------------------------------------------------------------------------
-- The Agda standard library
--
-- Lexicographic ordering of lists
------------------------------------------------------------------------

-- The definitions of lexicographic ordering used here are suitable if
-- the argument order is a strict partial order.

{-# OPTIONS --without-K --safe #-}

module Data.List.Relation.Binary.Lex.Strict where

open import Data.Empty using ()
open import Data.Unit.Base using (; tt)
open import Function using (_∘_; id)
open import Data.Product using (_,_)
open import Data.Sum.Base using (inj₁; inj₂)
open import Data.List.Base using (List; []; _∷_)
open import Level using (_⊔_)
open import Relation.Nullary using (yes; no; ¬_)
open import Relation.Binary
open import Relation.Binary.Consequences
open import Data.List.Relation.Binary.Pointwise as Pointwise
   using (Pointwise; []; _∷_; head; tail)

open import Data.List.Relation.Binary.Lex.Core as Core public
  using (base; halt; this; next; ²-this; ²-next)

----------------------------------------------------------------------
-- Strict lexicographic ordering.

module _ {a ℓ₁ ℓ₂} {A : Set a} where

  Lex-< : (_≈_ : Rel A ℓ₁) (_≺_ : Rel A ℓ₂) 
          Rel (List A) (a  ℓ₁  ℓ₂)
  Lex-< = Core.Lex 

  -- Properties

  module _ {_≈_ : Rel A ℓ₁} {_≺_ : Rel A ℓ₂} where

    private
      _≋_ = Pointwise _≈_
      _<_ = Lex-< _≈_ _≺_

    ¬[]<[] : ¬ [] < []
    ¬[]<[] (base ())

    <-irreflexive : Irreflexive _≈_ _≺_  Irreflexive _≋_ _<_
    <-irreflexive irr (x≈y  xs≋ys) (this x<y)     = irr x≈y x<y
    <-irreflexive irr (x≈y  xs≋ys) (next _ xs⊴ys) =
      <-irreflexive irr xs≋ys xs⊴ys

    <-asymmetric : Symmetric _≈_  _≺_ Respects₂ _≈_  Asymmetric _≺_ 
                   Asymmetric _<_
    <-asymmetric sym resp as = asym
      where
      irrefl : Irreflexive _≈_ _≺_
      irrefl = asym⟶irr resp sym as

      asym : Asymmetric _<_
      asym (base bot)       _                = bot
      asym (this x<y)       (this y<x)       = as x<y y<x
      asym (this x<y)       (next y≈x ys⊴xs) = irrefl (sym y≈x) x<y
      asym (next x≈y xs⊴ys) (this y<x)       = irrefl (sym x≈y) y<x
      asym (next x≈y xs⊴ys) (next y≈x ys⊴xs) = asym xs⊴ys ys⊴xs

    <-antisymmetric : Symmetric _≈_  Irreflexive _≈_ _≺_ 
                      Asymmetric _≺_  Antisymmetric _≋_ _<_
    <-antisymmetric = Core.antisymmetric

    <-transitive : IsEquivalence _≈_  _≺_ Respects₂ _≈_ 
                   Transitive _≺_  Transitive _<_
    <-transitive = Core.transitive

    <-compare : Symmetric _≈_  Trichotomous _≈_ _≺_ 
                Trichotomous _≋_ _<_
    <-compare sym tri []       []       = tri≈ ¬[]<[] []    ¬[]<[]
    <-compare sym tri []       (y  ys) = tri< halt   (λ()) (λ())
    <-compare sym tri (x  xs) []       = tri> (λ())  (λ()) halt
    <-compare sym tri (x  xs) (y  ys) with tri x y
    ... | tri< x<y x≉y y≮x =
          tri< (this x<y) (x≉y  head) (¬≤-this (x≉y  sym) y≮x)
    ... | tri> x≮y x≉y y<x =
          tri> (¬≤-this x≉y x≮y) (x≉y  head) (this y<x)
    ... | tri≈ x≮y x≈y y≮x with <-compare sym tri xs ys
    ...   | tri< xs<ys xs≉ys ys≮xs =
            tri< (next x≈y xs<ys) (xs≉ys  tail) (¬≤-next y≮x ys≮xs)
    ...   | tri≈ xs≮ys xs≈ys ys≮xs =
            tri≈ (¬≤-next x≮y xs≮ys) (x≈y  xs≈ys) (¬≤-next y≮x ys≮xs)
    ...   | tri> xs≮ys xs≉ys ys<xs =
            tri> (¬≤-next x≮y xs≮ys) (xs≉ys  tail) (next (sym x≈y) ys<xs)

