Catch exceptions that match a given Prism (or any Getter, really).

>>> catching _AssertionFailed (assert False (return "uncaught")) $ \ _ -> return "caught"
"caught"

 catching :: MonadCatchIO m => Prism' SomeException a     -> m r -> (a -> m r) -> m r
 catching :: MonadCatchIO m => Lens' SomeException a      -> m r -> (a -> m r) -> m r
 catching :: MonadCatchIO m => Traversal' SomeException a -> m r -> (a -> m r) -> m r
 catching :: MonadCatchIO m => Iso' SomeException a       -> m r -> (a -> m r) -> m r
 catching :: MonadCatchIO m => Getter SomeException a     -> m r -> (a -> m r) -> m r
 catching :: MonadCatchIO m => Fold SomeException a       -> m r -> (a -> m r) -> m r

Catch exceptions that match a given Prism (or any Getter), discarding the information about the match. This is particuarly useful when you have a Prism' e () where the result of the Prism or Fold isn't particularly valuable, just the fact that it matches.

>>> catching_ _AssertionFailed (assert False (return "uncaught")) $ return "caught"
"caught"

 catching_ :: MonadCatchIO m => Prism' SomeException a     -> m r -> m r -> m r
 catching_ :: MonadCatchIO m => Lens' SomeException a      -> m r -> m r -> m r
 catching_ :: MonadCatchIO m => Traversal' SomeException a -> m r -> m r -> m r
 catching_ :: MonadCatchIO m => Iso' SomeException a       -> m r -> m r -> m r
 catching_ :: MonadCatchIO m => Getter SomeException a     -> m r -> m r -> m r
 catching_ :: MonadCatchIO m => Fold SomeException a       -> m r -> m r -> m r

A version of catching with the arguments swapped around; useful in situations where the code for the handler is shorter.

>>> handling _NonTermination (\_ -> return "caught") $ throwIO NonTermination
"caught"

 handling :: MonadCatchIO m => Prism' SomeException a     -> (a -> m r) -> m r -> m r
 handling :: MonadCatchIO m => Lens' SomeException a      -> (a -> m r) -> m r -> m r
 handling :: MonadCatchIO m => Traversal' SomeException a -> (a -> m r) -> m r -> m r
 handling :: MonadCatchIO m => Iso' SomeException a       -> (a -> m r) -> m r -> m r
 handling :: MonadCatchIO m => Fold SomeException a       -> (a -> m r) -> m r -> m r
 handling :: MonadCatchIO m => Getter SomeException a     -> (a -> m r) -> m r -> m r

A version of catching_ with the arguments swapped around; useful in situations where the code for the handler is shorter.

>>> handling_ _NonTermination (return "caught") $ throwIO NonTermination
"caught"

 handling_ :: MonadCatchIO m => Prism' SomeException a     -> m r -> m r -> m r
 handling_ :: MonadCatchIO m => Lens' SomeException a      -> m r -> m r -> m r
 handling_ :: MonadCatchIO m => Traversal' SomeException a -> m r -> m r -> m r
 handling_ :: MonadCatchIO m => Iso' SomeException a       -> m r -> m r -> m r
 handling_ :: MonadCatchIO m => Getter SomeException a     -> m r -> m r -> m r
 handling_ :: MonadCatchIO m => Fold SomeException a       -> m r -> m r -> m r

A variant of try that takes a Prism (or any Getter) to select which exceptions are caught (c.f. tryJust, catchJust). If the Exception does not match the predicate, it is re-thrown.

 trying :: MonadCatchIO m => Prism'     SomeException a -> m r -> m (Either a r)
 trying :: MonadCatchIO m => Lens'      SomeException a -> m r -> m (Either a r)
 trying :: MonadCatchIO m => Traversal' SomeException a -> m r -> m (Either a r)
 trying :: MonadCatchIO m => Iso'       SomeException a -> m r -> m (Either a r)
 trying :: MonadCatchIO m => Getter     SomeException a -> m r -> m (Either a r)
 trying :: MonadCatchIO m => Fold       SomeException a -> m r -> m (Either a r)

Throw an Exception described by a Prism. Exceptions may be thrown from purely functional code, but may only be caught within the IO Monad.

 throwing l ≡ reviews l throw

 throwing :: Prism' SomeException t -> t -> a
 throwing :: Iso' SomeException t   -> t -> a

A variant of throwing that can only be used within the IO Monad (or any other MonadCatchIO instance) to throw an Exception described by a Prism.

