-- Copyright (c) 2014 Floris van Doorn. All rights reserved. -- Released under Apache 2.0 license as described in the file LICENSE. -- Author: Floris van Doorn -- category import logic.core.eq logic.core.connectives import data.unit data.sigma data.prod import algebra.function import logic.axioms.funext open eq eq.ops inductive category [class] (ob : Type) : Type := mk : Π (mor : ob → ob → Type) (comp : Π⦃A B C : ob⦄, mor B C → mor A B → mor A C) (id : Π {A : ob}, mor A A), (Π ⦃A B C D : ob⦄ {h : mor C D} {g : mor B C} {f : mor A B}, comp h (comp g f) = comp (comp h g) f) → (Π ⦃A B : ob⦄ {f : mor A B}, comp id f = f) → (Π ⦃A B : ob⦄ {f : mor A B}, comp f id = f) → category ob inductive Category : Type := mk : Π (A : Type), category A → Category namespace category section parameters {ob : Type} {Cat : category ob} {A B C D : ob} definition mor : ob → ob → Type := rec (λ mor compose id assoc idr idl, mor) Cat definition compose : Π {A B C : ob}, mor B C → mor A B → mor A C := rec (λ mor compose id assoc idr idl, compose) Cat definition id : Π {A : ob}, mor A A := rec (λ mor compose id assoc idr idl, id) Cat definition ID (A : ob) : mor A A := @id A precedence `∘` : 60 infixr `∘` := compose infixl `=>`:25 := mor theorem assoc : Π {A B C D : ob} {h : mor C D} {g : mor B C} {f : mor A B}, h ∘ (g ∘ f) = (h ∘ g) ∘ f := rec (λ mor comp id assoc idr idl, assoc) Cat theorem id_left : Π {A B : ob} {f : mor A B}, id ∘ f = f := rec (λ mor comp id assoc idl idr, idl) Cat theorem id_right : Π {A B : ob} {f : mor A B}, f ∘ id = f := rec (λ mor comp id assoc idl idr, idr) Cat theorem id_compose {A : ob} : (ID A) ∘ id = id := id_left theorem left_id_unique (i : mor A A) (H : Π{B} {f : mor B A}, i ∘ f = f) : i = id := calc i = i ∘ id : symm id_right ... = id : H theorem right_id_unique (i : mor A A) (H : Π{B} {f : mor A B}, f ∘ i = f) : i = id := calc i = id ∘ i : eq.symm id_left ... = id : H inductive is_section {A B : ob} (f : mor A B) : Type := mk : ∀{g}, g ∘ f = id → is_section f inductive is_retraction {A B : ob} (f : mor A B) : Type := mk : ∀{g}, f ∘ g = id → is_retraction f inductive is_iso {A B : ob} (f : mor A B) : Type := mk : ∀{g}, g ∘ f = id → f ∘ g = id → is_iso f definition retraction_of {A B : ob} (f : mor A B) {H : is_section f} : mor B A := is_section.rec (λg h, g) H definition section_of {A B : ob} (f : mor A B) {H : is_retraction f} : mor B A := is_retraction.rec (λg h, g) H definition inverse {A B : ob} (f : mor A B) {H : is_iso f} : mor B A := is_iso.rec (λg h1 h2, g) H postfix `⁻¹` := inverse theorem id_is_iso [instance] : is_iso (ID A) := is_iso.mk id_compose id_compose theorem inverse_compose {A B : ob} {f : mor A B} {H : is_iso f} : f⁻¹ ∘ f = id := is_iso.rec (λg h1 h2, h1) H theorem compose_inverse {A B : ob} {f : mor A B} {H : is_iso f} : f ∘ f⁻¹ = id := is_iso.rec (λg h1 h2, h2) H theorem iso_imp_retraction [instance] {A B : ob} (f : mor A B) {H : is_iso f} : is_section f := is_section.mk inverse_compose theorem iso_imp_section [instance] {A B : ob} (f : mor A B) {H : is_iso f} : is_retraction f := is_retraction.mk compose_inverse theorem retraction_compose {A B : ob} {f : mor A B} {H : is_section f} : retraction_of f ∘ f = id := is_section.rec (λg h, h) H theorem compose_section {A B : ob} {f : mor A B} {H : is_retraction f} : f ∘ section_of f = id := is_retraction.rec (λg h, h) H theorem left_inverse_eq_right_inverse {A B : ob} {f : mor A B} {g g' : mor B A} (Hl : g ∘ f = id) (Hr : f ∘ g' = id) : g = g' := calc g = g ∘ id : symm id_right ... = g ∘ f ∘ g' : {symm Hr} ... = (g ∘ f) ∘ g' : assoc ... = id ∘ g' : {Hl} ... = g' : id_left theorem section_eq_retraction {A B : ob} {f : mor A B} (Hl : is_section f) (Hr : is_retraction f) : retraction_of f = section_of f := left_inverse_eq_right_inverse retraction_compose compose_section theorem section_retraction_imp_iso {A B : ob} {f : mor A B} (Hl : is_section f) (Hr : is_retraction f) : is_iso f := is_iso.mk (subst (section_eq_retraction Hl Hr) retraction_compose) compose_section theorem inverse_unique {A B : ob} {f : mor A B} (H H' : is_iso f) : @inverse _ _ f H = @inverse _ _ f H' := left_inverse_eq_right_inverse inverse_compose compose_inverse theorem retraction_of_id {A : ob} : retraction_of (ID A) = id := left_inverse_eq_right_inverse retraction_compose id_compose theorem section_of_id {A : ob} : section_of (ID A) = id := symm (left_inverse_eq_right_inverse id_compose compose_section) theorem iso_of_id {A : ob} : ID A⁻¹ = id := left_inverse_eq_right_inverse inverse_compose id_compose theorem composition_is_section [instance] {f : mor A B} {g : mor B C} (Hf : is_section f) (Hg : is_section g) : is_section (g ∘ f) := is_section.mk (calc (retraction_of f ∘ retraction_of g) ∘ g ∘ f = retraction_of f ∘ retraction_of g ∘ g ∘ f : symm assoc ... = retraction_of f ∘ (retraction_of g ∘ g) ∘ f : {assoc} ... = retraction_of f ∘ id ∘ f : {retraction_compose} ... = retraction_of f ∘ f : {id_left} ... = id : retraction_compose) theorem composition_is_retraction [instance] {f : mor A B} {g : mor B C} (Hf : is_retraction f) (Hg : is_retraction g) : is_retraction (g ∘ f) := is_retraction.mk (calc (g ∘ f) ∘ section_of f ∘ section_of g = g ∘ f ∘ section_of f ∘ section_of g : symm assoc ... = g ∘ (f ∘ section_of f) ∘ section_of g : {assoc} ... = g ∘ id ∘ section_of g : {compose_section} ... = g ∘ section_of g : {id_left} ... = id : compose_section) theorem composition_is_inverse [instance] {f : mor A B} {g : mor B C} (Hf : is_iso f) (Hg : is_iso g) : is_iso (g ∘ f) := section_retraction_imp_iso _ _ definition mono {A B : ob} (f : mor A B) : Prop := ∀⦃C⦄ {g h : mor C A}, f ∘ g = f ∘ h → g = h definition epi {A B : ob} (f : mor A B) : Prop := ∀⦃C⦄ {g h : mor B C}, g ∘ f = h ∘ f → g = h theorem section_is_mono {f : mor A B} (H : is_section f) : mono f := λ C g h H, calc g = id ∘ g : symm id_left ... = (retraction_of f ∘ f) ∘ g : {symm retraction_compose} ... = retraction_of f ∘ f ∘ g : symm assoc ... = retraction_of f ∘ f ∘ h : {H} ... = (retraction_of f ∘ f) ∘ h : assoc ... = id ∘ h : {retraction_compose} ... = h : id_left theorem retraction_is_epi {f : mor A B} (H : is_retraction f) : epi f := λ C g h H, calc g = g ∘ id : symm id_right ... = g ∘ f ∘ section_of f : {symm compose_section} ... = (g ∘ f) ∘ section_of f : assoc ... = (h ∘ f) ∘ section_of f : {H} ... = h ∘ f ∘ section_of f : symm assoc ... = h ∘ id : {compose_section} ... = h : id_right end section definition objects [coercion] (C : Category) : Type := Category.rec (fun c s, c) C definition category_instance [instance] (C : Category) : category (objects C) := Category.rec (fun c s, s) C end end category open category inductive functor {obC obD : Type} (C : category obC) (D : category obD) : Type := mk : Π (obF : obC → obD) (morF : Π⦃A B : obC⦄, mor A B → mor (obF A) (obF B)), (Π ⦃A : obC⦄, morF (ID A) = ID (obF A)) → (Π ⦃A B C : obC⦄ {f : mor A B} {g : mor B C}, morF (g ∘ f) = morF g ∘ morF f) → functor C D inductive Functor (C D : Category) : Type := mk : functor (category_instance C) (category_instance D) → Functor C D infixl `⇒`:25 := functor namespace functor section basic_functor parameters {obC obD : Type} {C : category obC} {D : category obD} definition object [coercion] (F : C ⇒ D) : obC → obD := rec (λ obF morF Hid Hcomp, obF) F definition morphism [coercion] (F : C ⇒ D) : Π{A B : obC}, mor A B → mor (F A) (F B) := rec (λ obF morF Hid Hcomp, morF) F theorem respect_id (F : C ⇒ D) : Π {A : obC}, F (ID A) = ID (F A) := rec (λ obF morF Hid Hcomp, Hid) F theorem respect_comp (F : C ⇒ D) : Π {a b c : obC} {f : mor a b} {g : mor b c}, F (g ∘ f) = F g ∘ F f := rec (λ obF morF Hid Hcomp, Hcomp) F end basic_functor section category_functor protected definition compose {obC obD obE : Type} {C : category obC} {D : category obD} {E : category obE} (G : D ⇒ E) (F : C ⇒ D) : C ⇒ E := functor.mk (λx, G (F x)) (λ a b f, G (F f)) (λ a, calc G (F (ID a)) = G id : {respect_id F} ... = id : respect_id G) (λ a b c f g, calc G (F (g ∘ f)) = G (F g ∘ F f) : {respect_comp F} ... = G (F g) ∘ G (F f) : respect_comp G) precedence `∘∘` : 60 infixr `∘∘` := compose protected theorem assoc {obA obB obC obD : Type} {A : category obA} {B : category obB} {C : category obC} {D : category obD} {H : C ⇒ D} {G : B ⇒ C} {F : A ⇒ B} : H ∘∘ (G ∘∘ F) = (H ∘∘ G) ∘∘ F := rfl -- later check whether we want implicit or explicit arguments here. For the moment, define both protected definition id {ob : Type} {C : category ob} : functor C C := mk (λa, a) (λ a b f, f) (λ a, rfl) (λ a b c f g, rfl) protected definition ID {ob : Type} (C : category ob) : functor C C := id protected definition Id {C : Category} : Functor C C := Functor.mk id protected definition iD (C : Category) : Functor C C := Functor.mk id protected theorem id_left {obC obB : Type} {B : category obB} {C : category obC} {F : B ⇒ C} : id ∘∘ F = F := rec (λ obF morF idF compF, rfl) F protected theorem id_right {obC obB : Type} {B : category obB} {C : category obC} {F : B ⇒ C} : F ∘∘ id = F := rec (λ obF morF idF compF, rfl) F end category_functor section Functor -- parameters {C D E : Category} (G : Functor D E) (F : Functor C D) definition Functor_functor {C D : Category} (F : Functor C D) : functor (category_instance C) (category_instance D) := Functor.rec (λ x, x) F protected definition Compose {C D E : Category} (G : Functor D E) (F : Functor C D) : Functor C E := Functor.mk (compose (Functor_functor G) (Functor_functor F)) -- namespace Functor precedence `∘∘` : 60 infixr `∘∘` := Compose -- end Functor protected definition Assoc {A B C D : Category} {H : Functor C D} {G : Functor B C} {F : Functor A B} : H ∘∘ (G ∘∘ F) = (H ∘∘ G) ∘∘ F := rfl protected theorem Id_left {B : Category} {C : Category} {F : Functor B C} : Id ∘∘ F = F := Functor.rec (λ f, subst id_left rfl) F protected theorem Id_right {B : Category} {C : Category} {F : Functor B C} : F ∘∘ Id = F := Functor.rec (λ f, subst id_right rfl) F end Functor end functor open functor inductive natural_transformation {obC obD : Type} {C : category obC} {D : category obD} (F G : functor C D) : Type := mk : Π (η : Π(a : obC), mor (object F a) (object G a)), (Π{a b : obC} (f : mor a b), morphism G f ∘ η a = η b ∘ morphism F f) → natural_transformation F G -- inductive Natural_transformation {C D : Category} (F G : Functor C D) : Type := -- mk : natural_transformation (Functor_functor F) (Functor_functor G) → Natural_transformation F G infixl `==>`:25 := natural_transformation namespace natural_transformation section parameters {obC obD : Type} {C : category obC} {D : category obD} {F G : C ⇒ D} definition natural_map [coercion] (η : F ==> G) : Π(a : obC), mor (object F a) (object G a) := rec (λ x y, x) η definition naturality (η : F ==> G) : Π{a b : obC} (f : mor a b), morphism G f ∘ η a = η b ∘ morphism F f := rec (λ x y, y) η end section parameters {obC obD : Type} {C : category obC} {D : category obD} {F G H : C ⇒ D} protected definition compose (η : G ==> H) (θ : F ==> G) : F ==> H := natural_transformation.mk (λ a, η a ∘ θ a) (λ a b f, calc morphism H f ∘ (η a ∘ θ a) = (morphism H f ∘ η a) ∘ θ a : assoc ... = (η b ∘ morphism G f) ∘ θ a : {naturality η f} ... = η b ∘ (morphism G f ∘ θ a) : symm assoc ... = η b ∘ (θ b ∘ morphism F f) : {naturality θ f} ... = (η b ∘ θ b) ∘ morphism F f : assoc) end precedence `∘n` : 60 infixr `∘n` := compose section protected theorem assoc {obC obD : Type} {C : category obC} {D : category obD} {F₄ F₃ F₂ F₁ : C ⇒ D} {η₃ : F₃ ==> F₄} {η₂ : F₂ ==> F₃} {η₁ : F₁ ==> F₂} : η₃ ∘n (η₂ ∘n η₁) = (η₃ ∘n η₂) ∘n η₁ := congr_arg2_dep mk (funext (take x, assoc)) proof_irrel --TODO: check whether some of the below identities are superfluous protected definition id {obC obD : Type} {C : category obC} {D : category obD} {F : C ⇒ D} : natural_transformation F F := mk (λa, id) (λa b f, id_right ⬝ symm id_left) protected definition ID {obC obD : Type} {C : category obC} {D : category obD} (F : C ⇒ D) : natural_transformation F F := id -- protected definition Id {C D : Category} {F : Functor C D} : Natural_transformation F F := -- Natural_transformation.mk id -- protected definition iD {C D : Category} (F : Functor C D) : Natural_transformation F F := -- Natural_transformation.mk id protected theorem id_left {obC obD : Type} {C : category obC} {D : category obD} {F G : C ⇒ D} {η : F ==> G} : natural_transformation.compose id η = η := rec (λf H, congr_arg2_dep mk (funext (take x, id_left)) proof_irrel) η protected theorem id_right {obC obD : Type} {C : category obC} {D : category obD} {F G : C ⇒ D} {η : F ==> G} : natural_transformation.compose η id = η := rec (λf H, congr_arg2_dep mk (funext (take x, id_right)) proof_irrel) η end end natural_transformation -- examples of categories / basic constructions (TODO: move to separate file) open functor