--- /dev/null
+(*******************************************************************************)
+(* Hughes Arrows *)
+(*******************************************************************************)
+
+Generalizable All Variables.
+Require Import Preamble.
+Require Import General.
+Require Import Categories_ch1_3.
+Require Import Functors_ch1_4.
+Require Import Isomorphisms_ch1_5.
+Require Import ProductCategories_ch1_6_1.
+Require Import EpicMonic_ch2_1.
+Require Import InitialTerminal_ch2_2.
+Require Import Subcategories_ch7_1.
+Require Import NaturalTransformations_ch7_4.
+Require Import NaturalIsomorphisms_ch7_5.
+Require Import Coherence_ch7_8.
+Require Import MonoidalCategories_ch7_8.
+Require Import FreydCategories.
+Require Import CoqCategory.
+
+(* these notations are more for printing back than writing input (helps coax Coq into better pretty-printing) *)
+Notation "'_swap'" := (fun xy => let (a0, b0) := xy in ⟨b0, a0 ⟩).
+Notation "'_assoc'" := (fun xyz => let (ab, c) := xyz in let (a0, b0) := ab in ⟨a0, ⟨b0, c ⟩ ⟩).
+
+Class Arrow
+( arr_hom' : Type->Type->Type ) :=
+{ arr_hom := arr_hom' (* hack to make Coq notations work *) where "a ~> b" := (arr_hom a b)
+
+; arr_arr : forall {a b}, (a->b) -> a~>b
+; arr_comp : forall {a b c}, a~>b -> b~>c -> a~>c where "f >>> g" := (arr_comp f g)
+; arr_first : forall {a b} c, a~>b -> (a*c)~>(b*c) where "f ⋊ d" := (arr_first d f)
+
+; arr_eqv : forall {a b}, (a~>b) -> (a~>b) -> Prop where "a ~~ b" := (arr_eqv a b)
+; arr_eqv_equivalence : forall {a b}, Equivalence (@arr_eqv a b)
+
+; arr_comp_respects : forall {a b c}, Proper (arr_eqv ==> arr_eqv ==> arr_eqv) (@arr_comp a b c)
+; arr_first_respects : forall {a b c}, Proper (arr_eqv ==> arr_eqv) (@arr_first a b c)
+; arr_arr_respects : forall {a b}(f g:a->b), Proper (extensionality a b ==> arr_eqv) (@arr_arr a b)
+
+; arr_left_identity : forall `(f:a~>b), (arr_arr (fun x => x)) >>> f ~~ f
+; arr_right_identity : forall `(f:a~>b), f >>> (arr_arr (fun x => x)) ~~ f
+; arr_associativity : forall `(f:a~>b)`(g:b~>c)`(h:c~>d), (f >>> g) >>> h ~~ f >>> (g >>> h)
+; arr_comp_preserves : forall `(f:a->b)`(g:b->c), arr_arr (g ○ f) ~~ arr_arr f >>> arr_arr g
+; arr_extension : forall a b (f:a->b), forall d, (arr_arr f) ⋊ d ~~ arr_arr (Λ⟨x,y⟩ ⟨f x,y⟩)
+; arr_first_preserves : forall {d}`(f:a~>b)`(g:b~>c), (f >>> g) ⋊ d ~~ f ⋊ d >>> g ⋊ d
+; arr_exchange : forall `(f:a~>b)`(g:c->d), arr_arr (Λ⟨x,y⟩ ⟨x,g y⟩) >>> f ⋊ _ ~~ f ⋊ _ >>> arr_arr (Λ⟨x,y⟩ ⟨x,g y⟩)
+; arr_unit : forall {c}`(f:a~>b), f ⋊ c >>> arr_arr (Λ⟨x,y⟩x) ~~ (arr_arr (Λ⟨x,y⟩x)) >>> f
+; arr_association : forall {c}{d}`(f:a~>b), (f⋊c)⋊d >>> arr_arr(Λ⟨⟨x,y⟩,z⟩ ⟨x,⟨y,z⟩⟩) ~~ arr_arr (Λ⟨⟨x,y⟩,z⟩ ⟨x,⟨y,z⟩⟩) >>> f⋊_
+}.
+
+(*
+ ; loop : forall {a}{b}{c}, (a⊗c~>b⊗c) -> (a~>b)
+ (* names taken from Figure 7 of Paterson's "A New Notation for Arrows", which match the CCA paper *)
+ ; left_tightening : forall {a}{b}{c}{f:a⊗b~>c⊗b}{h}, loop (first c a b h >>> f) ~~ h >>> loop f
+ ; right_tightening : forall {a}{b}{c}{f:a⊗b~>c⊗b}{h}, loop (f >>> first c a b h) ~~ loop f >>> h
+ ; sliding : forall {a}{b}{c}{f:a⊗c~>b⊗c}{k}, central k -> loop (f >>> second _ _ b k) ~~ loop (second _ _ a k >>> f)
+ ; vanishing : forall {a}{b}{c}{d}{f:(a⊗c)⊗d~>(b⊗c)⊗d}, loop (loop f) ~~ loop (#assoc⁻¹ >>> f >>> #assoc)
+ ; superposing : forall {a}{b}{c}{d}{f:a⊗c~>b⊗c}, second _ _ d (loop f) ~~ loop (#assoc >>> second _ _ d f >>> #assoc⁻¹)
+*)
+
+(* register the arrow equivalence relation as a rewritable setoid, with >>> and first as morphisms *)
+Add Parametric Relation `(ba:Arrow)(a b:Type) : (arr_hom a b) arr_eqv
+ reflexivity proved by (@Equivalence_Reflexive _ _ (@arr_eqv_equivalence _ _ a b))
+ symmetry proved by (@Equivalence_Symmetric _ _ (@arr_eqv_equivalence _ _ a b))
+ transitivity proved by (@Equivalence_Transitive _ _ (@arr_eqv_equivalence _ _ a b))
+ as parametric_relation_arr_eqv.
+ Add Parametric Morphism `(ba:Arrow)(a b c:Type) : (@arr_comp _ _ a b c)
+ with signature (arr_eqv ==> arr_eqv ==> arr_eqv) as parametric_morphism_arr_comp.
+ intros; apply arr_comp_respects; auto.
+ Defined.
+ Add Parametric Morphism `(ba:Arrow)(a b c:Type) : (@arr_first _ _ a b c)
+ with signature (arr_eqv ==> arr_eqv) as parametric_morphism_arr_first.
+ intros; apply arr_first_respects; auto.
+ Defined.
+
+Notation "a ~> b" := (arr_hom a b) :arrow_scope.
+Notation "f >>> g" := (arr_comp f g) :arrow_scope.
+Notation "f ⋊ d" := (arr_first d f) :arrow_scope.
+Notation "a ~~ b" := (arr_eqv a b) :arrow_scope.
+
+Open Scope arrow_scope.
