The Arrays&References library supports Hugs 2003-2006 and GHC 6.4. It includes the following features:
This substitutes the numerous "fast mutable Ints", "fast mutable Bools" and "fast mutable Ptrs" ghc-specific modules that are used in almost any large project. In contrast to them, this library mimics the well-known interface of IORef/STRef:
import Data.Ref main = do x <- newIOURef (0::Int) writeIOURef x 1 a <- readIOURef x print a
Unboxed references for the IO monad have the type "IOURef a" and operations newIOURef, readIOURef, writeIOURef. Unboxed references for the ST monad have the type "STURef s a" and operations newSTURef, readSTURef, writeSTURef.
Unboxed references can only contain values of the following types: Bool, Char, Int, Int8..Int64, Word, Word8..Word64, Float, Double, Ptr a, FunPtr a, StablePtr a. These types are members of the Unboxed class and you can implement new instances of this class by converting values of some other type (say, CChar) to values of an already supported type.
Despite all these improvements, operations with unboxed references are compiled to the same code as for any "fast mutable variables". Moreover, unboxed references are available even for Hugs, which allows simplified debugging of programs that use them. Please note that unboxed references always hold computed values, in contrast to boxed references, which can contain unevaluated thunks.
I wish to thank Simon Marlow and especially Oleg Kiselyov who proposed the idea of these references and their implementation (in particular, see )
You can find examples of using unboxed references in "Examples/URef.hs"
Sometimes you need to write code that will be compatible with both IO and ST monads, and even better with any monad that is lifted from one of these two. This is especially useful for writing library code that should be as generic as possible. Operations for arrays, for example, are ready for such a kind of usage - readArray and writeArray can work in any monad. But this is not true for references - you need to use readIORef for the IO monad, but readSTRef for the ST monad, so if you need to implement a monad-independent algorithm that uses references, you will be in trouble. This module solves this problem by providing monad-independent operations on boxed and unboxed references. So, the following routine:
test_Ref = do x <- newRef (0::Int) writeRef x 1 readRef x
can be executed in both the IO and the ST monads:
main = do a <- test_Ref print a let b = runST test_Ref print b
This example uses the boxed references; unboxed references can be used in a similar way with operations newURef, readURef, writeURef.
You can find examples of writing monad-independent routines in "Examples/Universal.hs". Another library of mine, Library/Streams, widely uses this facility to implement common functionality for streams working in different monads.
Syntax sugar for mutable types
Haskell doesn't support a convenient syntax for using mutable vars, such as references, arrays and hash tables. The library includes a module that partially simplifies their usage. For example:
main = do -- syntax sugar used for reference: x <- ref (0::Int) x += 1 x .= (*2) a <- val x print a -- syntax sugar used for array: arr <- newArray (0,9) 0 :: IO Array Int Int (arr,0) =: 1 b <- val (arr,0) print b
Basically, the module supports syntactic sugar for using the following data types: all types of references, arrays and hash tables. Also, it includes two operations to creating references - ref (=newRef) and uref (=newURef). Other operations include
=: assign += increase -= decrease .= apply a pure function to the contents .<- apply a monadic computation to the contents val return current value
The left part of these operations can be a reference, array or hash element. Code examples:
reference x += 1 (array,index) (arr,0) =: 1 (hash,key) (hash,"str") .= (*2)
You can also omit extra parentheses when indexing a two- or three-dimensional array:
(arr,0,1) =: 1
is equivalent to
(arr,(0,1)) =: 1
Note, that this module supports the array implementations included in this library, not the standard Data.Array.* modules. Module "Examples/SyntaxSugar.hs" contains further examples.
Reimplemented Arrays library
The library also includes modified implementations of Data.Array.* modules. The main benefit of these modifications is a simplified internal library structure
Nevertheless, it also includes a few user-visible changes:
- Unboxed arrays now can be used in polymorphic functions, they are defined for every element type that belongs to the classes Unboxed and HasDefaultValue (see also ). You can add new instances to these classes
- The MArray class now supports arrays with dynamic bounds. It includes monadic operation getBounds, and if you change your code to use this operation with mutable arrays instead of `bounds`, your code will also be ready to work with dynamic (resizable) arrays
- Support for dynamic (resizable) arrays is included. Their bounds can be changed either explicitly (by `resizeDynamicArray`) or implicitly (by writing to a non-existing position). The policy of automatic array expansion is selected (or disabled) on array creation.
- Unboxed arrays of Bool values occupy one byte per element (in the old implementation they used one bit per element)
- castUArray/castIOUArray/castSTUArray operations are non-monadic, require "Enum ix" and recalculate upper bounds of arrays according to the size of their elements: UArray (1,2) Word32 -> UArray (1,8) Word8
- Some operations may be slower in the new implementation, because I'm not sure that I discovered all the clever tricks used in the original library. Please test speed and report me about any problems
In other aspects, the new arrays are equivalent to the old ones. Just change "Array" to "ArrayBZ" in your import statements and enjoy! :) Directory "Examples/Array" contains demonstrations of using each array type
Changes in MArray usage
The old Arrays library contained the following definitions:
class HasBounds a where bounds :: Ix i => a i e -> (i,i) class (Monad m, HasBounds a) => MArray a e m where ...
