Generalizable All Variables.
-Require Import Preamble.
+Require Import Notations.
Require Import Categories_ch1_3.
Require Import Functors_ch1_4.
Require Import Isomorphisms_ch1_5.
-Require Import ProductCategories_ch1_6_1.
Require Import InitialTerminal_ch2_2.
Require Import Subcategories_ch7_1.
+Require Import ProductCategories_ch1_6_1.
Require Import NaturalTransformations_ch7_4.
Require Import NaturalIsomorphisms_ch7_5.
Require Import Coherence_ch7_8.
+Require Import BinoidalCategories.
+Require Import PreMonoidalCategories.
(******************************************************************************)
-(* Chapter 7.8: (Pre)Monoidal Categories *)
+(* Chapter 7.8: Monoidal Categories *)
(******************************************************************************)
-Class BinoidalCat
-`( C : Category )
-( bin_obj' : C -> C -> C ) :=
-{ bin_obj := bin_obj' where "a ⊗ b" := (bin_obj a b)
-; bin_first : forall a:C, Functor C C (fun x => x⊗a)
-; bin_second : forall a:C, Functor C C (fun x => a⊗x)
-; bin_c := C
-}.
-Coercion bin_c : BinoidalCat >-> Category.
-Notation "a ⊗ b" := (@bin_obj _ _ _ _ _ a b) : category_scope.
-Notation "C ⋊ f" := (@fmor _ _ _ _ _ _ _ (@bin_second _ _ _ _ _ C) _ _ f) : category_scope.
-Notation "g ⋉ C" := (@fmor _ _ _ _ _ _ _ (@bin_first _ _ _ _ _ C) _ _ g) : category_scope.
-Notation "C ⋊ -" := (@bin_second _ _ _ _ _ C) : category_scope.
-Notation "- ⋉ C" := (@bin_first _ _ _ _ _ C) : category_scope.
+(* TO DO: show that the endofunctors on any given category form a monoidal category *)
-Class CentralMorphism `{BinoidalCat}`(f:a~>b) : Prop :=
-{ centralmor_first : forall `(g:c~>d), (f ⋉ _ >>> _ ⋊ g) ~~ (_ ⋊ g >>> f ⋉ _)
-; centralmor_second : forall `(g:c~>d), (g ⋉ _ >>> _ ⋊ f) ~~ (_ ⋊ f >>> g ⋉ _)
+(*
+ * Unlike Awodey, I define a monoidal category to be a premonoidal
+ * category in which all morphisms are central. This is partly to
+ * have a clean inheritance hierarchy, but also because Coq bogs down
+ * on product categories for some inexplicable reason.
+ *)
+Class MonoidalCat `(pm:PreMonoidalCat) :=
+{ mon_pm := pm
+; mon_commutative :> CommutativeCat pm
+}.
+Coercion mon_pm : MonoidalCat >-> PreMonoidalCat.
+Coercion mon_commutative : MonoidalCat >-> CommutativeCat.
+
+(* a monoidal functor is just a premonoidal functor between premonoidal categories which happen to be monoidal *)
+Definition MonoidalFunctor `(m1:MonoidalCat) `(m2:MonoidalCat) {fobj}(F:Functor m1 m2 fobj) := PreMonoidalFunctor m1 m2 F.
+
+Definition MonoidalFunctorsCompose
+ `{PM1 :MonoidalCat(C:=C1)}
+ `{PM2 :MonoidalCat(C:=C2)}
+ {fobj12:C1 -> C2 }
+ {PMFF12:Functor C1 C2 fobj12 }
+ (PMF12 :MonoidalFunctor PM1 PM2 PMFF12)
+ `{PM3 :MonoidalCat(C:=C3)}
+ {fobj23:C2 -> C3 }
+ {PMFF23:Functor C2 C3 fobj23 }
+ (PMF23 :MonoidalFunctor PM2 PM3 PMFF23)
+ := PreMonoidalFunctorsCompose PMF12 PMF23.
