Haskell's type checker is being reasonable. The problem is that the authors of a library you're using have done something... less reasonable.
The brief answer is: Yes,
10 :: (Float, Float) is perfectly valid if there's an instance
Num (Float, Float). There's nothing "very wrong" about it from the compiler's or the language's perspective. It just doesn't square with our intuition about what numeric literals do. Since you're used to the type system catching the sort of error you made, you're justifiably surprised and disappointed!
Num instances and the
You're surprised that the compiler accepts
10 :: Coord, i.e.
10 :: (Float, Float). It's reasonable to assume that numeric literals like
10 will be inferred to have "numeric" types. Out of the box, numeric literals can be interpreted as
Double. A tuple of numbers, with no other context, doesn't seem like a number in the way those four types are numbers. We're not talking about
Fortunately or unfortunately, however, Haskell is a very flexible language. The standard specifies that an integer literal like
10 will be interpreted as
fromInteger 10, which has type
Num a => a. So
10 could be inferred as any type that's had a
Num instance written for it. I explain this in a bit more detail in another answer.
So when you posted your question, an experienced Haskeller immediately spotted that for
10 :: (Float, Float) to be accepted, there must be an instance like
Num a => Num (a, a) or
Num (Float, Float). There's no such instance in the
Prelude, so it must have been defined somewhere else. Using
:i Num, you quickly spotted where it came from: the
Type synonyms and orphan instances
But hold on a minute. You're not using any
gloss types in this example; why did the instance in
gloss affect you? The answer comes in two steps.
First, a type synonym introduced with the keyword
type does not create a new type. In your module, writing
Coord is simply shorthand for
(Float, Float). Likewise in
(Float, Float). In other words, your
Point are literally equivalent.
So when the
gloss maintainers chose to write
instance Num Point where ..., they also made your
Coord type an instance of
Num. That's equivalent to
instance Num (Float, Float) where ... or
instance Num Coord where ....
(By default, Haskell doesn't allow type synonyms to be class instances. The
gloss authors had to enable a pair of language extensions,
FlexibleInstances, to write the instance.)
Second, this is surprising because it's an orphan instance, i.e. an instance declaration
instance C A where both
A are defined in other modules. Here it's particularly insidious because each part involved, i.e.
Float, comes from the
Prelude and is likely to be in scope everywhere.
Your expectation is that
Num is defined in
Prelude, and tuples and
Float are defined in
Prelude, so everything about how those three things work is defined in
Prelude. Why would importing a completely different module change anything? Ideally it wouldn't, but orphan instances break that intuition.
(Note that GHC warns about orphan instances—the authors of
gloss specifically overrode that warning. That should have raised a red flag and prompted at least a warning in the documentation.)
Class instances are global and cannot be hidden
Furthermore, class instances are global: any instance defined in any module that is transitively imported from your module will be in context and available to the typechecker when doing instance resolution. This makes global reasoning convenient, because we can (usually) assume that a class function like
(+) will always be the same for a given type. However, it also means that local decisions have global effects; defining a class instance irrevocably changes the context of downstream code, with no way to mask or conceal it behind module boundaries.
You cannot use import lists to avoid importing instances. Similarly, you cannot avoid exporting instances from modules you define.
This is a problematic and much-discussed area of the Haskell language design. There's a fascinating discussion of related issues in this reddit thread. See, for instance, Edward Kmett's comment on allowing visibility control for instances: "You basically throw out the correctness of almost all of the code I have written."
(By the way, as this answer demonstrated, you can break the global-instance assumption in some regards by using orphan instances!)
What to do—for library implementers
Think twice before implementing
Num. You cannot work around the
fromInteger problem—no, defining
fromInteger = error "not implemented" does not make it better. Will your users be confused or surprised—or worse, never notice—if their integer literals are accidentally inferred to have the type you're instantiating? Is providing
(+) that critical—particularly if you have to hack it?
Consider using alternative arithmetical operators defined in a library like Conal Elliott's
vector-space (for types of kind
*) or Edward Kmett's
linear (for types of kind
* -> *). This is what I tend to do myself.
-Wall. Do not implement orphan instances, and do not disable the orphan instance warning.
Alternately, follow the lead of
linear and many other well-behaved libraries, and provide orphan instances in a separate module ending in
.Instances. And do not import that module from any other module. Then users can import the orphans explicitly if they would like.
If you find yourself defining orphans, consider asking upstream maintainers to implement them instead, if possible and appropriate. I used to frequently write the orphan instance
Show a => Show (Identity a), until they added it to
transformers. I may even have raised a bug report about it; I don't remember.
What to do—for library consumers
You don't have many options. Reach out—politely and constructively!—to the library maintainers. Point them to this question. They may have had some special reason to write the problematic orphan, or they may just not realize.
More broadly: Be aware of this possibility. This is one of the few areas of Haskell where there are true global effects; you'd have to check that every module you import, and every module those modules import, doesn't implement orphan instances. Type annotations may sometimes alert you to problems, and of course you can use
:i in GHCi to check.
Define your own
newtypes instead of
type synonyms if it's important enough. You can be pretty sure nobody will mess with them.
If you're having frequent problems deriving from an open-source library, you can of course make your own version of the library, but maintenance can quickly become a headache.