this situation basically never happens
Yes, my experience is indeed that that is not a problem in the Node/JS ecosystem. And I think it is, in part, thanks to the robustness principle.
Below is my view on why and how.
Primitives, the early days
I think the first and foremost reason is that the language provides a common basis for primitive types (Number, String, Bool, Null, Undefined) and some basic compound types (Object, Array, RegExp, etc...).
So if I receive a String from one of the libs' APIs I use, and pass it to another, it cannot go wrong because there is just a single String type.
This is what used to happen, and still happens to some extent to this day: Library authors try to rely on the built-ins as much as possible and only diverge when there is sufficient reason to, and with sufficient care and thought.
Not so in Haskell. Before I started using stack
, I've run into the following situation quite a few times with Text and ByteString:
Couldn't match type ‘T.Text’
with ‘Text’
NB: ‘T.Text’
is defined in ‘Data.Text.Internal’ in package ‘text-1.2.2.1’
‘Text’ is defined in ‘Data.Text.Internal’ in package ‘text-1.2.2.0’
Expected type: String -> Text
Actual type: String -> T.Text
This is quite frustrating, because in the above example only the patch version is different. The two data types may only be different nominally, and the ADT definition and the underlying memory representation may be completely identical.
As an example, it could have been a minor bugfix to the intersperse
function that warranted the release of 1.2.2.1
. Which is completely irrelevant to me if all I care about, in this hypothetical example, is concatenating some Text
s and comparing their length
s.
Compound types, objects
Sometimes there is sufficient reason to diverge in JS from the built in data types: Take Promise
s as an example. It's such a useful abstraction over async computations compared to callbacks that many APIs started using them. What now? How come we don't run into many incompatibilities when different versions of these {then(), fail(), ...}
objects are being passed up, down and around the dependency tree?
I think it's thanks to the robustness principle.
Be conservative in what you send, be liberal in what you accept.
So if I am authoring a JS library which I know returns promises and takes promises as part of its API, I'll be very careful how I interact with the received objects. E.g. I won't be calling fancy .success()
, .finally()
, ['catch']()
methods on it, since I want to be as compatible as possible with different users, with different implementations of Promise
s. So, very conservatively, I may just use .then(done, fail)
, and nothing more. At this point, it doesn't matter if the user uses the promises that my lib returns, or Bluebirds
' or even if they hand-write their own, so long as those adhere to the most basic Promise
'laws' -- the most basic API contracts.
Can this still lead to breakage at runtime? Yes, it can. If even the most basic API contract is not fulfilled, you may get an exception saying "Uncaught TypeError: promise.then is not a function". I think the trick here is that library authors are explicit about what their API needs: e.g. a .then
method on the supplied object. And then its up to whoever is building on top of that API to make it damn sure that that method is available on the object they pass in.
I'd like to also point out here that this is also the case for Haskell, isn't it? Should I be so foolish as to write an instance for a typeclass that still type-checks without following its laws, I'll get runtime errors, won't I?
Where do we go from here?
Having thought through all this just now, I think we might be able to have the benefits of the robustness principle even in Haskell with much less (or even no(?)) risk for runtime exceptions/errors compared to JavaScript: We just need the typesystem be granular enough so it can distinguish what we want to do with the data we manipulate, and determine if that is still safe or not. E.g. The hypothetical Text
example above, I would wager is still safe. And the compiler should only complain if I'm trying to use intersperse
, and asks me to qualify it. E.g. with T.intersperse
so it can be sure which one I want to use.
How do we do this in practice? Do we need extra support, e.g. language extension flags from GHC? We might not.
Just recently I found bookkeeper, which is a compile-time type-checked anonymous records implementation.
Please note: The following is conjecture on my part, I haven't taken much time to try and experiment with Bookkeeper. But I intend to in my Haskell projects to see if what I write about below could really be achieved with an approach such as this.
With Bookkeeper I could define an API like so:
emptyBook & #then =: id & #fail =: const
:: Bookkeeper.Internal.Book'
'["fail" 'Data.Type.Map.:-> (a -> b -> a),
"then" 'Data.Type.Map.:-> (a1 -> a1)]
Since functions are also first-class values. And whichever API takes this Book
as an argument can be very specific what it demands from it: Namely the #then
function, and that it has to match a certain type signature. And it cares not for any other function that may or may not be present with whatever signature. All this checked at compile time.
Prelude Bookkeeper
> let f o = (o ?: #foo) "a" "b" in f $ emptyBook & #foo =: (++)
"ab"
Conclusion
Maybe Bookkeeper or something similar will turn out to be useful in my experiments. Maybe Backpack will rush to the rescue with its common interface definitions. Or some other solution comes along. But either way, I hope we can move towards being able to take advantage of the robustness principle. And that Haskell's dependency management can also "just work" most of the time and fail with type errors only when it is truly warranted.
Does the above make sense? Anything unclear? Does it answer your question? I'd be curious to hear.
Further possibly relevant discussion may be found in this /r/haskell reddit thread, where this topic came up just not long ago, and I thought to post this answer to both places.