+
+Class MonoidalNaturalIsomorphism
+ `{C1:MonoidalCat}`{C2:MonoidalCat}
+ `(F1:!MonoidalFunctor(fobj:=fobj1) C1 C2 Func1)
+ `(F2:!MonoidalFunctor(fobj:=fobj2) C1 C2 Func2) :=
+{ mni_ni : NaturalIsomorphism F1 F2
+; mni_commutes1 : forall A B,
+ #(ni_iso (mf_first(PreMonoidalFunctor:=F1) B) A) >>> #(ni_iso mni_ni (A⊗B)) ~~
+ #(ni_iso mni_ni _) ⋉ _ >>> _ ⋊ #(ni_iso mni_ni _) >>> #(ni_iso (mf_first(PreMonoidalFunctor:=F2) B) A)
+; mni_commutes2 : forall A B,
+ #(ni_iso (mf_second(PreMonoidalFunctor:=F1) A) B) >>> #(ni_iso mni_ni (A⊗B)) ~~
+ #(ni_iso mni_ni _) ⋉ _ >>> _ ⋊ #(ni_iso mni_ni _) >>> #(ni_iso (mf_second(PreMonoidalFunctor:=F2) A) B)
+}.
+Notation "F <~~⊗~~> G" := (@MonoidalNaturalIsomorphism _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ F _ _ G) : category_scope.
+
+(* an equivalence of categories via monoidal functors, but the natural iso isn't necessarily a monoidal natural iso *)
+Structure MonoidalEquivalence `{C1:MonoidalCat} `{C2:MonoidalCat} :=
+{ meqv_forward_fobj : C1 -> C2
+; meqv_forward : Functor C1 C2 meqv_forward_fobj
+; meqv_forward_mon : PreMonoidalFunctor _ _ meqv_forward
+; meqv_backward_fobj : C2 -> C1
+; meqv_backward : Functor C2 C1 meqv_backward_fobj
+; meqv_backward_mon : PreMonoidalFunctor _ _ meqv_backward
+; meqv_comp1 : meqv_forward >>>> meqv_backward ≃ functor_id _
+; meqv_comp2 : meqv_backward >>>> meqv_forward ≃ functor_id _
}.
-(* the central morphisms of a category constitute a subcategory *)
-Definition Center `(bc:BinoidalCat) : SubCategory bc (fun _ => True) (fun _ _ _ _ f => CentralMorphism f).
- apply Build_SubCategory; intros; apply Build_CentralMorphism; intros.
- abstract (setoid_rewrite (fmor_preserves_id(bin_first c));
- setoid_rewrite (fmor_preserves_id(bin_first d));
- setoid_rewrite left_identity; setoid_rewrite right_identity; reflexivity).
- abstract (setoid_rewrite (fmor_preserves_id(bin_second c));
- setoid_rewrite (fmor_preserves_id(bin_second d));
- setoid_rewrite left_identity; setoid_rewrite right_identity; reflexivity).
- abstract (setoid_rewrite <- (fmor_preserves_comp(bin_first c0));
- setoid_rewrite associativity;
- setoid_rewrite centralmor_first;
- setoid_rewrite <- associativity;
- setoid_rewrite centralmor_first;
- setoid_rewrite associativity;
- setoid_rewrite <- (fmor_preserves_comp(bin_first d));
- reflexivity).
- abstract (setoid_rewrite <- (fmor_preserves_comp(bin_second d));
- setoid_rewrite <- associativity;
- setoid_rewrite centralmor_second;
- setoid_rewrite associativity;
- setoid_rewrite centralmor_second;
- setoid_rewrite <- associativity;
- setoid_rewrite <- (fmor_preserves_comp(bin_second c0));
- reflexivity).
- Qed.
-
-Class CommutativeCat `(BinoidalCat) :=
-{ commutative_central : forall `(f:a~>b), CentralMorphism f
-; commutative_morprod := fun `(f:a~>b)`(g:a~>b) => f ⋉ _ >>> _ ⋊ g
+(* a monoidally-natural equivalence of categories *)
+(*
+Structure MonoidalNaturalEquivalence `{C1:MonoidalCat} `{C2:MonoidalCat} :=
+{ mneqv_forward_fobj : C1 -> C2
+; mneqv_forward : Functor C1 C2 mneqv_forward_fobj
+; mneqv_forward_mon : PreMonoidalFunctor _ _ mneqv_forward
+; mneqv_backward_fobj : C2 -> C1
+; mneqv_backward : Functor C2 C1 mneqv_backward_fobj
+; mneqv_backward_mon : PreMonoidalFunctor _ _ mneqv_backward
+; mneqv_comp1 : mneqv_forward_mon >>⊗>> mneqv_backward_mon <~~⊗~~> premonoidal_id _
+; mneqv_comp2 : mneqv_backward_mon >>⊗>> mneqv_forward_mon <~~⊗~~> premonoidal_id _
}.
-Notation "f × g" := (commutative_morprod f g).
+*)
Section BinoidalCat_from_Bifunctor.