    <-decidable : Decidable _≈_  Decidable _≺_  Decidable _<_
    <-decidable = Core.decidable (no id)

    <-respects₂ : IsEquivalence _≈_  _≺_ Respects₂ _≈_ 
                  _<_ Respects₂ _≋_
    <-respects₂ = Core.respects₂

    <-isStrictPartialOrder : IsStrictPartialOrder _≈_ _≺_ 
                             IsStrictPartialOrder _≋_ _<_
    <-isStrictPartialOrder spo = record
      { isEquivalence = Pointwise.isEquivalence isEquivalence
      ; irrefl        = <-irreflexive irrefl
      ; trans         = Core.transitive isEquivalence <-resp-≈ trans
      ; <-resp-≈      = Core.respects₂ isEquivalence <-resp-≈
      } where open IsStrictPartialOrder spo

    <-isStrictTotalOrder : IsStrictTotalOrder _≈_ _≺_ 
                           IsStrictTotalOrder _≋_ _<_
    <-isStrictTotalOrder sto = record
      { isEquivalence = Pointwise.isEquivalence isEquivalence
      ; trans         = <-transitive isEquivalence <-resp-≈ trans
      ; compare       = <-compare Eq.sym compare
      } where open IsStrictTotalOrder sto

<-strictPartialOrder :  {a ℓ₁ ℓ₂}  StrictPartialOrder a ℓ₁ ℓ₂ 
                       StrictPartialOrder _ _ _
<-strictPartialOrder spo = record
  { isStrictPartialOrder = <-isStrictPartialOrder isStrictPartialOrder
  } where open StrictPartialOrder spo

<-strictTotalOrder :  {a ℓ₁ ℓ₂}  StrictTotalOrder a ℓ₁ ℓ₂ 
                       StrictTotalOrder _ _ _
<-strictTotalOrder sto = record
  { isStrictTotalOrder = <-isStrictTotalOrder isStrictTotalOrder
  } where open StrictTotalOrder sto

----------------------------------------------------------------------
-- Non-strict lexicographic ordering.

module _ {a ℓ₁ ℓ₂} {A : Set a} where

  Lex-≤ : (_≈_ : Rel A ℓ₁) (_≺_ : Rel A ℓ₂) 
          Rel (List A) (a  ℓ₁  ℓ₂)
  Lex-≤ = Core.Lex 

  -- Properties

  ≤-reflexive : (_≈_ : Rel A ℓ₁) (_≺_ : Rel A ℓ₂) 
                Pointwise _≈_  Lex-≤ _≈_ _≺_
  ≤-reflexive _≈_ _≺_ []            = base tt
  ≤-reflexive _≈_ _≺_ (x≈y  xs≈ys) =
    next x≈y (≤-reflexive _≈_ _≺_ xs≈ys)

  module _ {_≈_ : Rel A ℓ₁} {_≺_ : Rel A ℓ₂} where

    private
      _≋_ = Pointwise _≈_
      _≤_ = Lex-≤ _≈_ _≺_

    ≤-antisymmetric : Symmetric _≈_  Irreflexive _≈_ _≺_ 
                      Asymmetric _≺_  Antisymmetric _≋_ _≤_
    ≤-antisymmetric = Core.antisymmetric

    ≤-transitive : IsEquivalence _≈_  _≺_ Respects₂ _≈_ 
                   Transitive _≺_  Transitive _≤_
    ≤-transitive = Core.transitive

    -- Note that trichotomy is an unnecessarily strong precondition for
    -- the following lemma.

