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74 lines
2.7 KiB
Idris
74 lines
2.7 KiB
Idris
module Data.Vect.Elem
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import Data.Vect
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import Decidable.Equality
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--------------------------------------------------------------------------------
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-- Vector membership proof
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--------------------------------------------------------------------------------
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||| A proof that some element is found in a vector
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public export
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data Elem : a -> Vect k a -> Type where
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Here : Elem x (x::xs)
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There : (later : Elem x xs) -> Elem x (y::xs)
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export
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Uninhabited (Elem x []) where
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uninhabited Here impossible
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||| An item not in the head and not in the tail is not in the Vect at all
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export
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neitherHereNorThere : Not (x = y) -> Not (Elem x xs) -> Not (Elem x (y :: xs))
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neitherHereNorThere xneqy xninxs Here = xneqy Refl
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neitherHereNorThere xneqy xninxs (There xinxs) = xninxs xinxs
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||| A decision procedure for Elem
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public export
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isElem : DecEq a => (x : a) -> (xs : Vect n a) -> Dec (Elem x xs)
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isElem x [] = No uninhabited
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isElem x (y::xs) with (decEq x y)
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isElem x (x::xs) | (Yes Refl) = Yes Here
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isElem x (y::xs) | (No xneqy) with (isElem x xs)
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isElem x (y::xs) | (No xneqy) | (Yes xinxs) = Yes (There xinxs)
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isElem x (y::xs) | (No xneqy) | (No xninxs) = No (neitherHereNorThere xneqy xninxs)
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public export
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replaceElem : (xs : Vect k t) -> (1 _ : Elem x xs) -> (y : t) -> (ys : Vect k t ** Elem y ys)
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replaceElem (x::xs) Here y = (y :: xs ** Here)
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replaceElem (x::xs) (There xinxs) y with (replaceElem xs xinxs y)
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replaceElem (x::xs) (There xinxs) y | (ys ** yinys) = (x :: ys ** There yinys)
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public export
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replaceByElem : (xs : Vect k t) -> (1 _ : Elem x xs) -> t -> Vect k t
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replaceByElem (x::xs) Here y = y :: xs
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replaceByElem (x::xs) (There xinxs) y = x :: replaceByElem xs xinxs y
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public export
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mapElem : {0 xs : Vect k t} -> {0 f : t -> u} ->
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(1 _ : Elem x xs) -> Elem (f x) (map f xs)
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mapElem Here = Here
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mapElem (There e) = There (mapElem e)
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||| Remove the element at the given position.
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||| @xs The vector to be removed from
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||| @p A proof that the element to be removed is in the vector
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public export
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dropElem : {k : _} -> (xs : Vect (S k) t) -> (1 _ : Elem x xs) -> Vect k t
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dropElem (x::ys) Here = ys
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dropElem {k = S k} (x::ys) (There later) = x :: dropElem ys later
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||| Erase the indices, returning the bounded numeric position of the element
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public export
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elemToFin : {0 xs : Vect n a} -> (1 _ : Elem x xs) -> Fin n
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elemToFin Here = FZ
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elemToFin (There p) = FS (elemToFin p)
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||| Find the element with a proof at a given bounded position
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public export
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indexElem : (1 _ : Fin n) -> (xs : Vect n a) -> (x ** Elem x xs)
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indexElem FZ (y::ys) = (y ** Here)
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indexElem (FS n) (y::ys) = let (x ** p) = indexElem n ys in
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(x ** There p)
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