Context `{C:Category}{Fobj}(F:Functor (C ×× C) C Fobj).
|}.
Defined.
- (*
- Lemma Bifunctors_Create_Commutative_Binoidal_Categories : CommutativeCat (BinoidalCat_from_Bifunctor F).
+ Lemma Bifunctors_Create_Commutative_Binoidal_Categories : CommutativeCat BinoidalCat_from_Bifunctor.
abstract (intros; apply Build_CommutativeCat; intros; apply Build_CentralMorphism; intros; simpl; (
etransitivity; [ apply (fmor_preserves_comp(F)) | idtac ]; symmetry;
etransitivity; [ apply (fmor_preserves_comp(F)) | idtac ];
[ etransitivity; [ apply left_identity | symmetry; apply right_identity ]
| etransitivity; [ apply right_identity | symmetry; apply left_identity ] ])).
Defined.
- *)
-End BinoidalCat_from_Bifunctor.
-
-(* not in Awodey *)
-Class PreMonoidalCat `(bc:BinoidalCat(C:=C))(I:C) :=
-{ pmon_I := I
-; pmon_bin := bc
-; pmon_cat := C
-; pmon_assoc : forall a b, (bin_second a >>>> bin_first b) <~~~> (bin_first b >>>> bin_second a)
-; pmon_cancelr : (bin_first I) <~~~> functor_id C
-; pmon_cancell : (bin_second I) <~~~> functor_id C
-; pmon_pentagon : Pentagon (fun a b c f => f ⋉ c) (fun a b c f => c ⋊ f) (fun a b c => #((pmon_assoc a c) b))
-; pmon_triangle : Triangle (fun a b c f => f ⋉ c) (fun a b c f => c ⋊ f) (fun a b c => #((pmon_assoc a c) b))
- (fun a => #(pmon_cancell a)) (fun a => #(pmon_cancelr a))
-; pmon_assoc_rr : forall a b, (bin_first (a⊗b)) <~~~> (bin_first a >>>> bin_first b)
-; pmon_assoc_ll : forall a b, (bin_second (a⊗b)) <~~~> (bin_second b >>>> bin_second a)
-; pmon_coherent_r : forall a c d:C, #(pmon_assoc_rr c d a) ~~ #(pmon_assoc a d c)⁻¹
-; pmon_coherent_l : forall a c d:C, #(pmon_assoc_ll c a d) ~~ #(pmon_assoc c d a)
-}.
-(*
- * Premonoidal categories actually have three associators (the "f"
- * indicates the position in which the operation is natural:
- *
- * assoc : (A ⋊ f) ⋉ C <-> A ⋊ (f ⋉ C)
- * assoc_rr : (f ⋉ B) ⋉ C <-> f ⋉ (B ⊗ C)
- * assoc_ll : (A ⋊ B) ⋊ f <-> (A ⊗ B) ⋊ f
- *
- * Fortunately, in a monoidal category these are all the same natural
- * isomorphism (and in any case -- monoidal or not -- the objects in
- * the left column are all the same and the objects in the right
- * column are all the same). This formalization assumes that is the
- * case even for premonoidal categories with non-central maps, in
- * order to keep the complexity manageable. I don't know much about
- * the consequences of having them and letting them be different; you
- * might need extra versions of the triangle/pentagon diagrams.
- *)
-
-Implicit Arguments pmon_cancell [ Ob Hom C bin_obj' bc I ].
-Implicit Arguments pmon_cancelr [ Ob Hom C bin_obj' bc I ].
-Implicit Arguments pmon_assoc [ Ob Hom C bin_obj' bc I ].
-Coercion pmon_bin : PreMonoidalCat >-> BinoidalCat.
-(* this turns out to be Exercise VII.1.1 from Mac Lane's CWM *)
-Lemma MacLane_ex_VII_1_1 `{mn:PreMonoidalCat(I:=EI)} a b
- : #((pmon_cancelr mn) (a ⊗ b)) ~~ #((pmon_assoc mn a EI) b) >>> (a ⋊-) \ #((pmon_cancelr mn) b).
- set (pmon_pentagon EI EI a b) as penta. unfold pmon_pentagon in penta.
- set (pmon_triangle a b) as tria. unfold pmon_triangle in tria.
- apply (fmor_respects(bin_second EI)) in tria.
- set (@fmor_preserves_comp) as fpc.
- setoid_rewrite <- fpc in tria.
- set (ni_commutes (pmon_assoc mn a b)) as xx.
- (* FIXME *)
- Admitted.
