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Difference between revisions of "RoadmapOAW5"

(Code blocks)
Line 227: Line 227:
   myExtension(String stuff) {
   myExtension(String stuff) {
     def x := stuff.length();
     def x := stuff.length();
     if (x>56)
     if x>56 then
     else {

Revision as of 07:06, 5 December 2007

Collection of features (rough)


In Version 5 we want to improve some of the Xtend language concepts and features. Codename is Xtend++ :


The import mechanism should be reworked, so that every import is explicit. We won't need any metamodel configuration in the workflow nor in the editors anymore. This will not only make the setup simpler but will also improve the performance.

The syntax would change to something like the following:

import org:openarchitectureware:Extension; // native import
import EMF "my/package/model.ecore"; // non-native import
import UML "my/test.profile.uml" as profile; // non-native import with name space definition
import Java "my.test.Class"; // non-native import introduces java types and features form my.test.Class
import XSD "" // non-native import importing the types from an XSD file
... (think of Hibernate mapping files, Groovy, etc.)

Native import

A native import refers to another extension file imports all public members (types, functions, extensions).

Non-native Import

A non native import starts with an identifier pointing to an installed adapter. The adapter is responsible for loading and converting the type information from the given string. The syntax in the string is defined by the adapter. The token directly after the import keyword defines which adapter to use.

Namespace definition

All members are included without namespace information. If you need a namespace you can explicitely define one per import.


The reexport keyword will be supported, so that imported stuff (types and functions) will be reexported.



  foo() : 'foo';


  reexported import myext1;
  bar() : 'bar';


  import myext2;
  fooBar() : foo()+bar();


We need full-fledged generics, which can conceptually be copied from Java's generics.

(complicated) Example:

  List<M> sort<T extends Comparable<T>, M>(List<M> toSort, (M)=>T closure)

which can be used like this


You don't have to deal with this complexity if you don't want to define functions which uses generics ;-)


We'll have real closures, not the built-in stuff we have now. Closure syntax:

  { parameterList '|' expression-using-parameters-and-scope }

Where parameter list must be typed, either implicitly or explicitly.


   String myText := "test";
   (Attribute)=>Boolean myClosure := {e|};     // e is inferred from the declared type of the assignee;

alternatively declare the parameter types explicitly

   var myText := "test";
   var myClosure := {Attribute e|};;
  // type of e is inferred from the declaration of the 'select()' function, you don't have to use the curly brackets.| == "test")

Type signatures of functions

The syntax for of a function's type signature looks as follows:



  (String, Entity)=>Entity

Example 2: declaration of higher-order functions using generics :

 List<T> select<T>(List<T> this, (T)=>Boolean closure) {


Functions can be invoked either using the functional syntax or using the member syntax (operation like, aka extensions):

  myFunction(foo, bar) == foo.myFuntion(bar)

A function is declared as follows:

  (private|cached|cached) ReturnType? functionName(declaredParameterList) ( guardExpression )? : bodyExpression ;


  private doStuff(Entity this) name!=null :

The detailed semantics of how the polymorphic resolution works (what role guards play here) and is described in the upcoming section.


  (private|cached) functionName(declaredParameterList) guardExpression blockExpression


  cached makeAbstract(Entity this) {
     abstract := true;
     name := 'Abstract'+name;

Block expressions are explained in their own section.

Polymorphic Resolution with signatures and guards

Usually polymorphism is based on the types of parameters. The same applies for Xtend++. In contrast to e.g. Java we use the dynamic types (actual types at runtime) of a given set of parameters in order to find the function which best fits (has the most specific declared paramter types).

Example: given the following two functions

  foo(String x) : "string";
  foo(Object o) : "object";

this assertions can be made:

  foo('S') == "string"
  foo(34)  == "object"
  foo((Object)'S') == "string" // would be "object" in Java

In addition to these concept, commonly known as "multiple dispatch" or "multi method", we introduce guards which can be used to controll the resolution based on the state of a given object not only the type.


  foo(String x) x.length>5 : "long";
  foo(String x) : "short";

this assertions can be made:

  foo('honolulu') == 'long'
  foo("bar") == 'short'

The semantics are as follows:

  • First select all possible features (functions and operations), based on the name and the given parameter types.
  • Then order those features by parameter types (best match first).Those functions with the same parameter type should be order so that the ones having a guard defined come first.

pseudo code

  for (Feature f : features)  {
     if (f.hasGuard()) {
        if (f.guard.evaluate())
           return f; // return the feature where the guard evaluates to true
     } else {
        return f; // return the feature without a guard
  return null; // no invocation
  • if there are features, but the guards evaluate to false, return null:

The static semantics are straight forward:

  • The guard must be of type boolean.

Extensions overwrite semantics

Functions and Operations can be overwritten. The precedence is based on th order of imports. Functions from later declared imports overwrite functions introduced before. Local functions overwrite imported functions. Consider overwriting the toString() Operation (which is invoked on String concatenations) for arbitrary meta types. This will allow very readable templates.

dynamically scoped extension overwriting

Another thing we want to address is the way one can extend generators provided by third parties (like the one shipped with GMF). So far everybody used AOP to "weave" customization and implementation in. The problem is that the generator designer does not really develop for extensibility and every Join Point becomes public API. We've been thinking about a concept called "dynamic extensions" which is a way to register extensions for a specific call graph.


 with(&toString(Entity)) {

Just to explain: '&toString(Entity) is a literal pointing to the 'toString(Entity)'-function. So one could write '&toString(Entity).evaluate(myEntity)' instead of 'myEntity.toString()' for example. The implementation of the function will be used whenever such a function is invoked within the callGMFCartridge(Entity) function (the third party cartridge). In other words one overwrites the toString() function for Entities for the following block. So what you as a generator developer could do is, provide a list of function which can be overwritten. In addition there is a final keyword, which prevents overwriting the corresponding function.

