lean2/hott/algebra/category/functor.hlean
Floris van Doorn 7e52c49dce feat(hott): many changes is the HoTT library
Prove that 'is_left_adjoint F' is a mere proposition, although this proof is commented out because it takes ~10 seconds
2015-09-01 15:17:46 -07:00

231 lines
9.9 KiB
Text
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/-
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
open 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 `⇒`:25 := 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`:60 := 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 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)
protected definition preserve_iso (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 left_inverse | apply right_inverse);
apply (respect_id F) ),
end
definition 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 left_inverse},
{apply respect_id}},
apply right_inverse
end
attribute functor.preserve_iso [instance]
definition 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
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
-- "functor C D" is equivalent to a certain sigma type
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, fapply functor.mk,
exact (S.1), exact (S.2.1),
-- TODO(Leo): investigate why we need to use relaxed-exact (rexact) tactic here
exact (pr₁ S.2.2), rexact (pr₂ S.2.2)},
{intro F, cases F with d1 d2 d3 d4, exact ⟨d1, d2, (d3, @d4)⟩},
{intro F, cases F, reflexivity},
{intro S, cases S with d1 S2, cases S2 with d2 P1, cases P1, reflexivity},
end
section
local attribute precategory.is_hset_hom [priority 1001]
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
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,
apply concat, rotate_left 1, apply functor_eq'_idp,
esimp
end
definition 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
definition 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
definition 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 cases pF; cases pH; cases pid; cases pcomp; apply idp
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