-
-(* Formalized Definition 3.10 *)
-Class PreMonoidalFunctor
-`(PM1:PreMonoidalCat(C:=C1)(I:=I1))
-`(PM2:PreMonoidalCat(C:=C2)(I:=I2))
- (fobj : C1 -> C2 ) :=
-{ mf_F :> Functor C1 C2 fobj
-; mf_preserves_i : mf_F I1 ≅ I2
-; mf_preserves_first : forall a, bin_first a >>>> mf_F <~~~> mf_F >>>> bin_first (mf_F a)
-; mf_preserves_second : forall a, bin_second a >>>> mf_F <~~~> mf_F >>>> bin_second (mf_F a)
-; mf_preserves_center : forall `(f:a~>b), CentralMorphism f -> CentralMorphism (mf_F \ f)
-}.
-Coercion mf_F : PreMonoidalFunctor >-> Functor.
-
-(*******************************************************************************)
-(* Braided and Symmetric Categories *)
-
-Class BraidedCat `(mc:PreMonoidalCat) :=
-{ br_swap : forall a b, a⊗b ≅ b⊗a
-; triangleb : forall a:C, #(pmon_cancelr mc a) ~~ #(br_swap a (pmon_I(PreMonoidalCat:=mc))) >>> #(pmon_cancell mc a)
-; hexagon1 : forall {a b c}, #(pmon_assoc mc _ _ _) >>> #(br_swap a _) >>> #(pmon_assoc mc _ _ _)
- ~~ #(br_swap _ _) ⋉ c >>> #(pmon_assoc mc _ _ _) >>> b ⋊ #(br_swap _ _)
-; hexagon2 : forall {a b c}, #(pmon_assoc mc _ _ _)⁻¹ >>> #(br_swap _ c) >>> #(pmon_assoc mc _ _ _)⁻¹
- ~~ a ⋊ #(br_swap _ _) >>> #(pmon_assoc mc _ _ _)⁻¹ >>> #(br_swap _ _) ⋉ b
-}.
-
-Class SymmetricCat `(bc:BraidedCat) :=
-{ symcat_swap : forall a b:C, #((br_swap(BraidedCat:=bc)) a b) ~~ #(br_swap _ _)⁻¹
-}.
-
-Class DiagonalCat `(BinoidalCat) :=
-{ copy : forall a, a ~> (a⊗a)
-(* copy >> swap == copy -- only necessary for non-cartesian braided diagonal categories *)
-}.
-
-Class CartesianCat `(mc:PreMonoidalCat(C:=C)) :=
-{ car_terminal : Terminal C
-; car_one : 1 ≅ pmon_I
-; car_diagonal : DiagonalCat mc
-; car_law1 : forall {a}, id a ~~ (copy(DiagonalCat:=car_diagonal) _) >>> ((drop a >>> #car_one) ⋉ a) >>> (#(pmon_cancell mc _))
-; car_law2 : forall {a}, id a ~~ (copy(DiagonalCat:=car_diagonal) _) >>> (a ⋊ (drop a >>> #car_one)) >>> (#(pmon_cancelr mc _))
-; car_cat := C
-; car_mn := mc
-}.
-Coercion car_diagonal : CartesianCat >-> DiagonalCat.
-Coercion car_terminal : CartesianCat >-> Terminal.
-Coercion car_mn : CartesianCat >-> PreMonoidalCat.
+ (* if this binoidal structure has all of the natural isomorphisms of a premonoidal category, then it's monoidal *)
+ Context {pmI}(pm:PreMonoidalCat BinoidalCat_from_Bifunctor pmI).
-(* Definition 7.23 *)
-Class MonoidalCat `{C:Category}{Fobj:prod_obj C C -> C}{F:Functor (C ×× C) C Fobj}(I:C) :=
-{ mon_f := F
-; mon_i := I
-; mon_c := C
-(*; mon_bin := BinoidalCat_from_Bifunctor mon_f*)
-; mon_first := fun a b c (f:a~>b) => F \ pair_mor (pair_obj a c) (pair_obj b c) f (id c)
-; mon_second := fun a b c (f:a~>b) => F \ pair_mor (pair_obj c a) (pair_obj c b) (id c) f
-; mon_cancelr : (func_rlecnac I >>>> F) <~~~> functor_id C
-; mon_cancell : (func_llecnac I >>>> F) <~~~> functor_id C
-; mon_assoc : ((F **** (functor_id C)) >>>> F) <~~~> func_cossa >>>> ((((functor_id C) **** F) >>>> F))
-; mon_pentagon : Pentagon mon_first mon_second (fun a b c => #(mon_assoc (pair_obj (pair_obj a b) c)))
-; mon_triangle : Triangle mon_first mon_second (fun a b c => #(mon_assoc (pair_obj (pair_obj a b) c)))
- (fun a => #(mon_cancell a)) (fun a => #(mon_cancelr a))
-}.
