Library UniMath.CategoryTheory.limits.cats.limits
*************************************************
Contents :
Definition of limits
Require Import UniMath.Foundations.PartD.
Require Import UniMath.Foundations.Propositions.
Require Import UniMath.Foundations.Sets.
Require Import UniMath.MoreFoundations.Tactics.
Require Import UniMath.MoreFoundations.Propositions.
Require Import UniMath.CategoryTheory.Core.Categories.
Require Import UniMath.CategoryTheory.Core.Isos.
Require Import UniMath.CategoryTheory.Core.NaturalTransformations.
Require Import UniMath.CategoryTheory.Core.Univalence.
Require Import UniMath.CategoryTheory.Core.Functors.
Require Import UniMath.CategoryTheory.FunctorCategory.
Local Open Scope cat.
Section lim_def.
Definition cone {J C : precategory} (F : functor J C) (c : C) : UU :=
∑ (f : ∏ (v : J), C⟦c,F v⟧),
∏ (u v : J) (e : J⟦u,v⟧), f u · # F e = f v.
Definition make_cone {J C : precategory} {F : functor J C} {c : C}
(f : ∏ v, C⟦c, F v⟧) (Hf : ∏ u v (e : J⟦u,v⟧) , f u · # F e = f v) :
cone F c := tpair _ f Hf.
Definition coneOut {J C : precategory} {F : functor J C} {c : C} (cc : cone F c) :
∏ v, C⟦c, F v⟧ := pr1 cc.
Lemma coneOutCommutes {J C : precategory} {F : functor J C} {c : C}
(cc : cone F c) : ∏ u v (e : J⟦u,v⟧), coneOut cc u · # F e = coneOut cc v.
Show proof.
Definition isLimCone {J C : precategory} (F : functor J C)
(l : C) (cc0 : cone F l) : UU := ∏ (c : C) (cc : cone F c),
iscontr (∑ x : C⟦c,l⟧, ∏ v, x · coneOut cc0 v = coneOut cc v).
Definition LimCone {J C : precategory} (F : functor J C) : UU :=
∑ (A : (∑ l, cone F l)), isLimCone F (pr1 A) (pr2 A).
Definition make_LimCone {J C : precategory} (F : functor J C)
(c : C) (cc : cone F c) (isCC : isLimCone F c cc) : LimCone F :=
tpair _ (tpair _ c cc) isCC.
Definition lim {J C : precategory} {F : functor J C} (CC : LimCone F) : C
:= pr1 (pr1 CC).
Definition limCone {J C : precategory} {F : functor J C} (CC : LimCone F) :
cone F (lim CC) := pr2 (pr1 CC).
Definition limOut {J C : precategory} {F : functor J C} (CC : LimCone F) :
∏ v, C⟦lim CC,F v⟧ := coneOut (limCone CC).
Lemma limOutCommutes {J C : precategory} {F : functor J C}
(CC : LimCone F) : ∏ u v (e : J⟦u,v⟧),
limOut CC u · # F e = limOut CC v.
Show proof.
Lemma limUnivProp {J C : precategory} {F : functor J C}
(CC : LimCone F) : ∏ (c : C) (cc : cone F c),
iscontr (∑ x : C⟦c, lim CC⟧, ∏ v, x · limOut CC v = coneOut cc v).
Show proof.
Lemma isaprop_isLimCone {J C : precategory} (F : functor J C) (c0 : C)
(cc0 : cone F c0) : isaprop (isLimCone F c0 cc0).
Show proof.
Definition isLimCone_LimCone {J C : precategory} {F : functor J C}
(CC : LimCone F)
: isLimCone F (lim CC) (tpair _ (limOut CC) (limOutCommutes CC))
:= pr2 CC.
Definition limArrow {J C : precategory} {F : functor J C} (CC : LimCone F)
(c : C) (cc : cone F c) : C⟦c, lim CC⟧ := pr1 (pr1 (isLimCone_LimCone CC c cc)).
Lemma limArrowCommutes {J C : precategory} {F : functor J C} (CC : LimCone F)
(c : C) (cc : cone F c) u :
limArrow CC c cc · limOut CC u = coneOut cc u.
Show proof.
Lemma limArrowUnique {J C : precategory} {F : functor J C} (CC : LimCone F)
(c : C) (cc : cone F c) (k : C⟦c, lim CC⟧)
(Hk : ∏ u, k · limOut CC u = coneOut cc u) :
k = limArrow CC c cc.
Show proof.
Lemma Cone_precompose {J C : precategory} {F : functor J C}
{c : C} (cc : cone F c) (x : C) (f : C⟦x,c⟧) :
∏ u v (e : J⟦u,v⟧), (f · coneOut cc u) · # F e = f · coneOut cc v.