namespace category section open unit definition one [instance] : category unit := category.mk (λa b, unit) (λ a b c f g, star) (λ a, star) (λ a b c d f g h, unit.equal _ _) (λ a b f, unit.equal _ _) (λ a b f, unit.equal _ _) end section parameter {ob : Type} definition opposite (C : category ob) : category ob := category.mk (λa b, mor b a) (λ a b c f g, g ∘ f) (λ a, id) (λ a b c d f g h, symm assoc) (λ a b f, id_right) (λ a b f, id_left) precedence `∘op` : 60 infixr `∘op` := @compose _ (opposite _) _ _ _ parameters {C : category ob} {a b c : ob} theorem compose_op {f : @mor ob C a b} {g : mor b c} : f ∘op g = g ∘ f := rfl theorem op_op {C : category ob} : opposite (opposite C) = C := category.rec (λ mor comp id assoc idl idr, refl (mk _ _ _ _ _ _)) C end definition Opposite (C : Category) : Category := Category.mk (objects C) (opposite (category_instance C)) section definition type_category : category Type := mk (λA B, A → B) (λ a b c, function.compose) (λ a, function.id) (λ a b c d h g f, symm (function.compose_assoc h g f)) (λ a b f, function.compose_id_left f) (λ a b f, function.compose_id_right f) end section cat_Cat definition Cat : category Category := mk (λ a b, Functor a b) (λ a b c g f, functor.Compose g f) (λ a, functor.Id) (λ a b c d h g f, functor.Assoc) (λ a b f, functor.Id_left) (λ a b f, functor.Id_right) end cat_Cat section functor_category parameters {obC obD : Type} (C : category obC) (D : category obD) definition functor_category : category (functor C D) := mk (λa b, natural_transformation a b) (λ a b c g f, natural_transformation.compose g f) (λ a, natural_transformation.id) (λ a b c d h g f, natural_transformation.assoc) (λ a b f, natural_transformation.id_left) (λ a b f, natural_transformation.id_right) end functor_category section slice open sigma definition slice {ob : Type} (C : category ob) (c : ob) : category (Σ(b : ob), mor b c) := mk (λa b, Σ(g : mor (dpr1 a) (dpr1 b)), dpr2 b ∘ g = dpr2 a) (λ a b c g f, dpair (dpr1 g ∘ dpr1 f) (show dpr2 c ∘ (dpr1 g ∘ dpr1 f) = dpr2 a, proof calc dpr2 c ∘ (dpr1 g ∘ dpr1 f) = (dpr2 c ∘ dpr1 g) ∘ dpr1 f : assoc ... = dpr2 b ∘ dpr1 f : {dpr2 g} ... = dpr2 a : {dpr2 f} qed)) (λ a, dpair id id_right) (λ a b c d h g f, dpair_eq assoc proof_irrel) (λ a b f, sigma.equal id_left proof_irrel) (λ a b f, sigma.equal id_right proof_irrel) -- We give proof_irrel instead of rfl, to give the unifier an easier time end slice section coslice open sigma definition coslice {ob : Type} (C : category ob) (c : ob) : category (Σ(b : ob), mor c b) := mk (λa b, Σ(g : mor (dpr1 a) (dpr1 b)), g ∘ dpr2 a = dpr2 b) (λ a b c g f, dpair (dpr1 g ∘ dpr1 f) (show (dpr1 g ∘ dpr1 f) ∘ dpr2 a = dpr2 c, proof calc (dpr1 g ∘ dpr1 f) ∘ dpr2 a = dpr1 g ∘ (dpr1 f ∘ dpr2 a): symm assoc ... = dpr1 g ∘ dpr2 b : {dpr2 f} ... = dpr2 c : {dpr2 g} qed)) (λ a, dpair id id_left) (λ a b c d h g f, dpair_eq assoc proof_irrel) (λ a b f, sigma.equal id_left proof_irrel) (λ a b f, sigma.equal id_right proof_irrel) -- theorem slice_coslice_opp {ob : Type} (C : category ob) (c : ob) : -- coslice C c = opposite (slice (opposite C) c) := -- sorry end coslice section product open prod definition product {obC obD : Type} (C : category