+ Instance PreMonoidalCat_from_bifunctor_is_Monoidal : MonoidalCat pm :=
+ { mon_commutative := Bifunctors_Create_Commutative_Binoidal_Categories
+ }.
-(* FIXME: show that the endofunctors on any given category form a monoidal category *)
+End BinoidalCat_from_Bifunctor.
-(* Coq manual on coercions: ... only the oldest one is valid and the
- * others are ignored. So the order of declaration of coercions is
- * important. *)
-Coercion mon_c : MonoidalCat >-> Category.
-(*Coercion mon_bin : MonoidalCat >-> BinoidalCat.*)
-Coercion mon_f : MonoidalCat >-> Functor.
-Implicit Arguments mon_f [Ob Hom C Fobj F I].
-Implicit Arguments mon_i [Ob Hom C Fobj F I].
-Implicit Arguments mon_c [Ob Hom C Fobj F I].
-(*Implicit Arguments mon_bin [Ob Hom C Fobj F I].*)
-Implicit Arguments MonoidalCat [Ob Hom ].
-Section MonoidalCat_is_PreMonoidal.
+(* we can go the other way: given a monoidal category, its left/right functors can be combined into a bifunctor *)
+Section Bifunctor_from_MonoidalCat.
Context `(M:MonoidalCat).
- Definition mon_bin_M := BinoidalCat_from_Bifunctor (mon_f M).
- Existing Instance mon_bin_M.
- Lemma mon_pmon_assoc : forall a b, (bin_second a >>>> bin_first b) <~~~> (bin_first b >>>> bin_second a).
- intros.
- set (fun c => mon_assoc (pair_obj (pair_obj a c) b)) as qq.
- simpl in qq.
- apply Build_NaturalIsomorphism with (ni_iso:=qq).
- abstract (intros; set ((ni_commutes mon_assoc) (pair_obj (pair_obj a A) b) (pair_obj (pair_obj a B) b)
- (pair_mor (pair_obj (pair_obj a A) b) (pair_obj (pair_obj a B) b)
- (pair_mor (pair_obj a A) (pair_obj a B) (id a) f) (id b))) as qr;
- apply qr).
- Defined.
- Lemma mon_pmon_assoc_rr : forall a b, (bin_first (a⊗b)) <~~~> (bin_first a >>>> bin_first b).
- intros.
- set (fun c:C => mon_assoc (pair_obj (pair_obj c a) b)) as qq.
- simpl in qq.
- apply ni_inv.
- apply Build_NaturalIsomorphism with (ni_iso:=qq).
- abstract (intros; set ((ni_commutes mon_assoc) (pair_obj (pair_obj _ _) _) (pair_obj (pair_obj _ _) _)
- (pair_mor (pair_obj (pair_obj _ _) _) (pair_obj (pair_obj _ _) _)
- (pair_mor (pair_obj _ _) (pair_obj _ _) f (id a)) (id b))) as qr;
- etransitivity; [ idtac | apply qr ];
- apply comp_respects; try reflexivity;
- unfold mon_f;
- simpl;
- apply ((fmor_respects F) (pair_obj _ _) (pair_obj _ _));
- split; try reflexivity;
- symmetry;
- simpl;
- set (@fmor_preserves_id _ _ _ _ _ _ _ F (pair_obj a b)) as qqqq;
- simpl in qqqq;
- apply qqqq).
- Defined.
- Lemma mon_pmon_assoc_ll : forall a b, (bin_second (a⊗b)) <~~~> (bin_second b >>>> bin_second a).
- intros.
- set (fun c:C => mon_assoc (pair_obj (pair_obj a b) c)) as qq.
- simpl in qq.
- set (@Build_NaturalIsomorphism _ _ _ _ _ _ _ _ (Fobj (pair_obj a b) ⋊-) (b ⋊- >>>> a ⋊-)) as qqq.
- set (qqq qq) as q'.
- apply q'.
- clear q'.
- clear qqq.
