------------------------------------------------------------------------
-- The Agda standard library
--
-- Properties of n-ary products
------------------------------------------------------------------------

{-# OPTIONS --cubical-compatible --safe #-}

module Data.Vec.Recursive.Properties where

open import Level using (Level)
open import Data.Nat.Base hiding (_^_)
open import Data.Product.Base
open import Data.Vec.Recursive
open import Data.Vec.Base using (Vec; _∷_)
open import Function.Bundles using (_↔_; mk↔ₛ′)
open import Relation.Binary.PropositionalEquality.Core as P
open import Relation.Binary.PropositionalEquality.Properties
  using (module ≡-Reasoning)
open ≡-Reasoning

private
  variable
    a : Level
    A : Set a

------------------------------------------------------------------------
-- Basic proofs

cons-head-tail-identity :  n (as : A ^ suc n)  cons n (head n as) (tail n as)  as
cons-head-tail-identity 0       as = P.refl
cons-head-tail-identity (suc n) as = P.refl

head-cons-identity :  n a (as : A ^ n)  head n (cons n a as)  a
head-cons-identity 0       a as = P.refl
head-cons-identity (suc n) a as = P.refl

tail-cons-identity :  n a (as : A ^ n)  tail n (cons n a as)  as
tail-cons-identity 0       a as = P.refl
tail-cons-identity (suc n) a as = P.refl

append-cons :  m n a (xs : A ^ m) ys 
  append (suc m) n (cons m a xs) ys  cons (m + n) a (append m n xs ys)
append-cons 0       n a xs ys = P.refl
append-cons (suc m) n a xs ys = P.refl

append-splitAt-identity :  m n (as : A ^ (m + n))  uncurry (append m n) (splitAt m n as)  as
append-splitAt-identity 0       n as = P.refl
append-splitAt-identity (suc m) n as = begin
  let x         = head (m + n) as in
  let (xs , ys) = splitAt m n (tail (m + n) as) in
  append (suc m) n (cons m (head (m + n) as) xs) ys
    ≡⟨ append-cons m n x xs ys 
  cons (m + n) x (append m n xs ys)
    ≡⟨ P.cong (cons (m + n) x) (append-splitAt-identity m n (tail (m + n) as)) 
  cons (m + n) x (tail (m + n) as)
    ≡⟨ cons-head-tail-identity (m + n) as 
  as
    

------------------------------------------------------------------------
-- Conversion to and from Vec

fromVec∘toVec :  n (xs : A ^ n)  fromVec (toVec n xs)  xs
fromVec∘toVec 0       _  = P.refl
fromVec∘toVec (suc n) xs = begin
  cons n (head n xs) (fromVec (toVec n (tail n xs)))
    ≡⟨ P.cong (cons n (head n xs)) (fromVec∘toVec n (tail n xs)) 
  cons n (head n xs) (tail n xs)
    ≡⟨ cons-head-tail-identity n xs 
  xs 

toVec∘fromVec :  {n} (xs : Vec A n)  toVec n (fromVec xs)  xs
toVec∘fromVec             Vec.[]       = P.refl
toVec∘fromVec {n = suc n} (x Vec.∷ xs) = begin
  head n (cons n x (fromVec xs)) Vec.∷ toVec n (tail n (cons n x (fromVec xs)))
    ≡⟨ P.cong₂  x xs  x Vec.∷ toVec n xs) hd-prf tl-prf 
  x Vec.∷ toVec n (fromVec xs)
    ≡⟨ P.cong (x Vec.∷_) (toVec∘fromVec xs) 
  x Vec.∷ xs
     where

  hd-prf = head-cons-identity _ x (fromVec xs)
  tl-prf = tail-cons-identity _ x (fromVec xs)

↔Vec :  n  A ^ n  Vec A n
↔Vec n = mk↔ₛ′ (toVec n) fromVec toVec∘fromVec (fromVec∘toVec n)

------------------------------------------------------------------------
-- DEPRECATED NAMES
------------------------------------------------------------------------
-- Please use the new names as continuing support for the old names is
-- not guaranteed.

-- Version 2.0

append-cons-commute = append-cons
{-# WARNING_ON_USAGE append-cons-commute
"Warning: append-cons-commute was deprecated in v2.0.
Please use append-cons instead."
#-}