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What's a good way to generate ad-hoc keys, where each key is unique to the program? Ideally, an action of the form:

newKey :: IO Key

such that:

do a <- newKey
   b <- newKey
   return (a == b)

always returns false. Also, it should be possible to use Key in an efficient associative container (e.g. a Map).

This could be used, for example, to maintain a collection of event handlers supporting random insertion and deletion:

Map Key EventHandler

Options I'm aware of:

  • newIORef(): Satisfies the invariant above, but IORef doesn't have an Ord instance.

  • malloc: Fast, and Ptr () has an Ord instance, but the result is not garbage collected.

  • newStablePtr(): Not garbage collected, and StablePtr does not have an Ord instance.

  • newIORef() >>=makeStableName: Should satisfy the invariant above and is garbage collected, but more difficult to use (requires me to use a hash table).

  • mallocForeignPtrBytes1: Satisfies both criteria, but is it efficient?

mallocForeignPtrBytes 1 seems like my best option. I suppose I could make it slightly more efficient by using GHC's newPinnedByteArray# primop directly.

Are there any better options? Is the mallocForeignPtrBytes approach flawed for some non-obvious reason?

share|improve this question
Data.Unique ? – luqui Dec 24 '11 at 6:09
Another option: the uuid package on hackage. – Dan Burton Dec 24 '11 at 17:52
up vote 11 down vote accepted

If you don't want to add any additional dependencies to your project, you can use Data.Unique in the base package.

Internally, the system uses a TVar (which relies on GHC's STM system) of Integers, such that every time you call newUnique, the TVar is incremented atomically, and the new Integer is stored in the opaque Unique data type. Because TVars cannot be modified by different threads simultaneously, they guarantee that Uniques are generated in sequence, and that they must, in fact, be unique.

share|improve this answer
I'm slightly surprised that it isn't built on atomicModifyIORef, which I'd always thought was the fastest way to do relatively simple atomic operations. – Louis Wasserman Dec 24 '11 at 17:07
@LouisWasserman: Look at the source. The comments explain why they didn't go that route: "using atomicModifyIORef would be slightly quicker, but can suffer from adverse scheduling issues (see #3838)" – Joey Adams Dec 24 '11 at 17:11
So that means values are unique across a single program's execution, but multiple instances of the program could generate the same "unique" values, right? – Dan Burton Dec 24 '11 at 17:55
@DanBurton: Correct. – Joey Adams Dec 24 '11 at 18:05
I accepted this answer because Data.Unique is pretty fast and is already available in base. Although newPinnedByteArray is faster, it is unlikely to make a difference in practice (or may even cause performance to vary wildly from run to run). See my benchmarks. – Joey Adams Dec 24 '11 at 18:08

There are several relevant packages on hackage. The concurrent-supply package looks to be quite carefully designed.

share|improve this answer

Thanks, dflemstr, for pointing out Data.Unique. I benchmarked Data.Unique versus a couple alternative implementations:


Based on mallocForeignPtrBytes:

{-# LANGUAGE DeriveDataTypeable #-}
module Unique2 (Unique2, newUnique2) where

import Control.Applicative
import Data.Typeable (Typeable)
import Data.Word (Word8)
import Foreign.ForeignPtr

newtype Unique2 = Unique2 (ForeignPtr Word8)
    deriving (Eq, Ord, Typeable)

newUnique2 :: IO Unique2
newUnique2 = Unique2 <$> mallocForeignPtrBytes 1


Based on newPinnedByteArray, which is used internally by mallocForeignPtrBytes. It's basically the same as Unique2, minus some wrapper overhead.