- abstract (intros; set ((ni_commutes mon_assoc) (pair_obj (pair_obj _ _) _) (pair_obj (pair_obj _ _) _)
- (pair_mor (pair_obj (pair_obj _ _) _) (pair_obj (pair_obj _ _) _)
- (pair_mor (pair_obj _ _) (pair_obj _ _) (id a) (id b)) f)) as qr;
- etransitivity; [ apply qr | idtac ];
- apply comp_respects; try reflexivity;
- unfold mon_f;
- simpl;
- apply ((fmor_respects F) (pair_obj _ _) (pair_obj _ _));
- split; try reflexivity;
- simpl;
- set (@fmor_preserves_id _ _ _ _ _ _ _ F (pair_obj a b)) as qqqq;
- simpl in qqqq;
- apply qqqq).
+ Definition Bifunctor_from_MonoidalCat_fobj : M ×× M -> M.
+ intro x.
+ destruct x.
+ exact (bin_obj' o o0).
Defined.
- Lemma mon_pmon_cancelr : (bin_first I0) <~~~> functor_id C.
- set (@Build_NaturalIsomorphism _ _ _ _ _ _ _ _ (bin_first I0) (functor_id C)) as qq.
- set (mon_cancelr) as z.
- simpl in z.
- simpl in qq.
- set (qq z) as zz.
- apply zz.
- abstract (intros;
- set (ni_commutes mon_cancelr) as q; simpl in *;
- apply q).
- Defined.
-
- Lemma mon_pmon_cancell : (bin_second I0) <~~~> functor_id C.
- set (@Build_NaturalIsomorphism _ _ _ _ _ _ _ _ (bin_second I0) (functor_id C)) as qq.
- set (mon_cancell) as z.
- simpl in z.
- simpl in qq.
- set (qq z) as zz.
- apply zz.
- abstract (intros;
- set (ni_commutes mon_cancell) as q; simpl in *;
- apply q).
- Defined.
-
- Lemma mon_pmon_triangle : forall a b, #(mon_pmon_cancelr a) ⋉ b ~~ #(mon_pmon_assoc _ _ _) >>> a ⋊ #(mon_pmon_cancell b).
- intros.
- set mon_triangle as q.
- simpl in q.
- apply q.
- Qed.
-
- Lemma mon_pmon_pentagon a b c d : (#(mon_pmon_assoc a c b ) ⋉ d) >>>
- #(mon_pmon_assoc a d _ ) >>>
- (a ⋊ #(mon_pmon_assoc b d c))
- ~~ #(mon_pmon_assoc _ d c ) >>>
- #(mon_pmon_assoc a _ b ).
- set (@pentagon _ _ _ _ _ _ _ mon_pentagon) as x.
- simpl in x.
- unfold bin_obj.
- unfold mon_first in x.
+ Definition Bifunctor_from_MonoidalCat_fmor {a}{b}(f:a~~{M××M}~~>b)
+ : (Bifunctor_from_MonoidalCat_fobj a)~~{M}~~>(Bifunctor_from_MonoidalCat_fobj b).
+ destruct a; destruct b; destruct f.
simpl in *.
- apply x.
- Qed.
-
- Definition MonoidalCat_is_PreMonoidal : PreMonoidalCat (BinoidalCat_from_Bifunctor (mon_f M)) (mon_i M).
- refine {| pmon_assoc := mon_pmon_assoc
- ; pmon_cancell := mon_pmon_cancell
- ; pmon_cancelr := mon_pmon_cancelr
- ; pmon_triangle := {| triangle := mon_pmon_triangle |}
- ; pmon_pentagon := {| pentagon := mon_pmon_pentagon |}
- ; pmon_assoc_ll := mon_pmon_assoc_ll
- ; pmon_assoc_rr := mon_pmon_assoc_rr
- |}.
- abstract (set (coincide mon_triangle) as qq; simpl in *; apply qq).
- abstract (intros; simpl; reflexivity).
- abstract (intros; simpl; reflexivity).
+ apply (h ⋉ _ >>> _ ⋊ h0).
Defined.
- Lemma MonoidalCat_all_central : forall a b (f:a~~{M}~~>b), CentralMorphism f.
- intros;
- set (@fmor_preserves_comp _ _ _ _ _ _ _ M) as fc.
- apply Build_CentralMorphism;
- intros; simpl in *.
- etransitivity.
- apply fc.
- symmetry.
- etransitivity.
- apply fc.
- apply (fmor_respects M).
- simpl.
- setoid_rewrite left_identity;
- setoid_rewrite right_identity;
- split; reflexivity.
- etransitivity.
- apply fc.
- symmetry.
- etransitivity.
