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https://github.com/idris-lang/Idris2.git
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21c6f4fb79
* [ breaking ] remove parsing of dangling binders It used to be the case that ``` ID : Type -> Type ID a = a test : ID (a : Type) -> a -> a test = \ a, x => x ``` and ``` head : List $ a -> Maybe a head [] = Nothing head (x :: _) = Just x ``` were accepted but these are now rejected because: * `ID (a : Type) -> a -> a` is parsed as `(ID (a : Type)) -> a -> a` * `List $ a -> Maybe a` is parsed as `List (a -> Maybe a)` Similarly if you want to use a lambda / rewrite / let expression as part of the last argument of an application, the use of `$` or parens is now mandatory. This should hopefully allow us to make progress on #1703
117 lines
3.7 KiB
Idris
117 lines
3.7 KiB
Idris
module Data.List.AtIndex
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import Data.DPair
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import Data.List.HasLength
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import Data.Nat
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import Decidable.Equality
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%default total
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||| @AtIndex witnesses the fact that a natural number encodes a membership proof.
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||| It is meant to be used as a runtime-irrelevant gadget to guarantee that the
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||| natural number is indeed a valid index.
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public export
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data AtIndex : a -> List a -> Nat -> Type where
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Z : AtIndex a (a :: as) Z
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S : AtIndex a as n -> AtIndex a (b :: as) (S n)
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||| Inversion principle for Z constructor
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export
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inverseZ : AtIndex x (y :: xs) Z -> x === y
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inverseZ Z = Refl
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||| inversion principle for S constructor
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export
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inverseS : AtIndex x (y :: xs) (S n) -> AtIndex x xs n
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inverseS (S p) = p
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||| An empty list cannot possibly have members
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export
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Uninhabited (AtIndex a [] n) where
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uninhabited Z impossible
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uninhabited (S _) impossible
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||| For a given list and a given index, there is only one possible value
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||| stored at that index in that list
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export
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atIndexUnique : AtIndex a as n -> AtIndex b as n -> a === b
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atIndexUnique Z Z = Refl
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atIndexUnique (S p) (S q) = atIndexUnique p q
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||| Provided that equality is decidable, we can look for the first occurence
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||| of a value inside of a list
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public export
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find : DecEq a => (x : a) -> (xs : List a) -> Dec (Subset Nat (AtIndex x xs))
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find x [] = No (\ p => void (absurd (snd p)))
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find x (y :: xs) with (decEq x y)
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find x (x :: xs) | Yes Refl = Yes (Element Z Z)
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find x (y :: xs) | No neqxy = case find x xs of
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Yes (Element n prf) => Yes (Element (S n) (S prf))
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No notInxs => No $ \case
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(Element Z p) => void (neqxy (inverseZ p))
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(Element (S n) prf) => absurd (notInxs (Element n (inverseS prf)))
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||| If the equality is not decidable, we may instead rely on interface resolution
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public export
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interface Member (0 t : a) (0 ts : List a) where
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isMember' : Subset Nat (AtIndex t ts)
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public export
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isMember : (0 t : a) -> (0 ts : List a) -> Member t ts =>
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Subset Nat (AtIndex t ts)
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isMember t ts @{p} = isMember' @{p}
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public export
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Member t (t :: ts) where
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isMember' = Element 0 Z
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public export
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Member t ts => Member t (u :: ts) where
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isMember' = let (Element n prf) = isMember t ts in
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Element (S n) (S prf)
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||| Given an index, we can decide whether there is a value corresponding to it
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public export
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lookup : (n : Nat) -> (xs : List a) -> Dec (Subset a (\ x => AtIndex x xs n))
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lookup n [] = No (\ p => void (absurd (snd p)))
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lookup Z (x :: xs) = Yes (Element x Z)
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lookup (S n) (x :: xs) = case lookup n xs of
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Yes (Element x p) => Yes (Element x (S p))
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No notInxs => No (\ (Element x p) => void (notInxs (Element x (inverseS p))))
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||| An AtIndex proof implies that n is less than the length of the list indexed into
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public export
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inRange : (n : Nat) -> (xs : List a) -> (0 _ : AtIndex x xs n) -> LTE n (length xs)
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inRange n [] p = void (absurd p)
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inRange Z (x :: xs) p = LTEZero
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inRange (S n) (x :: xs) p = LTESucc (inRange n xs (inverseS p))
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export
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weakenR : AtIndex x xs n -> AtIndex x (xs ++ ys) n
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weakenR Z = Z
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weakenR (S p) = S (weakenR p)
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export
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weakenL : (p : Subset Nat (HasLength ws)) -> AtIndex x xs n -> AtIndex x (ws ++ xs) (fst p + n)
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weakenL m p = case view m of
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Z => p
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(S m) => S (weakenL m p)
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export
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strengthenL : (p : Subset Nat (HasLength xs)) ->
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lt n (fst p) === True ->
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AtIndex x (xs ++ ys) n -> AtIndex x xs n
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strengthenL m lt idx = case view m of
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S m => case idx of
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Z => Z
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S idx => S (strengthenL m lt idx)
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export
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strengthenR : (p : Subset Nat (HasLength ws)) ->
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lte (fst p) n === True ->
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AtIndex x (ws ++ xs) n -> AtIndex x xs (minus n (fst p))
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strengthenR m lt idx = case view m of
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Z => rewrite minusZeroRight n in idx
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S m => case idx of S idx => strengthenR m lt idx
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