In Haskell, I'd be wrapping this code in some combination of monads, using Maybe's and Either's and translating and propagating errors as necessary. In the end, it all gets to an IO monad where I am able to output the status to the user.
In another language, I simply throw an exception and catch in the appropriate place. Straightforward. I don't spend much time in cognitive limbo trying to unravel what combination of mechanisms I need.
I wouldn't say you're necessarily approaching it wrong. Rather, your mistake is in thinking that these two scenarios are different; they're not.
To "simply throw and catch" is equivalent to imposing upon your entire program the exact same conceptual structure as some combination of Haskell's error-handling methods. The exact combination depends on the error-handling systems of the language you're comparing it to, which points to why Haskell seems more complicated: It lets you mix and match error handling structures based on need, rather than giving you an implicit, one-size-fits-most solution.
So, if you need a particular style of error handling, you use it; and you use it for only the code that needs it. Code that doesn't need it--due to neither generating nor handling the relevant sorts of errors--is marked as such, meaning you can use that code without worrying about that sort of error being created.
On the subject of syntactic clumsiness, that's an awkward subject. In theory, it should be painless, but:
- Haskell has been a research-driven language for a while, and in its early days many things were still in flux and useful idioms hadn't been popularized yet, so old code floating around is likely to be a poor role model
- Some libraries are not as flexible as they could be in how errors are handled, either due to fossilization of old code as above, or just lack of polish
- I'm not aware of any guides on how to best structure new code for error handling, so newcomers are left to their own devices
I'd guess that chances are you're "doing it wrong" somehow, and could avoid most of that syntactic clutter, but that it's probably not reasonable to expect you (or any average Haskell programmer) to find the best approaches on their own.
As far as monad transformer stacks go, I think the standard approach is to
newtype the entire stack for your application, derive or implement instances for the relevant type classes (e.g.,
MonadError), then use the type class's functions which won't generally need
lifting. Monadic functions you write for the core of your application should all use the
newtyped stack, so won't need lifting, either. About the only low-semantic-meaning thing you can't avoid is
liftIO, I think.
Dealing with large stacks of transformers can be an actual headache, but only when there's a lot of nested layers of different transformers (pile up alternating layers of
ErrorT with a
ContT tossed in the middle, then just try to tell me what your code will actually do). This is rarely what you actually want, though.
Edit: As a minor addendum, I want to bring attention to more general point that occurred to me while writing a couple comments.
As I remarked and @sclv demonstrated nicely, correct error-handling really is that complicated. All you can do is shuffle that complexity around, not eliminate it, because no matter what you're performing multiple operations that can produce errors independently and your program needs to handle every possible combination somehow, even if that "handling" is to simply fall over and die.
That said, Haskell really does differ intrinsically from most languages in one regard: Generally, error-handling is both explicit and first-class, meaning that everything is out in the open and can be manipulated freely. The flip side of this is a loss of implicit error-handling, meaning that even if all you want is to print an error message and die, you have to do so explicitly. So actually doing error-handling is easier in Haskell, because of first-class abstractions for it, but ignoring errors is harder. However, that sort of "all hands abandon ship" error non-handling is almost never correct in any sort of real-world, production use, which is why it seems like awkwardness gets brushed aside.
So, while it's true that things are more complicated at first when you need to deal with errors explicitly, the important thing is to remember that that's all there is to it. Once you learn how to use the proper error-handling abstractions, the complexity pretty much hits a plateau and doesn't really get significantly harder as a program expands; and the more you use those abstractions the more natural they become.