+
+(* Formalized Definition 2.3 *)
+Class BiArrow
+( biarr_hom : Type -> Type -> Type ) :=
+{ biarr_super :> Arrow biarr_hom
+
+; biarr_biarr : forall {a b}, (a->b) -> (b->a) -> (a~>b) where "f <--> g" := (biarr_biarr g f)
+; biarr_inv : forall {a b}, a~>b -> b~>a where "! f" := (biarr_inv f)
+
+(* BiArrow laws are numbered based on section 5 of Hunen+Jacobs paper *)
+; biarr_law3' : forall {a}{b}{c}{f1}{f2:b->c}{g1}{c2:a->b}, f1<-->c2 >>> g1<-->f2 ~~ (f1 ○ g1) <--> (f2 ○ c2)
+; biarr_law4' : forall {a}{b}{f:a~>b}, (fun x=>x)<-->(fun x=>x) >>> f ~~ f
+; biarr_law4'': forall {a}{b}{f:a~>b}, f >>> (fun x=>x)<-->(fun x=>x) ~~ f
+; biarr_law8' : forall {a}{b}{f:a->b}{g}{c}, (f<-->g) ⋊ c ~~ (Λ⟨x,y⟩ ⟨f x,y⟩)<-->(Λ⟨x,y⟩ ⟨g x,y⟩)
+; biarr_law22 : forall {a}{b}{f:a~>b}, !(!f) ~~ f
+; biarr_law23 : forall {a}{b}{c}{f:b~>c}{g:a~>b}, !(g >>> f) ~~ !f >>> !g
+; biarr_law24 : forall {a}{b}{f:a->b}{g}, !(f<-->g) ~~ g<-->f
+; biarr_law25 : forall {a}{b}{f:a~>b}{c}, !(f ⋊ _) ~~ (!f) ⋊ c
+; biarr_law6' : forall {a}{b}{c}{d}{f:a->b}{g}{h:c~>d}, (h ⋊ _) >>> (Λ⟨x,y⟩ ⟨x,f y⟩)<-->(Λ⟨x,y⟩ ⟨x,g y⟩) ~~
+ (Λ⟨x,y⟩ ⟨x,f y⟩)<-->(Λ⟨x,y⟩ ⟨x,g y⟩) >>> (h ⋊ _)
+
+(* for complete example, we'd also need biarr_biarr_respects and biarr_inv_respects, but this paper isn't about BiArrows *)
+}.
+
+Notation "f <--> g" := (biarr_biarr g f) :biarrow_scope.
+Notation "! f" := (biarr_inv f) :biarrow_scope.
+
+Open Scope biarrow_scope.
+Inductive left_invertible `{ba:BiArrow}{a}{b}(f:a~>b) : Prop := LI : ((f >>> !f) ~~ (arr_arr (fun x=>x))) -> left_invertible f.
+Inductive right_invertible `{ba:BiArrow}{a}{b}(f:a~>b) : Prop := RI : ((!f >>> f) ~~ (arr_arr (fun x=>x))) -> right_invertible f.
+Close Scope biarrow_scope.
+
+Hint Extern 4 (?A ~~ ?A) => reflexivity.
+Hint Extern 6 (?X ~~ ?Y) => apply Equivalence_Symmetric.
+Hint Extern 7 (?X ~~ ?Z) => match goal with [H : ?X ~~ ?Y, H' : ?Y ~~ ?Z |- ?X ~~ ?Z] => transitivity Y end.
+Hint Extern 10 (?X >>> ?Y ~~ ?Z >>> ?Q) => apply arr_comp_respects; auto.
+Hint Constructors Arrow.
+
+(* Formalized Lemma 3.2 *)
+Definition arrows_are_categories : forall `(ba:Arrow), Category Type arr_hom.
+ intros.
+ refine
+ {| id := fun a => arr_arr (fun x => x)
+ ; comp := fun a b c f g => arr_comp f g
+ ; eqv := fun a b f g => arr_eqv f g |}; intros; auto.
+ apply arr_left_identity.
+ apply arr_right_identity.
+ apply arr_associativity.
+ Defined.
+Coercion arrows_are_categories : Arrow >-> Category.
+
+(* a tactic to throw the kitchen sink at Arrow goals; using ATBR (http://coq.inria.fr/contribs/ATBR.html) would be a better idea *)
+Ltac magic :=
+ repeat apply arr_comp;
+ repeat apply arr_first;
+ repeat apply arr_arr_respects;
+ repeat setoid_rewrite arr_left_identity;
+ repeat setoid_rewrite arr_right_identity;
+ repeat setoid_rewrite <- arr_comp_preserves;
+ repeat setoid_rewrite arr_extension;
+ repeat setoid_rewrite arr_first_preserves.
+ (* need to handle associat, exchange, unit, association *)
+
+Definition Arrows_are_Binoidal `(ba:Arrow) : BinoidalCat ((arrows_are_categories ba)) prod.
+ intros; apply Build_BinoidalCat; intros;
+ [ apply (Build_Functor _ _ (ba) _ _ (ba) (fun X => X*a)
+ (fun X Y f => (arr_first(Arrow:=ba)) a f))
+ | apply (Build_Functor _ _ (ba) _ _ (ba) (fun X => a*X)
+ (fun X Y f => arr_arr (Λ⟨x,y⟩ ⟨y,x⟩) >>> arr_first(Arrow:=ba) a f >>> arr_arr(Arrow:=ba) (Λ⟨x,y⟩ ⟨y,x⟩)))
+ ]; intros; simpl; intros;
+ [ apply arr_first_respects; auto
+ | setoid_rewrite arr_extension; repeat setoid_rewrite <- arr_comp_preserves; apply arr_arr_respects
+ | symmetry; apply arr_first_preserves
+ | repeat apply arr_comp_respects; try reflexivity
+ | setoid_rewrite arr_extension; repeat setoid_rewrite <- arr_comp_preserves
+ | setoid_rewrite arr_first_preserves
+ ]; intros; auto.
+ idtac.
+ unfold extensionality; intros; destruct x; auto.
+ simpl in H; setoid_rewrite H; auto.
+ apply arr_arr_respects; intros; auto.
+ unfold extensionality; intros; destruct x; auto.
+ repeat rewrite arr_associativity; repeat setoid_rewrite <- arr_comp_preserves.
+ apply arr_comp_respects; try reflexivity.
+ apply arr_comp_respects; try reflexivity.
+ setoid_rewrite <- arr_associativity.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ setoid_rewrite <- arr_associativity.
+ apply arr_comp_respects; try reflexivity.
+ transitivity (arr_comp ((arr_arr(Arrow:=ba)) (fun x=>x)) (arr_first(Arrow:=ba) a g)).
+ apply arr_comp_respects; try reflexivity.
+ apply arr_arr_respects; intros; auto; unfold extensionality; intros; auto; try destruct x; auto.
+ apply arr_left_identity.
+ Defined.
+
+ Definition arrow_cancelr_iso : forall `(ba:Arrow)(A:ba), (Isomorphic(C:=ba)) (A*Datatypes.unit) A.
+ intros; apply (Build_Isomorphic _ _ ba (A*Datatypes.unit) A (arr_arr (Λ⟨x,y⟩ x)) (arr_arr (fun x => ⟨x,tt⟩))).
+ simpl; setoid_rewrite <- arr_comp_preserves; apply arr_arr_respects.
+ intros; destruct X. auto. auto.
+ unfold extensionality; intros; simpl. destruct x. destruct u. auto.
+ simpl; setoid_rewrite <- arr_comp_preserves; reflexivity.
+ Defined.
+ Definition arrow_cancelr_ni_iso `(ba:Arrow)
+ : (((bin_first(BinoidalCat:=Arrows_are_Binoidal ba)) (Datatypes.unit)) <~~~> functor_id (ba)).
+ intros; eapply Build_NaturalIsomorphism.
+ instantiate (1:=arrow_cancelr_iso ba).
+ intros;
+ transitivity (
+ arr_comp(Arrow:=ba)
+ (fmor (bin_first(BinoidalCat:=Arrows_are_Binoidal ba) Datatypes.unit) f)
+ (arr_arr(Arrow:=ba) (fun xy : B * unit => let (a, b) := xy in (fun (x : B) (_ : unit) => x) a b))
+ ).
+ symmetry.
+ apply (arr_unit(Arrow:=ba)(c:=(Datatypes.unit)) f).
+ apply Equivalence_Reflexive.
+ Defined.
+ Definition arrow_cancell_iso `(ba:Arrow)
+ : forall (A:ba), (Isomorphic(C:=ba)) (Datatypes.unit*A) A.
+ intros; apply (Build_Isomorphic _ _ ba _ _ (arr_arr (Λ⟨x,y⟩ y)) (arr_arr (fun x => ⟨tt,x⟩))).
