/- Copyright (c) 2016 Jakob von Raumer. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Floris van Doorn, Favonia The Wedge Sum of a family of Pointed Types -/ import homotopy.wedge ..move_to_lib ..choice ..pointed_pi open eq is_equiv pushout pointed unit trunc_index sigma bool equiv choice unit is_trunc sigma.ops lift function pi prod definition fwedge' {I : Type} (F : I → Type*) : Type := pushout (λi, ⟨i, Point (F i)⟩) (λi, ⋆) definition pt' [constructor] {I : Type} {F : I → Type*} : fwedge' F := inr ⋆ definition fwedge [constructor] {I : Type} (F : I → Type*) : Type* := pointed.MK (fwedge' F) pt' notation `⋁` := fwedge namespace fwedge variables {I : Type} {F : I → Type*} definition il {i : I} (x : F i) : ⋁F := inl ⟨i, x⟩ definition inl (i : I) (x : F i) : ⋁F := il x definition pinl [constructor] (i : I) : F i →* ⋁F := pmap.mk (inl i) (glue i) definition glue (i : I) : inl i pt = pt :> ⋁ F := glue i protected definition rec {P : ⋁F → Type} (Pinl : Π(i : I) (x : F i), P (il x)) (Pinr : P pt) (Pglue : Πi, pathover P (Pinl i pt) (glue i) (Pinr)) (y : fwedge' F) : P y := begin induction y, induction x, apply Pinl, induction x, apply Pinr, apply Pglue end protected definition elim {P : Type} (Pinl : Π(i : I) (x : F i), P) (Pinr : P) (Pglue : Πi, Pinl i pt = Pinr) (y : fwedge' F) : P := begin induction y with x u, induction x with i x, exact Pinl i x, induction u, apply Pinr, apply Pglue end protected definition elim_glue {P : Type} {Pinl : Π(i : I) (x : F i), P} {Pinr : P} (Pglue : Πi, Pinl i pt = Pinr) (i : I) : ap (fwedge.elim Pinl Pinr Pglue) (fwedge.glue i) = Pglue i := !pushout.elim_glue protected definition rec_glue {P : ⋁F → Type} {Pinl : Π(i : I) (x : F i), P (il x)} {Pinr : P pt} (Pglue : Πi, pathover P (Pinl i pt) (glue i) (Pinr)) (i : I) : apd (fwedge.rec Pinl Pinr Pglue) (fwedge.glue i) = Pglue i := !pushout.rec_glue end fwedge attribute fwedge.rec fwedge.elim [recursor 7] [unfold 7] attribute fwedge.il fwedge.inl [constructor] namespace fwedge definition fwedge_of_pwedge [unfold 3] {A B : Type*} (x : A ∨ B) : ⋁(bool.rec A B) := begin induction x with a b, { exact inl ff a }, { exact inl tt b }, { exact glue ff ⬝ (glue tt)⁻¹ } end definition pwedge_of_fwedge [unfold 3] {A B : Type*} (x : ⋁(bool.rec A B)) : A ∨ B := begin induction x with b x b, { induction b, exact pushout.inl x, exact pushout.inr x }, { exact pushout.inr pt }, { induction b, exact pushout.glue ⋆, reflexivity } end definition pwedge_pequiv_fwedge [constructor] (A B : Type*) : A ∨ B ≃* ⋁(bool.rec A B) := begin fapply pequiv_of_equiv, { fapply equiv.MK, { exact fwedge_of_pwedge }, { exact pwedge_of_fwedge }, { exact abstract begin intro x, induction x with b x b, { induction b: reflexivity }, { exact glue tt }, { apply eq_pathover_id_right, refine ap_compose fwedge_of_pwedge _ _ ⬝ ap02 _ !elim_glue ⬝ph _, induction b, exact !elim_glue ⬝ph whisker_bl _ hrfl, apply square_of_eq idp } end end }, { exact abstract begin intro x, induction x with a b, { reflexivity }, { reflexivity }, { apply eq_pathover_id_right, refine ap_compose pwedge_of_fwedge _ _ ⬝ ap02 _ !elim_glue ⬝ !ap_con ⬝ !elim_glue ◾ (!ap_inv ⬝ !elim_glue⁻²) ⬝ph _, exact hrfl } end end}}, { exact glue ff } end definition