- apply fc.
- apply (fmor_respects M).
- simpl.
- setoid_rewrite left_identity;
- setoid_rewrite right_identity;
- split; reflexivity.
- Qed.
-
-End MonoidalCat_is_PreMonoidal.
-
-Hint Extern 1 => apply MonoidalCat_all_central.
-Coercion MonoidalCat_is_PreMonoidal : MonoidalCat >-> PreMonoidalCat.
-(*Lemma CommutativePreMonoidalCategoriesAreMonoidal `(pm:PreMonoidalCat)(cc:CommutativeCat pm) : MonoidalCat pm.*)
-
-Section MonoidalFunctor.
- Context `(m1:MonoidalCat(C:=C1)) `(m2:MonoidalCat(C:=C2)).
- Class MonoidalFunctor {Mobj:C1->C2} (mf_F:Functor C1 C2 Mobj) :=
- { mf_f := mf_F where "f ⊕⊕ g" := (@fmor _ _ _ _ _ _ _ m2 _ _ (pair_mor (pair_obj _ _) (pair_obj _ _) f g))
- ; mf_coherence : (mf_F **** mf_F) >>>> (mon_f m2) <~~~> (mon_f m1) >>>> mf_F
- ; mf_phi := fun a b => #(mf_coherence (pair_obj a b))
- ; mf_id : (mon_i m2) ≅ (mf_F (mon_i m1))
- ; mf_cancelr : forall a, #(mon_cancelr(MonoidalCat:=m2) (mf_F a)) ~~
- (id (mf_F a)) ⊕⊕ #mf_id >>> mf_phi a (mon_i _) >>> mf_F \ #(mon_cancelr a)
- ; mf_cancell : forall b, #(mon_cancell (mf_F b)) ~~
- #mf_id ⊕⊕ (id (mf_F b)) >>> mf_phi (mon_i _) b >>> mf_F \ #(mon_cancell b)
- ; mf_assoc : forall a b c, (mf_phi a b) ⊕⊕ (id (mf_F c)) >>> (mf_phi _ c) >>>
- (mf_F \ #(mon_assoc (pair_obj (pair_obj a b) c) )) ~~
- #(mon_assoc (pair_obj (pair_obj _ _) _) ) >>>
- (id (mf_F a)) ⊕⊕ (mf_phi b c) >>> (mf_phi a _)
- }.
-End MonoidalFunctor.
-Coercion mf_f : MonoidalFunctor >-> Functor.
-Implicit Arguments mf_coherence [ Ob Hom C1 Fobj F I0 m1 Ob0 Hom0 C2 Fobj0 F0 I1 m2 Mobj mf_F ].
-Implicit Arguments mf_id [ Ob Hom C1 Fobj F I0 m1 Ob0 Hom0 C2 Fobj0 F0 I1 m2 Mobj mf_F ].
-
-Section MonoidalFunctorsCompose.
- Context `(m1:MonoidalCat).
- Context `(m2:MonoidalCat).
- Context `(m3:MonoidalCat).
- Context {f1obj}(f1:@Functor _ _ m1 _ _ m2 f1obj).
- Context {f2obj}(f2:@Functor _ _ m2 _ _ m3 f2obj).
- Context (mf1:MonoidalFunctor m1 m2 f1).
- Context (mf2:MonoidalFunctor m2 m3 f2).
-
- Lemma mf_compose_coherence : (f1 >>>> f2) **** (f1 >>>> f2) >>>> m3 <~~~> m1 >>>> (f1 >>>> f2).
- set (mf_coherence mf1) as mc1.
- set (mf_coherence mf2) as mc2.
- set (@ni_comp) as q.
- set (q _ _ _ _ _ _ _ ((f1 >>>> f2) **** (f1 >>>> f2) >>>> m3) _ ((f1 **** f1 >>>> m2) >>>> f2) _ (m1 >>>> (f1 >>>> f2))) as qq.
- apply qq; clear qq; clear q.
- apply (@ni_comp _ _ _ _ _ _ _ _ _ (f1 **** f1 >>>> (f2 **** f2 >>>> m3)) _ _).
- apply (@ni_comp _ _ _ _ _ _ _ _ _ ((f1 **** f1 >>>> f2 **** f2) >>>> m3) _ _).
- eapply ni_respects.
- apply ni_prod_comp.
- apply ni_id.
- apply ni_associativity.
- apply ni_inv.
- eapply ni_comp.
- apply (ni_associativity (f1 **** f1) m2 f2).
