{-# LANGUAGE DeriveFunctor #-} {-# LANGUAGE LambdaCase #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE TypeApplications #-} -- SPDX-License-Identifier: BSD-3-Clause ----------------------------------------------------------------------------- -- | -- Module : Data.Enumeration.Invertible -- Copyright : Brent Yorgey -- Maintainer : byorgey@gmail.com -- -- An /invertible enumeration/ is a bijection between a set of values -- and the natural numbers (or a finite prefix thereof), represented -- as a pair of inverse functions, one in each direction. Hence they -- support efficient indexing and can be constructed for very large -- finite sets. A few examples are shown below. -- -- Compared to "Data.Enumeration", one can also build invertible -- enumerations of functions (or other type formers with contravariant -- arguments); however, invertible enumerations no longer make for -- valid 'Functor', 'Applicative', or 'Alternative' instances. -- -- This module exports many of the same names as "Data.Enumeration"; -- the expectation is that you will choose one or the other to import, -- though of course it is possible to import both if you qualify the -- imports. -- ----------------------------------------------------------------------------- module Data.Enumeration.Invertible ( -- * Invertible enumerations IEnumeration -- ** Using enumerations , Cardinality(..), card , Index, select, locate , isFinite , enumerate -- ** Primitive enumerations , void , unit , singleton , finite , finiteList , boundedEnum , nat , int , cw , rat -- ** Enumeration combinators , mapE , takeE, dropE , zipE , infinite , (<+>) , (><) , interleave , maybeOf , eitherOf , listOf , finiteSubsetOf , finiteEnumerationOf , functionOf -- * Utilities , undiagonal ) where import Control.Applicative (Alternative (..)) import Data.Bits (shiftL, (.|.)) import Data.List (findIndex, foldl') import Data.Maybe (fromJust) import Data.Ratio import Data.Enumeration (Cardinality (..), Enumeration, Index) import qualified Data.Enumeration as E ------------------------------------------------------------ -- Setup for doctest examples ------------------------------------------------------------ -- $setup -- >>> :set -XTypeApplications -- >>> import Control.Arrow ((&&&)) -- >>> :{ -- data Tree = L | B Tree Tree deriving Show -- treesUpTo :: Int -> IEnumeration Tree -- treesUpTo 0 = singleton L -- treesUpTo n = mapE toTree fromTree (unit <+> (t' >< t')) -- where -- t' = treesUpTo (n-1) -- trees :: IEnumeration Tree -- trees = infinite $ mapE toTree fromTree (unit <+> (trees >< trees)) -- toTree :: Either () (Tree, Tree) -> Tree -- toTree = either (const L) (uncurry B) -- fromTree :: Tree -> Either () (Tree, Tree) -- fromTree L = Left () -- fromTree (B l r) = Right (l,r) -- :} ------------------------------------------------------------ -- Invertible enumerations ------------------------------------------------------------ -- | An invertible enumeration is a bijection between a set of -- enumerated values and the natural numbers, or a finite prefix of -- the natural numbers. An invertible enumeration is represented as -- a function from natural numbers to values, paired with an inverse -- function that returns the natural number index of a given value. -- Enumerations can thus easily be constructed for very large sets, -- and support efficient indexing and random sampling. -- -- Note that 'IEnumeration' cannot be made an instance of 'Functor', -- 'Applicative', or 'Alternative'. However, it does support the -- 'functionOf' combinator which cannot be supported by -- "Data.Enumeration". data IEnumeration a = IEnumeration { baseEnum :: Enumeration a -- | Compute the index of a particular value