| Copyright | (c) The University of Glasgow 2001 |
|---|---|
| License | BSD-style (see the file LICENSE in the 'random' repository) |
| Maintainer | libraries@haskell.org |
| Stability | stable |
| Safe Haskell | Trustworthy |
| Language | Haskell2010 |
System.Random
Contents
Description
This library deals with the common task of pseudo-random number generation.
Synopsis
- class RandomGen g where
- next :: g -> (Int, g)
- genWord8 :: g -> (Word8, g)
- genWord16 :: g -> (Word16, g)
- genWord32 :: g -> (Word32, g)
- genWord64 :: g -> (Word64, g)
- genWord32R :: Word32 -> g -> (Word32, g)
- genWord64R :: Word64 -> g -> (Word64, g)
- genShortByteString :: Int -> g -> (ShortByteString, g)
- genRange :: g -> (Int, Int)
- split :: g -> (g, g)
- uniform :: (RandomGen g, Uniform a) => g -> (a, g)
- uniformR :: (RandomGen g, UniformRange a) => (a, a) -> g -> (a, g)
- genByteString :: RandomGen g => Int -> g -> (ByteString, g)
- class Random a where
- class Uniform a
- class UniformRange a
- data StdGen
- mkStdGen :: Int -> StdGen
- getStdRandom :: MonadIO m => (StdGen -> (a, StdGen)) -> m a
- getStdGen :: MonadIO m => m StdGen
- setStdGen :: MonadIO m => StdGen -> m ()
- newStdGen :: MonadIO m => m StdGen
- randomIO :: (Random a, MonadIO m) => m a
- randomRIO :: (Random a, MonadIO m) => (a, a) -> m a
Introduction
This module provides type classes and instances for the following concepts:
- Pure pseudo-random number generators
RandomGenis an interface to pure pseudo-random number generators.StdGen, the standard pseudo-random number generator provided in this library, is an instance ofRandomGen. It uses the SplitMix implementation provided by the splitmix package. Programmers may, of course, supply their own instances ofRandomGen.
Usage
In pure code, use uniform and uniformR to generate pseudo-random values with a pure pseudo-random number generator like StdGen.
>>>:{let rolls :: RandomGen g => Int -> g -> [Word] rolls n = take n . unfoldr (Just . uniformR (1, 6)) pureGen = mkStdGen 137 in rolls 10 pureGen :: [Word] :} [4,2,6,1,6,6,5,1,1,5]
To run use a monadic pseudo-random computation in pure code with a pure pseudo-random number generator, use runGenState and its variants.
>>>:{let rollsM :: StatefulGen g m => Int -> g -> m [Word] rollsM n = replicateM n . uniformRM (1, 6) pureGen = mkStdGen 137 in runStateGen_ pureGen (rollsM 10) :: [Word] :} [4,2,6,1,6,6,5,1,1,5]
Pure number generator interface
Pseudo-random number generators come in two flavours: pure and monadic.
RandomGen: pure pseudo-random number generators- These generators produce a new pseudo-random value together with a new instance of the pseudo-random number generator.
Pure pseudo-random number generators should implement
splitif they are splittable, that is, if there is an efficient method to turn one generator into two. The pseudo-random numbers produced by the two resulting generators should not be correlated. See [1] for some background on splittable pseudo-random generators. StatefulGen: monadic pseudo-random number generators- See System.Random.Stateful module
class RandomGen g where Source #
RandomGen is an interface to pure pseudo-random number generators.
StdGen is the standard RandomGen instance provided by this library.
Methods
next :: g -> (Int, g) Source #
Deprecated: No longer used
Returns an Int that is uniformly distributed over the range returned by genRange (including both end points), and a new generator. Using next is inefficient as all operations go via Integer. See here for more details. It is thus deprecated.
genWord8 :: g -> (Word8, g) Source #
genWord16 :: g -> (Word16, g) Source #
genWord32 :: g -> (Word32, g) Source #
genWord64 :: g -> (Word64, g) Source #
genWord32R :: Word32 -> g -> (Word32, g) Source #
genWord32R upperBound g returns a Word32 that is uniformly distributed over the range [0, upperBound].
Since: 1.2.0
genWord64R :: Word64 -> g -> (Word64, g) Source #
genWord64R upperBound g returns a Word64 that is uniformly distributed over the range [0, upperBound].
Since: 1.2.0
genShortByteString :: Int -> g -> (ShortByteString, g) Source #
genShortByteString n g returns a ShortByteString of length n filled with pseudo-random bytes.
Since: 1.2.0
Instances
uniform :: (RandomGen g, Uniform a) => g -> (a, g) Source #
Generates a value uniformly distributed over all possible values of that type.
This is a pure version of uniformM.