This won't be a replacement for AOP, but we think that the AOP feature has been missused in order to provide extensibility. In addition the extension emchanism was bound to the static context so far which really is a limitation in some situations.

Code blocks

A code block is the replacement for chain expressions ( a-> b-> x) with the additional features:

  • provides variable declarations (Expression returning the assigned value)

It's something like a pseudo imperative syntax (but still is an expression!).

Variables are assign-once!


 myExtension(String stuff) {
    def x := stuff.length();
    if x>56 then

A code block is itself an expression consisting of a list of expressions. It returns the value returned by the last expression.

It is possible to overwrite the scope. Example:

 doStuff() {
   def x := "Foo";
     def x:= "Bar";

will return "Bar"

Object creation expression

We are thinking about a syntax to create model graphs inline. We need this not only for model transformations but also for writing model transformation tests.


  new Entity {
      name := "Person";
      references += new Reference {
         name := "someRef"
         type := anotherEntity

Assignment Expressions

They are just another syntax for invoking a setter resp. adder-operation. They return the assigned value.

Operator Overloading

There will be predefined operators which can be used instead of the usual function invocation syntax if there is an operator for a name and a specific number of parameters.

Some examples:

add(Object a, Object b) => a + b subtract(Object a, Object b) => a- b not(Object a) => !a


create / cache semantics

The creation expression should replace the "create extension" mechanism from Xtend 1.0. A creation of an Object is cached if the type name is suffixed with parenthesis containing any number of arguments. The arguments act as a key.

The scope of the caching is per execution context, which can be reused in several invocations?


  var paramPerOperationAndName := new Parameter cachedwith op,name { := name;
     type := aDatatype;
  var localSingleton := new Foo cachedwith {
     stuff := "bla";

cross referencing

We need a way to specify cross references within a declared tree. The problem is that we need a reference to a created type after it has been created and before it will be initialized. This can be accomplished by adding a special assignment construct:

  var x := new Entity as localRef {
     // x is not visible here, because the right hand expression has not been evaluated so far.
     // localRef holds a reference to the created but not yet initialized entity.
        name := "Person";
        references += new Reference {
           name := "partner"
           type := localRef

XString (Template syntax)

We want to come up with a special datatype calle XString, which has a special literal syntax (like Xpand template syntax) and is mutable and streamable.


 myTemplate() :»
    package «packageName»;
    public class «name» {
      «foreach (attributes as a)»
         «if (a.type!=null) then»
            public «a.type» «»;

It's just a string literal with the xpand syntax within. The terminals '«' and '»' should be configurable (or there should be an alternative at least).

The FILE statement will be removed. Files can be opened through extensions:

 generateCode(Entity e) :


Because XStrings are mutable and are converted to a string late, it is possible to create a tree structure containing XStrings, where you can add XStrings (or normal Strings) later on.


  toJava(Entity this) :"""
     package «packageName()»;
  cached imports(Entity this) :"""
     import java.util.*;

... to be continued (and cleaned up;-))

if expression

As seen in the previous example, we want an if-expression. using if, else keywords.

if (predicate) expression (else if (predicate) expression)* (else expression)? endif

The else part is optional and will return null if not defined.


  // The following expression will return null:
  if (false) "Holla" endif

No Checks anymore

Checks used to provide a declarative way of specifying constraints on types. We will come up with a framework to do the same thing, so a constraint can be written like so:

  import assertion::Extensions;
  check(Entity this) abstract :
     error("The abstract entity "+name+" has no subclasses.",

This would be the replacement for

  context Entity if abstract 
     ERROR "The abstract entity "+name+" has no subclasses." :

No big difference I think, but we don't need to introduce a whole new concept (checks).

In addition it is now possible to write hierarchicly structured constraints which depend on each other:

  check(Property this) {
     dev column := findTable(entity()).columnForName(columnName());
     if (error("No corresponding column found ",
               column!=null) {
         error("The type does not match",
               column.type == this.type.sqlType())

Moreover one can have a name for a constraint like this (only the 'check' prefix is needed)

  checkTableExists(Entity this) :
     error("No corresponding table exists ",

looks and is similar to what xunit does. And it's a good idea to have something like XUnit for our language as well.

Definition of Types (later)

So far we couldn't define Types within Xtend but had to define them using other techniques (ecore, Java, UML-profile, etc.). Defining tyoes within Xtend would be a great feature. Because it is much simpler and faster to write them in text. In addition we could define Type with logic (operations). A syntax could look like this:

type Entity extends Named {
  // simple attributes
  String name;
  Boolean isAbstract {
     private set(aValue)
     get : name.startsWith("Abstract");
  // references
  Set<Entity> superTypes;
  Set<Features>* features; // asterisk means containment
  Set<Reference>* references subsets features;
  // operations
  doStuff(String x) : x+name;
  doMoreStuff(String x) {
     name := x;
     features += var f := new Feature{

MV: I agree that this is not the most urgent feature.

BK added --- To be discussed

Add private keyword to XPand

This is useful for marking Definitions in Xpand-Files as Private-API, especially useful when using AOP-features. Otherwise the whole generator is public API which is not intended in most cases

SE: We don't have "Xpand definitions" anymore. We have functions with XString expressions (which look the same). As functions have a private keyword, I think your requirement is met.

AOP for Checks

When modifying an expression using AOP, there might be the situation that a check is no longer valid. It has to be modified as well

SE: We can't modify expressions using AOP. We just can hang an Advice around a function call. I don't understand what you mean by, checks have to be modified.


PF added --- to be discussed

Add a FOLDER keyword

In order to create empty directory structures, it would be nice to have a FOLDER keyword. Syntax:

«FOLDER expression»

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