Show proof.
Lemma limArrowEta {J C : precategory} {F : functor J C} (CC : LimCone F)
(c : C) (f : C⟦c, lim CC⟧) :
f = limArrow CC c (tpair _ (λ u, f · limOut CC u)
(Cone_precompose (limCone CC) c f)).
Show proof.
Definition limOfArrows {J C : precategory} {F1 F2 : functor J C}
(CC1 : LimCone F1) (CC2 : LimCone F2)
(f : ∏ u, C⟦F1 u,F2 u⟧)
(fNat : ∏ u v (e : J⟦u,v⟧), f u · # F2 e = # F1 e · f v) :
C⟦lim CC1 , lim CC2⟧.
Show proof.
apply limArrow; use make_cone.
- now intro u; apply (limOut CC1 u · f u).
- abstract (intros u v e; simpl;
now rewrite <- assoc, fNat, assoc, limOutCommutes).
- now intro u; apply (limOut CC1 u · f u).
- abstract (intros u v e; simpl;
now rewrite <- assoc, fNat, assoc, limOutCommutes).
Lemma limOfArrowsOut {J C : precategory} {F1 F2 : functor J C}
(CC1 : LimCone F1) (CC2 : LimCone F2)
(f : ∏ u, C⟦F1 u,F2 u⟧)
(fNat : ∏ u v (e : J⟦u,v⟧), f u · # F2 e = # F1 e · f v) :
∏ u, limOfArrows CC1 CC2 f fNat · limOut CC2 u =
limOut CC1 u · f u.
Show proof.
Lemma postCompWithLimOfArrows_subproof
{J C : precategory} {F1 F2 : functor J C}
(CC1 : LimCone F1) (CC2 : LimCone F2)
(f : ∏ u, C⟦F1 u,F2 u⟧)
(fNat : ∏ u v (e : J⟦u,v⟧), f u · # F2 e = # F1 e · f v)
(x : C) (cc : cone F1 x) u v (e : J⟦u,v⟧) :
(coneOut cc u · f u) · # F2 e = coneOut cc v · f v.
Show proof.
Lemma postcompWithLimOfArrows
{J C : precategory} {F1 F2 : functor J C}
(CC1 : LimCone F1) (CC2 : LimCone F2)
(f : ∏ u, C⟦F1 u,F2 u⟧)
(fNat : ∏ u v (e : J⟦u,v⟧), f u · # F2 e = # F1 e · f v)
(x : C) (cc : cone F1 x) :
limArrow CC1 x cc · limOfArrows CC1 CC2 f fNat =
limArrow CC2 x (make_cone (λ u, coneOut cc u · f u)
(postCompWithLimOfArrows_subproof CC1 CC2 f fNat x cc)).
Show proof.
Lemma postcompWithLimArrow {J C : precategory} {F : functor J C}
(CC : LimCone F) (c : C) (cc : cone F c) (d : C) (k : C⟦d,c⟧) :
k · limArrow CC c cc =
limArrow CC d (make_cone (λ u, k · coneOut cc u)
(Cone_precompose cc d k)).
Show proof.
Lemma lim_endo_is_identity {J C : precategory} {F : functor J C}
(CC : LimCone F) (k : lim CC --> lim CC)
(H : ∏ u, k · limOut CC u = limOut CC u) :
identity _ = k.
Show proof.
use (uniqueExists (limUnivProp CC _ _)).
- now apply (limCone CC).
- now intros v; apply id_left.
- simpl; now apply H.
- now apply (limCone CC).
- now intros v; apply id_left.
- simpl; now apply H.
Definition z_iso_from_lim_to_lim {J C : precategory} {F : functor J C}
(CC CC' : LimCone F) : z_iso (lim CC) (lim CC').
Show proof.
use make_z_iso.
- apply limArrow, limCone.
- apply limArrow, limCone.
- abstract (now split; apply pathsinv0, lim_endo_is_identity; intro u;
rewrite <- assoc, limArrowCommutes; eapply pathscomp0; try apply limArrowCommutes).
- apply limArrow, limCone.
- apply limArrow, limCone.
- abstract (now split; apply pathsinv0, lim_endo_is_identity; intro u;
rewrite <- assoc, limArrowCommutes; eapply pathscomp0; try apply limArrowCommutes).
End lim_def.
Section Lims.
Definition Lims (C : precategory) : UU := ∏ (J : precategory) (F : functor J C), LimCone F.
Definition hasLims : UU :=
∏ (J C : precategory) (F : functor J C), ishinh (LimCone F).
Definition Lims_of_shape (J C : precategory) : UU := ∏ (F : functor J C), LimCone F.
Section Universal_Unique.
Context (C : univalent_category).