Although throwingM has a type that is a specialization of the type of throwing, the two functions are subtly different:

 throwing l e `seq` x  ≡ throwing e
 throwingM l e `seq` x ≡ x

The first example will cause the Exception e to be raised, whereas the second one won't. In fact, throwingM will only cause an Exception to be raised when it is used within the MonadCatchIO instance. The throwingM variant should be used in preference to throwing to raise an Exception within the Monad because it guarantees ordering with respect to other monadic operations, whereas throwing does not.

 throwingM l ≡ reviews l throw

 throwingM :: MonadCatchIO m => Prism' SomeException t -> t -> m a
 throwingM :: MonadCatchIO m => Iso' SomeException t   -> t -> m a

throwingTo raises an Exception specified by a Prism in the target thread.

 throwingTo thread l ≡ reviews l (throwTo thread)

 throwingTo :: ThreadId -> Prism' SomeException t -> t -> m a
 throwingTo :: ThreadId -> Iso' SomeException t   -> t -> m a

Traverse the strongly typed Exception contained in SomeException where the type of your function matches the desired Exception.

 exception :: (Applicative f, Exception a, Exception b)
           => (a -> f b) -> SomeException -> f SomeException

Both MonadCatchIO-transformers and Control.Exception provide a Handler type.

This lets us write combinators to build handlers that are agnostic about the choice of which of these they use.

Exceptions that occur in the IO Monad. An IOException records a more specific error type, a descriptive string and maybe the handle that was used when the error was flagged.

Due to their richer structure relative to other exceptions, these have a more carefully overloaded signature.

Arithmetic exceptions.

Handle arithmetic _Overflow.

 _Overflow ≡ _ArithException . _Overflow

 _Overflow :: Prism' ArithException ArithException
 _Overflow :: Prism' SomeException  ArithException

Handle arithmetic _Underflow.

 _Underflow ≡ _ArithException . _Underflow

 _Underflow :: Prism' ArithException ArithException
 _Underflow :: Prism' SomeException  ArithException

Handle arithmetic loss of precision.

 _LossOfPrecision ≡ _ArithException . _LossOfPrecision

 _LossOfPrecision :: Prism' ArithException ArithException
 _LossOfPrecision :: Prism' SomeException  ArithException

Handle division by zero.

 _DivideByZero ≡ _ArithException . _DivideByZero

 _DivideByZero :: Prism' ArithException ArithException
 _DivideByZero :: Prism' SomeException  ArithException

Handle exceptional _Denormalized floating point.

 _Denormal ≡ _ArithException . _Denormal

 _Denormal :: Prism' ArithException ArithException
 _Denormal :: Prism' SomeException  ArithException

Added in base 4.6 in response to this libraries discussion:

http://haskell.1045720.n5.nabble.com/Data-Ratio-and-exceptions-td5711246.html

 _RatioZeroDenominator ≡ _ArithException . _RatioZeroDenominator

 _RatioZeroDenominator :: Prism' ArithException ArithException
 _RatioZeroDenominator :: Prism' SomeException  ArithException

Exceptions generated by array operations.

An attempt was made to index an array outside its declared bounds.

 _IndexOutOfBounds ≡ _ArrayException . _IndexOutOfBounds

 _IndexOutOfBounds :: Prism' ArrayException String
 _IndexOutOfBounds :: Prism' SomeException  String

An attempt was made to evaluate an element of an array that had not been initialized.

 _UndefinedElement ≡ _ArrayException . _UndefinedElement

 _UndefinedElement :: Prism' ArrayException String
 _UndefinedElement :: Prism' SomeException  String

assert was applied to False.

Asynchronous exceptions.

The current thread's stack exceeded its limit. Since an Exception has been raised, the thread's stack will certainly be below its limit again, but the programmer should take remedial action immediately.

 _StackOverflow :: Prism' AsyncException ()
 _StackOverflow :: Prism' SomeException  ()

The program's heap is reaching its limit, and the program should take action to reduce the amount of live data it has.

Notes:

• It is undefined which thread receives this Exception.
• GHC currently does not throw HeapOverflow exceptions.

 _HeapOverflow :: Prism' AsyncException ()
 _HeapOverflow :: Prism' SomeException  ()

This Exception is raised by another thread calling killThread, or by the system if it needs to terminate the thread for some reason.

 _ThreadKilled :: Prism' AsyncException ()
 _ThreadKilled :: Prism' SomeException  ()

This Exception is raised by default in the main thread of the program when the user requests to terminate the program via the usual mechanism(s) (e.g. Control-C in the console).

 _UserInterrupt :: Prism' AsyncException ()
 _UserInterrupt :: Prism' SomeException  ()

Thrown when the runtime system detects that the computation is guaranteed not to terminate. Note that there is no guarantee that the runtime system will notice whether any given computation is guaranteed to terminate or not.

Thrown when the program attempts to call atomically, from the STM package, inside another call to atomically.

The thread is blocked on an MVar, but there are no other references to the MVar so it can't ever continue.

The thread is waiting to retry an STM transaction, but there are no other references to any TVars involved, so it can't ever continue.

There are no runnable threads, so the program is deadlocked. The Deadlock Exception is raised in the main thread only.

A class method without a definition (neither a default definition, nor a definition in the appropriate instance) was called.

A pattern match failed.

An uninitialised record field was used.

A record selector was applied to a constructor without the appropriate field. This can only happen with a datatype with multiple constructors, where some fields are in one constructor but not another.

A record update was performed on a constructor without the appropriate field. This can only happen with a datatype with multiple constructors, where some fields are in one constructor but not another.

This is thrown when the user calls error.

This Exception is thrown by lens when the user somehow manages to rethrow an internal HandlingException.