In Haskell, you can throw an exception from purely functional code, but you can only catch in IO code.
- Can you catch in other contexts or only the IO monad?
- How do other purely functional languages handle it?
Because throwing an exception inside a function doesn't make that function's result dependent on anything but the argument values and the definition of the function; the function remains pure. OTOH catching an exception inside a function does (or at least can) make that function no longer a pure function.
I'm going to look at two kinds of exception. The first is nondeterministic; such exceptions arise unpredictably at runtime, and include things like out of memory errors. The existence of these exceptions is not included in the meaning of the functions that might generate them. They're just an unpleasant fact of life we have to deal with because we have actual physical machines in the real world, which don't always match up to the abstractions we're using to help us program them.
If a function throws such an exception, it means that that one particular attempt to evaluate the function failed to produce a value. It doesn't necessarily mean that the function's result is undefined (on the arguments it was invoked on this time), but the system was unable to produce the result.
If you could catch such an exception within a pure caller, you could do things like have a function that returns one (non-bottom) value when a sub-computation completes successfully, and another when it runs out of memory. This doesn't make sense as a pure function; the value computed by a function call should be uniquely determined by the values of its arguments and the definition of the function. Being able to return something different depending on whether the sub-computation ran out of memory makes the return value dependent on something else (how much memory is available on the physical machine, what other programs are running, the operating system and its policies, etc etc); by definition a function which can behave this way is not pure and can't (normally) exist in Haskell.
Because of purely operational failures, we do have to allow that evaluating a function may produce bottom instead of the value it "should" have produced. That doesn't completely ruin our semantic interpretation of Haskell programs, because we know the bottom will cause all the callers to produce bottom as well (unless they didn't need the value that was supposed to be computed, but in that case non-strict evaluation implies that the system never would have tried to evaluate this function and failed). That sounds bad, but when we get out to a computation in the
But what about deterministic exceptions? Here I'm talking about exceptions that are always thrown when evaluating a particular function on a particular set of arguments. Such exceptions include divide-by-zero errors, as well as any exception explicitly thrown from a pure function (since its result can only depend on its arguments and its definition, if it evaluates to a throw once it will always evaluate to the same throw for the same arguments).
It might seem like this class of exceptions should be catchable in pure code. After all, the value of
Here we get back to the point larsmans made in a comment. If a pure function can observe which exception it gets from
Again, the definition of a pure function is that only information which comes into a function through its arguments (and its definition) should affect its result. In the case of non-
As for your second dot point, no, other monads wouldn't work for catching exceptions. All the same arguments apply; computations producing
Remember, there's nothing particularly special about monads. They don't work any differently than other parts of Haskell. The monad typeclass is defined in ordinary Haskell code, as are almost all monad implementations. All the same rules that apply to ordinary Haskell code apply to all monads. It's
As for how other pure languages handle exception catching, the only other language with enforced purity that I have experience with is Mercury. Mercury does it a little differently from Haskell, and you can catch exceptions in pure code.
Mercury is a logic programming language, so rather than being built on functions Mercury programs are built from predicates; a call to a predicate can have zero, one, or more solutions (if you're familiar with programming in the list monad to get nondeterminism, it's a little bit like the entire language is in the list monad). Operationally, Mercury execution uses backtracking to recursively enumerate all possible solutions to a predicate, but the semantics of a nondeterministic predicate is that it simply has a set of solutions for each set of its input arguments, as opposed to a Haskell function which calculates a single result value for each set of its input arguments. Like Haskell, Mercury is pure (including I/O, though it uses a slightly different mechanism), so each call to a predicate must uniquely determine a single solution set, which depends only on the arguments and the definition of the predicate.
Mercury tracks the "determinism" of each predicate. Predicates which always result in exactly one solution are called
Catching an exception with a
Because the compiler keeps track of the determinism, it will not allow you to call
So how on earth is this useful? Well, you can have
It's important that
 Unless evaluating it encounters a nondeterministic error first. Real life's a pain.
 Languages which merely encourage the programmer to use purity without enforcing it (such as Scala) tend to just let you catch exceptions wherever you want, same as they allow you to do I/O wherever you want.
 Note that the "committed choice" concept is not how Mercury handles pure I/O. For that, Mercury uses unique types, which is orthogonal to the "committed choice" determinism class.
However, I can also see why reasons such as observing evaluation order or breaking monotonicity may not be persuasive on an intuitive level; it's difficult to imagine how either could cause much harm in the vast majority of code. As such, it might help to recall that exception handling is a control flow structure of a distinctly non-local variety, and being able to catch exceptions in pure code would allow (mis)using them for that purpose.
Allow me to illustrate exactly what horror this entails.
First, we define an exception type to use, and a version of
This will let us throw any
Yes, that actually works, with the caveat that it requires any use of the continuation to be evaluated whenever the whole expression is. Keep that in mind if you try this out, or just use
Escaping from inside a
Note the need to force evaluation.
Now, let us never speak of this again.