/- Copyright (c) 2015 Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Floris van Doorn, Jakob von Raumer Category of sets -/ import ..functor.basic ..category types.equiv types.lift open eq category equiv iso is_equiv is_trunc function sigma namespace category definition precategory_hset.{u} [reducible] [constructor] : precategory hset.{u} := precategory.mk (λx y : hset, x → y) (λx y z g f a, g (f a)) (λx a, a) (λx y z w h g f, eq_of_homotopy (λa, idp)) (λx y f, eq_of_homotopy (λa, idp)) (λx y f, eq_of_homotopy (λa, idp)) definition Precategory_hset [reducible] [constructor] : Precategory := Precategory.mk hset precategory_hset abbreviation set [constructor] := Precategory_hset namespace set local attribute is_equiv_subtype_eq [instance] definition iso_of_equiv [constructor] {A B : set} (f : A ≃ B) : A ≅ B := iso.MK (to_fun f) (to_inv f) (eq_of_homotopy (left_inv (to_fun f))) (eq_of_homotopy (right_inv (to_fun f))) definition equiv_of_iso [constructor] {A B : set} (f : A ≅ B) : A ≃ B := begin apply equiv.MK (to_hom f) (iso.to_inv f), exact ap10 (to_right_inverse f), exact ap10 (to_left_inverse f) end definition is_equiv_iso_of_equiv [constructor] (A B : set) : is_equiv (@iso_of_equiv A B) := adjointify _ (λf, equiv_of_iso f) (λf, proof iso_eq idp qed) (λf, equiv_eq idp) local attribute is_equiv_iso_of_equiv [instance] definition iso_of_eq_eq_compose (A B : hset) : @iso_of_eq _ _ A B = @iso_of_equiv A B ∘ @equiv_of_eq A B ∘ subtype_eq_inv _ _ ∘ @ap _ _ (to_fun (trunctype.sigma_char 0)) A B := eq_of_homotopy (λp, eq.rec_on p idp) definition equiv_equiv_iso (A B : set) : (A ≃ B) ≃ (A ≅ B) := equiv.MK (λf, iso_of_equiv f) (λf, proof equiv.MK (to_hom f) (iso.to_inv f) (ap10 (to_right_inverse f)) (ap10 (to_left_inverse f)) qed) (λf, proof iso_eq idp qed) (λf, proof equiv_eq idp qed) definition equiv_eq_iso (A B : set) : (A ≃ B) = (A ≅ B) := ua !equiv_equiv_iso definition is_univalent_hset (A B : set) : is_equiv (iso_of_eq : A = B → A ≅ B) := assert H₁ : is_equiv (@iso_of_equiv A B ∘ @equiv_of_eq A B ∘ subtype_eq_inv _ _ ∘ @ap _ _ (to_fun (trunctype.sigma_char 0)) A B), from @is_equiv_compose _ _ _ _ _ (@is_equiv_compose _ _ _ _ _ (@is_equiv_compose _ _ _ _ _ _ (@is_equiv_subtype_eq_inv _ _ _ _ _)) !univalence) !is_equiv_iso_of_equiv, let H₂ := (iso_of_eq_eq_compose A B)⁻¹ in begin rewrite H₂ at H₁, assumption end end set definition category_hset [instance] [constructor] [reducible] : category hset := category.mk precategory_hset set.is_univalent_hset definition Category_hset [reducible] [constructor] : Category := Category.mk hset category_hset abbreviation cset [constructor] := Category_hset open functor lift definition functor_lift.{u v} [constructor] : set.{u} ⇒ set.{max u v} := functor.mk tlift (λa b, lift_functor) (λa, eq_of_homotopy (λx, by induction x; reflexivity)) (λa b c g f, eq_of_homotopy (λx, by induction x; reflexivity)) end category