Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

The package versioning policy specifies that changing the type of any entity makes a change of the B number in A.B.C necessary.

However, it seems to me that some type changes don't break dependent code. In particular, consider the following example, where I drop a Typeable class constraint:

- foo :: Typeable a => AddHandler a -> NetworkDescription (Event a)
+ foo :: AddHandler a -> NetworkDescription (Event a)

So, my question is:

Can removing a type class constraint on a function break dependent code? Should I change the B number or just the C in version A.B.C when introducing this change?

share|improve this question
2  
I'm not certain SO is a good fit for this question because I don't think there's an authoritatively correct answer other than "whatever The Haskell Community wants". Maybe do a straw poll on haskell-cafe? IMHO a minor change would be sufficient. –  John L Sep 22 '11 at 9:16
    
@John L: Ok, I will poll on haskell-cafe. –  Heinrich Apfelmus Sep 22 '11 at 10:34
    
Seems to me that a tool which could compare two versions of a module and give a definitive answer might be useful. –  Paul Johnson Sep 22 '11 at 12:40
    
@PaulJohnson While I agree, you might wonder whether the "authoritative" answer that tool gave to this question was actually authoritative, or merely oversight on the parts of the people writing the policy/tool. I think that's the core of the question: the policy is clear, but does it actually reflect what people want? –  Daniel Wagner Sep 22 '11 at 13:12
1  
Some care does need to be taken around defaulting. For example, removing a Fractional constraint might cause a type variable that was previously defaulted to Double to be defaulted to Integer instead. –  hammar Mar 16 '13 at 10:04

2 Answers 2

up vote 3 down vote accepted

I have replied on -cafe, but I’ll also put my answer here:

You should bump the C number. The PVP, rule 2, specifies that an API addition implies that the C part of the version is to be increased. Removing a constraint behaves like adding a new function: Code that worked before continues to work, but code written against the new API might not work against the old one.

So if a programmer develops code against version 0.1.2 of foo, he’d specify foo >= 0.1.2 && < 0.2 as the requirement. He does not expect his code to work against foo-0.1.1. This works fine with removing the constraint.

share|improve this answer
    
As a developer, I would never add a C level constraint to a package description until someone complained that it was broken without it. –  Antoine Latter Sep 24 '11 at 3:11
    
@Joachim Breitner: Agreed, thanks. Furthermore, removing constraints should not create any ambiguity issues (since contexts get removed), though UndecidableInstances might spoil the fun. –  Heinrich Apfelmus Sep 24 '11 at 7:22

Can removing a type class constraint on a function break dependent code?

No, I don't believe so. Here's my reasoning. It's common to think of constraints as an additional function argument: a typeclass dictionary which is passed implicitly. You can think slightly more general than that, and imagine that constraints are a record of evidences which is passed implicitly. Thus, the type Foo can be thought of as {} -> Foo, where {} indicates an empty record of implicit evidences. It is irrelevant whether Foo itself is a function or not.

Now, suppose that our API promises to deliver something of type

{SomeConstraint} -> Foo

But what we actually deliver is

{} -> Foo

Well, record subtyping tells us that

{SomeConstraint} <: {}

therefore function subtyping tells us that

({} -> Foo) <: ({SomeConstraint} -> Foo)

therefore, anywhere in someone's program that we find a hole with the shape {SomeConstraint} -> Foo, we can plug in a {} -> Foo. In other words, nothing breaks. The user gives us evidence that SomeConstraint is satisfied, and we just ignore it.


At first I thought that weird corner cases in type inference might cause problems, but I cannot think of any examples where this is actually the case. So this thought was proven wrong by exhaustion of imagination.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.