lean2/hott/algebra/category/functor/basic.hlean

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/-
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
-/
import ..iso types.pi
open function category eq prod prod.ops equiv is_equiv sigma sigma.ops is_trunc funext iso pi
structure functor (C D : Precategory) : Type :=
(to_fun_ob : C → D)
(to_fun_hom : Π {a b : C}, hom a b → hom (to_fun_ob a) (to_fun_ob b))
(respect_id : Π (a : C), to_fun_hom (ID a) = ID (to_fun_ob a))
(respect_comp : Π {a b c : C} (g : hom b c) (f : hom a b),
to_fun_hom (g ∘ f) = to_fun_hom g ∘ to_fun_hom f)
namespace functor
infixl ` ⇒ `:55 := functor
variables {A B C D E : Precategory}
attribute to_fun_ob [coercion]
attribute to_fun_hom [coercion]
-- The following lemmas will later be used to prove that the type of
-- precategories forms a precategory itself
protected definition compose [reducible] [constructor] (G : functor D E) (F : functor C D)
: functor C E :=
functor.mk
(λ x, G (F x))
(λ a b f, G (F f))
(λ a, abstract calc
G (F (ID a)) = G (ID (F a)) : by rewrite respect_id
... = ID (G (F a)) : by rewrite respect_id end)
(λ a b c g f, abstract calc
G (F (g ∘ f)) = G (F g ∘ F f) : by rewrite respect_comp
... = G (F g) ∘ G (F f) : by rewrite respect_comp end)
infixr ` ∘f `:75 := functor.compose
protected definition id [reducible] [constructor] {C : Precategory} : functor C C :=
mk (λa, a) (λ a b f, f) (λ a, idp) (λ a b c f g, idp)
protected definition ID [reducible] [constructor] (C : Precategory) : functor C C := @functor.id C
notation 1 := functor.id
definition constant_functor [constructor] (C : Precategory) {D : Precategory} (d : D) : C ⇒ D :=
functor.mk (λc, d)
(λc c' f, id)
(λc, idp)
(λa b c g f, !id_id⁻¹)
/- introduction rule for equalities between functors -/
definition functor_mk_eq' {F₁ F₂ : C → D} {H₁ : Π(a b : C), hom a b → hom (F₁ a) (F₁ b)}
{H₂ : Π(a b : C), hom a b → hom (F₂ a) (F₂ b)} (id₁ id₂ comp₁ comp₂)
(pF : F₁ = F₂) (pH : pF ▸ H₁ = H₂)
: functor.mk F₁ H₁ id₁ comp₁ = functor.mk F₂ H₂ id₂ comp₂ :=
apd01111 functor.mk pF pH !is_hprop.elim !is_hprop.elim
definition functor_eq' {F₁ F₂ : C ⇒ D} : Π(p : to_fun_ob F₁ = to_fun_ob F₂),
(transport (λx, Πa b f, hom (x a) (x b)) p @(to_fun_hom F₁) = @(to_fun_hom F₂)) → F₁ = F₂ :=
by induction F₁; induction F₂; apply functor_mk_eq'
definition functor_mk_eq {F₁ F₂ : C → D} {H₁ : Π(a b : C), hom a b → hom (F₁ a) (F₁ b)}
{H₂ : Π(a b : C), hom a b → hom (F₂ a) (F₂ b)} (id₁ id₂ comp₁ comp₂) (pF : F₁ ~ F₂)
(pH : Π(a b : C) (f : hom a b), hom_of_eq (pF b) ∘ H₁ a b f ∘ inv_of_eq (pF a) = H₂ a b f)
: functor.mk F₁ H₁ id₁ comp₁ = functor.mk F₂ H₂ id₂ comp₂ :=
begin