in its enumeration. -- Note that the result of 'locate' is only valid when given a -- value which is actually in the range of the enumeration. , locate :: a -> Index } -- | Map a pair of inverse functions over an invertible enumeration of -- @a@ values to turn it into an invertible enumeration of @b@ -- values. Because invertible enumerations contain a /bijection/ to -- the natural numbers, we really do need both directions of a -- bijection between @a@ and @b@ in order to map. This is why -- 'IEnumeration' cannot be an instance of 'Functor'. mapE :: (a -> b) -> (b -> a) -> IEnumeration a -> IEnumeration b mapE f g (IEnumeration e l) = IEnumeration (f <$> e) (l . g) ------------------------------------------------------------ -- Using enumerations ------------------------------------------------------------ -- | Select the value at a particular index. Precondition: the index -- must be strictly less than the cardinality. select :: IEnumeration a -> (Index -> a) select = E.select . baseEnum -- | Get the cardinality of an enumeration. card :: IEnumeration a -> Cardinality card = E.card . baseEnum -- | Test whether an enumeration is finite. -- -- >>> isFinite (finiteList [1,2,3]) -- True -- -- >>> isFinite nat -- False isFinite :: IEnumeration a -> Bool isFinite (IEnumeration e _) = E.isFinite e -- | List the elements of an enumeration in order. Inverse of -- 'finiteList'. enumerate :: IEnumeration a -> [a] enumerate e = case card e of Infinite -> map (select e) [0 ..] Finite c -> map (select e) [0 .. c-1] ------------------------------------------------------------ -- Constructing Enumerations ------------------------------------------------------------ -- | The empty enumeration, with cardinality zero and no elements. -- -- >>> card void -- Finite 0 -- -- >>> enumerate void -- [] void :: IEnumeration a void = IEnumeration empty (error "locate void") -- | The unit enumeration, with a single value of @()@ at index 0. -- -- >>> card unit -- Finite 1 -- -- >>> enumerate unit -- [()] -- -- >>> locate unit () -- 0 unit :: IEnumeration () unit = IEnumeration E.unit (const 0) -- | An enumeration of a single given element at index 0. -- -- >>> card (singleton 17) -- Finite 1 -- -- >>> enumerate (singleton 17) -- [17] -- -- >>> locate (singleton 17) 17 -- 0 singleton :: a -> IEnumeration a singleton a = IEnumeration (E.singleton a) (const 0) -- | A finite prefix of the natural numbers. -- -- >>> card (finite 5) -- Finite 5 -- >>> card (finite 1234567890987654321) -- Finite 1234567890987654321 -- -- >>> enumerate (finite 5) -- [0,1,2,3,4] -- >>> enumerate (finite 0) -- [] -- -- >>> locate (finite 5) 2 -- 2 finite :: Integer -> IEnumeration Integer finite n = IEnumeration (E.finite n) id -- | Construct an enumeration from the elements of a /finite/ list. -- The elements of the list must all be distinct. To turn an -- enumeration back into a list, use 'enumerate'. -- -- >>> enumerate (finiteList [2,3,8,1]) -- [2,3,8,1] -- >>> select (finiteList [2,3,8,1]) 2 -- 8 -- >>> locate (finiteList [2,3,8,1]) 8 -- 2 -- -- 'finiteList' does not work on infinite lists: inspecting the -- cardinality of the resulting enumeration (something many of the -- enumeration combinators need to do) will hang trying to compute -- the length of the infinite list. -- -- 'finiteList' uses ('!!') and 'findIndex' internally (which both -- take $O(n)$ time), so you probably want to avoid using it on long -- lists. It would be possible to make a version with better -- indexing performance by allocating a vector internally, but I am -- too lazy to do it. If you have a good use case let me know -- (better yet, submit a pull request). finiteList :: Eq a => [a] -> IEnumeration a