Examples
>>>import System.Random>>>let pureGen = mkStdGen 137>>>uniform pureGen :: (Bool, StdGen)(True,StdGen {unStdGen = SMGen 11285859549637045894 7641485672361121627})
Since: 1.2.0
uniformR :: (RandomGen g, UniformRange a) => (a, a) -> g -> (a, g) Source #
Generates a value uniformly distributed over the provided range, which is interpreted as inclusive in the lower and upper bound.
uniformR (1 :: Int, 4 :: Int)generates values uniformly from the set \(\{1,2,3,4\}\)uniformR (1 :: Float, 4 :: Float)generates values uniformly from the set \(\{x\;|\;1 \le x \le 4\}\)
The following law should hold to make the function always defined:
uniformR (a, b) = uniformR (b, a)
This is a pure version of uniformRM.
Examples
>>>import System.Random>>>let pureGen = mkStdGen 137>>>uniformR (1 :: Int, 4 :: Int) pureGen(4,StdGen {unStdGen = SMGen 11285859549637045894 7641485672361121627})
Since: 1.2.0
genByteString :: RandomGen g => Int -> g -> (ByteString, g) Source #
Generates a ByteString of the specified size using a pure pseudo-random number generator. See uniformByteString for the monadic version.
Examples
>>>import System.Random>>>import Data.ByteString>>>let pureGen = mkStdGen 137>>>unpack . fst . genByteString 10 $ pureGen[51,123,251,37,49,167,90,109,1,4]
Since: 1.2.0
The class of types for which uniformly distributed values can be generated.
Random exists primarily for backwards compatibility with version 1.1 of this library. In new code, use the better specified Uniform and UniformRange instead.
Minimal complete definition
Nothing
Methods
randomR :: RandomGen g => (a, a) -> g -> (a, g) Source #
Takes a range (lo,hi) and a pseudo-random number generator g, and returns a pseudo-random value uniformly distributed over the closed interval [lo,hi], together with a new generator. It is unspecified what happens if lo>hi. For continuous types there is no requirement that the values lo and hi are ever produced, but they may be, depending on the implementation and the interval.
randomR :: (RandomGen g, UniformRange a) => (a, a) -> g -> (a, g) Source #
Takes a range (lo,hi) and a pseudo-random number generator g, and returns a pseudo-random value uniformly distributed over the closed interval [lo,hi], together with a new generator. It is unspecified what happens if lo>hi. For continuous types there is no requirement that the values lo and hi are ever produced, but they may be, depending on the implementation and the interval.
random :: RandomGen g => g -> (a, g) Source #
The same as randomR, but using a default range determined by the type:
random :: (RandomGen g, Uniform a) => g -> (a, g) Source #
The same as randomR, but using a default range determined by the type:
randomRs :: RandomGen g => (a, a) -> g -> [a] Source #
Plural variant of randomR, producing an infinite list of pseudo-random values instead of returning a new generator.
randoms :: RandomGen g => g -> [a] Source #
Plural variant of random, producing an infinite list of pseudo-random values instead of returning a new generator.
Instances
The class of types for which a uniformly distributed value can be drawn from all possible values of the type.
Since: 1.2.0
Minimal complete definition
Instances
class UniformRange a Source #
The class of types for which a uniformly distributed value can be drawn from a range.
Since: 1.2.0
Minimal complete definition
Instances
Standard pseudo-random number generator
The standard pseudo-random number generator.
Instances
| Eq StdGen Source # | |
| Show StdGen Source # | |
| NFData StdGen Source # | |
Defined in System.Random.Internal | |
| RandomGen StdGen Source # | |
Defined in System.Random.Internal Methods next :: StdGen -> (Int, StdGen) Source # genWord8 :: StdGen -> (Word8, StdGen) Source # genWord16 :: StdGen -> (Word16, StdGen) Source # genWord32 :: StdGen -> (Word32, StdGen) Source # genWord64 :: StdGen -> (Word64, StdGen) Source # genWord32R :: Word32 -> StdGen -> (Word32, StdGen) Source # genWord64R :: Word64 -> StdGen -> (Word64, StdGen) Source # genShortByteString :: Int -> StdGen -> (ShortByteString, StdGen) Source # | |
Global standard pseudo-random number generator
There is a single, implicit, global pseudo-random number generator of type StdGen, held in a global variable maintained by the IO monad. It is initialised automatically in some system-dependent fashion. To get deterministic behaviour, use setStdGen.
Note that mkStdGen also gives deterministic behaviour without requiring an IO context.
getStdRandom :: MonadIO m => (StdGen -> (a, StdGen)) -> m a Source #
Uses the supplied function to get a value from the current global random generator, and updates the global generator with the new generator returned by the function. For example, rollDice gets a pseudo-random integer between 1 and 6:
rollDice :: IO Int rollDice = getStdRandom (randomR (1,6))
newStdGen :: MonadIO m => m StdGen Source #
Applies split to the current global pseudo-random generator, updates it with one of the results, and returns the other.
randomIO :: (Random a, MonadIO m) => m a Source #
A variant of random that uses the global pseudo-random number generator.
randomRIO :: (Random a, MonadIO m) => (a, a) -> m a Source #
A variant of randomR that uses the global pseudo-random number generator.