obC) (D : category obD) : category (obC × obD) := mk (λa b, mor (pr1 a) (pr1 b) × mor (pr2 a) (pr2 b)) (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.equal id_left id_left ) (λ a b f, prod.equal id_right id_right) end product section arrow open sigma eq.ops -- theorem concat_commutative_squares {ob : Type} {C : category ob} {a1 a2 a3 b1 b2 b3 : ob} -- {f1 : a1 => b1} {f2 : a2 => b2} {f3 : a3 => b3} {g2 : a2 => a3} {g1 : a1 => a2} -- {h2 : b2 => b3} {h1 : b1 => b2} (H1 : f2 ∘ g1 = h1 ∘ f1) (H2 : f3 ∘ g2 = h2 ∘ f2) -- : f3 ∘ (g2 ∘ g1) = (h2 ∘ h1) ∘ f1 := -- calc -- f3 ∘ (g2 ∘ g1) = (f3 ∘ g2) ∘ g1 : assoc -- ... = (h2 ∘ f2) ∘ g1 : {H2} -- ... = h2 ∘ (f2 ∘ g1) : symm assoc -- ... = h2 ∘ (h1 ∘ f1) : {H1} -- ... = (h2 ∘ h1) ∘ f1 : assoc -- definition arrow {ob : Type} (C : category ob) : category (Σ(a b : ob), mor a b) := -- mk (λa b, Σ(g : mor (dpr1 a) (dpr1 b)) (h : mor (dpr2' a) (dpr2' b)), -- dpr3 b ∘ g = h ∘ dpr3 a) -- (λ a b c g f, dpair (dpr1 g ∘ dpr1 f) (dpair (dpr2' g ∘ dpr2' f) (concat_commutative_squares (dpr3 f) (dpr3 g)))) -- (λ a, dpair id (dpair id (id_right ⬝ (symm id_left)))) -- (λ a b c d h g f, dtrip_eq2 assoc assoc proof_irrel) -- (λ a b f, trip.equal2 id_left id_left proof_irrel) -- (λ a b f, trip.equal2 id_right id_right proof_irrel) definition arrow_obs (ob : Type) (C : category ob) := Σ(a b : ob), mor a b definition src {ob : Type} {C : category ob} (a : arrow_obs ob C) : ob := dpr1 a definition dst {ob : Type} {C : category ob} (a : arrow_obs ob C) : ob := dpr2' a definition to_mor {ob : Type} {C : category ob} (a : arrow_obs ob C) : mor (src a) (dst a) := dpr3 a definition arrow_mor (ob : Type) (C : category ob) (a b : arrow_obs ob C) : Type := Σ (g : mor (src a) (src b)) (h : mor (dst a) (dst b)), to_mor b ∘ g = h ∘ to_mor a definition mor_src {ob : Type} {C : category ob} {a b : arrow_obs ob C} (m : arrow_mor ob C a b) : mor (src a) (src b) := dpr1 m definition mor_dst {ob : Type} {C : category ob} {a b : arrow_obs ob C} (m : arrow_mor ob C a b) : mor (dst a) (dst b) := dpr2' m definition commute {ob : Type} {C : category ob} {a b : arrow_obs ob C} (m : arrow_mor ob C a b) : to_mor b ∘ (mor_src m) = (mor_dst m) ∘ to_mor a := dpr3 m definition arrow (ob : Type) (C : category ob) : category (arrow_obs ob C) := mk (λa b, arrow_mor ob C a b) (λ a b c g f, dpair (mor_src g ∘ mor_src f) (dpair (mor_dst g ∘ mor_dst f) (show to_mor c ∘ (mor_src g ∘ mor_src f) = (mor_dst g ∘ mor_dst f) ∘ to_mor a, proof calc to_mor c ∘ (mor_src g ∘ mor_src f) = (to_mor c ∘ mor_src g) ∘ mor_src f : assoc ... = (mor_dst g ∘ to_mor b) ∘ mor_src f : {commute g} ... = mor_dst g ∘ (to_mor b ∘ mor_src f) : symm assoc ... = mor_dst g ∘ (mor_dst f ∘ to_mor a) : {commute f} ... = (mor_dst g ∘ mor_dst f) ∘ to_mor a : assoc qed) )) (λ a, dpair id (dpair id (id_right ⬝ (symm id_left)))) (λ a b c d h g f, dtrip_eq_ndep assoc assoc proof_irrel) (λ a b f, trip.equal_ndep id_left id_left proof_irrel) (λ a b f, trip.equal_ndep id_right id_right proof_irrel) end arrow -- definition foo -- : category (sorry) := -- mk (λa b, sorry) -- (λ a b c g f, sorry) -- (λ a, sorry) -- (λ a b c d h g f, sorry) -- (λ a b f, sorry) -- (λ a b f, sorry) end category