/- Copyright (c) 2014 Floris van Doorn. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Module: algebra.precategory.constructions Authors: Floris van Doorn, Jakob von Raumer This file contains basic constructions on precategories, including common precategories -/ import .nat_trans import types.prod types.sigma types.pi open eq prod eq eq.ops equiv is_trunc namespace category namespace opposite definition opposite [reducible] {ob : Type} (C : precategory ob) : precategory ob := precategory.mk (λ a b, hom b a) (λ a b, !homH) (λ a b c f g, g ∘ f) (λ a, id) (λ a b c d f g h, !assoc⁻¹) (λ a b f, !id_right) (λ a b f, !id_left) definition Opposite [reducible] (C : Precategory) : Precategory := precategory.Mk (opposite C) infixr `∘op`:60 := @comp _ (opposite _) _ _ _ variables {C : Precategory} {a b c : C} set_option apply.class_instance false -- disable class instance resolution in the apply tactic definition compose_op {f : hom a b} {g : hom b c} : f ∘op g = g ∘ f := idp -- TODO: Decide whether just to use funext for this theorem or -- take the trick they use in Coq-HoTT, and introduce a further -- axiom in the definition of precategories that provides thee -- symmetric associativity proof. definition opposite_opposite' {ob : Type} (C : precategory ob) : opposite (opposite C) = C := begin apply (precategory.rec_on C), intros (hom', homH', comp', ID', assoc', id_left', id_right'), apply (ap (λassoc'', precategory.mk hom' @homH' comp' ID' assoc'' id_left' id_right')), repeat (apply eq_of_homotopy ; intros ), apply ap, apply (@is_hset.elim), apply !homH', end definition opposite_opposite : Opposite (Opposite C) = C := (ap (Precategory.mk C) (opposite_opposite' C)) ⬝ !Precategory.eta end opposite -- Note: Discrete precategory doesn't really make sense in HoTT, -- We'll define a discrete _category_ later. /-section open decidable unit empty variables {A : Type} [H : decidable_eq A] include H definition set_hom (a b : A) := decidable.rec_on (H a b) (λh, unit) (λh, empty) theorem set_hom_subsingleton [instance] (a b : A) : subsingleton (set_hom a b) := _ definition set_compose {a b c : A} (g : set_hom b c) (f : set_hom a b) : set_hom a c := decidable.rec_on (H b c) (λ Hbc g, decidable.rec_on (H a b) (λ Hab f, rec_on_true (trans Hab Hbc) ⋆) (λh f, empty.rec _ f) f) (λh (g : empty), empty.rec _ g) g omit H definition discrete_precategory (A : Type) [H : decidable_eq A] : precategory A := mk (λa b, set_hom a b) (λ a b c g f, set_compose g f) (λ a, decidable.rec_on_true rfl ⋆) (λ a b c d h g f, @subsingleton.elim (set_hom a d) _ _ _) (λ a b f, @subsingleton.elim (set_hom a b) _ _ _) (λ a b f, @subsingleton.elim (set_hom a b) _ _ _) definition Discrete_category (A : Type) [H : decidable_eq A] := Mk (discrete_category A) end section open unit bool definition category_one := discrete_category unit definition Category_one := Mk category_one definition category_two := discrete_category bool definition Category_two := Mk category_two end-/ namespace product section open prod is_trunc definition precategory_prod [reducible] {obC obD : Type} (C : precategory obC) (D : precategory obD) : precategory (obC × obD) := precategory.mk (λ a b, hom (pr1 a) (pr1 b) × hom (pr2 a) (pr2 b)) (λ a b, !is_trunc_prod) (λ a b c g f, (pr1 g ∘ pr1 f , pr2 g ∘ pr2 f)) (λ a, (id, id)) (λ a b c d h g f, pair_eq !assoc !assoc ) (λ a b f, prod_eq !id_left !id_left ) (λ a b f, prod_eq !id_right !id_right) definition Precategory_prod [reducible] (C D : Precategory) : Precategory := precategory.Mk (precategory_prod C D) end end product namespace ops --notation 1 := Category_one --notation 2 := Category_two postfix `ᵒᵖ`:max := opposite.Opposite infixr `×c`:30 := product.Precategory_prod --instance [persistent] type_category category_one -- category_two product.prod_category end ops open ops namespace opposite open ops functor definition opposite_functor [reducible] {C D : Precategory} (F : C ⇒ D) : Cᵒᵖ ⇒ Dᵒᵖ := begin apply (@functor.mk (Cᵒᵖ) (Dᵒᵖ)), intro a, apply (respect_id F), intros, apply (@respect_comp C D) end end opposite namespace product section open ops functor definition prod_functor [reducible] {C C' D D' : Precategory} (F : C ⇒ D) (G : C' ⇒ D') : C ×c C' ⇒ D ×c D' := functor.mk (λ a, pair (F (pr1 a)) (G (pr2 a))) (λ a b f, pair (F (pr1 f)) (G (pr2 f))) (λ a, pair_eq !respect_id !respect_id) (λ a b c g f, pair_eq !respect_comp !respect_comp) end end product definition precategory_hset [reducible] : precategory hset := 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] : Precategory := Precategory.mk hset precategory_hset section open iso functor nat_trans definition precategory_functor [instance] [reducible] (D C : Precategory) : precategory (functor C D) := precategory.mk (λa b, nat_trans a b) (λ a b, @is_hset_nat_trans C D a b) (λ a b c g f, nat_trans.compose g f) (λ a, nat_trans.id) (λ a b c d h g f, !nat_trans.assoc) (λ a b f, !nat_trans.id_left) (λ a b f, !nat_trans.id_right) definition Precategory_functor [reducible] (D C : Precategory) : Precategory := precategory.Mk (precategory_functor D C) -- definition Precategory_functor_rev [reducible] (C D : Precategory) : Precategory := -- Precategory_functor D C end namespace ops infixr `^c`:35 := Precategory_functor end ops section open iso functor nat_trans /- we prove that if a natural transformation is pointwise an to_fun, then it is an to_fun -/ variables {C D : Precategory} {F G : C ⇒ D} (η : F ⟹ G) [iso : Π(a : C), is_iso (η a)] include iso definition nat_trans_inverse : G ⟹ F := nat_trans.mk (λc, (η c)⁻¹) (λc d f, begin apply comp_inverse_eq_of_eq_comp, apply concat, rotate_left 1, apply assoc, apply eq_inverse_comp_of_comp_eq, apply inverse, apply naturality, end) definition nat_trans_left_inverse : nat_trans_inverse η ∘n η = nat_trans.id := begin fapply (apD011 nat_trans.mk), apply eq_of_homotopy, intro c, apply left_inverse, apply eq_of_homotopy, intros, apply eq_of_homotopy, intros, apply eq_of_homotopy, intros, apply is_hset.elim end definition nat_trans_right_inverse : η ∘n nat_trans_inverse η = nat_trans.id := begin fapply (apD011 nat_trans.mk), apply eq_of_homotopy, intro c, apply right_inverse, apply eq_of_homotopy, intros, apply eq_of_homotopy, intros, apply eq_of_homotopy, intros, apply is_hset.elim end definition is_iso_nat_trans : is_iso η := is_iso.mk (nat_trans_left_inverse η) (nat_trans_right_inverse η) omit iso -- local attribute is_iso_nat_trans [instance] -- definition functor_iso_functor (H : Π(a : C), F a ≅ G a) : F ≅ G := -- is this true? -- iso.mk _ end section open iso functor category.ops nat_trans iso.iso /- and conversely, if a natural transformation is an iso, it is componentwise an iso -/ variables {C D : Precategory} {F G : D ^c C} (η : hom F G) [isoη : is_iso η] (c : C) include isoη definition componentwise_is_iso : is_iso (η c) := @is_iso.mk _ _ _ _ _ (natural_map η⁻¹ c) (ap010 natural_map ( left_inverse η) c) (ap010 natural_map (right_inverse η) c) local attribute componentwise_is_iso [instance] definition natural_map_inverse : natural_map η⁻¹ c = (η c)⁻¹ := idp definition naturality_iso {c c' : C} (f : c ⟶ c') : G f = η c' ∘ F f ∘ (η c)⁻¹ := calc G f = (G f ∘ η c) ∘ (η c)⁻¹ : comp_inverse_cancel_right ... = (η c' ∘ F f) ∘ (η c)⁻¹ : {naturality η f} ... = η c' ∘ F f ∘ (η c)⁻¹ : assoc definition naturality_iso' {c c' : C} (f : c ⟶ c') : (η c')⁻¹ ∘ G f ∘ η c = F f := calc (η c')⁻¹ ∘ G f ∘ η c = (η c')⁻¹ ∘ η c' ∘ F f : {naturality η f} ... = F f : inverse_comp_cancel_left omit isoη definition componentwise_iso (η : F ≅ G) (c : C) : F c ≅ G c := @iso.mk _ _ _ _ (natural_map (to_hom η) c) (@componentwise_is_iso _ _ _ _ (to_hom η) (struct η) c) definition componentwise_iso_id (c : C) : componentwise_iso (iso.refl F) c = iso.refl (F c) := iso.eq_mk (idpath id) definition componentwise_iso_iso_of_eq (p : F = G) (c : C) : componentwise_iso (iso_of_eq p) c = iso_of_eq (ap010 to_fun_ob p c) := eq.rec_on p !componentwise_iso_id definition natural_map_hom_of_eq (p : F = G) (c : C) : natural_map (hom_of_eq p) c = hom_of_eq (ap010 to_fun_ob p c) := eq.rec_on p idp definition natural_map_inv_of_eq (p : F = G) (c : C) : natural_map (inv_of_eq p) c = hom_of_eq (ap010 to_fun_ob p c)⁻¹ := eq.rec_on p idp end namespace ops infixr `×f`:30 := product.prod_functor infixr `ᵒᵖᶠ`:(max+1) := opposite.opposite_functor end ops end category