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I've come across a slight problem for writing memory management with regard to the internal representation of types in a compiler for statically typed, complex languages. Consider a simple snippet in C++ which easily demonstrates a type that refers to itself.

class X {
    void f(const X&) {}

Types can have nearly infinitely complex relationships to each other. So, as a compiler process, how do you make sure that they are properly collected?

So far, I've decided that garbage collection might be the right way to go, which I wouldn't be too happy with because I want to write the compiler in C++, or alternatively, just leave them and never collect them for the life of the compile phase for which they are needed (which has a very fixed lifetime) and then collect them all afterwards. The problem with that is that if you had a lot of complex types, you could lose a lot of memory that way.

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What objects are you concerned with, exactly? Tokens? AST nodes? How does this relate to statically typed, “complex” (?) languages? – Konrad Rudolph Jul 6 '11 at 15:02
Common solution is to add several passes to your compiler. This is the easiest way to do it. First pass just resolves these names and links them, and then in the next pass it can be used. Depending on language, you might need several passes to get everything available correctly. – tp1 Jul 6 '11 at 15:07
@Konrad: The internal representation of a type, would probably be something like a class named Type. @tp1: That is for parsing and resolving symbols.. not managing the memory of the objects those symbols correspond to. – Puppy Jul 6 '11 at 15:10
What is your definition of a lot of memory, what is the target of your compiler? You can fit a huge amount of memory representations of complex types in a few megs of memory. I would go for the simple thing: keep them around for the whole phase, and only if that proves itself to be a problem work on optimizing it. – David Rodríguez - dribeas Jul 6 '11 at 15:12
@David: Well, keeping around type objects that are no longer necessary is quite the definition of a leak. I prefer not to design leaks into my program. I guess you might be right about the scale- post it as an answer and I may accept it. – Puppy Jul 6 '11 at 15:20

Memory management is easy, just have some table type-name -> type-descriptor for each declaration scopes. Types are uniquely identified by name, no matter how complex the nesting is. Even a recursive type is still only a single type. As tp1 says correctly, you typically perform multiple passes to fill in all blanks. For instance, you might check that a type name is known in the first pass and then compute all links, later on, you compute the type.

Keep in mind that languages like C don't have a really complex type system -- even though they have pointers (which allow for recursive types), there is not much type computation going on.

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In my language then many types will have no name and no place in the global namespace. – Puppy Jul 6 '11 at 15:17
@DeadMG: You could just generate a unique name e.g. #AnonStruct15. There is no way to refer to the anonymous type by name anyway, so it should be safe. – kennytm Jul 6 '11 at 15:59
@DeadMG if you have <code>void main() { List&lt;string&gt; MyList = new List&lt;string&gt;()</code>, the "MyList" variable is an internal anonymous type, maybe with an automatic generated id. by your compiler. – umlcat Jul 6 '11 at 17:17

I think you can remove the cycles from the dependency graph by using separate objects to represent declarations and definitions. Assuming a type system similar to C++, you will then have a hierarchical dependency:

  • Function definitions depend on type definitions and function declarations
  • Type definitions depend on function and type declarations (and definitions of contained types)
  • Function declarations depend on type declarations

In your example, the dependency graph is f_def -> X_def -> f_decl -> X_decl.

With no cycles in the graph, you can manage objects using simple reference counting.

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The trouble is the second line. Type definitions depend on type definitions. class X { std::vector<X> my_x_vector; }; – Puppy Jul 6 '11 at 15:51
@DeadMG: Does it depend on the definition of X or on the declaration of X? – David Rodríguez - dribeas Jul 6 '11 at 16:11
If the template instantiation needs the definition of X, then the code is ill-formed, since X is incomplete at that point. vector only requires a declaration of X, so there is no problem. – Mike Seymour Jul 6 '11 at 16:25
@Mike Seymour: I'm pretty sure that vector requires a definition, since it calls member functions like the copy constructor and destructor, and that X is fully defined in it's scope. – Puppy Jul 7 '11 at 11:13
@DeadMG: its member functions require the definition, but they aren't instantiated until they are needed. The class definition only needs a declaration, since it doesn't contain any objects of type X. If it did need a definition, then your example code wouldn't compile, since X is incomplete when vector<X> is instantiated. – Mike Seymour Jul 7 '11 at 12:11

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