+ simpl; setoid_rewrite <- arr_comp_preserves; apply arr_arr_respects.
+ intros; destruct X. auto. auto.
+ unfold extensionality; intros; simpl. destruct x. auto. destruct u. auto.
+ simpl; setoid_rewrite <- arr_comp_preserves; reflexivity.
+ Defined.
+ Definition arrow_cancell_ni_iso `(ba:Arrow)
+ : (((bin_second(BinoidalCat:=(Arrows_are_Binoidal ba))) (Datatypes.unit)) <~~~> functor_id (ba)).
+ intros; eapply Build_NaturalIsomorphism.
+ instantiate (1:=arrow_cancell_iso ba).
+ intros. simpl.
+ repeat setoid_rewrite arr_associativity.
+ setoid_rewrite <- arr_comp_preserves.
+ simpl;
+ setoid_replace (arr_arr (fun x : B * unit => let (_, b) := let (a, b) := x in ⟨b, a ⟩ in b))
+ with (arr_arr (fun x : B * unit => let (b, _) := x in b)).
+ setoid_rewrite arr_unit.
+ setoid_rewrite <- arr_associativity.
+ magic.
+ apply arr_comp_respects.
+ apply arr_arr_respects.
+ intros; destruct X; auto.
+ intros; destruct X; auto.
+ unfold extensionality; intros; simpl.
+ destruct x; auto.
+ apply Equivalence_Reflexive.
+ apply arr_arr_respects.
+ intros; destruct X; auto.
+ intros; destruct X; auto.
+ unfold extensionality; intros; simpl.
+ destruct x.
+ auto.
+ Defined.
+
+ Definition arrow_assoc_iso `(ba:Arrow) : forall A B C, (Isomorphic(C:=ba)) ((A*B)*C) (A*(B*C)).
+ intros; eapply (Build_Isomorphic _ _ ba _ _ (arr_arr (Λ⟨⟨x,y⟩,z⟩ ⟨x,⟨y,z⟩⟩)) (arr_arr (Λ⟨x,⟨y,z⟩⟩ ⟨⟨x,y⟩,z⟩)));
+ [ intros; simpl; setoid_rewrite <- arr_comp_preserves
+ | intros; simpl; simpl; setoid_rewrite <- arr_comp_preserves; apply arr_arr_respects; auto
+ ]; simpl; try apply arr_arr_respects; intros; try destruct X; try destruct x; try destruct p; auto;
+ unfold extensionality; intros; intros; destruct x; destruct p; auto.
+ Defined.
+ Definition arrow_assoc_ni_iso `(ba:Arrow) :
+ (∀A : ba, ∀B : ba,
+ (bin_second(BinoidalCat:=(Arrows_are_Binoidal ba))) A >>>>
+ (bin_first(BinoidalCat:=(Arrows_are_Binoidal ba))) B <~~~>
+ (bin_first(BinoidalCat:=(Arrows_are_Binoidal ba))) B >>>>
+ (bin_second(BinoidalCat:=(Arrows_are_Binoidal ba))) A).
+ intros.
+ eapply Build_NaturalIsomorphism.
+ instantiate (1:=(fun X:ba => (arrow_assoc_iso ba A X B))).
+ simpl; intros.
+ setoid_rewrite arr_first_preserves.
+ setoid_rewrite arr_first_preserves.
+ setoid_rewrite arr_associativity.
+ setoid_replace
+ ( (arr_first(Arrow:=ba) A (arr_first(Arrow:=ba) B f)) >>> @arr_arr arr_hom' ba (B0 * B * A) (A * (B0 * B)) _swap)
+ with
+ ((( (arr_first(Arrow:=ba) A (arr_first(Arrow:=ba) B f)) >>>
+ (arr_arr (Λ⟨⟨x,y⟩,z⟩ ⟨x,⟨y,z⟩⟩))) >>> (arr_arr (Λ⟨x,⟨y,z⟩⟩ ⟨⟨x,y⟩,z⟩))) >>>
+ @arr_arr arr_hom' ba (B0 * B * A) (A * (B0 * B)) _swap).
+ setoid_rewrite arr_association.
+ repeat setoid_rewrite arr_associativity.
+ setoid_replace
+ ((arr_first(Arrow:=ba) B (arr_first(Arrow:=ba) A f))
+ >>> ((arr_first(Arrow:=ba) B (@arr_arr arr_hom' ba (B0 * A) (A * B0) _swap))
+ >>> (@arr_arr arr_hom' ba (A * B0 * B) (A * (B0 * B)) _assoc)))
+ with
+ ((((arr_first(Arrow:=ba) B (arr_first(Arrow:=ba) A f))
+ >>> (arr_arr (Λ⟨⟨x,y⟩,z⟩ ⟨x,⟨y,z⟩⟩)))
+ >>> (arr_arr (Λ⟨x,y⟩ ⟨y,x⟩))
+ >>> (arr_arr (Λ⟨x,y⟩ ⟨y,x⟩))
+ >>> (arr_arr (Λ⟨x,⟨y,z⟩⟩ ⟨⟨x,y⟩,z⟩)))
+ >>> ((arr_first(Arrow:=ba) B (@arr_arr arr_hom' ba (B0 * A) (A * B0) _swap))
+ >>> (@arr_arr arr_hom' ba (A * B0 * B) (A * (B0 * B)) _assoc))).
+ setoid_rewrite arr_association.
+ setoid_replace (arr_first(Arrow:=ba) (A*B) f)
+ with (((arr_first(Arrow:=ba) (A*B) f)
+ >>> (arr_arr (Λ⟨x,y⟩ ⟨x,(fun q => match q with (a,b) => (b,a) end) y⟩)))
+ >>> (arr_arr (Λ⟨x,y⟩ ⟨x,(fun q => match q with (a,b) => (b,a) end) y⟩))).
+ setoid_rewrite <- arr_exchange.
+ repeat magic.
+ repeat setoid_rewrite <- arr_associativity.
+ repeat magic.
+ repeat setoid_rewrite arr_associativity.
+ repeat magic.
+ apply arr_comp_respects.
+ apply arr_arr_respects.
+ intros; destruct X; destruct p; auto.
+ intros; destruct X; destruct p; auto.
+ unfold extensionality; intros; simpl.
+ destruct x. destruct p; auto.
+ apply arr_comp_respects.
+ reflexivity.
+ apply arr_arr_respects.
+ intros; destruct X; destruct p; auto.
+ intros; destruct X; destruct p; auto.
+ unfold extensionality; intros; simpl.
+ destruct x. destruct p; auto.
+ setoid_rewrite arr_associativity.
+ magic.
+ setoid_replace (arr_first(Arrow:=ba) (A*B) f) with (arr_first(Arrow:=ba) (A*B) f >>> arr_arr (fun x => x)).
+ apply arr_comp_respects.
+ setoid_rewrite arr_right_identity.
+ reflexivity.
+ apply arr_arr_respects.
+ intros; destruct X; destruct p; auto.
+ intros; destruct X; destruct p; auto.
+ unfold extensionality; intros; simpl.
+ destruct x. destruct p; auto.
+ setoid_rewrite <- arr_right_identity.
+ setoid_rewrite arr_associativity.
+ repeat magic.
+ reflexivity.
+ repeat magic.
+ repeat setoid_rewrite arr_associativity.
+ repeat magic.
+ apply arr_comp_respects.
+ reflexivity.
+ apply arr_arr_respects.
+ intros; destruct X; destruct p; auto.
+ intros; destruct X; destruct p; auto.
+ unfold extensionality; intros; simpl.
+ destruct x. destruct p; auto.
+ repeat setoid_rewrite arr_associativity.
+ repeat magic.
+ apply arr_comp_respects.
+ reflexivity.
