Abstactions and concrete implementations of mutable containers.
See docs and README at http://www.stackage.org/package/mutable-containers
One of Haskell's strengths is immutable data structures. These structures make it easier to reason about code, simplify concurrency and parallelism, and in some cases can improve performance by allowing sharing. However, there are still classes of problems where mutable data structures can both be more convenient, and provide a performance boost. This library is meant to provide such structures in a performant, well tested way. It also provides a simple abstraction over such data structures via typeclasses.
Before anything else, let me provide the caveats of this package:
- Don't use this package unless you have a good reason to! Immutable data structures are a better approach most of the time!
- This code is intentionally not multithread safe. If you need something like a concurrent queue, there are many options on Hackage, from
Chan
toTChan
, to chaselev-deque.
We'll first talk about the general approach to APIs in this package. Next, there are two main sets of abstractions provided, which we'll cover in the following two sections, along with their concrete implementations. Finally, we'll cover benchmarks.
API structure
The API takes heavy advantage of the PrimMonad
typeclass from the primitive package. This allows our data structures to work in both IO
and ST
code. Each data structure has an associated type, MCState
, which gives the primitive state for that structure. For example, in the case of IORef
, that state is RealWorld
, whereas for STRef s
, it would be s
. This associated type is quite similar to the PrimState
associated type from primitive, and in many type signatures you'll see an equality constraint along the lines of:
PrimState m ~ MCState c
For those who are wondering, MCState
stands for "mutable container state."
All actions are part of a typeclass, which allows for generic access to different types of structures quite easily. In addition, we provide type hint functions, such as asIORef
, which can help specify types when using such generic functions. For example, a common idiom might be:
ioref <- fmap asIORef $ newRef someVal
Wherever possible, we stick to well accepted naming and type signature standards. For example, note how closely modifyRef
and modifyRef'
match modifyIORef
and modifyIORef'
.
Single cell references
The base package provides both IORef
and STRef
as boxed mutable references, for storing a single value. The primitive package also provides MutVar
, which generalizes over both of those and works for any PrimMonad
instance. The MutableRef
typeclass in this package abstracts over all three of those. It has two associated types: MCState
for the primitive state, and RefElement
to specify what is contained by the reference.
You may be wondering: why not just take the reference as a type parameter? That wouldn't allow us to have monomorphic reference types, which may be useful under some circumstances. This is a similar motivation to how the mono-traversable
package works.
In addition to providing an abstraction over IORef
, STRef
, and MutVar
, this package provides four additional single-cell mutable references. URef
, SRef
, and BRef
all contain a 1-length mutable vector under the surface, which is unboxed, storable, and boxed, respectively. The advantage of the first two over boxed standard boxed references is that it can avoid a significant amount of allocation overhead. See the relevant Stack Overflow discussion and the benchmarks below.
While BRef
doesn't give this same advantage (since the values are still boxed), it was trivial to include it along with the other two, and does actually demonstrate a performance advantage. Unlike URef
and SRef
, there is no restriction on the type of value it can store.
The final reference type is PRef
. Unlike the other three mentioned, it doesn't use vectors at all, but instead drops down directly to a mutable bytearray to store values. This means it has slightly less overhead (no need to store the size of the vector), but also restricts the types of things that can be stored (only instances of Prim
).
You should benchmark your program to determine the most efficient reference type, but generally speaking PRef
will be most performant, followed by URef
and SRef
, and finally BRef
.
Collections
Collections allow you to push and pop values to the beginning and end of themselves. Since different data structures allow different operations, each operation goes into its own typeclass, appropriately named MutablePushFront
, MutablePushBack
, MutablePopFront
, and MutablePopBack
. There is also a parent typeclass MutableCollection
which provides:
- The
CollElement
associated type to indicate what kinds of values are in the collection. - The
newColl
function to create a new, empty collection.
The mono-traversable
package provides a typeclass IsSequence
which abstracts over sequence-like things. In particular, it provides operations for cons
, snoc
, uncons
, and unsnoc
. Using this abstraction, we can provide an instance for all of the typeclasses listed above for any mutable reference containing an instance of IsSequence
, e.g. IORef [Int]
or BRef s (Seq Double)
.
