private VariableSlotLoader loadWithSubscript(Expression expression) {
    final OperandStack operandStack = controller.getOperandStack();
    // if we have a BinaryExpression, let us check if it is with
    // subscription
    if (expression instanceof BinaryExpression) {
      BinaryExpression be = (BinaryExpression) expression;
      if (be.getOperation().getType() == Types.LEFT_SQUARE_BRACKET) {
        // right expression is the subscript expression
        // we store the result of the subscription on the stack
        Expression subscript = be.getRightExpression();
        subscript.visit(controller.getAcg());
        ClassNode subscriptType = operandStack.getTopOperand();
        int id =
            controller.getCompileStack().defineTemporaryVariable("$subscript", subscriptType, true);
        VariableSlotLoader subscriptExpression =
            new VariableSlotLoader(subscriptType, id, operandStack);
        // do modified visit
        BinaryExpression newBe =
            new BinaryExpression(be.getLeftExpression(), be.getOperation(), subscriptExpression);
        newBe.copyNodeMetaData(be);
        newBe.setSourcePosition(be);
        newBe.visit(controller.getAcg());
        return subscriptExpression;
      }
    }

    // normal loading of expression
    expression.visit(controller.getAcg());
    return null;
  }
  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);
  }
Ejemplo n.º 3
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  public static void loadReference(String name, WriterController controller) {
    CompileStack compileStack = controller.getCompileStack();
    MethodVisitor mv = controller.getMethodVisitor();
    ClassNode classNode = controller.getClassNode();
    AsmClassGenerator acg = controller.getAcg();

    // compileStack.containsVariable(name) means to ask if the variable is already declared
    // compileStack.getScope().isReferencedClassVariable(name) means to ask if the variable is a
    // field
    // If it is no field and is not yet declared, then it is either a closure shared variable or
    // an already declared variable.
    if (!compileStack.containsVariable(name)
        && compileStack.getScope().isReferencedClassVariable(name)) {
      acg.visitFieldExpression(new FieldExpression(classNode.getDeclaredField(name)));
    } else {
      BytecodeVariable v =
          compileStack.getVariable(name, !classNodeUsesReferences(controller.getClassNode()));
      if (v == null) {
        // variable is not on stack because we are
        // inside a nested Closure and this variable
        // was not used before
        // then load it from the Closure field
        FieldNode field = classNode.getDeclaredField(name);
        mv.visitVarInsn(ALOAD, 0);
        mv.visitFieldInsn(
            GETFIELD,
            controller.getInternalClassName(),
            name,
            BytecodeHelper.getTypeDescription(field.getType()));
      } else {
        mv.visitVarInsn(ALOAD, v.getIndex());
      }
      controller.getOperandStack().push(ClassHelper.REFERENCE_TYPE);
    }
  }
  protected void evaluateCompareExpression(
      MethodCaller compareMethod, BinaryExpression expression) {
    Expression leftExp = expression.getLeftExpression();
    TypeChooser typeChooser = controller.getTypeChooser();
    ClassNode cn = controller.getClassNode();
    ClassNode leftType = typeChooser.resolveType(leftExp, cn);
    Expression rightExp = expression.getRightExpression();
    ClassNode rightType = typeChooser.resolveType(rightExp, cn);

    boolean done = false;
    if (ClassHelper.isPrimitiveType(leftType) && ClassHelper.isPrimitiveType(rightType)) {
      BinaryExpressionMultiTypeDispatcher helper =
          new BinaryExpressionMultiTypeDispatcher(getController());
      done = helper.doPrimitiveCompare(leftType, rightType, expression);
    }

    if (!done) {
      AsmClassGenerator acg = controller.getAcg();
      OperandStack operandStack = controller.getOperandStack();

      leftExp.visit(acg);
      operandStack.box();
      rightExp.visit(acg);
      operandStack.box();

      compareMethod.call(controller.getMethodVisitor());
      ClassNode resType = ClassHelper.boolean_TYPE;
      if (compareMethod == findRegexMethod) {
        resType = ClassHelper.OBJECT_TYPE;
      }
      operandStack.replace(resType, 2);
    }
  }
Ejemplo n.º 5
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  public boolean addGeneratedClosureConstructorCall(ConstructorCallExpression call) {
    ClassNode classNode = controller.getClassNode();
    if (!classNode.declaresInterface(ClassHelper.GENERATED_CLOSURE_Type)) return false;

    AsmClassGenerator acg = controller.getAcg();
    OperandStack operandStack = controller.getOperandStack();