Compatibility and reproducibility
Backwards compatibility and deprecations
Version 1.2 mostly maintains backwards compatibility with version 1.1. This has a few consequences users should be aware of:
- The type class
Randomis only provided for backwards compatibility. New code should useUniformandUniformRangeinstead. - The methods
nextandgenRangeinRandomGenare deprecated and only provided for backwards compatibility. New instances ofRandomGenshould implement word-based methods instead. See below for more information about how to write aRandomGeninstance. This library provides instances for
Randomfor some unbounded types for backwards compatibility. For an unbounded type, there is no way to generate a value with uniform probability out of its entire domain, so therandomimplementation for unbounded types actually generates a value based on some fixed range.For
Integer,randomgenerates a value in theIntrange. ForFloatandDouble,randomgenerates a floating point value in the range[0, 1).This library does not provide
Uniforminstances for any unbounded types.
Reproducibility
If you have two builds of a particular piece of code against this library, any deterministic function call should give the same result in the two builds if the builds are
- compiled against the same major version of this library
- on the same architecture (32-bit or 64-bit)
Notes for pseudo-random number generator implementors
How to implement RandomGen
Consider these points when writing a RandomGen instance for a given pure pseudo-random number generator:
- If the pseudo-random number generator has a power-of-2 modulus, that is, it natively outputs
2^nbits of randomness for somen, implementgenWord8,genWord16,genWord32andgenWord64. See below for more details. - If the pseudo-random number generator does not have a power-of-2 modulus, implement
nextandgenRange. See below for more details. - If the pseudo-random number generator is splittable, implement
split. If there is no suitable implementation,splitshould fail with a helpful error message.
How to implement RandomGen for a pseudo-random number generator with power-of-2 modulus
Suppose you want to implement a permuted congruential generator.
>>>data PCGen = PCGen !Word64 !Word64
It produces a full Word32 of randomness per iteration.
>>>import Data.Bits>>>:{let stepGen :: PCGen -> (Word32, PCGen) stepGen (PCGen state inc) = let newState = state * 6364136223846793005 + (inc .|. 1) xorShifted = fromIntegral (((state `shiftR` 18) `xor` state) `shiftR` 27) :: Word32 rot = fromIntegral (state `shiftR` 59) :: Word32 out = (xorShifted `shiftR` (fromIntegral rot)) .|. (xorShifted `shiftL` fromIntegral ((-rot) .&. 31)) in (out, PCGen newState inc) :}
>>>fst $ stepGen $ snd $ stepGen (PCGen 17 29)3288430965
You can make it an instance of RandomGen as follows:
>>>:{instance RandomGen PCGen where genWord32 = stepGen split _ = error "PCG is not splittable" :}
How to implement RandomGen for a pseudo-random number generator without a power-of-2 modulus
We do not recommend you implement any new pseudo-random number generators without a power-of-2 modulus.
Pseudo-random number generators without a power-of-2 modulus perform significantly worse than pseudo-random number generators with a power-of-2 modulus with this library. This is because most functionality in this library is based on generating and transforming uniformly pseudo-random machine words, and generating uniformly pseudo-random machine words using a pseudo-random number generator without a power-of-2 modulus is expensive.
The pseudo-random number generator from L’Ecuyer (1988) natively generates an integer value in the range [1, 2147483562]. This is the generator used by this library before it was replaced by SplitMix in version 1.2.
>>>data LegacyGen = LegacyGen !Int32 !Int32>>>:{let legacyNext :: LegacyGen -> (Int, LegacyGen) legacyNext (LegacyGen s1 s2) = (fromIntegral z', LegacyGen s1'' s2'') where z' = if z < 1 then z + 2147483562 else z z = s1'' - s2'' k = s1 `quot` 53668 s1' = 40014 * (s1 - k * 53668) - k * 12211 s1'' = if s1' < 0 then s1' + 2147483563 else s1' k' = s2 `quot` 52774 s2' = 40692 * (s2 - k' * 52774) - k' * 3791 s2'' = if s2' < 0 then s2' + 2147483399 else s2' :}
You can make it an instance of RandomGen as follows:
>>>:{instance RandomGen LegacyGen where next = legacyNext genRange _ = (1, 2147483562) split _ = error "Not implemented" :}
References
- Guy L. Steele, Jr., Doug Lea, and Christine H. Flood. 2014. Fast splittable pseudorandom number generators. In Proceedings of the 2014 ACM International Conference on Object Oriented Programming Systems Languages & Applications (OOPSLA '14). ACM, New York, NY, USA, 453-472. DOI: https://doi.org/10.1145/2660193.2660195