Let H : is_univalent C := pr2 C.
Lemma isaprop_Lims: isaprop (Lims C).
Show proof.
apply impred; intro J; apply impred; intro F.
apply invproofirrelevance; intros Hccx Hccy.
apply subtypePath.
- intro; apply isaprop_isLimCone.
- apply (total2_paths_f (isotoid _ H (z_iso_from_lim_to_lim Hccx Hccy))).
set (B c := ∏ v, C⟦c,F v⟧).
set (C' (c : C) f := ∏ u v (e : J⟦u,v⟧), @compose _ c _ _ (f u) (# F e) = f v).
rewrite (@transportf_total2 _ B C').
apply subtypePath.
+ intro; repeat (apply impred; intro). apply (homset_property C).
+ abstract (simpl; eapply pathscomp0; [apply transportf_isotoid_dep'|]; apply funextsec;
intro v; rewrite inv_isotoid, idtoiso_isotoid; cbn; apply limArrowCommutes).
apply invproofirrelevance; intros Hccx Hccy.
apply subtypePath.
- intro; apply isaprop_isLimCone.
- apply (total2_paths_f (isotoid _ H (z_iso_from_lim_to_lim Hccx Hccy))).
set (B c := ∏ v, C⟦c,F v⟧).
set (C' (c : C) f := ∏ u v (e : J⟦u,v⟧), @compose _ c _ _ (f u) (# F e) = f v).
rewrite (@transportf_total2 _ B C').
apply subtypePath.
+ intro; repeat (apply impred; intro). apply (homset_property C).
+ abstract (simpl; eapply pathscomp0; [apply transportf_isotoid_dep'|]; apply funextsec;
intro v; rewrite inv_isotoid, idtoiso_isotoid; cbn; apply limArrowCommutes).
End Universal_Unique.
End Lims.
Section LimFunctor.
Variable A C : precategory.
Variable hsC : has_homsets C.
Variable (J : precategory).
Variable (D : functor J [A, C, hsC]).
Definition functor_pointwise (a : A) : functor J C.
Show proof.
use tpair.
- apply (tpair _ (λ v, pr1 (D v) a)).
intros u v e; simpl; apply (pr1 (# D e) a).
- abstract (use tpair;
[ intro x; simpl;
apply (toforallpaths _ _ _ (maponpaths pr1 (functor_id D x)) a)
| intros x y z f g; simpl;
apply (toforallpaths _ _ _ (maponpaths pr1 (functor_comp D f g)) a)]).
- apply (tpair _ (λ v, pr1 (D v) a)).
intros u v e; simpl; apply (pr1 (# D e) a).
- abstract (use tpair;
[ intro x; simpl;
apply (toforallpaths _ _ _ (maponpaths pr1 (functor_id D x)) a)
| intros x y z f g; simpl;
apply (toforallpaths _ _ _ (maponpaths pr1 (functor_comp D f g)) a)]).
Variable (HCg : ∏ (a : A), LimCone (functor_pointwise a)).
Definition LimFunctor_ob (a : A) : C := lim (HCg a).
Definition LimFunctor_mor (a a' : A) (f : A⟦a, a'⟧) :
C⟦LimFunctor_ob a,LimFunctor_ob a'⟧.
Show proof.
use limOfArrows.
- now intro u; apply (# (pr1 (D u)) f).
- abstract (now intros u v e; simpl; apply (nat_trans_ax (# D e))).
- now intro u; apply (# (pr1 (D u)) f).
- abstract (now intros u v e; simpl; apply (nat_trans_ax (# D e))).
Definition LimFunctor_data : functor_data A C := tpair _ _ LimFunctor_mor.
Lemma is_functor_LimFunctor_data : is_functor LimFunctor_data.
Show proof.
split.
- intro a; simpl.
apply pathsinv0, lim_endo_is_identity; intro u.
unfold LimFunctor_mor; rewrite limOfArrowsOut.
assert (H : # (pr1 (D u)) (identity a) = identity (pr1 (D u) a)).
apply (functor_id (D u) a).
now rewrite H, id_right.
- intros a b c fab fbc; simpl; unfold LimFunctor_mor.
apply pathsinv0.
eapply pathscomp0; [now apply postcompWithLimOfArrows|].
apply pathsinv0, limArrowUnique; intro u.
rewrite limOfArrowsOut, (functor_comp (D u)); simpl.
now rewrite <- assoc.
- intro a; simpl.
apply pathsinv0, lim_endo_is_identity; intro u.
unfold LimFunctor_mor; rewrite limOfArrowsOut.
assert (H : # (pr1 (D u)) (identity a) = identity (pr1 (D u) a)).
apply (functor_id (D u) a).
now rewrite H, id_right.
