FP Complete


The content below is still correct, but has been absorbed into the more comprehensive safe exception handling tutorial document instead. I recommend reading that, which provides more information and more up-to-date library references.

Over the years, I’ve written a number of different documents, tutorials, comments, and libraries on how to do proper exception handling in Haskell. Most of this has culminated in the creation of safe-exceptions library, which I strongly recommend everyone use. That library contains a full tutorial which explains many of the more subtle points of exceptions, and describes how exceptions are handled by that library.

Overall, I consider that library uncontroversial, simply addressing the reality of exceptions in GHC today. This blog post is the opinionated part: how I recommend you use exceptions in Haskell, and how to structure your code around them. There are dissenting opinions, which is why this is an opinion blog post instead of library documentation. However, in my experience, these approaches are the best way to make your code robust.

This blog post is also part of the FP Complete Haskell Syllabus and part of our Haskell training.

The IO contract

A commonly stated position in the Haskell community around exceptions goes something like “all exceptions should be explicit at the type level, and async exceptions are terrible.” We can argue as much as we want about this point in a theoretical sense. However, practically, it is irrelevant, because GHC has already chosen a stance on this: it supports async exceptions, and all code that runs in IO can have exceptions of any type which is an instance of Exception.

I’d go a step further, and say not only are we stuck with GHC’s decisions, but GHC’s decisions are a great point in the design space. I’ll explain that below.

So take as a given: any code in IO can throw a runtime exception, and any thread can be killed at any time by an asynchronous exception.

Let’s identify a few anti-patterns in Haskell exception handling, and then move on to recommended practices.

The bad

ExceptT IO anti-pattern

A common (bad) design pattern I see is something like the following:

myFunction :: String -> ExceptT MyException IO Int

There are (at least) three problems with this:

  1. It’s non-composable. If someone else has a separate exception type HisException, these two functions do not easily compose.
  2. It gives an implication which is almost certainly false, namely: the only exception that can be thrown from this function is MyException. Almost any IO code in there will have the ability to throw some other type of exception, and additionally, almost any async exception can be thrown even if no synchronous exception is possible.
  3. You haven’t limited the possibility of exceptions, you’ve only added one extra avenue by which an exception can be thrown. myFunction can now either throwE or liftIO . throwIO.

It is almost always wrong to wrap an ExceptT, EitherT, or ErrorT around an IO-based transformer stack.

Separate issue: it’s also almost always a bad idea to have such a concrete transformer stack used in a public-facing API. It’s usually better to express a function in terms of typeclass requirements, using mtl typeclasses as necessary.

A similar pattern is

myFunction :: String -> ExceptT Text IO Int

This is usually done with the idea that in the future the error type will be changed from Text to something like MyException. However, Text may end up sticking around forever because it helps avoid the composition problems of a real data type. However that leads to expressing useful error data types as unstructured Text.

Generally the solution to the ExceptT IO anti-pattern is to return an Either from more functions and throw an exception for uncommon errors. Note that returning Either from ExceptT IO means there are now 3 distinct sources of errors in just one function.

Please note that using ExceptT, etc with a non-IO base monad (for example with pure code) is a perfectly fine pattern.

Mask-them-all anti-pattern

This anti-pattern goes like this: remembering to deal with async exceptions everywhere is hard, so I’ll just mask them all.

Every time you do this, 17 kittens are mauled to death by the loch ness monster.

Async exceptions may be annoying, but they are vital to keeping a system functioning correctly. The timeout function uses them to great benefit. The Warp webserver bases all of its slowloris protection on async exceptions. The cancel function from the async package will hang indefinitely if async exceptions are masked. Et cetera et cetera.

Are async exceptions difficult to work with? Sometimes, yes. Deal with it anyway. Best practices include:

The good

MonadThrow

Consider the following function:

foo <- lookup "foo" m
bar <- lookup "bar" m
baz <- lookup "baz" m
f foo bar baz

If this function returns Nothing, we have no idea why. It could be because:

  1. “foo” wasn’t in the map.
  2. “bar” wasn’t in the map.
  3. “baz” wasn’t in the map.
  4. f returned Nothing.

The problem is that we’ve thrown away a lot of information by having our functions return Maybe. Instead, wouldn’t it be nice if the types of our functions were:

lookup :: Eq k => k -> [(k, v)] -> Either (KeyNotFound k) v

f :: SomeVal -> SomeVal -> SomeVal -> Either F'sExceptionType F'sResult

The problem is that these types don’t unify. Also, it’s commonly the case that we really don’t need to know about why a lookup failed, we just need to deal with it. For those cases, Maybe is better.

The solution to this is the MonadThrow typeclass from the exceptions package. With that, we would write the type signatures as:

lookup :: (MonadThrow m, Eq k) => k -> [(k, v)] -> m v
f :: MonadThrow m => SomeVal -> SomeVal -> SomeVal -> m F'sResult

Versus the Either signature, we lose some information, namely the type of exception that could be thrown. However, we gain composability and unification with Maybe (as well as many other useful instances of MonadThrow, like IO).

The MonadThrow typeclass is a tradeoff, but it’s a well thought out tradeoff, and usually the right one. It’s also in line with Haskell’s runtime exception system, which does not capture the types of exceptions that can be thrown.