+ apply arr_arr_respects.
+ intros; destruct X; destruct p; auto.
+ intros; destruct X; destruct p; auto.
+ unfold extensionality; intros; simpl.
+ destruct x. destruct p; auto.
+ Defined.
+
+ Definition arrow_assoc_rr_iso `(ba:Arrow) := fun a b X:ba => iso_inv _ _ (arrow_assoc_iso ba X a b).
+ Definition arrow_assoc_rr_ni_iso `(ba:Arrow) :
+ ∀a b:ba, NaturalIsomorphism
+ (bin_first(BinoidalCat:=(Arrows_are_Binoidal ba)) ((bin_obj(BinoidalCat:=(Arrows_are_Binoidal ba))) a b))
+ ((bin_first(BinoidalCat:=(Arrows_are_Binoidal ba)) a)
+ >>>>
+ (bin_first(BinoidalCat:=(Arrows_are_Binoidal ba)) b)).
+ intros; eapply Build_NaturalIsomorphism.
+ instantiate(1:=arrow_assoc_rr_iso ba a b).
+ intros.
+ simpl.
+ setoid_replace ((arr_first(Arrow:=ba) (a*b) f))
+ with (arr_arr (fun q:A*(a*b) => (Λ⟨x,⟨y,z⟩⟩ ⟨⟨x,y⟩,z⟩) q)
+ >>> ((arr_arr (Λ⟨⟨x,y⟩,z⟩ ⟨x,⟨y,z⟩⟩))
+ >>> (arr_first(Arrow:=ba) (a*b) f))).
+ setoid_rewrite <- arr_association.
+ repeat setoid_rewrite arr_associativity.
+ magic.
+ apply arr_comp_respects.
+ apply arr_arr_respects.
+ intros. destruct X. destruct p. auto.
+ intros. destruct X. destruct p. auto.
+ unfold extensionality.
+ intros; auto.
+ transitivity (arr_first(Arrow:=ba) b (arr_first(Arrow:=ba) a f) >>> arr_arr (fun x=>x)).
+ setoid_rewrite arr_right_identity.
+ reflexivity.
+ apply arr_comp_respects.
+ reflexivity.
+ apply arr_arr_respects.
+ intros. destruct X. destruct p. auto.
+ intros. destruct X. destruct p. auto.
+ unfold extensionality.
+ intros; auto.
+ destruct x.
+ destruct p.
+ auto.
+ setoid_rewrite <- arr_associativity.
+ magic.
+ transitivity (arr_arr (fun x=>x) >>> (arr_first(Arrow:=ba) (a*b) f)).
+ setoid_rewrite arr_left_identity.
+ reflexivity.
+ apply arr_comp_respects.
+ apply arr_arr_respects.
+ intros. destruct X. destruct p. auto.
+ intros. destruct X. destruct p. auto.
+ unfold extensionality.
+ intros; auto.
+ destruct x.
+ destruct p.
+ auto.
+ reflexivity.
+ Defined.
+
+ Definition arrow_assoc_ll_iso `(ba:Arrow) := fun a b X:ba => arrow_assoc_iso ba a b X.
+ Definition arrow_assoc_ll_ni_iso `(ba:Arrow) :
+ forall a b:ba, NaturalIsomorphism
+ (bin_second(BinoidalCat:=(Arrows_are_Binoidal ba)) ((bin_obj(BinoidalCat:=(Arrows_are_Binoidal ba))) a b))
+ ((bin_second(BinoidalCat:=(Arrows_are_Binoidal ba)) b)
+ >>>>
+ (bin_second(BinoidalCat:=(Arrows_are_Binoidal ba)) a)).
+ intros.
+ eapply Build_NaturalIsomorphism.
+ simpl; intros.
+ instantiate(1:=(arrow_assoc_ll_iso ba a b)).
+ simpl.
+ magic.
+ repeat setoid_rewrite arr_associativity.
+ setoid_replace
+ ((arr_first a (arr_first(Arrow:=ba) b f)) >>> ((arr_first _ ((@arr_arr arr_hom' ba (B * b) (b * B) _swap))) >>>
+ @arr_arr arr_hom' ba (b * B * a) (a * (b * B)) _swap))
+ with
+ ((((arr_first a (arr_first(Arrow:=ba) b f)
+ >>> ((arr_arr(a:=((B*b)*a)) (Λ⟨⟨x,y⟩,z⟩ ⟨x,⟨y,z⟩⟩)))))
+ >>> (arr_arr(Arrow:=ba) (Λ⟨x,yz⟩ ⟨x,(match yz with (y,z) => (z,y) end)⟩)))
+ >>> (arr_arr(Arrow:=ba) (Λ⟨x,⟨y,z⟩⟩ ⟨y,⟨z,x⟩⟩))).
+ setoid_rewrite arr_association.
+ setoid_replace (arr_arr(a:=((A*b)*a)) _assoc >>> (arr_first(Arrow:=ba) (b*a) f) >>>
+ arr_arr(Arrow:=ba)
+ (fun xy : B * (b * a) =>
+ let (a0, b0) := xy in ⟨a0, let (y, z) := b0 in ⟨z, y ⟩ ⟩))
+ with
+ (arr_arr(a:=((A*b)*a)) _assoc >>> ((arr_first(Arrow:=ba) (b*a) f) >>>
+ arr_arr(Arrow:=ba)
+ (fun xy : B * (b * a) =>
+ let (a0, b0) := xy in ⟨a0, ((fun xy:b*a => let (a0, b0) := xy in ⟨b0, a0 ⟩)) b0 ⟩))).
+ setoid_rewrite <- arr_exchange.
+ repeat magic.
+ repeat setoid_rewrite <- arr_associativity.
+ repeat magic.
+ apply arr_comp_respects.
+ apply arr_comp_respects.
+ apply arr_arr_respects.
+ exact (fun xyz => match xyz with (xy,z) => match xy with (x,y) => (z,(x,y)) end end).
+ exact (fun xyz => match xyz with (xy,z) => match xy with (x,y) => (z,(x,y)) end end).
+ unfold extensionality; intros; simpl.
+ destruct x.
+ destruct b0.
+ auto.
+ reflexivity.
+ apply arr_arr_respects.
+ intros. destruct X. destruct b1. auto.
+ intros. destruct X. destruct b1. auto.
+ unfold extensionality; intros; simpl.
+ destruct x.
+ destruct b1.
+ auto.
+ repeat setoid_rewrite <- arr_associativity.
+ apply arr_comp_respects.
+ reflexivity.
+ apply arr_arr_respects.
+ intros. destruct X. destruct p. auto.
+ intros. destruct X. destruct p. auto.
+ unfold extensionality; intros; simpl.
+ destruct x.
+ destruct p.
+ auto.
+ setoid_rewrite arr_extension.
+ repeat setoid_rewrite arr_associativity.
+ magic.
+ apply arr_comp_respects.
+ reflexivity.
+ apply arr_arr_respects.
+ intros. destruct X. destruct p. auto.
+ intros. destruct X. destruct p. auto.
+ unfold extensionality; intros; simpl.
+ destruct x.
+ destruct p.
+ auto.
+ Defined.
+
+ Instance arrows_monoidal `(ba:Arrow) : PreMonoidalCat (Arrows_are_Binoidal ba) (Datatypes.unit) :=
+ { pmon_assoc := arrow_assoc_ni_iso ba
+ ; pmon_cancelr := arrow_cancelr_ni_iso ba
+ ; pmon_cancell := arrow_cancell_ni_iso ba
+ ; pmon_assoc_ll := arrow_assoc_ll_ni_iso ba
+ ; pmon_assoc_rr := arrow_assoc_rr_ni_iso ba
+ }.
+ apply Build_Pentagon; intros.
+ intros; simpl.