is_contr_fwedge_of_neg {I : Type} (P : I → Type*) (H : ¬ I) : is_contr (⋁P) := begin apply is_contr.mk pt, intro x, induction x, contradiction, reflexivity, contradiction end definition is_contr_fwedge_empty [instance] : is_contr (⋁empty.elim) := is_contr_fwedge_of_neg _ id definition fwedge_pmap [constructor] {I : Type} {F : I → Type*} {X : Type*} (f : Πi, F i →* X) : ⋁F →* X := begin fconstructor, { intro x, induction x, exact f i x, exact pt, exact respect_pt (f i) }, { reflexivity } end definition pwedge_pmap [constructor] {A B : Type*} {X : Type*} (f : A →* X) (g : B →* X) : (A ∨ B) →* X := begin fapply pmap.mk, { intro x, induction x, exact (f a), exact (g a), exact (respect_pt (f) ⬝ (respect_pt g)⁻¹) }, { exact respect_pt f } end definition fwedge_pmap_beta [constructor] {I : Type} {F : I → Type*} {X : Type*} (f : Πi, F i →* X) (i : I) : fwedge_pmap f ∘* pinl i ~* f i := begin fapply phomotopy.mk, { reflexivity }, { exact !idp_con ⬝ !fwedge.elim_glue⁻¹ } end definition fwedge_pmap_eta [constructor] {I : Type} {F : I → Type*} {X : Type*} (g : ⋁F →* X) : fwedge_pmap (λi, g ∘* pinl i) ~* g := begin fapply phomotopy.mk, { intro x, induction x, reflexivity, exact (respect_pt g)⁻¹, apply eq_pathover, refine !elim_glue ⬝ph _, apply whisker_lb, exact hrfl }, { exact con.left_inv (respect_pt g) } end definition fwedge_pmap_pinl [constructor] {I : Type} {F : I → Type*} : fwedge_pmap (λi, pinl i) ~* pid (⋁ F) := begin fapply phomotopy.mk, { intro x, induction x, reflexivity, reflexivity, apply eq_pathover, apply hdeg_square, refine !elim_glue ⬝ !ap_id⁻¹ }, { reflexivity } end definition fwedge_pmap_equiv [constructor] {I : Type} (F : I → Type*) (X : Type*) : ⋁F →* X ≃ Πi, F i →* X := begin fapply equiv.MK, { intro g i, exact g ∘* pinl i }, { exact fwedge_pmap }, { intro f, apply eq_of_homotopy, intro i, apply eq_of_phomotopy, apply fwedge_pmap_beta f i }, { intro g, apply eq_of_phomotopy, exact fwedge_pmap_eta g } end definition pwedge_pmap_equiv [constructor] (A B X : Type*) : ((A ∨ B) →* X) ≃ ((A →* X) × (B →* X)) := calc (A ∨ B) →* X ≃ ⋁(bool.rec A B) →* X : by exact pequiv_ppcompose_right (pwedge_pequiv_fwedge A B)⁻¹ᵉ* ... ≃ Πi, (bool.rec A B) i →* X : by exact fwedge_pmap_equiv (bool.rec A B) X ... ≃ (A →* X) × (B →* X) : by exact pi_bool_left (λ i, bool.rec A B i →* X) definition fwedge_pmap_nat₂ {I : Type}(F : I → Type*){X Y : Type*} (f : X →* Y) (h : Πi, F i →* X) (w : fwedge F) : (f ∘* (fwedge_pmap h)) w = fwedge_pmap (λi, f ∘* (h i)) w := begin induction w, reflexivity, refine !respect_pt, apply eq_pathover, refine ap_compose f (fwedge_pmap h) _ ⬝ph _, refine ap (ap f) !elim_glue ⬝ph _, refine _ ⬝hp !elim_glue⁻¹, esimp, apply whisker_br, apply !hrefl end -- making the maps in hsquare 1: -- top and bottom: definition prod_pi_bool_comp_funct {A B : Type*}(X : Type*) : (A →* X) × (B →* X) → Π u, (bool.rec A B u →* X) := begin refine equiv.symm _, fapply pi_bool_left end -- left: definition prod_funct_comp {A B X Y : Type*} (f : X →* Y) : (A →* X) × (B →* X) → (A →* Y) × (B →* Y) := prod_functor (pcompose f) (pcompose f) -- right: definition left_comp_pi_bool_funct {A B X Y : Type*} (f : X →* Y) : (Π u, (bool.rec A B u →* X)) → (Π u, (bool.rec A B u →* Y)) := begin