{-# OPTIONS --cubical --safe --no-sized-types --no-guardedness
            --no-subtyping #-}

module Agda.Builtin.Cubical.Glue where

open import Agda.Primitive
open import Agda.Builtin.Sigma
open import Agda.Primitive.Cubical renaming (primINeg to ~_; primIMax to _∨_; primIMin to _∧_;
                                             primHComp to hcomp; primTransp to transp; primComp to comp;
                                             itIsOne to 1=1)
open import Agda.Builtin.Cubical.Path
open import Agda.Builtin.Cubical.Sub renaming (Sub to _[_↦_]; primSubOut to ouc)
import Agda.Builtin.Cubical.HCompU as HCompU

module Helpers = HCompU.Helpers

open Helpers


-- We make this a record so that isEquiv can be proved using
-- copatterns. This is good because copatterns don't get unfolded
-- unless a projection is applied so it should be more efficient.
record isEquiv { ℓ'} {A : Set } {B : Set ℓ'} (f : A  B) : Set (  ℓ') where
  no-eta-equality
  field
    equiv-proof : (y : B)  isContr (fiber f y)

open isEquiv public

infix 4 _≃_


_≃_ :  { ℓ'} (A : Set ) (B : Set ℓ')  Set (  ℓ')
A  B = Σ (A  B) \ f  (isEquiv f)

equivFun :  { ℓ'} {A : Set } {B : Set ℓ'}  A  B  A  B
equivFun e = fst e

-- Improved version of equivProof compared to Lemma 5 in CCHM. We put
-- the (φ = i0) face in contr' making it be definitionally c in this
-- case. This makes the computational behavior better, in particular
-- for transp in Glue.
equivProof :  {la lt} (T : Set la) (A : Set lt)  (w : T  A)  (a : A)
             ψ  (Partial ψ (fiber (w .fst) a))  fiber (w .fst) a
equivProof A B w a ψ fb = contr' {A = fiber (w .fst) a} (w .snd .equiv-proof a) ψ fb
  where
    contr' :  {} {A : Set }  isContr A  (φ : I)  (u : Partial φ A)  A
    contr' {A = A} (c , p) φ u = hcomp  i  λ { (φ = i1)  p (u 1=1) i
                                                ; (φ = i0)  c }) c


{-# BUILTIN EQUIV      _≃_        #-}
{-# BUILTIN EQUIVFUN   equivFun   #-}
{-# BUILTIN EQUIVPROOF equivProof #-}

primitive
    primGlue    :  { ℓ'} (A : Set ) {φ : I}
       (T : Partial φ (Set ℓ'))  (e : PartialP φ  o  T o  A))
       Set ℓ'
    prim^glue   :  { ℓ'} {A : Set } {φ : I}
       {T : Partial φ (Set ℓ')}  {e : PartialP φ  o  T o  A)}
       (t : PartialP φ T)  (a : A)  primGlue A T e
    prim^unglue :  { ℓ'} {A : Set } {φ : I}
       {T : Partial φ (Set ℓ')}  {e : PartialP φ  o  T o  A)}
       primGlue A T e  A



module _ { : I  Level} (P : (i : I)  Set ( i)) where
  private
    E : (i : I)  Set ( i)
    E  = λ i  P i
    ~E : (i : I)  Set ( (~ i))
    ~E = λ i  P (~ i)

    A = P i0
    B = P i1

    f : A  B
    f x = transp E i0 x

    g : B  A
    g y = transp ~E i0 y

    u :  i  A  E i
    u i x = transp  j  E (i  j)) (~ i) x

    v :  i  B  E i
    v i y = transp  j  ~E ( ~ i  j)) i y

    fiberPath : (y : B)  (xβ0 xβ1 : fiber f y)  xβ0  xβ1
    fiberPath y (x0 , β0) (x1 , β1) k = ω , λ j  δ (~ j) where
      module _ (j : I) where
        private
          sys : A   i  PartialP (~ j  j)  _  E (~ i))
          sys x i (j = i0) = v (~ i) y
          sys x i (j = i1) = u (~ i) x
        ω0 = comp ~E (sys x0) ((β0 (~ j)))
        ω1 = comp ~E (sys x1) ((β1 (~ j)))
        θ0 = fill ~E (sys x0) (inc (β0 (~ j)))
        θ1 = fill ~E (sys x1) (inc (β1 (~ j)))
      sys = λ {j (k = i0)  ω0 j ; j (k = i1)  ω1 j}
      ω = hcomp sys (g y)
      θ = hfill sys (inc (g y))
      δ = λ (j : I)  comp E
             i  λ { (j = i0)  v i y ; (k = i0)  θ0 j (~ i)
                     ; (j = i1)  u i ω ; (k = i1)  θ1 j (~ i) })
             (θ j)

    γ : (y : B)  y  f (g y)
    γ y j = comp E  i  λ { (j = i0)  v i y
                            ; (j = i1)  u i (g y) }) (g y)

  pathToisEquiv : isEquiv f
  pathToisEquiv .equiv-proof y .fst .fst = g y
  pathToisEquiv .equiv-proof y .fst .snd = sym (γ y)
  pathToisEquiv .equiv-proof y .snd = fiberPath y _

  pathToEquiv : A  B
  pathToEquiv .fst = f
  pathToEquiv .snd = pathToisEquiv