+ repeat setoid_rewrite arr_extension.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ apply arr_arr_respects; unfold extensionality; intros; simpl;
+ try destruct x; try destruct X; try destruct b0; try destruct p; auto.
+ destruct b0. unfold bin_obj. auto.
+ destruct b0. unfold bin_obj. auto.
+ destruct b0. unfold bin_obj. auto.
+ apply Build_Triangle; intros; simpl.
+ repeat setoid_rewrite arr_extension.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ apply arr_arr_respects; unfold extensionality; intros; simpl;
+ try destruct x; try destruct X; try destruct p; try destruct b0; try destruct p; unfold bin_obj; auto.
+ simpl. apply arr_arr_respects;
+ [ exact (fun (xy:unit*unit) => tt)
+ | exact (fun (xy:unit*unit) => tt)
+ | idtac
+ ]; unfold extensionality; intros; simpl; destruct x; destruct u; destruct u0; auto.
+ intros; reflexivity.
+ intros; reflexivity.
+ Defined.
+
+Definition arrow_inclusion_functor `(ba:Arrow) : Functor coqCategory (ba) (fun x=>x).
+ intros; apply (Build_Functor _ _ coqCategory _ _ (ba) _ (fun A B => fun f:A->B => arr_arr f));
+ intros; unfold eqv; simpl;
+ [ apply arr_arr_respects; auto
+ | reflexivity
+ | symmetry; apply arr_comp_preserves ].
+ Defined.
+
+Instance Arrow_inclusion_is_a_monoidal_functor `(ba:Arrow)
+: PreMonoidalFunctor coqPreMonoidalCat (arrows_monoidal ba) (fun x=>x) :=
+{ mf_F := arrow_inclusion_functor ba
+}.
+ simpl; apply iso_id.
+ intros; apply (Build_NaturalIsomorphism _ _ coqCategory _ _ (ba) (fun a0 : Type => a0 * a) (fun a0 : Type => a0 * a) _ _
+ (fun A:coqCategory => (iso_id(C:=ba)) ((fun a0 : Type => a0 * a) A))).
+ intros; simpl; setoid_rewrite ((arr_extension(Arrow:=ba)) A B f a); setoid_rewrite <- arr_comp_preserves; reflexivity.
+ intros; apply (@Build_NaturalIsomorphism _ _ coqCategory _ _ (ba) (fun a0 : Type => a * a0) (fun a0 : Type => a * a0) _ _
+ (fun A:coqCategory => (iso_id(C:=ba)) ((fun a0 : Type => a * a0) A))).
+ intros; simpl; setoid_rewrite arr_extension; repeat setoid_rewrite <- arr_comp_preserves.
+ apply arr_arr_respects; intros; unfold extensionality; intros; try destruct X; try destruct x; try destruct p; auto.
+ intros.
+ intros; apply Build_CentralMorphism; intros. simpl.
+
+ simpl.
+ setoid_rewrite arr_extension.
+ setoid_rewrite <- arr_associativity.
+ setoid_rewrite <- arr_associativity.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ transitivity (
+ arr_arr (fun x:a*c => let (a0,c0) := x in (c0,a0))
+ >>>
+ arr_arr (fun x:c*a => let (c0,a0) := x in (c0, f a0)) >>> ((arr_first(Arrow:=ba)) b g) >>>
+ (arr_arr (fun x:d*b => let (d0,b0):=x in (b0,d0)))).
+ repeat setoid_rewrite <- arr_associativity.
+ apply arr_comp_respects; try reflexivity.
+ apply arr_comp_respects; try reflexivity.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ apply arr_arr_respects; unfold extensionality; intros; try destruct X; try destruct x; intros; auto.
+ repeat setoid_rewrite arr_associativity.
+ apply arr_comp_respects; try reflexivity.
+ repeat setoid_rewrite <- arr_associativity.
+ setoid_rewrite <- arr_extension.
+ setoid_rewrite arr_extension.
+ repeat setoid_rewrite arr_associativity.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ repeat setoid_rewrite <- arr_associativity.
+ setoid_rewrite arr_exchange.
+ repeat setoid_rewrite arr_associativity.
+ apply arr_comp_respects; try reflexivity.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ apply arr_arr_respects; unfold extensionality; intros; try destruct X; try destruct x; intros; auto.
+
+ simpl.
+ setoid_rewrite arr_extension.
+ setoid_rewrite <- arr_associativity.
+ setoid_rewrite <- arr_associativity.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ transitivity (arr_arr (fun x:c*a => let (c0,a0) := x in (c0, f a0)) >>> ((arr_first(Arrow:=ba)) b g)).
+ setoid_rewrite arr_exchange.
+ repeat setoid_rewrite arr_associativity.
+ apply arr_comp_respects. reflexivity.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ apply arr_arr_respects; unfold extensionality; intros; try destruct X; try destruct x; intros; auto.
+ apply arr_comp_respects; try reflexivity.
+ apply arr_arr_respects; unfold extensionality; intros; try destruct X; try destruct x; intros; auto.
+ Defined.
+
+Definition arrow_swap_iso `(ba:Arrow) : forall A B, (Isomorphic(C:=ba)) (A*B) (B*A).
+ intros; apply (Build_Isomorphic _ _ ba _ _ (arr_arr (Λ⟨x,y⟩ ⟨y,x⟩)) (arr_arr (Λ⟨x,y⟩ ⟨y,x⟩)));
+ simpl; setoid_rewrite <- arr_comp_preserves;
+ apply arr_arr_respects;
+ intros; auto; intros; auto;
+ unfold extensionality; intros; simpl.
+ try destruct X; try destruct x; auto; destruct x; auto.
+ destruct x. simpl. reflexivity.
+ Defined.
+
+Instance arrows_are_braided `(ba:Arrow) : BraidedCat (arrows_monoidal ba).
+ intros; apply (Build_BraidedCat _ _ (ba) _ _ _ _ (fun A B => arrow_swap_iso ba A B));
+ intros; simpl;
+ repeat setoid_rewrite arr_extension;
+ repeat setoid_rewrite <- arr_associativity;
+ repeat setoid_rewrite <- arr_comp_preserves;
+ apply arr_arr_respects; intros; simpl; try destruct X; auto; unfold extensionality; unfold bin_obj;
+ intros; auto; try destruct x; try destruct p; try destruct b0; auto.
+ Defined.
+
+Instance arrows_are_symmetric `(ba:Arrow) : SymmetricCat (arrows_are_braided ba).
+ intros; apply Build_SymmetricCat; intros. simpl. reflexivity.
+ Defined.
+
+Instance Freyd_from_Arrow `(ba:Arrow)
+: FreydCategory coqPreMonoidalCat :=
+{ freyd_C_cartesian := coqCartesianCat
+; freyd_K := ba
+; freyd_K_binoidal := Arrows_are_Binoidal ba
+; freyd_K_monoidal := arrows_monoidal ba
+; freyd_F := Arrow_inclusion_is_a_monoidal_functor ba
+; freyd_K_braided := arrows_are_braided ba
+; freyd_K_symmetric := arrows_are_symmetric ba
+}.
+ intros; apply Build_CentralMorphism; intros; simpl.
+ repeat setoid_rewrite arr_extension.
+ repeat setoid_rewrite <- arr_associativity.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ setoid_replace
+ (arr_arr (fun x : a * c => let (a0, b0) := let (a0, b0) := x in ⟨f a0, b0 ⟩ in ⟨b0, a0 ⟩) >>> (arr_first(Arrow:=ba) b g))
+ with
+ (arr_arr (fun x : a * c => let (a0, b0) := x in ⟨b0,a0 ⟩) >>> (arr_arr (fun x : c * a => let (a0, b0) := x in ⟨a0,f b0 ⟩)
+ >>> (arr_first(Arrow:=ba) b g))).
+ setoid_rewrite arr_exchange.
