Library UniMath.CategoryTheory.categories.rings
Require Import UniMath.Foundations.PartD.
Require Import UniMath.Foundations.Propositions.
Require Import UniMath.Foundations.Sets.
Require Import UniMath.Foundations.UnivalenceAxiom.
Require Import UniMath.Algebra.BinaryOperations.
Require Import UniMath.Algebra.Monoids.
Require Import UniMath.Algebra.RigsAndRings.
Require Import UniMath.CategoryTheory.Core.Categories.
Require Import UniMath.CategoryTheory.Core.Isos.
Require Import UniMath.CategoryTheory.Core.Univalence.
Local Open Scope cat.
Section def_ring_precategory.
Definition ring_fun_space (A B : ring) : hSet := make_hSet (ringfun A B) (isasetrigfun A B).
Definition ring_precategory_ob_mor : precategory_ob_mor :=
tpair (λ ob : UU, ob → ob → UU) ring (λ A B : ring, ring_fun_space A B).
Definition ring_precategory_data : precategory_data :=
make_precategory_data
ring_precategory_ob_mor (λ (X : ring), (rigisotorigfun (idrigiso X)))
(fun (X Y Z : ring) (f : ringfun X Y) (g : ringfun Y Z) ⇒ rigfuncomp f g).
Local Lemma ring_id_left (X Y : ring) (f : ringfun X Y) :
rigfuncomp (rigisotorigfun (idrigiso X)) f = f.
Proof.
use rigfun_paths. use idpath.
Defined.
Opaque ring_id_left.
Local Lemma ring_id_right (X Y : ring) (f : ringfun X Y) :
rigfuncomp f (rigisotorigfun (idrigiso Y)) = f.
Proof.
use rigfun_paths. use idpath.
Defined.
Opaque ring_id_right.
Local Lemma ring_assoc (X Y Z W : ring) (f : ringfun X Y) (g : ringfun Y Z) (h : ringfun Z W) :
rigfuncomp f (rigfuncomp g h) = rigfuncomp (rigfuncomp f g) h.
Proof.
use rigfun_paths. use idpath.
Defined.
Opaque ring_assoc.
Lemma is_precategory_ring_precategory_data : is_precategory ring_precategory_data.
Proof.
use make_is_precategory_one_assoc.
- intros a b f. use ring_id_left.
- intros a b f. use ring_id_right.
- intros a b c d f g h. use ring_assoc.
Qed.
Definition ring_precategory : precategory :=
make_precategory ring_precategory_data is_precategory_ring_precategory_data.
Lemma has_homsets_ring_precategory : has_homsets ring_precategory.
Proof.
intros X Y. use isasetrigfun.
Qed.
End def_ring_precategory.
Definition ring_fun_space (A B : ring) : hSet := make_hSet (ringfun A B) (isasetrigfun A B).
Definition ring_precategory_ob_mor : precategory_ob_mor :=
tpair (λ ob : UU, ob → ob → UU) ring (λ A B : ring, ring_fun_space A B).
Definition ring_precategory_data : precategory_data :=
make_precategory_data
ring_precategory_ob_mor (λ (X : ring), (rigisotorigfun (idrigiso X)))
(fun (X Y Z : ring) (f : ringfun X Y) (g : ringfun Y Z) ⇒ rigfuncomp f g).
Local Lemma ring_id_left (X Y : ring) (f : ringfun X Y) :
rigfuncomp (rigisotorigfun (idrigiso X)) f = f.
Proof.
use rigfun_paths. use idpath.
Defined.
Opaque ring_id_left.
Local Lemma ring_id_right (X Y : ring) (f : ringfun X Y) :
rigfuncomp f (rigisotorigfun (idrigiso Y)) = f.
Proof.
use rigfun_paths. use idpath.
Defined.
Opaque ring_id_right.
Local Lemma ring_assoc (X Y Z W : ring) (f : ringfun X Y) (g : ringfun Y Z) (h : ringfun Z W) :
rigfuncomp f (rigfuncomp g h) = rigfuncomp (rigfuncomp f g) h.
Proof.
use rigfun_paths. use idpath.
Defined.
Opaque ring_assoc.
Lemma is_precategory_ring_precategory_data : is_precategory ring_precategory_data.
Proof.
use make_is_precategory_one_assoc.
- intros a b f. use ring_id_left.
- intros a b f. use ring_id_right.
- intros a b c d f g h. use ring_assoc.
Qed.
Definition ring_precategory : precategory :=
make_precategory ring_precategory_data is_precategory_ring_precategory_data.
