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I'm wondering if it is possible to design, for example, a type-safe singly linked list structure such that it is impossible to ask for the next node from the tail node.

At the same time, the client would need to be able to traverse (recursively or otherwise) through the list via node.getChild() but be prevented at compile time (at least with human-written explicit type checking) from going past the tail.

I'm wondering:

  1. Is there a name for this type of problem?
  2. Is there an object oriented or other approach that would help to avoid explicit run-time type checking?

The implementation language isn't important, but here's a Java example of what I'm thinking of.

Edit after Joop's answer:

public class TestHiddenInterfaces {
   interface Node { HasNoChildNode getTail(); }
   interface HasNoChildNode extends Node {};
   interface HasChildNode extends Node { Node getChild(); }
   class HasNoChild implements HasNoChildNode {
      @Override public HasNoChildNode getTail() { return this; }
   }
   class HasChild implements HasChildNode {
      final Node child;
      @Override
      public Node getChild() { return child; }
      HasChild(Node child) {
         this.child = child;
      }
      @Override public HasNoChildNode getTail() {
         if(child instanceof HasChild) return ((HasChild) child).getTail();
         else if(child instanceof HasNoChild) return (HasNoChildNode) child;
         else throw new RuntimeException("Unknown type");
      }
   }

   @Test
   public void test() {
      HasNoChild tail = new HasNoChild();
      assertEquals(tail, tail.getTail());
      HasChild level1 = new HasChild(tail);
      assertEquals(tail, level1.getTail());
      HasChild level2 = new HasChild(level1);
      assertEquals(tail, level2.getTail());
   }
}
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1  
Have you thought of having the node which is being asked for the parent check for a null parent (if it wasn't set, it would default as null) and either throwing an exception at that point (for which the client of the node would check for) or having some other smart default behavior that would be documented in your javadoc and checked for by the client? –  Jack Feb 6 '12 at 20:54
    
I don't know what you mean by "//Not type safe". In your last assertion, you say: level2.getParent().getParent(). That returns the Root node. Why would that assertion fail? You wouldn't be able to call getParent() on the Root unless you cast it to a (NonRoot) type, which would cause a ClassCastException. So yes, the only way to identify the root is to use some kind of runtime check. –  Sam Goldberg Feb 6 '12 at 21:14
    
@Jack I intend to use language support to make the getParent() method nonexistent as I showed in the interface RootNode extends Node {}; line. –  Jeff Axelrod Feb 7 '12 at 1:31
1  
@glenviewjeff, see also a recent question from me which demonstrates a data structure similar to what you're asking about. (It's demonstrating the idea using a persistent stack ADT, which is implemented as a reverse linked list, using C# recursive generics.) –  stakx Feb 8 '12 at 21:35

2 Answers 2

In Scala one uses "case types" for such typing. In Java, or UML diagrams, one often sees that a distinction is made between branch and leaf. And that can reduce half the memory of unused leaf children.

The types coexist like enum values.

So one might use the following:

/**
 * Base of all nodes. For the remaining types I have dropped the type parameter T.
 */
public interface Node<T> {
    void setValue(T value);
    T getValue();
}

public interface HasParent extends Node {
    void setParent(HasChildren node);
    HasChildren getParent();
}

public interface HasChildren extends Node {
    void setChildren(HasParent... children);
    HasPOarent[] getChildren();
}

public final class RootBranch implements HasChildren {
    ...
}

public final class SubBranch implements HasChildren, HasParent {
    ...
}

public final class Leaf implements HasParent {
    ...
}

public final class RootLeaf implements Node {
    ...
}

The usage would either use overloading, or distinguishing cases:

void f(Node node) {
    if (node instanceof HasParent) {
         HasParent nodeHavingParent = (HasParent) node;
         ...
    }
}

Personally I think this is overdone in Java, but in Scala for instance, where the type declaration is the constructor, this would make sense: SubBranche(parent, child1, child2).

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+1 just for suggesting Scala :) Thanks for the instanceof clue. I haven't used that operator before, and it will definitely help me implement this to a tolerable level in Java. Still, I don't understand how your example shows Scala's advantage over Java here. Does your example show how Scala uses [case classes/pattern matching] or am I missing something? –  Jeff Axelrod Feb 7 '12 at 1:34
    
Scala does not need if(instanceof)cast, has for instance a switch statement on case types. Also in Scale one would write the least creating SubBranche(parent, child1, child2) whereas in Java one would need to define a constructor for it. But I do not necessarily favour Scala over Java. Only its typing is a bit more fitting here. –  Joop Eggen Feb 7 '12 at 2:53

The only way that such a hierarchy could exist is if each level implemented a different interface (where I'm using interface in a wider sense than a specific language term).

The root node cannot implement getParent - that's the only way you'll achieve a compilation error that I can think of. So, the "interface" of the root node doesn't include getParent.

The first children can implement getParent - but in order to be compile safe, they have to return a type that is, at compile time, known to be the root node (i.e. a type that doesn't implement getParent).

At the next level, the implementation of getParent must return a type that implements a getParent that returns a root node that doesn't have getParent.

In short, even if you did choose to produce such an implementation, it would be very brittle, because you'd need to write different code to deal with each level of the hierarchy.


There are certain problems where a runtime check is right, and this would be one of those times. If every problem could be solved at compile time, then every compiled program would just be a set of results (and possibly a massive switch statement to pick which result you want to output)

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