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The following Scheme code

(let ((x 1))
   (define (f y) (+ x y))
   (set! x 2)
   (f 3) )

which evaluates to 5 instead of 4. It is surprising considering Scheme promotes static scoping. Allowing subsequent mutation to affect bindings in the closed environment in a closure seems to revert to kinda dynamic scoping. Any specific reason that it is allowed?


I realized the code above is less obvious to reveal the problem I am concerned. I put another code fragment below:

(define x 1)

(define (f y) (+ x y))

(set! x 2)

(f 3)  ; evaluates to 5 instead of 4
share|improve this question
I made the change to make it less tangled with local scope. – day Nov 14 '12 at 13:07
up vote 2 down vote accepted

Allowing such mutation is excellent. It allows you to define objects with internal state, accessible only through pre-arranged means:

(define (adder n)
  (let ((x n))    
    (lambda (y)
      (cond ((pair? y) (set! x (car y)))
            (else (+ x y))))))

(define f (adder 1))
(f 5)                 ; 6
(f (list 10))
(f 5)                 ; 15

There is no way to change that x except through the f function and its established protocols - precisely because of lexical scoping in Scheme.

The x variable refers to a memory cell in the internal environment frame belonging to that let in which the internal lambda is defined - thus returning the combination of lambda and its defining environment, otherwise known as "closure".

And if you do not provide the protocols for mutating this internal variable, nothing can change it, as it is internal and we've long left the defining scope:

(set! x 5) ; WRONG: "x", what "x"? it's inaccessible!

EDIT: your new code, which changes the meaning of your question completely, there's no problem there as well. It is like we are still inside that defining environment, so naturally the internal variable is still accessible.

More problematic is the following

(define x 1)
(define (f y) (+ x y))
(define x 4)
(f 5) ;?? it's 9.

I would expect the second define to not interfere with the first, but R5RS says define is like set! in the top-level.

Closures package their defining environments with them. Top-level environment is always accessible.

The variable x that f refers to, lives in the top-level environment, and hence is accessible from any code in the same scope. That is to say, any code.

share|improve this answer
I agree this simulating-object feature is plausible. But note that set! in your example appears inside f. Naturally it can mutate x. (set! x 5) here would fail but because x is a variable local to adder, that is, it is not in scope. I have updated the code fragment in my question. You can see that set! appears outside f but can still mutate a variable that is closed in the closure for f. It is this use case I am against. I think it is possible still to support the feature you exemplified and disallowing set! to variables closed in a closure from outside the closure. – day Nov 14 '12 at 13:05
I think my argument against this mutating a variable closed in a closure outside the closure (you note my previous comment) remains, regardless of top-level. – day Nov 14 '12 at 13:13
thanks for the quick response, :) Regarding your new EDIT, how about putting the first two definitions in a file, load it, and then setting or redefine x, and then evaluate (f 5). Would you say that we are still inside the definition environment? – day Nov 14 '12 at 13:19
the top level in a file may also behave that way; the point is, closure packages lambda with its definitional environment, and the top level is always accessible, so such closures are always "open". Yes, in file the second define acts like set!, just as in REPL. I'm using MIT Scheme - don't know if it's implementation dependent. I'd expect the second x not to affect the 1st. – Will Ness Nov 14 '12 at 13:20
But you have seen that in the first piece of code, even the closed environment is not the always-accesible top-level environment, you can still mutate a variable closed in a closure from outside the closure. That is why I think whether the closed environment is the top-level is irrelevant here. – day Nov 14 '12 at 13:24

There are two ideas you are confusing here: scoping and indirection through memory. Lexical scope guarantees you that the reference to x always points to the binding of x in the let binding.

This is not violated in your example. Conceptually, the let binding is actually creating a new location in memory (containing 1) and that location is the value bound to x. When the location is dereferenced, the program looks up the current value at that memory location. When you use set!, it sets the value in memory. Only parties that have access to the location bound to x (via lexical scope) can access or mutate the contents in memory.

In contrast, dynamic scope allows any code to change the value you're referring to in f, regardless of whether you gave access to the location bound to x. For example,

(define f
  (let ([x 1])
    (define (f y) (+ x y))
    (set! x 2)

(let ([x 3]) (f 3))

would return 6 in an imaginary Scheme with dynamic scope.

share|improve this answer
You are right. It is not dynamic scoping (I said "kinda", maybe I should have said "seeming" ;) My concern here is whether allowing such behavior is good or not. At least I could not see any positive consequence. Imaging you define a function f in which a global variable x is used. Later you set! x and call f, it explodes. It seems to me when creating a closure only closing environment but not store is a bad design choice. – day Nov 14 '12 at 9:46
Okay, I think I better understand your question now. Closing over the store has other issues: how do you determine how much of the store to close over? With the environment, it's obvious from the text of the program: only the references in scope. With the store, if f calls g, does f have to close over the memory locations accessed by g? Also, how would that affect programs that concurrently use the same memory locations you closed over? – Asumu Takikawa Nov 14 '12 at 16:21
I think f does not have to close the store accessible by g even if f calls g, since g have already closed it. I have not thought about the possible consequence involving concurrency yet. – day Nov 14 '12 at 17:32

No, it is not dynamic scoping. Note that your define here is an internal definition, accessible only to the code inside the let. In specific, f is not defined at the module level. So nothing has leaked out.

Internal definitions are internally implemented as letrec (R5RS) or letrec* (R6RS). So, it's treated the same (if using R6RS semantics) as:

(let ((x 1))
  (letrec* ((f (lambda (y) (+ x y))))
    (set! x 2)
    (f 3)))
share|improve this answer
I think this is wrong in spirit - in particular, you can very well return the f function to the module level and it will still refer to the internal closure's environment's cell and it will still very well be mutable (were the f to provide the venue to request such mutation). – Will Ness Nov 14 '12 at 12:32

My answer is obvious, but I don't think that anyone else has touched upon it, so let me say it: yes, it's scary. What you're really observing here is that mutation makes it very hard to reason about what your program is going to do. Purely functional code--code with no mutation--always produces the same result when called with the same inputs. Code with state and mutation does not have this property. It may be that calling a function twice with the same inputs will produce separate results.

share|improve this answer
Thanks for the reminder, John, :). But here I am particularly interested in the problem mutation could cause and how to restrict the trouble it could make. – day Nov 14 '12 at 17:34
no, the OP is just wrong in their claim that the variable inside closure can be mutated from the outside. It can't, the variable in question is in top level scope, and everything is inside top-level scope. The question is not about merits of stateful vs pure functional programming; it is specific. – Will Ness Nov 15 '12 at 8:19
@plmday the Scheme way of restricting "mutation troubles" is to introduce new scope and to close over a variable in that new scope, to prevent any "outside" access to it - while allowing the authorized access from inside the same scope (or any "child" scope). – Will Ness Nov 15 '12 at 13:35
@plmday let's talk implementation: do you want to duplicate the representations of all store values referred to by the closure? You might be able to do something like that, but I think that for most people, it's simpler just to use immutable data or to ensure that there are no external references to the mutable ones. – John Clements Nov 15 '12 at 19:37
@plmday just don't define them that way, that's all. Define them inside child environments - extended by let (as shown in my answer, with adder, or as (define f (let ((x ...)) (lambda ... x ...))) ) - and all will be OK. Define them with references to top-level variables only if you really need that kind of behaviour (which is, almost never). That's all. IOW, this is a non-issue. :) – Will Ness Nov 15 '12 at 20:30

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