+ repeat setoid_rewrite arr_associativity.
+ apply arr_comp_respects; try reflexivity.
+ apply arr_comp_respects; try reflexivity.
+ setoid_rewrite <- arr_comp_preserves.
+ apply arr_arr_respects; intros; simpl; try destruct X; auto; unfold extensionality; unfold bin_obj;
+ intros; auto; try destruct x; try destruct p; try destruct b0; auto.
+
+ setoid_rewrite <- arr_associativity.
+ apply arr_comp_respects; try reflexivity.
+ setoid_rewrite <- arr_comp_preserves.
+ apply arr_arr_respects; intros; simpl; try destruct X; auto; unfold extensionality; unfold bin_obj;
+ intros; auto; try destruct x; try destruct p; try destruct b0; auto.
+
+ repeat setoid_rewrite arr_extension.
+ repeat setoid_rewrite <- arr_comp_preserves.
+ transitivity ((arr_arr(Arrow:=ba) (fun x:c*a => let (a0,b0):=x in ⟨a0,f b0 ⟩)) >>> (arr_first(Arrow:=ba) b g));
+ [ setoid_rewrite arr_exchange | idtac ];
+ apply arr_comp_respects; try reflexivity;
+ apply arr_arr_respects; intros; simpl; try destruct X; auto; unfold extensionality; unfold bin_obj;
+ intros; auto; try destruct x; try destruct p; try destruct b0; auto.
+
+ intros; simpl; unfold bin_obj; reflexivity.
+ intros; simpl; unfold bin_obj; reflexivity.
+ intros; simpl; unfold bin_obj; reflexivity.
+ intros; simpl; unfold bin_obj; reflexivity.
+ intros; simpl; unfold bin_obj; reflexivity.
+ Defined.
+
+Theorem converter (fc:FreydCategory coqPreMonoidalCat) : forall q:Type, freyd_K(FreydCategory:=fc).
+ intros. exact q. Defined.
+
+Notation "` x" := (converter _ x) (at level 1) : temporary_scope1.
+Notation "`( x )" := (converter _ x) : temporary_scope1.
+Open Scope temporary_scope1.
+Notation "a ~~> b" := (freyd_K_hom a b) : category_scope.
+
+Close Scope arrow_scope.
+Open Scope arrow_scope.
+Open Scope category_scope.
+
+Lemma inverse_of_identity_is_identity : forall `{C:Category}{a:C}(i:Isomorphic a a), #i ~~ (id a) -> #i⁻¹ ~~ (id a).
+ intros.
+ transitivity (#i >>> #i⁻¹).
+ setoid_rewrite H.
+ symmetry; apply left_identity.
+ apply iso_comp1.
+ Qed.
+
+Lemma iso_both_sides' :
+ forall `{C:Category}{a b c d:C}(f:a~>b)(g:c~>d)(i1:Isomorphic d b)(i2:Isomorphic c a),
+ f >>> #i1 ⁻¹ ~~ #i2 ⁻¹ >>> g
+ ->
+ #i2 >>> f ~~ g >>> #i1.
+ symmetry.
+ apply iso_shift_right.
+ setoid_rewrite <- associativity.
+ symmetry.
+ apply iso_shift_left.
+ auto.
+ Qed.
+
+Lemma l1 (fc:FreydCategory coqPreMonoidalCat)`(f:a->b)(d:Type) :
+ fc \ f ⋉ `d ~~ fc \ (fun xy : a * d => let (a0, b0) := xy in ⟨f a0, b0 ⟩).
+ intros; set (freyd_K(FreydCategory:=fc)) as kc.
+ apply (monic #(mf_preserves_first(PreMonoidalFunctor:=fc) d b)).
+ apply iso_monic.
+ symmetry.
+ set (ni_commutes (mf_preserves_first(PreMonoidalFunctor:=fc) d) f) as help.
+ simpl in help.
+ symmetry in help.
+ apply (transitivity(R:=eqv _ _) help).
+ clear help.
+ transitivity (id _ >>> fc \ f ⋉ `d).
+ apply comp_respects; try reflexivity.
+ set (freyd_F_strict_first d a) as help.
+ simpl in help. apply help.
+ symmetry.
+ transitivity (fc \ f ⋉ `d >>> id _).
+ apply comp_respects; try reflexivity.
+ set (freyd_F_strict_first d b) as help.
+ simpl in help. apply help.
+ transitivity (fc \ f ⋉ `d).
+ apply right_identity.
+ symmetry; apply left_identity.
+ Qed.
+
+Lemma l2 (fc : FreydCategory coqPreMonoidalCat) : forall `(f:`a~~>`b)`(g:c->d),
+ fc \ (fun xy : a * c => let (a0, b0) := xy in ⟨a0, g b0 ⟩) >>> f ⋉ `d ~~
+ f ⋉ `c >>> fc \ (fun xy : b * c => let (a0, b0) := xy in ⟨a0, g b0 ⟩).
+ intros; set (freyd_K(FreydCategory:=fc)) as kc.
+ symmetry.
+ apply (monic #((mf_preserves_second(PreMonoidalFunctor:=fc) b d))).
+ apply iso_monic.
+ transitivity (f ⋉ `c >>> ((fc \ (fun xy : b * c => let (a0, b0) := xy in ⟨a0, g b0 ⟩)) >>>
+ #(mf_preserves_second(PreMonoidalFunctor:=fc) `b d))).
+ apply associativity.
+ transitivity (f ⋉ `c >>> (#(mf_preserves_second(PreMonoidalFunctor:=fc) `b c) >>> (fc >>>> bin_second (fc b)) \ g)).
+ apply comp_respects; try reflexivity.
+ symmetry.
+ apply (ni_commutes ( (mf_preserves_second(PreMonoidalFunctor:=fc) b)) g).
+ symmetry.
+ transitivity (((fc \ (fun xy : a * c => let (a0, b0) := xy in ⟨a0, g b0 ⟩) >>> f ⋉ `d)) >>> id _).
+ apply comp_respects; try reflexivity.
+ apply (freyd_F_strict_second(FreydCategory:=fc) b d).
+ transitivity (((fc \ (fun xy : a * c => let (a0, b0) := xy in ⟨a0, g b0 ⟩) >>> f ⋉ `d))).
+ apply right_identity.
+ symmetry.
+ transitivity (f ⋉ `c >>> (id (`(b*c)) >>> (fc >>>> bin_second (fc b)) \ g)).
+ apply comp_respects; [ reflexivity | idtac ].
+ apply comp_respects; [
+ apply (freyd_F_strict_second(FreydCategory:=fc) b c) |
+ reflexivity ].
+ transitivity (f ⋉ `c >>> (fc >>>> bin_second (fc b)) \ g).
+ apply comp_respects; [ reflexivity | apply left_identity ].
+ transitivity (`a ⋊ fc \ g >>> f ⋉ `d).
+ assert (CentralMorphism (fc \ g)). apply freyd_F_central.
+ set (centralmor_second(f:=(fc \ g)) f) as help.
+ apply help.
+ apply comp_respects; [ idtac | reflexivity ].
+ apply (epic #(iso_inv _ _ (mf_preserves_second(PreMonoidalFunctor:=fc) a c))).
+ set (iso_epic (((mf_preserves_second a) c) ⁻¹)) as q.
+ apply q.
+ symmetry.
+ transitivity (`a ⋊ fc \ g >>> iso_backward (mf_preserves_second(PreMonoidalFunctor:=fc) `a `d)).
+ apply (ni_commutes (ni_inv (mf_preserves_second(PreMonoidalFunctor:=fc) a)) g).
+ transitivity (`a ⋊ fc \ g >>> id _).
+ apply comp_respects; try reflexivity.
+ apply (inverse_of_identity_is_identity (mf_preserves_second(PreMonoidalFunctor:=fc) `a `d)).