- intros a b c fab fbc; simpl; unfold LimFunctor_mor.
apply pathsinv0.
eapply pathscomp0; [now apply postcompWithLimOfArrows|].
apply pathsinv0, limArrowUnique; intro u.
rewrite limOfArrowsOut, (functor_comp (D u)); simpl.
now rewrite <- assoc.
Definition LimFunctor : functor A C := tpair _ _ is_functor_LimFunctor_data.
Definition lim_nat_trans_in_data v : [A, C, hsC] ⟦ LimFunctor, D v ⟧.
Show proof.
use tpair.
- intro a; exact (limOut (HCg a) v).
- abstract (intros a a' f; apply (limOfArrowsOut (HCg a) (HCg a'))).
- intro a; exact (limOut (HCg a) v).
- abstract (intros a a' f; apply (limOfArrowsOut (HCg a) (HCg a'))).
Definition cone_pointwise (F : [A,C,hsC]) (cc : cone D F) a :
cone (functor_pointwise a) (pr1 F a).
Show proof.
use make_cone.
- now intro v; apply (pr1 (coneOut cc v) a).
- abstract (intros u v e;
now apply (nat_trans_eq_pointwise (coneOutCommutes cc u v e))).
- now intro v; apply (pr1 (coneOut cc v) a).
- abstract (intros u v e;
now apply (nat_trans_eq_pointwise (coneOutCommutes cc u v e))).
Lemma LimFunctor_unique (F : [A, C, hsC]) (cc : cone D F) :
iscontr (∑ x : [A, C, hsC] ⟦ F, LimFunctor ⟧,
∏ v, x · lim_nat_trans_in_data v = coneOut cc v).
Show proof.
use tpair.
- use tpair.
+ apply (tpair _ (λ a, limArrow (HCg a) _ (cone_pointwise F cc a))).
abstract (intros a a' f; simpl; apply pathsinv0; eapply pathscomp0;
[ apply (postcompWithLimOfArrows (HCg a))
| apply pathsinv0; eapply pathscomp0;
[ apply postcompWithLimArrow
| apply limArrowUnique; intro u; eapply pathscomp0;
[ now apply limArrowCommutes | now use nat_trans_ax]]]).
+ abstract (intro u; apply (nat_trans_eq hsC); simpl; intro a;
now apply (limArrowCommutes (HCg a))).
- abstract (intro t; destruct t as [t1 t2];
apply subtypePath; simpl;
[ intro; apply impred; intro u; apply functor_category_has_homsets
| apply (nat_trans_eq hsC); simpl; intro a;
apply limArrowUnique; intro u;
now apply (nat_trans_eq_pointwise (t2 u))]).
- use tpair.
+ apply (tpair _ (λ a, limArrow (HCg a) _ (cone_pointwise F cc a))).
abstract (intros a a' f; simpl; apply pathsinv0; eapply pathscomp0;
[ apply (postcompWithLimOfArrows (HCg a))
| apply pathsinv0; eapply pathscomp0;
[ apply postcompWithLimArrow
| apply limArrowUnique; intro u; eapply pathscomp0;
[ now apply limArrowCommutes | now use nat_trans_ax]]]).
+ abstract (intro u; apply (nat_trans_eq hsC); simpl; intro a;
now apply (limArrowCommutes (HCg a))).
- abstract (intro t; destruct t as [t1 t2];
apply subtypePath; simpl;
[ intro; apply impred; intro u; apply functor_category_has_homsets
| apply (nat_trans_eq hsC); simpl; intro a;
apply limArrowUnique; intro u;
now apply (nat_trans_eq_pointwise (t2 u))]).
Lemma LimFunctorCone : LimCone D.
Show proof.
use make_LimCone.
- exact LimFunctor.
- use make_cone.
+ now apply lim_nat_trans_in_data.
+ abstract (now intros u v e; apply (nat_trans_eq hsC);
intro a; apply (limOutCommutes (HCg a))).
- now intros F cc; simpl; apply (LimFunctor_unique _ cc).
- exact LimFunctor.
- use make_cone.
+ now apply lim_nat_trans_in_data.
+ abstract (now intros u v e; apply (nat_trans_eq hsC);
intro a; apply (limOutCommutes (HCg a))).
- now intros F cc; simpl; apply (LimFunctor_unique _ cc).
End LimFunctor.
Lemma LimsFunctorCategory (A C : precategory) (hsC : has_homsets C)
(HC : Lims C) : Lims [A,C,hsC].
Show proof.
Lemma LimsFunctorCategory_of_shape (J A C : precategory) (hsC : has_homsets C)
(HC : Lims_of_shape J C) : Lims_of_shape J [A,C,hsC].
Show proof.