{-# LANGUAGE DeriveDataTypeable #-}
module Unique3 (Unique3, newUnique3) where

import Control.Applicative
import Data.Primitive.ByteArray
import Data.Primitive.Types
import Data.Typeable

newtype Unique3 = Unique3 Addr
    deriving (Eq, Ord, Typeable)

newUnique3 :: IO Unique3
newUnique3 = Unique3 . mutableByteArrayContents <$> newPinnedByteArray 1


import Criterion.Main

import Control.Exception (evaluate)
import Control.Monad
import Data.Unique
import Unique2
import Unique3

import qualified Data.Set as S

main :: IO ()
main = defaultMain
    [ bench "Unique" $
        replicateM 10000 newUnique  >>= evaluate . S.size . S.fromList
    , bench "Unique2" $
        replicateM 10000 newUnique2 >>= evaluate . S.size . S.fromList
    , bench "Unique3" $
        replicateM 10000 newUnique3 >>= evaluate . S.size . S.fromList


Compiled with ghc -Wall -O2 -threaded -fforce-recomp unique-benchmark.hs:

benchmarking Unique
mean: 15.75516 ms, lb 15.62392 ms, ub 15.87852 ms, ci 0.950
std dev: 651.5598 us, lb 568.6396 us, ub 761.7921 us, ci 0.950

benchmarking Unique2
mean: 20.41976 ms, lb 20.11922 ms, ub 20.67800 ms, ci 0.950
std dev: 1.427356 ms, lb 1.254366 ms, ub 1.607923 ms, ci 0.950

benchmarking Unique3
mean: 14.30127 ms, lb 14.17271 ms, ub 14.42338 ms, ci 0.950
std dev: 643.1826 us, lb 568.2373 us, ub 737.8637 us, ci 0.950

If I bump the magnitude from 10000 up to 100000:

benchmarking Unique
collecting 100 samples, 1 iterations each, in estimated 21.26808 s
mean: 206.9683 ms, lb 206.5749 ms, ub 207.7638 ms, ci 0.950
std dev: 2.738490 ms, lb 1.602821 ms, ub 4.941017 ms, ci 0.950

benchmarking Unique2
collecting 100 samples, 1 iterations each, in estimated 33.76100 s
mean: 319.7642 ms, lb 316.2466 ms, ub 323.2613 ms, ci 0.950
std dev: 17.94974 ms, lb 16.93904 ms, ub 19.34948 ms, ci 0.950

benchmarking Unique3
collecting 100 samples, 1 iterations each, in estimated 21.22741 s
mean: 200.0456 ms, lb 199.2538 ms, ub 200.9107 ms, ci 0.950
std dev: 4.231600 ms, lb 3.840245 ms, ub 4.679455 ms, ci 0.950


Data.Unique (the built-in implementation) and Unique3 (based on newPinnedByteArray) are neck and neck in these tests. newUnique3 itself is over ten times faster than newUnique, but key generation overhead is dwarfed by usage cost.

Unique2 loses due to wrapper overhead, but between Data.Unique and Unique3, my results are inconclusive. I would recommend Data.Unique simply because it's already available in base. However, if you're struggling to squeeze the last bit of performance out of some application, try substituting Data.Unique with Unique3, and tell me how it goes.

share|improve this answer
I think Unique3 is unsafe, since the memory will be collected by the GC and reused, as you don't hold on to the array. – ehird Dec 25 '11 at 17:24

One way I've seen if you want it at top level is with a hack like this:

import Data.IORef
import System.IO.Unsafe

newtype Key = Key Integer deriving (Ord, Eq, Show)

newKey :: IO Key
{-# NOINLINE newKey #-}
newKey = unsafePerformIO mkNewKey

mkNewKey :: IO (IO Key)
mkNewKey = do
  r <- newIORef 0
  return $ do
    modifyIORef r (+1)
    Key `fmap` (readIORef r)

main = do
  a <- newKey
  b <- newKey
  print (a,b)
share|improve this answer
This doesn't work when you have multiple threads that need unique values -- because modifyIORef might happen in parallel, you might get two identical Keys. Using atomicModifyIORef removes this problem, but can lead to inefficiencies. – dflemstr Dec 24 '11 at 6:41
@dflemstr, what inefficiencies? atomicModifyIORef isn't expensive. – luqui Dec 24 '11 at 8:24
@luqui I thought I had read somewhere that atomicModifyIORef could lead to race conditions if overused (e.g. one thread performing atomic operations in a loop would occlude all other threads trying to access the particular IORef), but I can't seem to find the particular source for this claim. – dflemstr Dec 24 '11 at 8:47
@dfelmstr: See hackage.haskell.org/trac/ghc/ticket/3838. It looks like this issue is fixed; Data.Unique uses atomicModifyIORef now. – Joey Adams Mar 26 '13 at 1:01

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