fapply functor_mk_eq',
{ exact eq_of_homotopy pF},
{ refine eq_of_homotopy (λc, eq_of_homotopy (λc', eq_of_homotopy (λf, _))), intros,
rewrite [+pi_transport_constant,-pH,-transport_hom]}
end
definition functor_eq {F₁ F₂ : C ⇒ D} : Π(p : to_fun_ob F₁ ~ to_fun_ob F₂),
(Π(a b : C) (f : hom a b), hom_of_eq (p b) ∘ F₁ f ∘ inv_of_eq (p a) = F₂ f) → F₁ = F₂ :=
by induction F₁; induction F₂; apply functor_mk_eq
definition functor_mk_eq_constant {F : C → D} {H₁ : Π(a b : C), hom a b → hom (F a) (F b)}
{H₂ : Π(a b : C), hom a b → hom (F a) (F b)} (id₁ id₂ comp₁ comp₂)
(pH : Π(a b : C) (f : hom a b), H₁ a b f = H₂ a b f)
: functor.mk F H₁ id₁ comp₁ = functor.mk F H₂ id₂ comp₂ :=
functor_eq (λc, idp) (λa b f, !id_leftright ⬝ !pH)
definition preserve_is_iso [constructor] (F : C ⇒ D) {a b : C} (f : hom a b) [H : is_iso f]
: is_iso (F f) :=
begin
fapply @is_iso.mk, apply (F (f⁻¹)),
repeat (apply concat ; symmetry ; apply (respect_comp F) ;
apply concat ; apply (ap (λ x, to_fun_hom F x)) ;
(apply iso.left_inverse | apply iso.right_inverse);
apply (respect_id F) ),
end
theorem respect_inv (F : C ⇒ D) {a b : C} (f : hom a b) [H : is_iso f] [H' : is_iso (F f)] :
F (f⁻¹) = (F f)⁻¹ :=
begin
fapply @left_inverse_eq_right_inverse, apply (F f),
transitivity to_fun_hom F (f⁻¹ ∘ f),
{symmetry, apply (respect_comp F)},
{transitivity to_fun_hom F category.id,
{congruence, apply iso.left_inverse},
{apply respect_id}},
apply iso.right_inverse
end
attribute preserve_is_iso [instance] [priority 100]
definition to_fun_iso [constructor] (F : C ⇒ D) {a b : C} (f : a ≅ b) : F a ≅ F b :=
iso.mk (F f) _
theorem respect_inv' (F : C ⇒ D) {a b : C} (f : hom a b) {H : is_iso f} : F (f⁻¹) = (F f)⁻¹ :=
respect_inv F f
theorem respect_refl (F : C ⇒ D) (a : C) : to_fun_iso F (iso.refl a) = iso.refl (F a) :=
iso_eq !respect_id
theorem respect_symm (F : C ⇒ D) {a b : C} (f : a ≅ b)
: to_fun_iso F f⁻¹ⁱ = (to_fun_iso F f)⁻¹ⁱ :=
iso_eq !respect_inv
theorem respect_trans (F : C ⇒ D) {a b c : C} (f : a ≅ b) (g : b ≅ c)
: to_fun_iso F (f ⬝i g) = to_fun_iso F f ⬝i to_fun_iso F g :=
iso_eq !respect_comp
definition respect_iso_of_eq (F : C ⇒ D) {a b : C} (p : a = b) :
to_fun_iso F (iso_of_eq p) = iso_of_eq (ap F p) :=
by induction p; apply respect_refl
theorem respect_hom_of_eq (F : C ⇒ D) {a b : C} (p : a = b) :
F (hom_of_eq p) = hom_of_eq (ap F p) :=
by induction p; apply respect_id
definition respect_inv_of_eq (F : C ⇒ D) {a b : C} (p : a = b) :
F (inv_of_eq p) = inv_of_eq (ap F p) :=
by induction p; apply respect_id
protected definition assoc (H : C ⇒ D) (G : B ⇒ C) (F : A ⇒ B) :
H ∘f (G ∘f F) = (H ∘f G) ∘f F :=
!functor_mk_eq_constant (λa b f, idp)