Note that the performance of some of these combinations is terrible. In particular, pushBack
or popBack
on a list requires traversing the entire list, and any push operations on a Vector
requires copying the entire contents of the vector. Caveat emptor! If you must use one of these structures, it's highly recommended to use Seq
, which gives the best overall performance.
However, in addition to these instances, this package also provides two additional data structures: double-ended queues and doubly-linked lists. The former is based around mutable vectors, and therefore as unboxed (UDeque
), storable (SDeque
), and boxed (BDeque
) variants. Doubly-linked lists have no such variety, and are simply DLList
s.
For general purpose queue-like structures, UDeque
or SDeque
is likely to give you best performance. As usual, benchmark your own program to be certain, and see the benchmark results below.
Benchmark results
The following benchmarks were performed on January 7, 2015, against version 0.2.0.
Ref benchmark
benchmarking IORef
time 4.322 μs (4.322 μs .. 4.323 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 4.322 μs (4.322 μs .. 4.323 μs)
std dev 1.401 ns (1.114 ns .. 1.802 ns)
benchmarking STRef
time 4.484 μs (4.484 μs .. 4.485 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 4.484 μs (4.484 μs .. 4.484 μs)
std dev 941.0 ps (748.5 ps .. 1.164 ns)
benchmarking MutVar
time 4.482 μs (4.482 μs .. 4.483 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 4.482 μs (4.482 μs .. 4.483 μs)
std dev 843.2 ps (707.9 ps .. 1.003 ns)
benchmarking URef
time 2.020 μs (2.019 μs .. 2.020 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 2.020 μs (2.019 μs .. 2.020 μs)
std dev 955.2 ps (592.2 ps .. 1.421 ns)
benchmarking PRef
time 2.015 μs (2.014 μs .. 2.015 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 2.014 μs (2.014 μs .. 2.015 μs)
std dev 901.3 ps (562.8 ps .. 1.238 ns)
benchmarking SRef
time 2.231 μs (2.230 μs .. 2.232 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 2.231 μs (2.230 μs .. 2.231 μs)
std dev 1.938 ns (1.589 ns .. 2.395 ns)
benchmarking BRef
time 4.279 μs (4.279 μs .. 4.279 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 4.279 μs (4.279 μs .. 4.279 μs)
std dev 1.281 ns (1.016 ns .. 1.653 ns)
Deque benchmark
benchmarking IORef [Int]
time 8.371 ms (8.362 ms .. 8.382 ms)
1.000 R² (1.000 R² .. 1.000 R²)
mean 8.386 ms (8.378 ms .. 8.398 ms)
std dev 29.25 μs (20.73 μs .. 42.47 μs)
benchmarking IORef (Seq Int)
time 142.9 μs (142.7 μs .. 143.1 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 142.7 μs (142.6 μs .. 142.9 μs)
std dev 542.8 ns (426.5 ns .. 697.0 ns)
benchmarking UDeque
time 107.5 μs (107.4 μs .. 107.6 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 107.5 μs (107.4 μs .. 107.6 μs)
std dev 227.4 ns (171.8 ns .. 297.8 ns)
benchmarking SDeque
time 97.82 μs (97.76 μs .. 97.89 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 97.82 μs (97.78 μs .. 97.89 μs)
std dev 169.5 ns (110.6 ns .. 274.5 ns)
benchmarking BDeque
time 113.5 μs (113.4 μs .. 113.6 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 113.6 μs (113.5 μs .. 113.7 μs)
std dev 300.4 ns (221.8 ns .. 424.1 ns)
benchmarking DList
time 156.5 μs (156.3 μs .. 156.6 μs)
1.000 R² (1.000 R² .. 1.000 R²)
mean 156.4 μs (156.3 μs .. 156.6 μs)
std dev 389.5 ns (318.3 ns .. 502.8 ns)
Test coverage
As of version 0.2.0, this package has 100% test coverage. If you look at the report yourself, you'll see some uncovered code; it's just the automatically derived Show
instance needed for QuickCheck inside the test suite itself.