| Maintainer | gtk2hs-users@lists.sourceforge.net |
|---|---|
| Stability | provisional |
| Portability | portable (depends on GHC) |
| Safe Haskell | None |
| Language | Haskell98 |
System.Glib.GError
Contents
Description
- data GError = GError !GErrorDomain !GErrorCode !GErrorMessage
- type GErrorDomain = GQuark
- type GErrorCode = Int
- type GErrorMessage = Text
- catchGErrorJust :: GErrorClass err => err -> IO a -> (GErrorMessage -> IO a) -> IO a
- catchGErrorJustDomain :: GErrorClass err => IO a -> (err -> GErrorMessage -> IO a) -> IO a
- handleGErrorJust :: GErrorClass err => err -> (GErrorMessage -> IO a) -> IO a -> IO a
- handleGErrorJustDomain :: GErrorClass err => (err -> GErrorMessage -> IO a) -> IO a -> IO a
- catchGError :: IO a -> (GError -> IO a) -> IO a
- handleGError :: (GError -> IO a) -> IO a -> IO a
- failOnGError :: IO a -> IO a
- throwGError :: GError -> IO a
- class Enum err => GErrorClass err where
- propagateGError :: (Ptr (Ptr ()) -> IO a) -> IO a
- checkGError :: (Ptr (Ptr ()) -> IO a) -> (GError -> IO a) -> IO a
Data types
A GError consists of a domain, code and a human readable message.
Constructors
| GError !GErrorDomain !GErrorCode !GErrorMessage |
type GErrorDomain = GQuark Source #
A code used to identify the 'namespace' of the error. Within each error domain all the error codes are defined in an enumeration. Each gtk/gnome module that uses GErrors has its own error domain. The rationale behind using error domains is so that each module can organise its own error codes without having to coordinate on a global error code list.
type GErrorCode = Int Source #
A code to identify a specific error within a given GErrorDomain. Most of
time you will not need to deal with this raw code since there is an
enumeration type for each error domain. Of course which enumeraton to use
depends on the error domain, but if you use catchGErrorJustDomain or
handleGErrorJustDomain, this is worked out for you automatically.
type GErrorMessage = Text Source #
A human readable error message.
Catching GError exceptions
To catch GError exceptions thrown by Gtk2Hs functions use the
catchGError* or handleGError* functions. They work in a similar way to
the standard catch and handle
functions.
catchGError / handleGError catches all GError exceptions, you provide
a handler function that gets given the GError if an exception was thrown.
This is the most general but is probably not what you want most of the
time. It just gives you the raw error code rather than a Haskell
enumeration of the error codes. Most of the time you will only want to
catch a specific error or any error from a specific error domain. To
catch just a single specific error use
catchGErrorJust / handleGErrorJust. To catch any error in a
particular error domain use catchGErrorJustDomain /
handleGErrorJustDomain
Arguments
| :: GErrorClass err | |
| => err | The error to catch |
| -> IO a | The computation to run |
| -> (GErrorMessage -> IO a) | Handler to invoke if an exception is raised |
| -> IO a |
This will catch just a specific GError exception. If you need to catch a
range of related errors, catchGErrorJustDomain is probably more
appropriate. Example:
do image <- catchGErrorJust PixbufErrorCorruptImage loadImage (\errorMessage -> do log errorMessage return mssingImagePlaceholder)
catchGErrorJustDomain Source #
Arguments
| :: GErrorClass err | |
| => IO a | The computation to run |
| -> (err -> GErrorMessage -> IO a) | Handler to invoke if an exception is raised |
| -> IO a |
Catch all GErrors from a particular error domain. The handler function should just deal with one error enumeration type. If you need to catch errors from more than one error domain, use this function twice with an appropriate handler functions for each.
catchGErrorJustDomain loadImage (\err message -> case err of PixbufErrorCorruptImage -> ... PixbufErrorInsufficientMemory -> ... PixbufErrorUnknownType -> ... _ -> ...)
handleGErrorJust :: GErrorClass err => err -> (GErrorMessage -> IO a) -> IO a -> IO a Source #
A verson of handleGErrorJust with the arguments swapped around.
handleGErrorJustDomain :: GErrorClass err => (err -> GErrorMessage -> IO a) -> IO a -> IO a Source #
A verson of catchGErrorJustDomain with the arguments swapped around.
Deprecated
Arguments
| :: IO a | The computation to run |
| -> (GError -> IO a) | Handler to invoke if an exception is raised |
| -> IO a |
Deprecated: Use ordinary Control.Exception.catch
This will catch any GError exception. The handler function will receive the
raw GError. This is probably only useful when you want to take some action
that does not depend on which GError exception has occured, otherwise it
would be better to use either catchGErrorJust or catchGErrorJustDomain.
For example:
catchGError (do ... ...) (\(GError dom code msg) -> fail msg)
handleGError :: (GError -> IO a) -> IO a -> IO a Source #
Deprecated: Use ordinary Control.Exception.handle
A verson of catchGError with the arguments swapped around.
handleGError (\(GError dom code msg) -> ...) $ ...
failOnGError :: IO a -> IO a Source #
Catch all GError exceptions and convert them into a general failure.
throwGError :: GError -> IO a Source #
Deprecated: Use ordinary Control.Exception.throw
Use this if you need to explicitly throw a GError or re-throw an existing GError that you do not wish to handle.
Checking for GErrors returned by glib/gtk functions
- Note, these functions are only useful to implementors
If you are wrapping a new API that reports GErrors you should probably
use propagateGError to convert the GError into an exception. You should
also note in the documentation for the function that it throws GError
exceptions and the Haskell enumeration for the expected glib GError
domain(s), so that users know what exceptions they might want to catch.
If you think it is more appropriate to use an alternate return value (eg
Either/Maybe) then you should use checkGError.
class Enum err => GErrorClass err where Source #
Each error domain's error enumeration type should be an instance of this
class. This class helps to hide the raw error and domain codes from the
user. This interface should be implemented by calling the approrpiate
{error_domain}_error_quark. It is safe to use a pure FFI call for this.
Example for PixbufError:
instance GErrorClass PixbufError where
gerrorDomain _ = {#call pure unsafe pixbuf_error_quark#}Minimal complete definition
Methods
gerrorDomain :: err -> GErrorDomain Source #
propagateGError :: (Ptr (Ptr ()) -> IO a) -> IO a Source #
Glib functions which report GErrors take as a parameter a GError
**error. Use this function to supply such a parameter. It checks if an
error was reported and if so throws it as a Haskell exception.
Example of use:
propagateGError $ \gerrorPtr ->
{# call g_some_function_that_might_return_an_error #} a b gerrorPtrcheckGError :: (Ptr (Ptr ()) -> IO a) -> (GError -> IO a) -> IO a Source #
Like propagateGError but instead of throwing the GError as an exception
handles the error immediately using the supplied error handler.
Example of use:
checkGError
(\gerrorPtr -> {# call g_some_function_that_might_return_an_error #} a b gerrorPtr)
(\(GError domain code msg) -> ...)