+ apply (freyd_F_strict_second(FreydCategory:=fc) a d).
+ transitivity (`a ⋊ fc \ g).
+ apply right_identity.
+ symmetry.
+ transitivity (id _ >>> `a ⋊ fc \ g).
+ apply comp_respects; try reflexivity.
+ apply (inverse_of_identity_is_identity (mf_preserves_second(PreMonoidalFunctor:=fc) `a `c)).
+ apply (freyd_F_strict_second(FreydCategory:=fc) a c).
+ apply left_identity.
+ Qed.
+
+Lemma l3 (fc : FreydCategory coqPreMonoidalCat) : forall `(f:`a~~>`b)(c:Type),
+ f ⋉ `c >>> fc \ (fun xy : b * c => let (a0, _) := xy in a0) ~~
+ fc \ (fun xy : a * c => let (a0, _) := xy in a0) >>> f.
+ intros; set (freyd_K(FreydCategory:=fc)) as kc.
+ transitivity (f ⋉ `c >>> (fc \ (comp(Category:=coqCategory) _ _ _
+ (fun xy : b * c => let (a0, _) := xy in (a0,tt))
+ (fun xy : b * unit => let (a0, _) := xy in a0)))).
+ apply comp_respects; [ reflexivity | idtac ].
+ simpl; apply (fmor_respects(Functor:=fc)).
+ simpl. intros. destruct x; auto.
+ symmetry.
+ transitivity (fc \ (comp(Category:=coqCategory) _ _ _
+ (fun xy : a * c => let (a0, _) := xy in (a0,tt))
+ (fun xy : a * unit => let (a0, _) := xy in a0)) >>> f).
+ apply comp_respects; [ idtac | reflexivity ].
+ simpl; apply (fmor_respects(Functor:=fc)).
+ simpl. intros. destruct x; auto.
+ transitivity ((fc \ (fun xy : a * c => let (a0, _) := xy in ⟨a0, tt ⟩) >>>
+ fc \ (fun xy : a * unit => let (a0, _) := xy in a0)) >>> f).
+ apply comp_respects; [ idtac | reflexivity ].
+ symmetry; apply (fmor_preserves_comp(Functor:=fc)).
+ symmetry.
+ transitivity (f ⋉ `c >>>
+ (fc \ (fun xy : b * c => let (a0, _) := xy in ⟨a0, tt ⟩) >>>
+ fc \ (fun xy : b * unit => let (a0, _) := xy in a0))).
+ apply comp_respects; [ reflexivity | idtac ].
+ symmetry; apply (fmor_preserves_comp(Functor:=fc)).
+ transitivity (f ⋉ `c >>> (fc \ (fun xy : b * c => let (a0, _) := xy in ⟨a0, tt ⟩) >>> #(pmon_cancelr fc b))).
+ apply comp_respects; [ reflexivity | idtac ].
+ apply comp_respects; [ reflexivity | idtac ].
+ apply (freyd_F_strict_cr(FreydCategory:=fc) b).
+ symmetry.
+ transitivity ((fc \ (fun xy : a * c => let (a0, _) := xy in ⟨a0, tt ⟩) >>> #(pmon_cancelr fc a)) >>> f).
+ apply comp_respects; [ idtac | reflexivity ].
+ apply comp_respects; [ reflexivity | idtac ].
+ apply (freyd_F_strict_cr(FreydCategory:=fc) a).
+ transitivity (((`a ⋊ fc \ (fun _ : c => tt)
+ >>> iso_backward (mf_preserves_second(PreMonoidalFunctor:=fc) `a unit)) >>> #(pmon_cancelr fc a)) >>> f).
+ apply comp_respects; [ idtac | reflexivity ].
+ apply comp_respects; [ idtac | reflexivity ].
+ symmetry.
+ transitivity (iso_backward (mf_preserves_second(PreMonoidalFunctor:=fc) a c) >>>
+ fc \ (fun xy : a * c => let (a0, _) := xy in ⟨a0, tt ⟩)).
+ symmetry.
+ apply (ni_commutes (ni_inv (mf_preserves_second(PreMonoidalFunctor:=fc) a)) (fun x:c=>tt)).
+ transitivity (id _ >>> fc \ (fun xy : a * c => let (a0, _) := xy in ⟨a0, tt ⟩)).
+ apply comp_respects; [ idtac | reflexivity ].
+ set (inverse_of_identity_is_identity (mf_preserves_second(PreMonoidalFunctor:=fc) `a `c)) as foo.
+ simpl in foo.
+ apply foo.
+ apply (freyd_F_strict_second(FreydCategory:=fc) a c).
+ apply left_identity.
+ symmetry.
+ transitivity (f ⋉ `c >>>
+ ((#(mf_preserves_second(PreMonoidalFunctor:=fc) b c) >>> `b ⋊ fc \ (fun _ : c => tt)) >>>
+ #(pmon_cancelr fc b))).
+ apply comp_respects; [ reflexivity | idtac ].
+ apply comp_respects; [ idtac | reflexivity ].
+ transitivity (fc \ (fun xy : b * c => let (a0, _) := xy in ⟨a0, tt ⟩)
+ >>> #(mf_preserves_second(PreMonoidalFunctor:=fc) b unit)).
+ symmetry.
+ transitivity (fc \ (fun xy : b * c => let (a0, _) := xy in ⟨a0, tt ⟩) >>> id _).
+ apply comp_respects; [ reflexivity | idtac ].
+ apply (freyd_F_strict_second(FreydCategory:=fc) b unit).
+ apply right_identity.
+ symmetry.
+ apply (ni_commutes ( (mf_preserves_second(PreMonoidalFunctor:=fc) b)) (fun x:c=>tt)).
+ transitivity (f ⋉ `c >>>
+ ((id _ >>> `b ⋊ fc \ (fun _ : c => tt)) >>>
+ #(pmon_cancelr fc b))).
+ apply comp_respects; [ reflexivity | idtac ].
+ apply comp_respects; [ idtac | reflexivity ].
+ apply comp_respects; [ idtac | reflexivity ].
+ apply (freyd_F_strict_second(FreydCategory:=fc) b c).
+ transitivity (f ⋉ `c >>>
+ ((`b ⋊ fc \ (fun _ : c => tt)) >>>
+ #(pmon_cancelr fc b))).
+ apply comp_respects; [ reflexivity | idtac ].
+ apply comp_respects; [ idtac | reflexivity ].
+ apply left_identity.
+ symmetry.
+ transitivity (((`a ⋊ fc \ (fun _ : c => tt) >>>
+ id _) >>>
+ #(pmon_cancelr fc a)) >>> f).
+ apply comp_respects; [ idtac | reflexivity ].
+ apply comp_respects; [ idtac | reflexivity ].
+ apply comp_respects; [ reflexivity | idtac ].
+ set (inverse_of_identity_is_identity (mf_preserves_second(PreMonoidalFunctor:=fc) `a unit)) as foo.
+ simpl in foo.
+ apply foo.
+ apply (freyd_F_strict_second(FreydCategory:=fc) `a unit).
+ transitivity (((`a ⋊ fc \ (fun _ : c => tt)) >>> #(pmon_cancelr fc a)) >>> f).
+ apply comp_respects; [ idtac | reflexivity ].
+ apply comp_respects; [ idtac | reflexivity ].
+ apply right_identity.
+ symmetry.
+ transitivity ((f ⋉ `c >>> `b ⋊ fc \ (fun _ : c => tt)) >>> #(pmon_cancelr fc b)).
+ symmetry; apply associativity.
+ transitivity ((`a ⋊ fc \ (fun _ : c => tt) >>> f ⋉ `unit) >>> #(pmon_cancelr fc b)).
+ apply comp_respects; [ idtac | reflexivity ].
+ assert (CentralMorphism (fc \ (fun _ : c => tt))).