    MethodVisitor mv = controller.getMethodVisitor();
    mv.visitVarInsn(ALOAD, 0);
    ClassNode callNode = classNode.getSuperClass();
    TupleExpression arguments = (TupleExpression) call.getArguments();
    if (arguments.getExpressions().size() != 2)
      throw new GroovyBugError(
          "expected 2 arguments for closure constructor super call, but got"
              + arguments.getExpressions().size());
    arguments.getExpression(0).visit(acg);
    operandStack.box();
    arguments.getExpression(1).visit(acg);
    operandStack.box();
    // TODO: replace with normal String, p not needed
    Parameter p = new Parameter(ClassHelper.OBJECT_TYPE, "_p");
    String descriptor =
        BytecodeHelper.getMethodDescriptor(ClassHelper.VOID_TYPE, new Parameter[] {p, p});
    mv.visitMethodInsn(
        INVOKESPECIAL, BytecodeHelper.getClassInternalName(callNode), "<init>", descriptor, false);
    operandStack.remove(2);
    return true;
  }
Ejemplo n.º 6
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 public ClassNode getOrAddClosureClass(ClosureExpression expression, int mods) {
   ClassNode closureClass = closureClassMap.get(expression);
   if (closureClass == null) {
     closureClass = createClosureClass(expression, mods);
     closureClassMap.put(expression, closureClass);
     controller.getAcg().addInnerClass(closureClass);
     closureClass.addInterface(ClassHelper.GENERATED_CLOSURE_Type);
     closureClass.putNodeMetaData(WriterControllerFactory.class, factory);
   }
   return closureClass;
 }
Ejemplo n.º 7
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 public void pushDynamicName(Expression name) {
   if (name instanceof ConstantExpression) {
     ConstantExpression ce = (ConstantExpression) name;
     Object value = ce.getValue();
     if (value instanceof String) {
       pushConstant(ce);
       return;
     }
   }
   new CastExpression(ClassHelper.STRING_TYPE, name).visit(controller.getAcg());
 }
  private void evaluateNormalTernary(TernaryExpression expression) {
    MethodVisitor mv = controller.getMethodVisitor();
    OperandStack operandStack = controller.getOperandStack();
    TypeChooser typeChooser = controller.getTypeChooser();

    Expression boolPart = expression.getBooleanExpression();
    Expression truePart = expression.getTrueExpression();
    Expression falsePart = expression.getFalseExpression();

    ClassNode truePartType = typeChooser.resolveType(truePart, controller.getClassNode());
    ClassNode falsePartType = typeChooser.resolveType(falsePart, controller.getClassNode());
    ClassNode common = WideningCategories.lowestUpperBound(truePartType, falsePartType);

    // we compile b?x:y as
    //      boolean(b)?S(x):S(y), S = common super type of x,y
    // so we load b, do boolean conversion.
    // In the true part load x and cast it to S,
    // in the false part load y and cast y to S

    // load b and convert to boolean
    int mark = operandStack.getStackLength();
    boolPart.visit(controller.getAcg());
    operandStack.castToBool(mark, true);

    Label l0 = operandStack.jump(IFEQ);
    // true part: load x and cast to S
    truePart.visit(controller.getAcg());
    operandStack.doGroovyCast(common);
    Label l1 = new Label();
    mv.visitJumpInsn(GOTO, l1);

    // false part: load y and cast to S
    mv.visitLabel(l0);
    falsePart.visit(controller.getAcg());
    operandStack.doGroovyCast(common);

    // finish and cleanup
    mv.visitLabel(l1);
    controller.getOperandStack().replace(common, 2);
  }
Ejemplo n.º 9
0
  public void writeClosure(ClosureExpression expression) {
    CompileStack compileStack = controller.getCompileStack();
    MethodVisitor mv = controller.getMethodVisitor();
    ClassNode classNode = controller.getClassNode();
    AsmClassGenerator acg = controller.getAcg();

    // generate closure as public class to make sure it can be properly invoked by classes of the
    // Groovy runtime without circumventing JVM access checks (see CachedMethod for example).
    ClassNode closureClass = getOrAddClosureClass(expression, ACC_PUBLIC);
    String closureClassinternalName = BytecodeHelper.getClassInternalName(closureClass);
    List constructors = closureClass.getDeclaredConstructors();
    ConstructorNode node = (ConstructorNode) constructors.get(0);

    Parameter[] localVariableParams = node.getParameters();

    mv.visitTypeInsn(NEW, closureClassinternalName);
    mv.visitInsn(DUP);
    if (controller.isStaticMethod() || compileStack.isInSpecialConstructorCall()) {
      (new ClassExpression(classNode)).visit(acg);
      (new ClassExpression(controller.getOutermostClass())).visit(acg);
    } else {
      mv.visitVarInsn(ALOAD, 0);
      controller.getOperandStack().push(ClassHelper.OBJECT_TYPE);
      loadThis();
    }

    // now let's load the various parameters we're passing
    // we start at index 2 because the first variable we pass
    // is the owner instance and at this point it is already
    // on the stack
    for (int i = 2; i < localVariableParams.length; i++) {
      Parameter param = localVariableParams[i];
      String name = param.getName();
      loadReference(name, controller);
      if (param.getNodeMetaData(ClosureWriter.UseExistingReference.class) == null) {
        param.setNodeMetaData(ClosureWriter.UseExistingReference.class, Boolean.TRUE);
      }
    }