finiteList as = IEnumeration (E.finiteList as) locateFinite -- Note the use of !! and findIndex is not very efficient, but for -- small lists it probably still beats the overhead of allocating a -- vector. Most likely this will only ever be used with very small -- lists anyway. If it becomes a problem we could add another -- combinator that behaves just like finiteList but allocates a -- Vector internally. where locateFinite a = fromIntegral . fromJust $ findIndex (==a) as -- | Enumerate all the values of a bounded 'Enum' instance. -- -- >>> enumerate (boundedEnum @Bool) -- [False,True] -- -- >>> select (boundedEnum @Char) 97 -- 'a' -- >>> locate (boundedEnum @Char) 'Z' -- 90 -- -- >>> card (boundedEnum @Int) -- Finite 18446744073709551616 -- >>> select (boundedEnum @Int) 0 -- -9223372036854775808 boundedEnum :: forall a. (Enum a, Bounded a) => IEnumeration a boundedEnum = IEnumeration E.boundedEnum (subtract lo . fromIntegral . fromEnum) where lo :: Index lo = fromIntegral (fromEnum (minBound @a)) -- | The natural numbers, @0, 1, 2, ...@. -- -- >>> enumerate . takeE 10 $ nat -- [0,1,2,3,4,5,6,7,8,9] nat :: IEnumeration Integer nat = IEnumeration E.nat id -- | All integers in the order @0, 1, -1, 2, -2, 3, -3, ...@. int :: IEnumeration Integer int = IEnumeration E.int locateInt where locateInt z | z <= 0 = 2 * abs z | otherwise = 2*z - 1 -- | The positive rational numbers, enumerated according to the -- [Calkin-Wilf sequence](http://www.cs.ox.ac.uk/publications/publication1664-abstract.html). -- -- >>> enumerate . takeE 10 $ cw -- [1 % 1,1 % 2,2 % 1,1 % 3,3 % 2,2 % 3,3 % 1,1 % 4,4 % 3,3 % 5] -- >>> locate cw (3 % 2) -- 4 -- >>> locate cw (23 % 99) -- 3183 cw :: IEnumeration Rational cw = IEnumeration E.cw (pred . locateCW) where locateCW r = go (numerator r, denominator r) go (1,1) = 1 go (a,b) | a < b = 2 * go (a, b - a) | otherwise = 1 + 2 * go (a - b, b) -- | An enumeration of all rational numbers: 0 first, then each -- rational in the Calkin-Wilf sequence followed by its negative. -- -- >>> enumerate . takeE 10 $ rat -- [0 % 1,1 % 1,(-1) % 1,1 % 2,(-1) % 2,2 % 1,(-2) % 1,1 % 3,(-1) % 3,3 % 2] -- >>> locate rat (-45 % 61) -- 2540 rat :: IEnumeration Rational rat = mapE (either (const 0) (either id negate)) unrat (unit <+> (cw <+> cw)) where unrat 0 = Left () unrat r | r > 0 = Right (Left r) | otherwise = Right (Right (-r)) -- | Take a finite prefix from the beginning of an enumeration. @takeE -- k e@ always yields the empty enumeration for \(k \leq 0\), and -- results in @e@ whenever @k@ is greater than or equal to the -- cardinality of the enumeration. Otherwise @takeE k e@ has -- cardinality @k@ and matches @e@ from @0@ to @k-1@. -- -- >>> enumerate $ takeE 3 (boundedEnum @Int) -- [-9223372036854775808,-9223372036854775807,-9223372036854775806] -- -- >>> enumerate $ takeE 2 (finiteList [1..5]) -- [1,2] -- -- >>> enumerate $ takeE 0 (finiteList [1..5]) -- [] -- -- >>> enumerate $ takeE 7 (finiteList [1..5]) -- [1,2,3,4,5] takeE :: Integer -> IEnumeration a -> IEnumeration a takeE k (IEnumeration e l) = IEnumeration (E.takeE k e) l -- | Drop some elements from the beginning of an enumeration. @dropE k -- e@ yields @e@ unchanged if \(k \leq 0\), and results in the empty -- enumeration whenever @k@ is greater than or equal to the -- cardinality of @e@. -- -- >>> enumerate $ dropE 2 (finiteList [1..5]) -- [3,4,5] -- -- >>> enumerate $ dropE 0 (finiteList [1..5]) -- [1,2,3,4,5] -- -- >>> enumerate $ dropE 7 (finiteList [1..5]) -- [] dropE :: Integer -> IEnumeration a -> IEnumeration a dropE k (IEnumeration e l) = IEnumeration (E.dropE k e) (subtract (max 0 k) . l) -- | Explicitly mark an enumeration as having an infinite cardinality, -- ignoring