intro, intro, exact f ∘* (a u) end definition left_comp_pi_bool {A B X Y : Type*} (f : X →* Y) : Π u, ((bool.rec A B u →* X) → (bool.rec A B u →* Y)) := begin intro, intro, exact f∘* a end -- hsquare 1: definition prod_to_pi_bool_nat_square {A B X Y : Type*} (f : X →* Y) : hsquare (prod_pi_bool_comp_funct X) (prod_pi_bool_comp_funct Y) (prod_funct_comp f) (@left_comp_pi_bool_funct A B X Y f) := begin intro x, fapply eq_of_homotopy, intro u, induction u, esimp, esimp end -- hsquare 2: definition fwedge_pmap_nat_square {A B X Y : Type*} (f : X →* Y) : hsquare (fwedge_pmap_equiv (bool.rec A B) X)⁻¹ᵉ (fwedge_pmap_equiv (bool.rec A B) Y)⁻¹ᵉ (left_comp_pi_bool_funct f) (pcompose f) := begin intro h, esimp, fapply pmap_eq, exact fwedge_pmap_nat₂ (λ u, bool.rec A B u) f h, esimp, end -- hsquare 3: definition fwedge_to_pwedge_nat_square {A B X Y : Type*} (f : X →* Y) : hsquare (pequiv_ppcompose_right (pwedge_pequiv_fwedge A B)) (pequiv_ppcompose_right (pwedge_pequiv_fwedge A B)) (pcompose f) (pcompose f) := begin exact sorry end definition pwedge_pmap_nat₂ (A B X Y : Type*) (f : X →* Y) (h : A →* X) (k : B →* X) : Π (w : A ∨ B), (f ∘* (pwedge_pmap h k)) w = pwedge_pmap (f ∘* h )(f ∘* k) w := have H : _, from (@prod_to_pi_bool_nat_square A B X Y f) ⬝htyh (fwedge_pmap_nat_square f) ⬝htyh (fwedge_to_pwedge_nat_square f), sorry -- SA to here 7/5 definition fwedge_pmap_phomotopy {I : Type} {F : I → Type*} {X : Type*} {f g : Π i, F i →* X} (h : Π i, f i ~* g i) : fwedge_pmap f ~* fwedge_pmap g := begin fconstructor, { fapply fwedge.rec, { exact h }, { reflexivity }, { intro i, apply eq_pathover, refine _ ⬝ph _ ⬝hp _, { exact (respect_pt (g i)) }, { exact (respect_pt (f i)) }, { exact !elim_glue }, { apply square_of_eq, exact ((phomotopy.sigma_char (f i) (g i)) (h i)).2 }, { refine !elim_glue⁻¹ } } }, { reflexivity } end open trunc definition trunc_fwedge_pmap_equiv.{u} {n : ℕ₋₂} {I : Type.{u}} (H : has_choice n I) (F : I → pType.{u}) (X : pType.{u}) : trunc n (⋁F →* X) ≃ Πi, trunc n (F i →* X) := trunc_equiv_trunc n (fwedge_pmap_equiv F X) ⬝e choice_equiv (λi, F i →* X) definition fwedge_functor [constructor] {I : Type} {F F' : I → Type*} (f : Π i, F i →* F' i) : ⋁ F →* ⋁ F' := fwedge_pmap (λ i, pinl i ∘* f i) definition fwedge_functor_pid {I : Type} {F : I → Type*} : @fwedge_functor I F F (λ i, !pid) ~* !pid := calc fwedge_pmap (λ i, pinl i ∘* !pid) ~* fwedge_pmap pinl : by exact fwedge_pmap_phomotopy (λ i, pcompose_pid (pinl i)) ... ~* fwedge_pmap (λ i, !pid ∘* pinl i) : by exact fwedge_pmap_phomotopy (λ i, phomotopy.symm (pid_pcompose (pinl i))) ... ~* !pid : by exact fwedge_pmap_eta !pid definition fwedge_functor_pcompose {I : Type} {F F' F'' : I → Type*} (g : Π i, F' i →* F'' i) (f : Π i, F i →* F' i) : fwedge_functor (λ i, g i ∘* f i) ~* fwedge_functor g ∘* fwedge_functor f := calc fwedge_functor (λ i, g i ∘* f i) ~* fwedge_pmap (λ i, (pinl i ∘* g i) ∘* f i) : by exact fwedge_pmap_phomotopy (λ i, phomotopy.symm (passoc (pinl i) (g i) (f i))) ... ~* fwedge_pmap (λ i, (fwedge_functor g ∘* pinl i) ∘* f i) : by exact fwedge_pmap_phomotopy (λ i, pwhisker_right (f i) (phomotopy.symm (fwedge_pmap_beta (λ i, pinl i ∘* g i) i))) ... ~* fwedge_pmap (λ i, fwedge_functor g ∘* (pinl