+ apply (freyd_F_central(FreydCategory:=fc)).
+ apply (centralmor_second(CentralMorphism:=H)).
+ transitivity (`a ⋊ fc \ (fun _ : c => tt) >>> (f ⋉ `unit >>> #(pmon_cancelr fc b))).
+ apply associativity.
+ symmetry.
+ transitivity (`a ⋊ fc \ (fun _ : c => tt) >>> (#(pmon_cancelr fc a) >>> f)).
+ apply associativity.
+ apply comp_respects; [ reflexivity | idtac ].
+ set (ni_commutes (pmon_cancelr fc)) as help.
+ simpl in help. apply help.
+ Qed.
+
+Lemma l4 (fc : FreydCategory coqPreMonoidalCat) : forall `(f:`a~>b)(c d:Type),
+ (f ⋉ `c) ⋉ `d >>> fc \ ((fun xyz:(b*c)*d => let (ab, c) := xyz in let (a0, b0) := ab in ⟨a0, ⟨b0, c ⟩ ⟩))
+ ~~ fc \ ((fun xyz:(a*c)*d => let (ab, c) := xyz in let (a0, b0) := ab in ⟨a0, ⟨b0, c ⟩ ⟩)) >>> f ⋉ _.
+ intros; set (freyd_K(FreydCategory:=fc)) as kc.
+ simpl in f.
+ symmetry.
+ transitivity (#(pmon_assoc freyd_K_monoidal _ _ _) >>> f ⋉ (c*d:(freyd_K))).
+ apply comp_respects; try reflexivity.
+ apply (freyd_F_strict_a(FreydCategory:=fc) `a d c).
+ symmetry.
+ transitivity (((f ⋉ (c: (freyd_K))) ⋉ (d:(freyd_K)) >>> #(pmon_assoc freyd_K_monoidal _ _ _))).
+ apply comp_respects; try reflexivity.
+ apply (freyd_F_strict_a(FreydCategory:=fc) `b `d `c).
+ symmetry.
+ apply (iso_both_sides' _ _ (pmon_assoc fc `b d c) (pmon_assoc fc `a d c)).
+ symmetry.
+ transitivity ( #(ni_iso (pmon_assoc_rr(PreMonoidalCat:=(freyd_K_monoidal(FreydCategory:=fc))) `c `d) a) >>>
+ (f ⋉ (c:(freyd_K))) ⋉ (d:(freyd_K))).
+ apply comp_respects; try reflexivity.
+ symmetry.
+ apply ((pmon_coherent_r(PreMonoidalCat:=freyd_K_monoidal(FreydCategory:=fc))) a c d).
+ symmetry.
+ transitivity (f ⋉ (c*d:(freyd_K)) >>>
+ #(ni_iso (pmon_assoc_rr(PreMonoidalCat:=(freyd_K_monoidal(FreydCategory:=fc))) _ _ ) _)).
+ apply comp_respects; try reflexivity.
+ symmetry.
+ apply ((pmon_coherent_r(PreMonoidalCat:=freyd_K_monoidal(FreydCategory:=fc))) b c d).
+ symmetry.
+ simpl.
+ apply (@ni_commutes _ _ _ _ _ _ _ _ _ _ (pmon_assoc_rr(PreMonoidalCat:=(freyd_K_monoidal(FreydCategory:=fc))) c d) a `b f).
+ Qed.
+
+(* Formalized Theorem 3.17 *)
+Definition Arrow_from_Freyd (fc:FreydCategory coqPreMonoidalCat)
+ : Arrow (fun A B => freyd_K_hom(FreydCategory:=fc) (converter fc A) (converter fc B)).
+ intros.
+ set (freyd_K(FreydCategory:=fc)) as kc.
+ apply (@Build_Arrow
+ (fun A B => (`A) ~~> (`B))
+ (fun A B => fun f:A->B => fc \ f)
+ (fun (A B C : Type) (X : `A ~~> `B) (X0 : `B ~~> `C) => X >>> X0)
+ (fun (A B C : coqCategory) (X : `A ~~> `B) => X ⋉ `C)
+ (fun (A B : Type) (X X0 : `A ~~> `B) => X ~~ X0));
+ unfold Proper; unfold Reflexive; unfold Symmetric; unfold Transitive; unfold respectful;
+ intros ; simpl.
+ apply Build_Equivalence.
+ unfold Reflexive; intros. apply Equivalence_Reflexive.
+ unfold Symmetric; intros. apply Equivalence_Symmetric. auto.
+ unfold Transitive; intros. transitivity y; auto.
+ apply comp_respects; auto.
+ apply (fmor_respects(Functor:=(bin_first(BinoidalCat:=fc) `c))); auto.
+ apply (fmor_respects(Functor:=fc)); auto.
+ transitivity ((id _) >>> f).
+ apply comp_respects; try reflexivity.
+ apply (fmor_preserves_id(Functor:=fc)).
+ apply left_identity.
+ transitivity (f >>> (id _)).
+ apply comp_respects; try reflexivity.
+ apply (fmor_preserves_id(Functor:=fc)).
+ apply right_identity.
+ apply associativity.
+ symmetry. apply (fmor_preserves_comp(Functor:=fc) f g).
+ apply (l1 fc f d).
+ symmetry; apply (fmor_preserves_comp(Functor:=(bin_first `d)) f g).
+ apply (l2 fc f g).
+ apply (l3 fc f c).
+ apply (l4 fc f c d).
+ Defined.
+
+(* one half: every Arrow is isomorphic to its implied Freyd category *)
+(*
+
+(* FIXME: isomorphism of categories must be via a premonoidal functor *)
+
+
+(* FIXME: the isomorphism needs to be a premonoidal functor *)
+Theorem arrow_both_defs : forall `(ba:Arrow), IsomorphicCategories (Freyd_from_Arrow ba) (ba).
+ intros.
+ apply Build_IsomorphicCategories with (isoc_forward:=ToFunc (functor_id _))(isoc_backward:=ToFunc (functor_id _)).
+ simpl. unfold EqualFunctors. intros.
+ simpl; intros; apply (@heq_morphisms_intro (ba) a b _ _); auto.
+ simpl. unfold EqualFunctors. intros.
+ simpl; intros; apply (@heq_morphisms_intro (ba) a b _ _); auto.
+ Defined.
+
+(* the other half: [the codomain of] every Freyd category is isomorphic to its implied Arrow *)
+Theorem arrow_both_defs' : forall (fc:FreydCategory coqPreMonoidalCat), IsomorphicCategories fc ((Arrow_from_Freyd fc)).
+ Lemma iforward (fc:FreydCategory coqPreMonoidalCat) : Functor fc ((Arrow_from_Freyd fc)) (fun x=> x).
+ intros; apply (Build_Functor fc ((Arrow_from_Freyd fc)) _ (fun a b f => f));
+ intros; auto; simpl; [ idtac | reflexivity ];
+ symmetry; apply (fmor_preserves_id(Functor:=fc)).
+ Defined.
+ Lemma ibackward (fc:FreydCategory coqPreMonoidalCat) : Functor ((Arrow_from_Freyd fc)) fc (fun x=> x).
+ intros; apply (Build_Functor ((Arrow_from_Freyd fc)) fc _ (fun a b f => f));
+ intros; auto; simpl; [ idtac | reflexivity ];
+ apply (fmor_preserves_id(Functor:=fc)).
+ Defined.
+ intros; apply (@Build_IsomorphicCategories _ _ (ToFunc (iforward fc)) (ToFunc (ibackward fc))); simpl; intros; auto.
+ unfold EqualFunctors; simpl; auto.
+ unfold EqualFunctors; simpl; auto.
+ Defined.
+*)
+
+Close Scope arrow_scope.
+Close Scope temporary_scope1.
+Open Scope tree_scope.
+