the previous cardinality. It is sometimes necessary to -- use this as a "hint" when constructing a recursive enumeration -- whose cardinality would otherwise consist of an infinite sum of -- finite cardinalities. -- -- For example, consider the following definitions: -- -- @ -- data Tree = L | B Tree Tree deriving Show -- -- toTree :: Either () (Tree, Tree) -> Tree -- toTree = either (const L) (uncurry B) -- -- fromTree :: Tree -> Either () (Tree, Tree) -- fromTree L = Left () -- fromTree (B l r) = Right (l,r) -- -- treesBad :: IEnumeration Tree -- treesBad = mapE toTree fromTree (unit '<+>' (treesBad '><' treesBad)) -- -- trees :: IEnumeration Tree -- trees = infinite $ mapE toTree fromTree (unit '<+>' (trees '><' trees)) -- @ -- -- Trying to use @treesBad@ at all will simply hang, since trying to -- compute its cardinality leads to infinite recursion. -- -- @ -- \>>>\ select treesBad 5 -- ^CInterrupted. -- @ -- -- However, using 'infinite', as in the definition of @trees@, -- provides the needed laziness: -- -- >>> card trees -- Infinite -- >>> enumerate . takeE 3 $ trees -- [L,B L L,B L (B L L)] -- >>> select trees 87239862967296 -- B (B (B (B (B L L) (B (B (B L L) L) L)) (B L (B L (B L L)))) (B (B (B L (B L (B L L))) (B (B L L) (B L L))) (B (B L (B L (B L L))) L))) (B (B L (B (B (B L (B L L)) (B L L)) L)) (B (B (B L (B L L)) L) L)) -- >>> select trees 123 -- B (B L (B L L)) (B (B L (B L L)) (B L (B L L))) -- >>> locate trees (B (B L (B L L)) (B (B L (B L L)) (B L (B L L)))) -- 123 infinite :: IEnumeration a -> IEnumeration a infinite (IEnumeration e l) = IEnumeration (E.infinite e) l -- | Fairly interleave a set of /infinite/ enumerations. -- -- For a finite set of infinite enumerations, a round-robin -- interleaving is used. That is, if we think of an enumeration of -- enumerations as a 2D matrix read off row-by-row, this corresponds -- to taking the transpose of a matrix with finitely many infinite -- rows, turning it into one with infinitely many finite rows. For -- an infinite set of infinite enumerations, /i.e./ an infinite 2D -- matrix, the resulting enumeration reads off the matrix by -- 'Data.Enumeration.diagonal's. -- -- Note that the type of this function is slightly different than -- its counterpart in "Data.Enumeration": each enumerated value in -- the output is tagged with an index indicating which input -- enumeration it came from. This is required to make the result -- invertible, and is analogous to the way the output values of -- '<+>' are tagged with 'Left' or 'Right'; in fact, 'interleave' -- can be thought of as an iterated version of '<+>', but with a -- more efficient implementation. interleave :: IEnumeration (IEnumeration a) -> IEnumeration (Index, a) interleave e = IEnumeration { baseEnum = E.mkEnumeration Infinite $ \k -> let (i,j) = case card e of Finite n -> k `divMod` n Infinite -> E.diagonal k in (j, select (select e j) i) , locate = \(j, a) -> let i = locate (select e j) a in case card e of Finite n -> i*n + j Infinite -> undiagonal (i,j) } -- | Zip two enumerations in parallel, producing the pair of -- elements at each index. The resulting enumeration is truncated -- to the cardinality of the smaller of the two arguments. -- -- Note that defining @zipWithE@ as in "Data.Enumeration" is not -- possible since there would be no way to invert it in general. -- However, one can use 'zipE' in combination with 'mapE' to achieve -- a similar result. -- -- >>> enumerate $ zipE nat (boundedEnum @Bool) -- [(0,False),(1,True)] -- -- >>> cs = mapE (uncurry replicate) (length &&& head) (zipE (finiteList [1..10]) (dropE 35 (boundedEnum @Char))) -- >>> enumerate cs -- ["#","$$","%%%","&&&&","'''''","((((((",")))))))","********","+++++++++",",,,,,,,,,,"] -- >>> locate cs "********" -- 7 zipE :: IEnumeration a -> IEnumeration b -> IEnumeration (a,b) zipE ea eb = IEnumeration { baseEnum = E.zipE (baseEnum ea) (baseEnum eb) , locate = locate ea . fst } -- | Sum, /i.e./ disjoint union, of two enumerations. If both are -- finite, all the values of the first will be enumerated before the -- values of the second. If only one is finite, the values from the -- finite enumeration will be listed first. If both are infinite, a -- fair (alternating) interleaving is used, so that every value ends -- up at a finite index in the result. -- -- Note that this has a different type than the version in -- "Data.Enumeration". Here we require the output to carry an -- explicit 'Either' tag to make it invertible. -- -- >>> enumerate . takeE 5 $ singleton 17 <+> nat -- [Left 17,Right 0,Right 1,Right 2,Right 3] -- -- >>> enumerate . takeE 5 $ nat <+> singleton 17 -- [Right 17,Left 0,Left 1,Left 2,Left 3] -- -- >>> enumerate . takeE 5 $ nat <+> nat -- [Left 0,Right 0,Left 1,Right 1,Left 2] -- -- >>> locate (nat <+> nat) (Right 35) -- 71 (<+>) :: IEnumeration a -> IEnumeration b -> IEnumeration (Either a b) a <+> b = IEnumeration (Left <$> baseEnum a <|> Right <$> baseEnum b) (locateEither a b) where locateEither :: IEnumeration a -> IEnumeration b -> (Either a b -> Index) locateEither a b = case (card a, card b) of (Finite k1, _) -> either (locate a) ((+k1) . locate b) (_, Finite k2) -> either ((+k2) . locate a) (locate b) _ -> either ((*2) . locate a) (succ . (*2) . locate b) -- | The other half of the isomorphism between \(\mathbb{N}\) and -- \(\mathbb{N} \times \mathbb{N}\) which enumerates by diagonals: -- turn a pair of natural numbers giving a position in the 2D grid -- into the number in the cell, according to this numbering scheme: -- -- @ -- 0 1 3 6 ... -- 2 4 7 -- 5 8 -- 9 -- @ undiagonal :: (Integer, Integer) -> Integer undiagonal (r,c) = (r+c) * (r+c+1) `div` 2 + r -- | Cartesian product of enumerations. If both are finite, uses a -- simple lexicographic ordering. If only one is finite, the -- resulting enumeration is still in lexicographic order, with the -- infinite enumeration as the most significant component. For two -- infinite enumerations, uses a fair 'Data.Enumeration.diagonal' interleaving. -- -- >>> enumerate $ finiteList [1..3] >< finiteList "abcd" -- [(1,'a'),(1,'b'),(1,'c'),(1,'d'),(2,'a'),(2,'b'),(2,'c'),(2,'d'),(3,'a'),(3,'b'),(3,'c'),(3,'d')] -- -- >>> enumerate . takeE 10 $ finiteList "abc" >< nat -- [('a',0),('b',0),('c',0),('a',1),('b',1),('c',1),('a',2),('b',2),('c',2),('a',3)] -- -- >>> enumerate . takeE 10 $ nat >< finiteList "abc" -- [(0,'a'),(0,'b'),(0,'c'),(1,'a'),(1,'b'),(1,'c'),(2,'a'),(2,'b'),(2,'c'),(3,'a')] -- -- >>> enumerate . takeE 10 $ nat >< nat -- [(0,0),(0,1),(1,0),(0,2),(1,1),(2,0),(0,3),(1,2),(2,1),(3,0)] -- -- >>> locate (nat >< nat) (1,1) -- 4 -- >>> locate (nat >< nat) (36,45) -- 3357 -- -- Like ('<+>'), this operation is also not associative (not even up -- to reassociating tuples). (><) :: IEnumeration a -> IEnumeration b -> IEnumeration (a,b) a >< b = IEnumeration (baseEnum a E.