In the new library, the MArray class is defined as:
class (Monad m) => HasMutableBounds a m where getBounds :: Ix i => a i e -> m (i,i) class (Monad m, HasMutableBounds a m) => MArray a e m where ...
This means that definitions like this will no longer work:
arrayHead :: (MArray a e m, Ix i) => a i e -> m e arrayHead marr = case bounds marr of (l,_) -> readArray marr l
because the `bounds` operation is part of HasBounds class, that is no longer a base class for MArray. What can you do to fix this problem? Either:
- Add a HasBounds restriction to the operation type:
arrayHead :: (MArray a e m, HasBounds a, Ix i) => a i e -> m e
This way, your code will become compatible with both the old and the new versions of the Arrays library, but it will work only with "old" mutable arrays and won't support dynamic arrays.
- Replace calls to the `bounds` operation with calls to `getBounds`. This way, your function will become compatible with any instance of the MArray class, including dynamic arrays:
arrayHead marr = do (l,_) <- getBounds marr readArray marr l
I should mention that, despite the fact that MArray isn't based on the HasBounds class anymore, all the old mutable array types (IOArray..StorableArray) still implement this interface. Only the new dynamic arrays don't implement it because this is impossible. So, you can use the `bounds` operation in code that works with one of "old" array constructors:
arrayHead :: IOArray i e -> IO e arrayHead marr = case bounds marr of (l,_) -> readArray marr l
Using dynamic (resizable) arrays
Just to let you know - the current implementation of dynamic arrays is very trivial: it just saves a reference (IORef or STRef) to the mutable array. When a dynamic array is resized, a new mutable array is allocated and the contents is copied. New elements are filled with the same default value as when the array was created with the newArray or newDynamicArray operation. If a dynamic array is created with newArray_ or newDynamicArray_, then new elements will be left undefined.
A dynamic array can be resized explicitly by the resizeDynamicArray operation:
resizeDynamicArray array (l,u)
where (l,u) are new array bounds. If the dynamic array was created by a newArray or newArray_ operation, it is the only way to resize it - attempts to write beyond current bounds will raise an exception:
arr <- newArray (0,-1) 99 :: IO (DynamicIOArray Int Int) resizeDynamicArray arr (0,0) writeArray arr 1 1 -- this operation raises an exception
To create an array that will be automatically resized on attempt to write beyond current bounds, you should use a newDynamicArray or newDynamicArray_ operation (the former initializes an array with a given value, while the latter leaves the array uninitialized). Their first argument determines the array expansion policy:
arr <- newDynamicArray_ growTwoTimes (0,-1) :: IO (DynamicIOArray Int Int)
This array will grow to at least two times its current size, each time automatic expansion occurs, which is determined by using the `growTwoTimes` parameter. This parameter is just an ordinary function that has the following type:
type GrowBoundsF i = (i,i) -> i -> (i,i)
This function accepts old array bounds and offending index and returns new array bounds. You can write new functions for expansion policies yourself, or use one of predefined ones:
growTwoTimes - expand array to at least two times its current size growMinimally - minimal growth that ensures inclusion of new index noGrow - disable automatic growth. This policy is used for arrays created by newArray or newArray_
Please note that not every array can work with every expansion policy and that is why I supported freedom of selection of this policy. Only the noGrow policy is compatible with every index type. The growMinimally policy by its type is compatible with any index, but it will not work for partially ordered indexes, in particular for multi-dimensional arrays. Imagine, for example, an array with the bounds (0,0)..(9,9). When you try to write to index (15,5), this expansion policy function will be unable to determine what the new bounds should be (0,0)..(15,9). So you should always provide a custom expansion policy function for partially ordered indexes. At last, the growTwoTimes policy is compatible only with indexes belonging to class Num, but it is the most useful policy of all, because it ensures that the program will not spend all its time expanding arrays. On the other hand, you can provide your own policy function that will, for example, expand an array only 1.5 times.
Dynamic arrays support the same MArray and HasMutableBounds interfaces as other mutable arrays, but they don't support the HasBounds interface.
And now about types of dynamic arrays. These types reflect all the types you can use for mutable arrays, and include DynamicIOArray, DynamicIOUArray, DynamicSTArray, DynamicSTUArray, which have the same parameters as corresponding arrays without the "Dynamic" prefix. Some examples are:
DynamicIOArray Int Double DynamicSTUArray s (Int,Int) Bool
You can also create dynamic arrays from other mutable array types working in the IO monad:
DynamicIO StorableArray Int Double
or the ST monad:
DynamicST s (STUArray s) (Int,Int) Bool
or any other monad (ask me if you need this). Btw, implementation of dynamic arrays use the monad-independent references class mentioned above.
See "Examples/Array/Dynamic.hs" for further examples on using these arrays.
Downloading and installation
You can download the latest version of the library at http://www.haskell.org/library/ArrayRef.tar.gz
The library is cabalized. To install it, run command:
Directory "Examples" contains usage examples for the library.
This wiki page is official library documentation. Please continue to improve it and add more information about using the library. Feel free to ask me about library usage via email: Bulat.Ziganshin@gmail.com