protected definition id_left (F : C ⇒ D) : 1 ∘f F = F :=
functor.rec_on F (λF1 F2 F3 F4, !functor_mk_eq_constant (λa b f, idp))
protected definition id_right (F : C ⇒ D) : F ∘f 1 = F :=
functor.rec_on F (λF1 F2 F3 F4, !functor_mk_eq_constant (λa b f, idp))
protected definition comp_id_eq_id_comp (F : C ⇒ D) : F ∘f 1 = 1 ∘f F :=
!functor.id_right ⬝ !functor.id_left⁻¹
definition functor_of_eq [constructor] {C D : Precategory} (p : C = D :> Precategory) : C ⇒ D :=
functor.mk (transport carrier p)
(λa b f, by induction p; exact f)
(by intro c; induction p; reflexivity)
(by intros; induction p; reflexivity)
protected definition sigma_char :
(Σ (to_fun_ob : C → D)
(to_fun_hom : Π ⦃a b : C⦄, hom a b → hom (to_fun_ob a) (to_fun_ob b)),
(Π (a : C), to_fun_hom (ID a) = ID (to_fun_ob a)) ×
(Π {a b c : C} (g : hom b c) (f : hom a b),
to_fun_hom (g ∘ f) = to_fun_hom g ∘ to_fun_hom f)) ≃ (functor C D) :=
begin
fapply equiv.MK,
{intro S, induction S with d1 S2, induction S2 with d2 P1, induction P1 with P11 P12,
exact functor.mk d1 d2 P11 @P12},
{intro F, induction F with d1 d2 d3 d4, exact ⟨d1, @d2, (d3, @d4)⟩},
{intro F, induction F, reflexivity},
{intro S, induction S with d1 S2, induction S2 with d2 P1, induction P1, reflexivity},
end
definition change_fun [constructor] (F : C ⇒ D) (Fob : C → D)
(Fhom : Π⦃c c' : C⦄ (f : c ⟶ c'), Fob c ⟶ Fob c') (p : F = Fob) (q : F =[p] Fhom) : C ⇒ D :=
functor.mk
Fob
Fhom
proof abstract λa, transporto (λFo (Fh : Π⦃c c'⦄, _), Fh (ID a) = ID (Fo a))
q (respect_id F a) end qed
proof abstract λa b c g f, transporto (λFo (Fh : Π⦃c c'⦄, _), Fh (g ∘ f) = Fh g ∘ Fh f)
q (respect_comp F g f) end qed
section
local attribute precategory.is_hset_hom [instance] [priority 1001]
local attribute trunctype.struct [instance] [priority 1] -- remove after #842 is closed
protected theorem is_hset_functor [instance]
[HD : is_hset D] : is_hset (functor C D) :=
by apply is_trunc_equiv_closed; apply functor.sigma_char
end
/- higher equalities in the functor type -/
definition functor_mk_eq'_idp (F : C → D) (H : Π(a b : C), hom a b → hom (F a) (F b))
(id comp) : functor_mk_eq' id id comp comp (idpath F) (idpath H) = idp :=
begin
fapply apd011 (apd01111 functor.mk idp idp),
apply is_hset.elim,
apply is_hset.elim
end
definition functor_eq'_idp (F : C ⇒ D) : functor_eq' idp idp = (idpath F) :=
by (cases F; apply functor_mk_eq'_idp)
definition functor_eq_eta' {F₁ F₂ : C ⇒ D} (p : F₁ = F₂)
: functor_eq' (ap to_fun_ob p) (!tr_compose⁻¹ ⬝ apd to_fun_hom p) = p :=
begin
cases p, cases F₁,
refine _ ⬝ !functor_eq'_idp,
esimp
end
theorem functor_eq2' {F₁ F₂ : C ⇒ D} {p₁ p₂ : to_fun_ob F₁ = to_fun_ob F₂} (q₁ q₂)
