21

Is it recommended to always have exhaustive pattern matches in Haskell, even for "impossible" cases?

For example, in the following code, I am pattern matching on the "accumulator" of a foldr. I am in complete control of the contents of the accumulator, because I create it (it is not passed to me as input, but rather built within my function). Therefore, I know certain patterns should never match it. If I strive to never get the "Pattern match(es) are non-exhaustive" error, then I would place a pattern match for it that simply error's with the message "This pattern should never happen." Much like an assert in C#. I can't think of anything else to do there.

What practice would you recommend in this situation and why?

Here's the code:

gb_groupBy p input = foldr step [] input
   where
      step item acc = case acc of
           []                           -> [[item]]
           ((x:xs):ys)                  -> if p x item
                                           then (item:x:xs):ys
                                           else [item]:acc

The pattern not matched (as reported by the interpreter) is:

Warning: Pattern match(es) are non-exhaustive In a case alternative: Patterns not matched: [] : _

3
  • 10
    The annoying thing here is that to silence the warning you often end up putting in a less helpful runtime error message. I'd like to just acknowledge the missing case but allow for the default runtime error text (which points to the file/line number) to be used. May 7, 2009 at 7:47
  • That's a great point. I guess there's currently no way to do that. Too bad. May 7, 2009 at 7:59
  • see also stackoverflow.com/questions/1882334
    – sdcvvc
    Feb 21, 2012 at 13:05

6 Answers 6

23

This is probably more a matter of style than anything else. Personally, I would put in a

_ -> error "Impossible! Empty list in step"

if only to silence the warning :)

4
  • 2
    I agree with this approach. It helps indicate that you intentionally did not handle the other cases because you think it's impossible, rather than you just forgetting or not realizing.
    – newacct
    May 7, 2009 at 5:31
  • 7
    It's always fun when your program suddenly terminates with this descriptive message: *** Exception: The impossible happened! May 7, 2009 at 5:39
  • Yeah, reminds me of when I was very new to programming, and I'd have comments like "You should never reach this line". :) May 7, 2009 at 7:59
  • 2
    The downside of this approach is if you add more cases to your sum data type, then the compiler will not remind you to update the appropriate functions. Aug 4, 2016 at 15:33
13

You can resolve the warning in this special case by doing this:

gb_groupBy p input = foldr step [] input
   where
     step item acc = case acc of
        []                           -> [[item]]
        (xs:xss)                      -> if p (head xs) item
                                         then  (item:xs):xss
                                         else [item]:acc

The pattern matching is then complete, and the "impossible" condition of an empty list at the head of the accumulator would cause a runtime error but no warning.

Another way of looking at the more general problem of incomplete pattern matchings is to see them as a "code smell", i.e. an indication that we're trying to solve a problem in a suboptimal, or non-Haskellish, way, and try to rewrite our functions.

Implementing groupBy with a foldr makes it impossible to apply it to an infinite list, which is a design goal that the Haskell List functions try to achieve wherever semantically reasonable. Consider

take 5 $ groupBy (==) someFunctionDerivingAnInfiniteList

If the first 5 groups w.r.t. equality are finite, lazy evaluation will terminate. This is something you can't do in a strictly evaluated language. Even if you don't work with infinite lists, writing functions like this will yield better performance on long lists, or avoid the stack overflow that occurs when evaluating expressions like

take 5 $ gb_groupBy (==) [1..1000000]

In List.hs, groupBy is implemented like this:

groupBy         :: (a -> a -> Bool) -> [a] -> [[a]]
groupBy _  []       =  []
groupBy eq (x:xs)   =  (x:ys) : groupBy eq zs
                           where (ys,zs) = span (eq x) xs

This enables the interpreter/compiler to evaluate only the parts of the computation necessary for the result. span yields a pair of lists, where the first consists of (consecutive) elements from the head of the list all satisfying a predicate, and the second is the rest of the list. It's also implemented to work on infinite lists.

2
  • >This is something you can't do in a strictly evaluated language This can be done in any Turing-complete language... And sometimes even not too hard. For example, you can easily model "infinite" lists even in Java. Sep 12, 2013 at 17:33
  • 1
    Turing computation refers to what kind of computation you can do, not how you specify it, the latter being the obvious scope of my answer. Of course you can cobble something together with, say, Guava collection utilities in Java, or more elegantly, build something using LINQ in .NET. But this requires collections that don't just implement Iterable or IEnumerable, but explicitly enable lazy computation, e.g. by implementing Guava's AbstractIterator or the yield keyword in C#. In Haskell, everything returning a collection can be used lazily, without further ado.
    – Christoph
    Sep 17, 2013 at 18:55
9

I find exhaustiveness checking on case patterns indispensible. I try never to use _ in a case at top level, because _ matches everything, and by using it you vitiate the value of exhaustiveness checking. This is less important with lists but critical important with user-defined algebraic data types, because I want to be able to add a new constructor and have the compiler barf on all the missing cases. For this reason I always compile with -Werror turned on, so there is no way I can leave out a case.

As observed, your code can be extended with this case

[] : _ -> error "this can't happen"

Internally, GHC has a panic function, which unlike error will give source coordinates, but I looked at the implementation and couldn't make head or tail of it.

4
  • 2
    I really like that as a guideline. When programming in C#, I've often wished for something like "exhaustiveness checking". For example, if I had an enum, and a case statement to handle each enum member, I wanted to be able to tell the compiler "make sure I've covered all the cases". I had no idea that such a concept would be part of the foundation of Haskell and other functional langs. May 8, 2009 at 1:03
  • Oh yes, I always feel guilty when using enums and switch. But its so much more concise than creating a whole class hierarchy and splitting up one serious method into many tiny virtual methods. Jan 27, 2010 at 18:29
  • Yeah. I'm a big believer in polymorhism, but even aside from that, there are cases where you want to "fork" on a value by breaking it down into subcategories (less than 3, 3 or higher but odd, and 3 or higher but even). If you express it incorrectly, you have "boundary" errors. But the compiler could easily catch that for you if it knew you were trying to cover all the possible ranges. And that's one of the things pattern matching in a lot of the functional languages does. Mar 23, 2010 at 23:41
  • 2
    Wow, Norman, it's almost a year later and only now am I getting your pun. I guess the first time I read it I didn't make head or tail of it :) Apr 28, 2010 at 22:17
4

To follow up on my earlier comment, I realised that there is a way to acknowledge the missing case but still get a useful error with file/line number. It's not ideal as it'll only appear in unoptimized builds, though (see here).

...
[]:xs -> assert False (error "unreachable because I know everything")
1
  • Nice. Thanks for the follow-up. May 7, 2009 at 18:18
2

The type system is your friend, and the warning is letting you know your function has cracks. The very best approach is to go for a cleaner, more elegant fit between types.

Consider ghc's definition of groupBy:

groupBy                 :: (a -> a -> Bool) -> [a] -> [[a]]
groupBy _  []           =  []
groupBy eq (x:xs)       =  (x:ys) : groupBy eq zs
                           where (ys,zs) = span (eq x) xs
1

My point of view is that an impossible case is undefined.
If it's undefined we have a function for it: the cunningly named undefined.

Complete your matching with the likes of:

_ -> undefined

And there you have it!

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