Transformers

The following type signature is overly restrictive:

foo :: Int -> IO String

This can always be generalized with a usage of liftIO to:

foo :: MonadIO m => Int -> m String

This allows our function to easily work with any transformer on top of IO. However, given how easy it is to apply liftIO, it’s not too horrible a restriction. However, consider this function:

bar :: FilePath -> (Handle -> IO a) -> IO a

If you want your inner function to live in a transformer on top of IO, you’ll find it difficult to make it work. It can be done with lifted-base, but it’s non-trivial. Instead, it’s much better to express this function in terms of functions from either the safe-exceptions library, and get the following more generalized type signatures:

bar :: (MonadIO m, MonadMask m) => FilePath -> (Handle -> m a) -> m a

This doesn’t just apply to exception handling, but also to dealing with things like forking threads. Another thing to consider in these cases is to use the Acquire type from resourcet.

Custom exception types

The following is bad practice:

foo = do
    if x then return y else error "something bad happened"

The problem is the usage of arbitrary string-based error messages. This makes it difficult to handle this exceptional case directly in a higher level in the call stack. Instead, despite the boilerplate overhead involved, it’s best to define a custom exception type:

data SomethingBad = SomethingBad
    deriving Typeable
instance Show SomethingBad where
    show SomethingBad = "something bad happened"
instance Exception SomethingBad
foo = do
    if x then return y else throwM SomethingBad

Now it’s trivial to catch the SomethingBad exception type at a higher level. Additionally, throwM gives better exception ordering guarantees than error, which creates an exception in a pure value that needs to be evaluated before it’s thrown.

One sore point is that some people strongly oppose a Show instance like this. This is an open discussion, but for now I believe we need to make the tradeoff at this point in the spectrum. The displayException method in the Exception typeclass may allow for a better resolution to this point in the future.

Why GHC’s point in the design space is great

This section is adapted from a comment I made on Reddit in 2014.

I don’t believe there is a better solution to sync exceptions, actually. That’s because most of the time I see people complaining about IO throwing exceptions, what they really mean is “this specific exception just bit me, why isn’t this exception explicit in the type signature?” To clarify my point further:

My belief is that people are simply ignoring the reality of the situation: the contract for IO implicitly includes “this action may also fail.” And I mean in every single case. Built in, runtime exceptions hide that in the type, but you need to be aware of it. Runtime exceptions also happen to be far more efficient than using ErrorT everywhere.

And as much as some people complain that exceptions are difficult to handle correctly, I highly doubt ErrorT or anything else would be easier to work with, we’d just be trading in a well-developed, mostly-understood system for a system we think we understand.

Concrete example: readLine

After a request on Twitter, I decided to add a little section here showing a pragmatic example: how should we implement a function to read a line from stdin and parse it? Let’s start with a simpler question: how about just parsing an input String? We’d like to have a meaningful exception that tells us which value didn’t parse (the input String) and what type we tried to parse it as. We’ll implement this as a readM function:

#!/usr/bin/env stack
-- stack --resolver lts-7.8 runghc --package safe-exceptions
{-# OPTIONS_GHC -Wall -Werror #-}
import Control.Exception.Safe (Exception, MonadThrow, SomeException, throwM)
import Data.Typeable          (TypeRep, Typeable, typeRep)
import Text.Read              (readMaybe)

data ReadException = ReadException String TypeRep
  deriving (Typeable)

instance Show ReadException where
  show (ReadException s typ) = concat
    [ "Unable to parse as "
    , show typ
    , ": "
    , show s
    ]

instance Exception ReadException

readM :: (MonadThrow m, Read a, Typeable a) => String -> m a
readM s = res
  where
    res =
      case readMaybe s of
        Just x -> return x
        Nothing -> throwM $ ReadException s (typeRep res)

main :: IO ()
main = do
  print (readM "hello" :: Either SomeException Int)
  print (readM "5" :: Either SomeException Int)
  print (readM "5" :: Either SomeException Bool)

  -- Also works in plain IO
  res1 <- readM "6"
  print (res1 :: Int)
  res2 <- readM "not an int"
  print (res2 :: Int) -- will never get called

This meets our criteria of having a generalizable function to multiple monads and useful exceptions. If we now make a readLine function that reads from stdin, we have essentially two different choices of type signature:

Which one of these you choose in practice really does depend on your personal preferences. The former is much more explicit about the failure. However, in general I’d steer away from it, since – like ExceptT over IO – it gives the false impression that all failures are captured by the inner value. Still, I thought it was worth demonstrating both options:

#!/usr/bin/env stack
-- stack --resolver lts-7.8 runghc --package safe-exceptions
{-# OPTIONS_GHC -Wall -Werror #-}
import Control.Exception.Safe (Exception, MonadThrow, SomeException, throwM)
import Control.Monad          (join)
import Control.Monad.IO.Class (MonadIO, liftIO)
import Data.Typeable          (TypeRep, Typeable, typeRep)
import Text.Read              (readMaybe)

data ReadException = ReadException String TypeRep
  deriving (Typeable)

instance Show ReadException where
  show (ReadException s typ) = concat
    [ "Unable to parse as "
    , show typ
    , ": "
    , show s
    ]

instance Exception ReadException

readM :: (MonadThrow m, Read a, Typeable a) => String -> m a
readM s = res
  where
    res =
      case readMaybe s of
        Just x -> return x
        Nothing -> throwM $ ReadException s (typeRep res)

readLine1 :: (MonadIO m, MonadThrow n, Read a, Typeable a) => m (n a)
readLine1 = fmap readM (liftIO getLine)

-- Without the usage of liftIO here, we'd need both MonadIO and
-- MonadThrow constraints.
readLine2 :: (MonadIO m, Read a, Typeable a) => m a
readLine2 = liftIO (join readLine1)

main :: IO ()
main = do
  putStrLn "Enter an Int (non-runtime exception)"
  res1 <- readLine1
  print (res1 :: Either SomeException Int)
  putStrLn "Enter an Int (runtime exception)"
  res2 <- readLine2
  print (res2 :: Int)

See also

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