    // we may need to pass in some other constructors
    // cv.visitMethodInsn(INVOKESPECIAL, innerClassinternalName, "<init>", prototype + ")V");
    mv.visitMethodInsn(
        INVOKESPECIAL,
        closureClassinternalName,
        "<init>",
        BytecodeHelper.getMethodDescriptor(ClassHelper.VOID_TYPE, localVariableParams),
        false);
    controller.getOperandStack().replace(ClassHelper.CLOSURE_TYPE, localVariableParams.length);
  }
  private void evaluateCompareTo(BinaryExpression expression) {
    Expression leftExpression = expression.getLeftExpression();
    AsmClassGenerator acg = controller.getAcg();
    OperandStack operandStack = controller.getOperandStack();

    leftExpression.visit(acg);
    operandStack.box();

    // if the right hand side is a boolean expression, we need to autobox
    Expression rightExpression = expression.getRightExpression();
    rightExpression.visit(acg);
    operandStack.box();

    compareToMethod.call(controller.getMethodVisitor());
    operandStack.replace(ClassHelper.Integer_TYPE, 2);
  }
  private void evaluateInstanceof(BinaryExpression expression) {
    OperandStack operandStack = controller.getOperandStack();

    expression.getLeftExpression().visit(controller.getAcg());
    operandStack.box();
    Expression rightExp = expression.getRightExpression();
    ClassNode classType;
    if (rightExp instanceof ClassExpression) {
      ClassExpression classExp = (ClassExpression) rightExp;
      classType = classExp.getType();
    } else {
      throw new RuntimeException(
          "Right hand side of the instanceof keyword must be a class name, not: " + rightExp);
    }
    String classInternalName = BytecodeHelper.getClassInternalName(classType);
    controller.getMethodVisitor().visitTypeInsn(INSTANCEOF, classInternalName);
    operandStack.replace(ClassHelper.boolean_TYPE);
  }
  private void evaluateLogicalAndExpression(BinaryExpression expression) {
    MethodVisitor mv = controller.getMethodVisitor();
    AsmClassGenerator acg = controller.getAcg();
    OperandStack operandStack = controller.getOperandStack();

    expression.getLeftExpression().visit(acg);
    operandStack.doGroovyCast(ClassHelper.boolean_TYPE);
    Label falseCase = operandStack.jump(IFEQ);

    expression.getRightExpression().visit(acg);
    operandStack.doGroovyCast(ClassHelper.boolean_TYPE);
    operandStack.jump(IFEQ, falseCase);

    ConstantExpression.PRIM_TRUE.visit(acg);
    Label trueCase = new Label();
    mv.visitJumpInsn(GOTO, trueCase);

    mv.visitLabel(falseCase);
    ConstantExpression.PRIM_FALSE.visit(acg);

    mv.visitLabel(trueCase);
    operandStack.remove(1); // have to remove 1 because of the GOTO
  }
  protected void evaluateBinaryExpressionWithAssignment(
      String method, BinaryExpression expression) {
    Expression leftExpression = expression.getLeftExpression();
    AsmClassGenerator acg = controller.getAcg();
    OperandStack operandStack = controller.getOperandStack();

    if (leftExpression instanceof BinaryExpression) {
      BinaryExpression leftBinExpr = (BinaryExpression) leftExpression;
      if (leftBinExpr.getOperation().getType() == Types.LEFT_SQUARE_BRACKET) {
        evaluateArrayAssignmentWithOperator(method, expression, leftBinExpr);
        return;
      }
    }

    evaluateBinaryExpression(method, expression);

    // br to leave a copy of rvalue on the stack. see also isPopRequired()
    operandStack.dup();

    controller.getCompileStack().pushLHS(true);
    leftExpression.visit(acg);
    controller.getCompileStack().popLHS();
  }
 protected void assignToArray(
     Expression parent, Expression receiver, Expression index, Expression rhsValueLoader) {
   // let's replace this assignment to a subscript operator with a
   // method call
   // e.g. x[5] = 10
   // -> (x, [], 5), =, 10
   // -> methodCall(x, "putAt", [5, 10])
   ArgumentListExpression ae = new ArgumentListExpression(index, rhsValueLoader);
   controller
       .getInvocationWriter()
       .makeCall(
           parent,
           receiver,
           new ConstantExpression("putAt"),
           ae,
           InvocationWriter.invokeMethod,
           false,
           false,
           false);
   controller.getOperandStack().pop();
   // return value of assignment
   rhsValueLoader.visit(controller.getAcg());
 }
  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
  }
  private void evaluateLogicalOrExpression(BinaryExpression expression) {
    MethodVisitor mv = controller.getMethodVisitor();
    AsmClassGenerator acg = controller.getAcg();
    OperandStack operandStack = controller.getOperandStack();

    Label end = new Label();

    expression.getLeftExpression().visit(acg);
    operandStack.doGroovyCast(ClassHelper.boolean_TYPE);
    Label trueCase = operandStack.jump(IFNE);

    expression.getRightExpression().visit(acg);
    operandStack.doGroovyCast(ClassHelper.boolean_TYPE);
    Label falseCase = operandStack.jump(IFEQ);

    mv.visitLabel(trueCase);
    ConstantExpression.PRIM_TRUE.visit(acg);
    operandStack.jump(GOTO, end);

    mv.visitLabel(falseCase);
    ConstantExpression.PRIM_FALSE.visit(acg);

    mv.visitLabel(end);
  }
  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);
  }