Lemma has_homsets_ring_precategory : has_homsets ring_precategory.
Proof.
intros X Y. use isasetrigfun.
Qed.
End def_ring_precategory.
Lemma ring_iso_is_equiv (A B : ob ring_precategory) (f : iso A B) : isweq (pr1 (pr1 f)).
Proof.
use isweq_iso.
- exact (pr1rigfun _ _ (inv_from_iso f)).
- intros x.
use (toforallpaths _ _ _ (subtypeInjectivity _ _ _ _ (iso_inv_after_iso f)) x).
intros x0. use isapropisrigfun.
- intros x.
use (toforallpaths _ _ _ (subtypeInjectivity _ _ _ _ (iso_after_iso_inv f)) x).
intros x0. use isapropisrigfun.
Defined.
Opaque ring_iso_is_equiv.
Lemma ring_iso_equiv (X Y : ob ring_precategory) : iso X Y → ringiso (X : ring) (Y : ring).
Proof.
intro f.
use make_ringiso.
- exact (make_weq (pr1 (pr1 f)) (ring_iso_is_equiv X Y f)).
- exact (pr2 (pr1 f)).
Defined.
Lemma ring_equiv_is_iso (X Y : ob ring_precategory) (f : ringiso (X : ring) (Y : ring)) :
@is_iso ring_precategory X Y (ringfunconstr (pr2 f)).
Proof.
use is_iso_qinv.
- exact (ringfunconstr (pr2 (invrigiso f))).
- use make_is_inverse_in_precat.
+ use rigfun_paths. use funextfun. intros x. use homotinvweqweq.
+ use rigfun_paths. use funextfun. intros y. use homotweqinvweq.
Defined.
Opaque ring_equiv_is_iso.
Lemma ring_equiv_iso (X Y : ob ring_precategory) : ringiso (X : ring) (Y : ring) → iso X Y.
Proof.
intros f. exact (@make_iso ring_precategory X Y (ringfunconstr (pr2 f))
(ring_equiv_is_iso X Y f)).
Defined.
Lemma ring_iso_equiv_is_equiv (X Y : ring_precategory) : isweq (ring_iso_equiv X Y).
Proof.
use isweq_iso.
- exact (ring_equiv_iso X Y).
- intros x. use eq_iso. use rigfun_paths. use idpath.
- intros y. use rigiso_paths. use subtypePath.
+ intros x0. use isapropisweq.
+ use idpath.
Defined.
Opaque ring_iso_equiv_is_equiv.
Definition ring_iso_equiv_weq (X Y : ob ring_precategory) :
weq (iso X Y) (ringiso (X : ring) (Y : ring)).
Proof.
use make_weq.
- exact (ring_iso_equiv X Y).
- exact (ring_iso_equiv_is_equiv X Y).
Defined.
Lemma ring_equiv_iso_is_equiv (X Y : ob ring_precategory) : isweq (ring_equiv_iso X Y).
Proof.
use isweq_iso.
- exact (ring_iso_equiv X Y).
- intros y. use rigiso_paths. use subtypePath.
+ intros x0. use isapropisweq.
+ use idpath.
- intros x. use eq_iso. use rigfun_paths. use idpath.
Defined.
Opaque ring_equiv_iso_is_equiv.
Definition ring_equiv_weq_iso (X Y : ob ring_precategory) :
(ringiso (X : ring) (Y : ring)) ≃ (iso X Y).
Proof.
use make_weq.
- exact (ring_equiv_iso X Y).
- exact (ring_equiv_iso_is_equiv X Y).
Defined.
Definition ring_precategory_isweq (X Y : ob ring_precategory) : isweq (λ p : X = Y, idtoiso p).
Proof.
use (@isweqhomot
(X = Y) (iso X Y)
(pr1weq (weqcomp (ring_univalence X Y) (ring_equiv_weq_iso X Y)))
_ _ (weqproperty (weqcomp (ring_univalence X Y) (ring_equiv_weq_iso X Y)))).
intros e. induction e.
use (pathscomp0 weqcomp_to_funcomp_app).
use total2_paths_f.
- use idpath.
- use proofirrelevance. use isaprop_is_iso.
Defined.
Opaque ring_precategory_isweq.
Definition ring_precategory_is_univalent : is_univalent ring_precategory.
Proof.
use make_is_univalent.
- intros X Y. exact (ring_precategory_isweq X Y).
- exact has_homsets_ring_precategory.
Defined.
Definition ring_category : univalent_category :=
make_univalent_category ring_precategory ring_precategory_is_univalent.
End def_ring_category.