =
new MethodCallExpression(
rhsValueLoader, "getAt", new ArgumentListExpression(new ConstantExpression(i)));
call.visit(acg);
i++;
if (defineVariable) {
operandStack.doGroovyCast(var);
compileStack.defineVariable(var, true);
operandStack.remove(1);
} else {
acg.visitVariableExpression(var);
}
}
}
// single declaration
else if (defineVariable) {
rhsValueLoader.visit(acg);
operandStack.remove(1);
compileStack.popLHS();
return;
}
// normal assignment
else {
int mark = operandStack.getStackLength();
// to leave a copy of the rightExpression value on the stack after the assignment.
rhsValueLoader.visit(acg);
TypeChooser typeChooser = controller.getTypeChooser();
ClassNode targetType = typeChooser.resolveType(leftExpression, controller.getClassNode());
operandStack.doGroovyCast(targetType);
leftExpression.visit(acg);
operandStack.remove(operandStack.getStackLength() - mark);
}
compileStack.popLHS();
// return value of assignment
rhsValueLoader.visit(acg);
compileStack.removeVar(rhsValueId);
}
private boolean doAssignmentToArray(BinaryExpression binExp) {
if (!isAssignmentToArray(binExp)) return false;
// we need to handle only assignment to arrays combined with an operation
// special here. e.g x[a] += b
int operation = removeAssignment(binExp.getOperation().getType());
ClassNode current = getController().getClassNode();
Expression leftExp = binExp.getLeftExpression();
ClassNode leftType = getController().getTypeChooser().resolveType(leftExp, current);
Expression rightExp = binExp.getRightExpression();
ClassNode rightType = getController().getTypeChooser().resolveType(rightExp, current);
int operationType = getOperandType(leftType);
BinaryExpressionWriter bew = binExpWriter[operationType];
boolean simulationSuccess = bew.arrayGet(LEFT_SQUARE_BRACKET, true);
simulationSuccess = simulationSuccess && bew.write(operation, true);
simulationSuccess = simulationSuccess && bew.arraySet(true);
if (!simulationSuccess) return false;
AsmClassGenerator acg = getController().getAcg();
OperandStack operandStack = getController().getOperandStack();
CompileStack compileStack = getController().getCompileStack();
// for x[a] += b we have the structure:
// x = left(left(binExp))), b = right(binExp), a = right(left(binExp)))
// for array set we need these values on stack: array, index, right
// for array get we need these values on stack: array, index
// to eval the expression we need x[a] = x[a]+b
// -> arraySet(x,a, x[a]+b)
// -> arraySet(x,a, arrayGet(x,a,b))
// --> x,a, x,a, b as operands
// --> load x, load a, DUP2, call arrayGet, load b, call operation,call arraySet
// since we cannot DUP2 here easily we will save the subscript and DUP x
// --> sub=a, load x, DUP, load sub, call arrayGet, load b, call operation, load sub, call
// arraySet
BinaryExpression arrayWithSubscript = (BinaryExpression) leftExp;
Expression subscript = arrayWithSubscript.getRightExpression();
// load array index: sub=a [load x, DUP, load sub, call arrayGet, load b, call operation, load
// sub, call arraySet]
subscript.visit(acg);
operandStack.doGroovyCast(int_TYPE);
int subscriptValueId = compileStack.defineTemporaryVariable("$sub", ClassHelper.int_TYPE, true);
// load array: load x and DUP [load sub, call arrayGet, load b, call operation, load sub, call
// arraySet]
arrayWithSubscript.getLeftExpression().visit(acg);
operandStack.doGroovyCast(leftType.makeArray());
operandStack.dup();
// array get: load sub, call arrayGet [load b, call operation, load sub, call arraySet]
operandStack.load(ClassHelper.int_TYPE, subscriptValueId);
bew.arrayGet(LEFT_SQUARE_BRACKET, false);
operandStack.replace(leftType, 2);
// complete rhs: load b, call operation [load sub, call arraySet]
binExp.getRightExpression().visit(acg);
if (!(bew instanceof BinaryObjectExpressionHelper)) {
// in primopts we convert to the left type for supported binary operations
operandStack.doGroovyCast(leftType);
}
bew.write(operation, false);
// let us save that value for the return
operandStack.dup();
int resultValueId = compileStack.defineTemporaryVariable("$result", rightType, true);
// array set: load sub, call arraySet []
operandStack.load(ClassHelper.int_TYPE, subscriptValueId);
operandStack.swap();
bew.arraySet(false);
operandStack.remove(3); // 3 operands, the array, the index and the value!
// load return value
operandStack.load(rightType, resultValueId);
// cleanup
compileStack.removeVar(resultValueId);
compileStack.removeVar(subscriptValueId);
return true;
}