- apply (ni_respects (F0:=f1 **** f1)(F1:=f1 **** f1)(G0:=(m2 >>>> f2))(G1:=(f2 **** f2 >>>> m3))).
- apply ni_id.
- apply ni_inv.
- apply mc2.
- apply ni_inv.
- eapply ni_comp.
- eapply ni_inv.
- apply (ni_associativity m1 f1 f2).
- apply ni_respects.
- apply ni_inv.
- apply mc1.
- apply ni_id.
- Qed.
+ Instance Bifunctor_from_MonoidalCat : Functor (M ×× M) M Bifunctor_from_MonoidalCat_fobj :=
+ { fmor := fun x y f => Bifunctor_from_MonoidalCat_fmor f }.
+ intros; simpl.
+ destruct a; destruct b; destruct f; destruct f'; simpl in *.
+ destruct H.
+ apply comp_respects.
+ apply (fmor_respects (-⋉o0)); auto.
+ apply (fmor_respects (o1⋊-)); auto.
+ intros; destruct a; simpl in *.
+ setoid_rewrite (fmor_preserves_id (-⋉o0)).
+ setoid_rewrite left_identity.
+ apply fmor_preserves_id.
+ intros; destruct a; destruct b; destruct c; destruct f; destruct g; simpl in *.
+ setoid_rewrite <- fmor_preserves_comp.
+ setoid_rewrite juggle3 at 1.
+ assert (CentralMorphism h1).
+ apply mon_commutative.
+ setoid_rewrite <- (centralmor_first(CentralMorphism:=H)).
+ setoid_rewrite <- juggle3.
+ reflexivity.
+ Defined.
+
+End Bifunctor_from_MonoidalCat.
+
+
+Instance MonoidalFullSubcategory_Monoidal `(mc:MonoidalCat) {Pobj} Pobj_unit Pobj_closed V
+ : MonoidalCat (PreMonoidalFullSubcategory_PreMonoidal(Pobj:=Pobj) mc V Pobj_unit Pobj_closed).
+ apply Build_MonoidalCat.
+ apply Build_CommutativeCat.
+ intros.
+ idtac.
+ apply Build_CentralMorphism; intros.
+ destruct a.
+ destruct b.
+ destruct c.
+ destruct d.
+ simpl.
+ apply (centralmor_first(CentralMorphism:=commutative_central(CommutativeCat:=mon_commutative(MonoidalCat:=mc)) f)).
+
+ destruct a.
+ destruct b.
+ destruct c.
+ destruct d.
+ simpl.
+ apply (centralmor_first(CentralMorphism:=commutative_central(CommutativeCat:=mon_commutative(MonoidalCat:=mc)) g)).
+ Defined.
- Instance MonoidalFunctorsCompose : MonoidalFunctor m1 m3 (f1 >>>> f2) :=
- { mf_id := id_comp (mf_id mf2) (functors_preserve_isos f2 (mf_id mf1))
- ; mf_coherence := mf_compose_coherence
- }.
- admit.
- admit.
- admit.
- Defined.
+Class DiagonalCat `(mc:MonoidalCat) :=
+{ copy : forall (a:mc), a~~{mc}~~>(bin_obj(BinoidalCat:=mc) a a)
+; copy_natural1 : forall {a}{b}(f:a~~{mc}~~>b)(c:mc), copy _ >>> f ⋉ a >>> b ⋊ f ~~ f >>> copy _
+; copy_natural2 : forall {a}{b}(f:a~~{mc}~~>b)(c:mc), copy _ >>> a ⋊ f >>> f ⋉ b ~~ f >>> copy _
+(* for non-cartesian braided diagonal categories we also need: copy >> swap == copy *)
+}.
-End MonoidalFunctorsCompose.
+Class CartesianCat `(mc:MonoidalCat) :=
+{ car_terminal :> TerminalObject mc (pmon_I mc)
+; car_diagonal : DiagonalCat mc
+; car_law1 : forall {a}, id a ~~ (copy(DiagonalCat:=car_diagonal) a) >>> (drop a ⋉ a) >>> (#(pmon_cancell _))
+; car_law2 : forall {a}, id a ~~ (copy(DiagonalCat:=car_diagonal) a) >>> (a ⋊ drop a) >>> (#(pmon_cancelr _))
+; car_mn := mc
+}.
+Coercion car_diagonal : CartesianCat >-> DiagonalCat.
+Coercion car_terminal : CartesianCat >-> TerminalObject.
+Coercion car_mn : CartesianCat >-> MonoidalCat.