    ≤-total : Symmetric _≈_  Trichotomous _≈_ _≺_  Total _≤_
    ≤-total _   _   []       []       = inj₁ (base tt)
    ≤-total _   _   []       (x  xs) = inj₁ halt
    ≤-total _   _   (x  xs) []       = inj₂ halt
    ≤-total sym tri (x  xs) (y  ys) with tri x y
    ... | tri< x<y _ _ = inj₁ (this x<y)
    ... | tri> _ _ y<x = inj₂ (this y<x)
    ... | tri≈ _ x≈y _ with ≤-total sym tri xs ys
    ...   | inj₁ xs≲ys = inj₁ (next      x≈y  xs≲ys)
    ...   | inj₂ ys≲xs = inj₂ (next (sym x≈y) ys≲xs)

    ≤-decidable : Decidable _≈_  Decidable _≺_  Decidable _≤_
    ≤-decidable = Core.decidable (yes tt)

    ≤-respects₂ : IsEquivalence _≈_  _≺_ Respects₂ _≈_ 
                  _≤_ Respects₂ _≋_
    ≤-respects₂ = Core.respects₂

    ≤-isPreorder : IsEquivalence _≈_  Transitive _≺_ 
                   _≺_ Respects₂ _≈_  IsPreorder _≋_ _≤_
    ≤-isPreorder eq tr resp = record
      { isEquivalence = Pointwise.isEquivalence eq
      ; reflexive     = ≤-reflexive _≈_ _≺_
      ; trans         = Core.transitive eq resp tr
      }

    ≤-isPartialOrder : IsStrictPartialOrder _≈_ _≺_ 
                       IsPartialOrder _≋_ _≤_
    ≤-isPartialOrder  spo = record
      { isPreorder = ≤-isPreorder isEquivalence trans <-resp-≈
      ; antisym    = Core.antisymmetric Eq.sym irrefl asym
      }
      where open IsStrictPartialOrder spo

    ≤-isTotalOrder : IsStrictTotalOrder _≈_ _≺_  IsTotalOrder _≋_ _≤_
    ≤-isTotalOrder sto = record
      { isPartialOrder = ≤-isPartialOrder isStrictPartialOrder
      ; total          = ≤-total Eq.sym compare
      }
      where open IsStrictTotalOrder sto

    ≤-isDecTotalOrder : IsStrictTotalOrder _≈_ _≺_ 
                        IsDecTotalOrder _≋_ _≤_
    ≤-isDecTotalOrder sto = record
      { isTotalOrder = ≤-isTotalOrder sto
      ; _≟_          = Pointwise.decidable _≟_
      ; _≤?_         = ≤-decidable _≟_ _<?_
      }
      where open IsStrictTotalOrder sto

≤-preorder :  {a ℓ₁ ℓ₂}  Preorder a ℓ₁ ℓ₂  Preorder _ _ _
≤-preorder pre = record
  { isPreorder = ≤-isPreorder isEquivalence trans ∼-resp-≈
  } where open Preorder pre

≤-partialOrder :  {a ℓ₁ ℓ₂}  StrictPartialOrder a ℓ₁ ℓ₂  Poset _ _ _
≤-partialOrder spo = record
  { isPartialOrder = ≤-isPartialOrder isStrictPartialOrder
  } where open StrictPartialOrder spo

≤-decTotalOrder :  {a ℓ₁ ℓ₂}  StrictTotalOrder a ℓ₁ ℓ₂ 
                  DecTotalOrder _ _ _
≤-decTotalOrder sto = record
  { isDecTotalOrder = ≤-isDecTotalOrder isStrictTotalOrder
  } where open StrictTotalOrder sto