>< baseEnum b) (locatePair a b) where locatePair :: IEnumeration a -> IEnumeration b -> ((a,b) -> Index) locatePair a b = case (card a, card b) of (_, Finite k2) -> \(x,y) -> k2 * locate a x + locate b y (Finite k1, _) -> \(x,y) -> k1 * locate b y + locate a x _ -> \(x,y) -> undiagonal (locate a x, locate b y) ------------------------------------------------------------ -- Building standard data types ------------------------------------------------------------ -- | Enumerate all possible values of type `Maybe a`, where the values -- of type `a` are taken from the given enumeration. -- -- >>> enumerate $ maybeOf (finiteList [1,2,3]) -- [Nothing,Just 1,Just 2,Just 3] -- >>> locate (maybeOf (maybeOf (finiteList [1,2,3]))) (Just (Just 2)) -- 3 maybeOf :: IEnumeration a -> IEnumeration (Maybe a) maybeOf a = mapE (either (const Nothing) Just) (maybe (Left ()) Right) (unit <+> a) -- | Enumerae all possible values of type @Either a b@ with inner values -- taken from the given enumerations. -- -- Note that for invertible enumerations, 'eitherOf' is simply a -- synonym for '<+>'. -- -- >>> enumerate . takeE 6 $ eitherOf nat nat -- [Left 0,Right 0,Left 1,Right 1,Left 2,Right 2] eitherOf :: IEnumeration a -> IEnumeration b -> IEnumeration (Either a b) eitherOf = (<+>) -- | Enumerate all possible finite lists containing values from the -- given enumeration. -- -- >>> enumerate . takeE 15 $ listOf nat -- [[],[0],[0,0],[1],[0,0,0],[1,0],[2],[0,1],[1,0,0],[2,0],[3],[0,0,0,0],[1,1],[2,0,0],[3,0]] -- >>> locate (listOf nat) [3,4,20,5,19] -- 666270815854068922513792635440014 listOf :: IEnumeration a -> IEnumeration [a] listOf a = case card a of Finite 0 -> singleton [] _ -> listOfA where listOfA = infinite $ mapE (either (const []) (uncurry (:))) uncons (unit <+> (a >< listOfA)) uncons [] = Left () uncons (a:as) = Right (a, as) -- | Enumerate all possible finite subsets of values from the given -- enumeration. The elements in each list will always occur in -- increasing order of their index in the given enumeration. -- -- >>> enumerate $ finiteSubsetOf (finite 3) -- [[],[0],[1],[0,1],[2],[0,2],[1,2],[0,1,2]] -- -- >>> locate (finiteSubsetOf nat) [2,3,6,8] -- 332 -- >>> 332 == 2^8 + 2^6 + 2^3 + 2^2 -- True finiteSubsetOf :: IEnumeration a -> IEnumeration [a] finiteSubsetOf a = IEnumeration (E.finiteSubsetOf (baseEnum a)) unpick where unpick = foldl' (.|.) 0 . map ((1 `shiftL`) . fromIntegral . locate a) -- | @finiteEnumerationOf n a@ creates an enumeration of all sequences -- of exactly n items taken from the enumeration @a@. -- -- >>> map E.enumerate . enumerate $ finiteEnumerationOf 2 (finite 3) -- [[0,0],[0,1],[0,2],[1,0],[1,1],[1,2],[2,0],[2,1],[2,2]] -- -- >>> map E.enumerate . take 10 . enumerate $ finiteEnumerationOf 3 nat -- [[0,0,0],[0,0,1],[1,0,0],[0,1,0],[1,0,1],[2,0,0],[0,0,2],[1,1,0],[2,0,1],[3,0,0]] finiteEnumerationOf :: Int -> IEnumeration a -> IEnumeration (Enumeration a) finiteEnumerationOf 0 _ = singleton empty finiteEnumerationOf n a = case card a of Finite k -> IEnumeration (E.finiteEnumerationOf n (baseEnum a)) (locateEnum k) Infinite -> foldr prod (singleton empty) (replicate n a) where locateEnum k = fromBase k . reverse . E.enumerate . fmap (locate a) fromBase k = foldr (\d r -> d + k*r) 0 prod :: IEnumeration a -> IEnumeration (Enumeration a) -> IEnumeration (Enumeration a) prod a as = mapE (\(a,e) -> E.singleton a <|> e) (\e -> (E.select e 0, E.dropE 1 e)) (a >< as) -- | @functionOf a b@ creates an enumeration of all functions taking -- values from the enumeration @a@ and returning values from the -- enumeration @b@. As a precondition, @a@ must be finite; -- otherwise @functionOf@ throws an error. -- -- >>> bbs = functionOf (boundedEnum @Bool) (boundedEnum @Bool) -- >>> card bbs -- Finite 4 -- >>> map (select bbs 2) [False, True] -- [True,False] -- >>> locate bbs not -- 2 -- -- >>> locate (functionOf bbs (boundedEnum @Bool)) (\f -> f True) -- 5 functionOf :: IEnumeration a -> IEnumeration b -> IEnumeration (a -> b) functionOf as bs = case card as of Infinite -> error "functionOf with infinite domain" Finite n -> mapE toFunc fromFunc (finiteEnumerationOf (fromIntegral n) bs) where toFunc bTuple a = E.select bTuple (locate as a) fromFunc f = f <$> baseEnum as