Is there a way to tell if a list in Haskell is infinite? The reason is that I don't want to apply functions such as length
to infinite lists.

Applying You said in a comment:
Not really. While some of us wish there were better ways to distinguish between necessarily finite and necessarily infinite data, you're always safe when you create, process, and examine lazy structures incrementally. Computing the length is clearly not incremental, but checking to see if the length is above or below some cutoff value is, and very often that's all you wanted to do anyway! A trivial case is testing for nonempty lists.
Not only is this is safe to apply to an infinite list, it's also much more efficient on finite listsit takes only constant time, instead of time linear in the length of the list. It's also how the standard library function To generalize this for length testing relative to a cutoff, you'll obviously need to examine as much of the list as the length you're comparing to. We can do exactly this, and no more, using the standard library function
Given a length The key point here is that it's better in most cases to think of lists as iterative streams, not a simple data structure. When possible you want to do things like transform, accumulate, truncate, etc., and either produce another list as output or examine only a knownfinite amount of the list, rather than trying to process the entire list in one go. If you use this approach, not only will your functions work correctly on finite and infinite lists both, but they'll also benefit more from laziness and GHC's optimizer, and be likely to run faster and use less memory. 


The Halting Problem was first proved unsolvable by assuming a Halting Oracle existed, then writing a function that did the opposite of what that oracle said would happen. Let's reproduce that here:
Now, we want to make a list
Try this out yourself in ghci with 





We don't need to solve the Halting Problem to call 'length' safely. We just need to be conservative; accept everything that has a finiteness proof, reject everything that doesn't (including many finite lists). This is exactly what type systems are for, so we use the following type (t is our element type, which we ignore):
The Finite class will only contains finite lists, so the typechecker will ensure we have a finite argument. membership of Finite will be our proof of finiteness. The "toList" function just turns Finite values into regular Haskell lists:
Now what are our instances? We know that empty lists are finite, so we make a datatype to represent them:
If we 'cons' an element on to a finite list, we get a finite list (eg. "x:xs" is finite if "xs" is finite):
Anyone calling our terminatingLength function must now prove that their list is finite, otherwise their code won't compile. This hasn't removed the Halting Problem issue, but we have shifted it to compiletime rather than runtime. The compiler may hang while trying to determine membership of Finite, but that's better than having a production program hang when it's given some unexpected data. A word of caution: Haskell's 'adhoc' polymorphism allows pretty much arbitrary instances of Finite to be declared at other points in the code, and terminatingLength will accept these as finiteness proofs even if they're not. This isn't too bad though; if someone's trying to bypass the safety mechanisms of your code, they get the errors they deserve ;) 


No  you may at best estimate. See the Halting Problem. 


There is also the possibility of separating finite and infinite lists by design and use distinct types for them. Unfortunately Haskell (unlike Agda for example) doesn't allow you to enforce that a data structure is always finite, you can employ techniques of total functional programming to ensure that. And you can declare infinite lists (AKA streams) as
which doesn't have any way how to terminate a sequence (it's basically a list without 