(r : p₁ = p₂) : functor_eq' p₁ q₁ = functor_eq' p₂ q₂ :=
by cases r; apply (ap (functor_eq' p₂)); apply is_hprop.elim
theorem functor_eq2 {F₁ F₂ : C ⇒ D} (p q : F₁ = F₂) (r : ap010 to_fun_ob p ~ ap010 to_fun_ob q)
: p = q :=
begin
cases F₁ with ob₁ hom₁ id₁ comp₁,
cases F₂ with ob₂ hom₂ id₂ comp₂,
rewrite [-functor_eq_eta' p, -functor_eq_eta' q],
apply functor_eq2',
apply ap_eq_ap_of_homotopy,
exact r,
end
theorem ap010_apd01111_functor {F₁ F₂ : C → D} {H₁ : Π(a b : C), hom a b → hom (F₁ a) (F₁ b)}
{H₂ : Π(a b : C), hom a b → hom (F₂ a) (F₂ b)} {id₁ id₂ comp₁ comp₂}
(pF : F₁ = F₂) (pH : pF ▸ H₁ = H₂) (pid : cast (apd011 _ pF pH) id₁ = id₂)
(pcomp : cast (apd0111 _ pF pH pid) comp₁ = comp₂) (c : C)
: ap010 to_fun_ob (apd01111 functor.mk pF pH pid pcomp) c = ap10 pF c :=
by induction pF; induction pH; induction pid; induction pcomp; reflexivity
definition ap010_functor_eq {F₁ F₂ : C ⇒ D} (p : to_fun_ob F₁ ~ to_fun_ob F₂)
(q : (λ(a b : C) (f : hom a b), hom_of_eq (p b) ∘ F₁ f ∘ inv_of_eq (p a)) ~3 @(to_fun_hom F₂))
(c : C) : ap010 to_fun_ob (functor_eq p q) c = p c :=
begin
cases F₁ with F₁o F₁h F₁id F₁comp, cases F₂ with F₂o F₂h F₂id F₂comp,
esimp [functor_eq,functor_mk_eq,functor_mk_eq'],
rewrite [ap010_apd01111_functor,↑ap10,{apd10 (eq_of_homotopy p)}right_inv apd10]
end
definition ap010_functor_mk_eq_constant {F : C → D} {H₁ : Π(a b : C), hom a b → hom (F a) (F b)}
{H₂ : Π(a b : C), hom a b → hom (F a) (F b)} {id₁ id₂ comp₁ comp₂}
(pH : Π(a b : C) (f : hom a b), H₁ a b f = H₂ a b f) (c : C) :
ap010 to_fun_ob (functor_mk_eq_constant id₁ id₂ comp₁ comp₂ pH) c = idp :=
!ap010_functor_eq
definition ap010_assoc (H : C ⇒ D) (G : B ⇒ C) (F : A ⇒ B) (a : A) :
ap010 to_fun_ob (functor.assoc H G F) a = idp :=
by apply ap010_functor_mk_eq_constant
definition compose_pentagon (K : D ⇒ E) (H : C ⇒ D) (G : B ⇒ C) (F : A ⇒ B) :
(calc K ∘f H ∘f G ∘f F = (K ∘f H) ∘f G ∘f F : functor.assoc
... = ((K ∘f H) ∘f G) ∘f F : functor.assoc)
=
(calc K ∘f H ∘f G ∘f F = K ∘f (H ∘f G) ∘f F : ap (λx, K ∘f x) !functor.assoc
... = (K ∘f H ∘f G) ∘f F : functor.assoc
... = ((K ∘f H) ∘f G) ∘f F : ap (λx, x ∘f F) !functor.assoc) :=
begin
have lem1 : Π{F₁ F₂ : A ⇒ D} (p : F₁ = F₂) (a : A),
ap010 to_fun_ob (ap (λx, K ∘f x) p) a = ap (to_fun_ob K) (ap010 to_fun_ob p a),
by intros; cases p; esimp,
have lem2 : Π{F₁ F₂ : B ⇒ E} (p : F₁ = F₂) (a : A),
ap010 to_fun_ob (ap (λx, x ∘f F) p) a = ap010 to_fun_ob p (F a),
by intros; cases p; esimp,
apply functor_eq2,
intro a, esimp,
rewrite [+ap010_con,lem1,lem2,
ap010_assoc K H (G ∘f F) a,
ap010_assoc (K ∘f H) G F a,
ap010_assoc H G F a,
ap010_assoc K H G (F a),
ap010_assoc K (H ∘f G) F a],
end
end functor