base-4.18.2.1: Core data structures and operations
Copyright(c) The University of Glasgow 2008
Licensesee libraries/base/LICENSE
Maintainercvs-ghc@haskell.org
Stabilityinternal
Portabilitynon-portable (GHC Extensions)
Safe HaskellUnsafe
LanguageHaskell2010

GHC.IORef

Description

The IORef type

Synopsis

Documentation

newtype IORef a Source #

A mutable variable in the IO monad.

>>> import Data.IORef
>>> r <- newIORef 0
>>> readIORef r
0
>>> writeIORef r 1
>>> readIORef r
1
>>> atomicWriteIORef r 2
>>> readIORef r
2
>>> modifyIORef' r (+ 1)
>>> readIORef r
3
>>> atomicModifyIORef' r (\a -> (a + 1, ()))
>>> readIORef r
4

See also STRef and MVar.

Constructors

IORef (STRef RealWorld a) 

Instances

Instances details
Eq (IORef a) Source #

Pointer equality.

Since: base-4.0.0.0

Instance details

Defined in GHC.IORef

Methods

(==) :: IORef a -> IORef a -> Bool Source #

(/=) :: IORef a -> IORef a -> Bool Source #

newIORef :: a -> IO (IORef a) Source #

Build a new IORef

readIORef :: IORef a -> IO a Source #

Read the value of an IORef.

Beware that the CPU executing a thread can reorder reads or writes to independent locations. See Data.IORef for more details.

writeIORef :: IORef a -> a -> IO () Source #

Write a new value into an IORef.

This function does not create a memory barrier and can be reordered with other independent reads and writes within a thread, which may cause issues for multithreaded execution. In these cases, consider using atomicWriteIORef instead. See Data.IORef for more details.

atomicModifyIORef2Lazy :: IORef a -> (a -> (a, b)) -> IO (a, (a, b)) Source #

Atomically apply a function to the contents of an IORef, installing its first component in the IORef and returning the old contents and the result of applying the function. The result of the function application (the pair) is not forced. As a result, this can lead to memory leaks. It is generally better to use atomicModifyIORef2.

atomicModifyIORef2 :: IORef a -> (a -> (a, b)) -> IO (a, (a, b)) Source #

Atomically apply a function to the contents of an IORef, installing its first component in the IORef and returning the old contents and the result of applying the function. The result of the function application (the pair) is forced, but neither of its components is.

atomicModifyIORefLazy_ :: IORef a -> (a -> a) -> IO (a, a) Source #

Atomically apply a function to the contents of an IORef and return the old and new values. The result of the function is not forced. As this can lead to a memory leak, it is usually better to use atomicModifyIORef'_.

atomicModifyIORef'_ :: IORef a -> (a -> a) -> IO (a, a) Source #

Atomically apply a function to the contents of an IORef and return the old and new values. The result of the function is forced.

atomicModifyIORefP :: IORef a -> (a -> (a, b)) -> IO b Source #

A version of atomicModifyIORef that forces the (pair) result of the function.

atomicSwapIORef :: IORef a -> a -> IO a Source #

Atomically replace the contents of an IORef, returning the old contents.

atomicModifyIORef' :: IORef a -> (a -> (a, b)) -> IO b Source #

Strict version of atomicModifyIORef. This forces both the value stored in the IORef and the value returned. The new value is installed in the IORef before the returned value is forced. So

atomicModifyIORef' ref (x -> (x+1, undefined))

will increment the IORef and then throw an exception in the calling thread.

This function imposes a memory barrier, preventing reordering; see Data.IORef for details.

Since: base-4.6.0.0