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||| foldr is the unique solution to the equation:
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||| h f e [] = e
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||| h f e (x :: xs) = x `h` (foldr f e xs)
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||| (This fact is called 'the universal property of foldr'.)
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||| Since the prelude defines foldr tail-recursively, this fact isn't immediate
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||| and we need some lemmata to prove it.
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module Data.Vect.Properties.Foldr
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import Data.Vect
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import Data.Vect.Elem
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import Data.Fin
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import Data.Nat
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import Data.Nat.Order
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import Syntax.PreorderReasoning
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import Syntax.PreorderReasoning.Generic
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2021-07-09 11:06:27 +03:00
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import Control.Order
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2021-05-20 13:55:22 +03:00
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2021-06-01 17:05:04 +03:00
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||| Sum implemented with foldr
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public export
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sumR : (Foldable f, Num a) => f a -> a
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sumR = foldr (+) 0
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%transform "sumR/sum" sumR = sum
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||| A function H : forall n. Vect n A -> B preserving the structure of vectors over A
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public export
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record VectHomomorphismProperty {0 A, B : Type} (F : A -> B -> B) (E : B) (H : forall n . Vect n A -> B) where
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constructor ShowVectHomomorphismProperty
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nil : H [] = E
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cons : {0 n : Nat} -> (x : A) -> (xs : Vect n A) -> H (x :: xs) = x `F` (H xs)
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||| There is an extensionally unique function preserving the vector structure
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export
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nilConsInitiality :
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(f : a -> b -> b) -> (e : b)
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-> (h1, h2 : forall n . Vect n a -> b)
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-> (prf1 : VectHomomorphismProperty f e h1)
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-> (prf2 : VectHomomorphismProperty f e h2)
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-> (xs : Vect n a) -> h1 xs = h2 xs
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nilConsInitiality f e h1 h2 prf1 prf2 [] = Calc $
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|~ h1 []
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~~ e ...(prf1.nil)
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~~ h2 [] ...(sym prf2.nil)
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nilConsInitiality f e h1 h2 prf1 prf2 (x :: xs) = Calc $
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|~ h1 (x :: xs)
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~~ (x `f` (h1 xs)) ...(prf1.cons _ _)
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~~ (x `f` (h2 xs)) ...(cong (x `f`) $ nilConsInitiality f e h1 h2 prf1 prf2 xs)
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~~ h2 (x :: xs) ...(sym $ prf2.cons _ _)
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||| extensionality is a congruence with respect to Data.Vect.foldrImpl
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foldrImplExtensional :
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(f : a -> b -> b) -> (e : b)
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-> (go1, go2 : b -> b)
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-> ((y : b) -> go1 y = go2 y)
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-> (xs : Vect n a)
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-> foldrImpl f e go1 xs = foldrImpl f e go2 xs
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foldrImplExtensional f e go1 go2 ext [] = ext e
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foldrImplExtensional f e go1 go2 ext (x :: xs) =
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foldrImplExtensional f e _ _
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(\y => ext (f x y))
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xs
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||| foldrImpl f e x : (b -> -) -> - is natural
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foldrImplNaturality : (f : a -> b -> b) -> (e : b) -> (xs : Vect n a) -> (go1, go2 : b -> b)
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-> foldrImpl f e (go1 . go2) xs = go1 (foldrImpl f e go2 xs)
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foldrImplNaturality f e [] go1 go2 = Refl
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foldrImplNaturality f e (x :: xs) go1 go2 = foldrImplNaturality f e xs go1 (go2 . (f x))
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||| Our tail-recursive foldr preserves the vector structure
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export
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foldrVectHomomorphism : VectHomomorphismProperty f e (foldr f e)
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foldrVectHomomorphism = ShowVectHomomorphismProperty
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{ nil = Refl
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, cons = \x, xs => Calc $
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|~ foldr f e (x :: xs)
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~~ foldrImpl f e (id . (f x)) xs ...(Refl)
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~~ foldrImpl f e ((f x) . id) xs ...(foldrImplExtensional f e _ _ (\y => Refl) xs)
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~~ f x (foldrImpl f e id xs) ...(foldrImplNaturality f e xs (f x) _)
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~~ f x (foldr f e xs) ...(Refl)
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}
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||| foldr is the unique function preserving the vector structure
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export
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foldrUniqueness : (h : forall n . Vect n a -> b) -> VectHomomorphismProperty f e h -> (xs : Vect n a) -> h xs = foldr f e xs
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foldrUniqueness {f} h prf xs = irrelevantEq $
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nilConsInitiality f e h (foldr f e) prf foldrVectHomomorphism xs
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||| Each summand is `LTE` the sum
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export
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sumIsGTEtoParts : {x : Nat} -> (xs : Vect n Nat) -> (x `Elem` xs) -> sumR xs `GTE` x
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sumIsGTEtoParts (x :: xs) Here
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= CalcWith $
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|~ x
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~~ x + 0 ...(sym $ plusZeroRightNeutral _)
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<~ x + (sumR xs) ...(plusLteMonotoneLeft x 0 _ LTEZero)
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~~ sumR (x :: xs) ...(sym $ (foldrVectHomomorphism {f = plus} {e = 0}).cons _ _)
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sumIsGTEtoParts {x} (y :: xs) (There later)
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= CalcWith $
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|~ x
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<~ sumR xs ...(sumIsGTEtoParts {x} xs later)
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~~ 0 + sumR xs ...(Refl)
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<~ y + (sumR xs) ...(plusLteMonotoneRight (sumR xs) 0 y LTEZero)
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~~ sumR (y :: xs) ...(sym $ (foldrVectHomomorphism {f = plus} {e = 0}).cons _ _)
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||| `sumR : Vect n Nat -> Nat` is monotone
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export
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sumMonotone : {n : Nat} -> (xs, ys : Vect n Nat)
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-> (prf : (i : Fin n) -> index i xs `LTE` index i ys)
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-> (sumR xs `LTE` sumR ys)
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sumMonotone [] [] prf = LTEZero
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sumMonotone (x :: xs) (y :: ys) prf =
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let prf' = sumMonotone xs ys (\i => prf (FS i))
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in CalcWith $
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|~ sumR (x :: xs)
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~~ x + sumR xs ...((foldrVectHomomorphism {f = plus} {e = 0}).cons x xs)
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<~ y + sumR ys ...(plusLteMonotone (prf 0) prf')
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~~ sumR (y :: ys) ...(sym $ (foldrVectHomomorphism {f = plus} {e = 0}).cons y ys)
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