i ∘* f i)) : by exact fwedge_pmap_phomotopy (λ i, passoc (fwedge_functor g) (pinl i) (f i)) ... ~* fwedge_pmap (λ i, fwedge_functor g ∘* (fwedge_functor f ∘* pinl i)) : by exact fwedge_pmap_phomotopy (λ i, pwhisker_left (fwedge_functor g) (phomotopy.symm (fwedge_pmap_beta (λ i, pinl i ∘* f i) i))) ... ~* fwedge_pmap (λ i, (fwedge_functor g ∘* fwedge_functor f) ∘* pinl i) : by exact fwedge_pmap_phomotopy (λ i, (phomotopy.symm (passoc (fwedge_functor g) (fwedge_functor f) (pinl i)))) ... ~* fwedge_functor g ∘* fwedge_functor f : by exact fwedge_pmap_eta (fwedge_functor g ∘* fwedge_functor f) definition fwedge_functor_phomotopy {I : Type} {F F' : I → Type*} {f g : Π i, F i →* F' i} (h : Π i, f i ~* g i) : fwedge_functor f ~* fwedge_functor g := fwedge_pmap_phomotopy (λ i, pwhisker_left (pinl i) (h i)) definition fwedge_pequiv [constructor] {I : Type} {F F' : I → Type*} (f : Π i, F i ≃* F' i) : ⋁ F ≃* ⋁ F' := let pto := fwedge_functor (λ i, f i) in let pfrom := fwedge_functor (λ i, (f i)⁻¹ᵉ*) in begin fapply pequiv_of_pmap, exact pto, fapply adjointify, exact pfrom, { intro y, refine (fwedge_functor_pcompose (λ i, f i) (λ i, (f i)⁻¹ᵉ*) y)⁻¹ ⬝ _, refine fwedge_functor_phomotopy (λ i, pright_inv (f i)) y ⬝ _, exact fwedge_functor_pid y }, { intro y, refine (fwedge_functor_pcompose (λ i, (f i)⁻¹ᵉ*) (λ i, f i) y)⁻¹ ⬝ _, refine fwedge_functor_phomotopy (λ i, pleft_inv (f i)) y ⬝ _, exact fwedge_functor_pid y } end definition plift_fwedge.{u v} {I : Type} (F : I → pType.{u}) : plift.{u v} (⋁ F) ≃* ⋁ (plift.{u v} ∘ F) := calc plift.{u v} (⋁ F) ≃* ⋁ F : by exact !pequiv_plift ⁻¹ᵉ* ... ≃* ⋁ (λ i, plift.{u v} (F i)) : by exact fwedge_pequiv (λ i, !pequiv_plift) definition fwedge_down_left.{u v} {I : Type} (F : I → pType) : ⋁ (F ∘ down.{u v}) ≃* ⋁ F := proof let pto := @fwedge_pmap (lift.{u v} I) (F ∘ down) (⋁ F) (λ i, pinl (down i)) in let pfrom := @fwedge_pmap I F (⋁ (F ∘ down.{u v})) (λ i, pinl (up.{u v} i)) in begin fapply pequiv_of_pmap, { exact pto }, fapply adjointify, { exact pfrom }, { intro x, exact calc pto (pfrom x) = fwedge_pmap (λ i, (pto ∘* pfrom) ∘* pinl i) x : by exact (fwedge_pmap_eta (pto ∘* pfrom) x)⁻¹ ... = fwedge_pmap (λ i, pto ∘* (pfrom ∘* pinl i)) x : by exact fwedge_pmap_phomotopy (λ i, passoc pto pfrom (pinl i)) x ... = fwedge_pmap (λ i, pto ∘* pinl (up.{u v} i)) x : by exact fwedge_pmap_phomotopy (λ i, pwhisker_left pto (fwedge_pmap_beta (λ i, pinl (up.{u v} i)) i)) x ... = fwedge_pmap pinl x : by exact fwedge_pmap_phomotopy (λ i, fwedge_pmap_beta (λ i, (pinl (down.{u v} i))) (up.{u v} i)) x ... = x : by exact fwedge_pmap_pinl x }, { intro x, exact calc pfrom (pto x) = fwedge_pmap (λ i, (pfrom ∘* pto) ∘* pinl i) x : by exact (fwedge_pmap_eta (pfrom ∘* pto) x)⁻¹ ... = fwedge_pmap (λ i, pfrom ∘* (pto ∘* pinl i)) x : by exact fwedge_pmap_phomotopy (λ i, passoc pfrom pto (pinl i)) x ... = fwedge_pmap (λ i, pfrom ∘* pinl (down.{u v} i)) x : by exact fwedge_pmap_phomotopy (λ i, pwhisker_left pfrom (fwedge_pmap_beta (λ i, pinl (down.{u v} i)) i)) x ... = fwedge_pmap pinl x : by exact fwedge_pmap_phomotopy (λ i, begin induction i with i, exact fwedge_pmap_beta (λ i, (pinl (up.{u v} i))) i end ) x ... = x : by exact fwedge_pmap_pinl x } end qed end fwedge