Safe Haskell | Safe-Inferred |
---|---|
Language | Haskell2010 |
The dynamically dispatched variant of the Error
effect.
Note: unless you plan to change interpretations at runtime, it's recommended to use the statically dispatched variant, i.e. Effectful.Error.Static.
Synopsis
- data Error e :: Effect where
- ThrowError :: e -> Error e m a
- CatchError :: m a -> (CallStack -> e -> m a) -> Error e m a
- runError :: Eff (Error e ': es) a -> Eff es (Either (CallStack, e) a)
- runErrorWith :: (CallStack -> e -> Eff es a) -> Eff (Error e ': es) a -> Eff es a
- runErrorNoCallStack :: Eff (Error e ': es) a -> Eff es (Either e a)
- runErrorNoCallStackWith :: (e -> Eff es a) -> Eff (Error e ': es) a -> Eff es a
- throwError :: (HasCallStack, Error e :> es) => e -> Eff es a
- catchError :: (HasCallStack, Error e :> es) => Eff es a -> (CallStack -> e -> Eff es a) -> Eff es a
- handleError :: Error e :> es => (CallStack -> e -> Eff es a) -> Eff es a -> Eff es a
- tryError :: (HasCallStack, Error e :> es) => Eff es a -> Eff es (Either (CallStack, e) a)
- type HasCallStack = ?callStack :: CallStack
- data CallStack
- getCallStack :: CallStack -> [([Char], SrcLoc)]
- prettyCallStack :: CallStack -> String
Effect
data Error e :: Effect where Source #
Provide the ability to handle errors of type e
.
ThrowError :: e -> Error e m a | |
CatchError :: m a -> (CallStack -> e -> m a) -> Error e m a |
Instances
type DispatchOf (Error e) Source # | |
Defined in Effectful.Error.Dynamic |
Handlers
runError :: Eff (Error e ': es) a -> Eff es (Either (CallStack, e) a) Source #
Handle errors of type e
(via Effectful.Error.Static).
Handle errors of type e
(via Effectful.Error.Static) with a specific
error handler.
runErrorNoCallStack :: Eff (Error e ': es) a -> Eff es (Either e a) Source #
Handle errors of type e
(via Effectful.Error.Static). In case of an
error discard the CallStack
.
runErrorNoCallStackWith Source #
Handle errors of type e
(via Effectful.Error.Static) with a specific
error handler. In case of an error discard the CallStack
.
Operations
:: (HasCallStack, Error e :> es) | |
=> e | The error. |
-> Eff es a |
Throw an error of type e
.
:: (HasCallStack, Error e :> es) | |
=> Eff es a | The inner computation. |
-> (CallStack -> e -> Eff es a) | A handler for errors in the inner computation. |
-> Eff es a |
Handle an error of type e
.
:: Error e :> es | |
=> (CallStack -> e -> Eff es a) | A handler for errors in the inner computation. |
-> Eff es a | The inner computation. |
-> Eff es a |
The same as
, which is useful in situations where the
code for the handler is shorter.flip
catchError
:: (HasCallStack, Error e :> es) | |
=> Eff es a | The inner computation. |
-> Eff es (Either (CallStack, e) a) |
Similar to catchError
, but returns an Either
result which is a Right
if no error was thrown and a Left
otherwise.
Re-exports
type HasCallStack = ?callStack :: CallStack #
Request a CallStack.
NOTE: The implicit parameter ?callStack :: CallStack
is an
implementation detail and should not be considered part of the
CallStack
API, we may decide to change the implementation in the
future.
Since: base-4.9.0.0
CallStack
s are a lightweight method of obtaining a
partial call-stack at any point in the program.
A function can request its call-site with the HasCallStack
constraint.
For example, we can define
putStrLnWithCallStack :: HasCallStack => String -> IO ()
as a variant of putStrLn
that will get its call-site and print it,
along with the string given as argument. We can access the
call-stack inside putStrLnWithCallStack
with callStack
.
>>>
:{
putStrLnWithCallStack :: HasCallStack => String -> IO () putStrLnWithCallStack msg = do putStrLn msg putStrLn (prettyCallStack callStack) :}
Thus, if we call putStrLnWithCallStack
we will get a formatted call-stack
alongside our string.
>>>
putStrLnWithCallStack "hello"
hello CallStack (from HasCallStack): putStrLnWithCallStack, called at <interactive>:... in interactive:Ghci...
GHC solves HasCallStack
constraints in three steps:
- If there is a
CallStack
in scope -- i.e. the enclosing function has aHasCallStack
constraint -- GHC will append the new call-site to the existingCallStack
. - If there is no
CallStack
in scope -- e.g. in the GHCi session above -- and the enclosing definition does not have an explicit type signature, GHC will infer aHasCallStack
constraint for the enclosing definition (subject to the monomorphism restriction). - If there is no
CallStack
in scope and the enclosing definition has an explicit type signature, GHC will solve theHasCallStack
constraint for the singletonCallStack
containing just the current call-site.
CallStack
s do not interact with the RTS and do not require compilation
with -prof
. On the other hand, as they are built up explicitly via the
HasCallStack
constraints, they will generally not contain as much
information as the simulated call-stacks maintained by the RTS.
A CallStack
is a [(String, SrcLoc)]
. The String
is the name of
function that was called, the SrcLoc
is the call-site. The list is
ordered with the most recently called function at the head.
NOTE: The intrepid user may notice that HasCallStack
is just an
alias for an implicit parameter ?callStack :: CallStack
. This is an
implementation detail and should not be considered part of the
CallStack
API, we may decide to change the implementation in the
future.
Since: base-4.8.1.0
getCallStack :: CallStack -> [([Char], SrcLoc)] #
Extract a list of call-sites from the CallStack
.
The list is ordered by most recent call.
Since: base-4.8.1.0
prettyCallStack :: CallStack -> String #
Pretty print a CallStack
.
Since: base-4.9.0.0