X-Git-Url: http://git.megacz.com/?a=blobdiff_plain;f=src%2FPreMonoidalCategories.v;h=e56c72750ef96123175d40ce6fdfe84fe5f81965;hb=37fcc257b54bd8d13ad27f9d80d4a0298429c7ce;hp=d0b7cd2926dd63ed188d8891713472ca62d39190;hpb=1dd1bee2b13b43812ebbc078bdbf774886392886;p=coq-categories.git diff --git a/src/PreMonoidalCategories.v b/src/PreMonoidalCategories.v index d0b7cd2..e56c727 100644 --- a/src/PreMonoidalCategories.v +++ b/src/PreMonoidalCategories.v @@ -19,8 +19,8 @@ Class PreMonoidalCat `(bc:BinoidalCat(C:=C))(I: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)⁻¹) -; 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)⁻¹) +; 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) @@ -54,31 +54,31 @@ Implicit Arguments pmon_assoc [ Ob Hom C bin_obj' bc I PreMonoidalCat ]. 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)} d c +Lemma MacLane_ex_VII_1_1 `{mn:PreMonoidalCat(I:=EI)} b a : - let α := fun a b c => #((pmon_assoc a c) b)⁻¹ - in α EI c d >>> #(pmon_cancell _) ⋉ _ ~~ #(pmon_cancell _). + let α := fun a b c => #((pmon_assoc a c) b) + in α a b EI >>> _ ⋊ #(pmon_cancelr _) ~~ #(pmon_cancelr _). intros. simpl in α. (* following Mac Lane's hint, we aim for (λ >>> α >>> λ×1)~~(λ >>> λ) *) - set (epic _ (iso_epic (pmon_cancell (EI⊗(c⊗d))))) as q. + set (epic _ (iso_epic (pmon_cancelr ((a⊗b)⊗EI)))) as q. apply q. clear q. (* next, we show that the hint goal above is implied by the bottom-left 1/5th of the big whiteboard diagram *) - set (ni_commutes pmon_cancell (α EI c d)) as q. + set (ni_commutes pmon_cancelr (α a b EI)) as q. setoid_rewrite <- associativity. setoid_rewrite q. clear q. setoid_rewrite associativity. - set (ni_commutes pmon_cancell (#(pmon_cancell c) ⋉ d)) as q. + set (ni_commutes pmon_cancelr (a ⋊ #(pmon_cancelr b))) as q. simpl in q. setoid_rewrite q. clear q. - set (ni_commutes pmon_cancell (#(pmon_cancell (c⊗d)))) as q. + set (ni_commutes pmon_cancelr (#(pmon_cancelr (a⊗b)))) as q. simpl in q. setoid_rewrite q. clear q. @@ -89,68 +89,59 @@ Lemma MacLane_ex_VII_1_1 `{mn:PreMonoidalCat(I:=EI)} d c (* now we carry out the proof in the whiteboard diagram, starting from the pentagon diagram *) (* top 2/5ths *) - assert (α EI EI (c⊗d) >>> α _ _ _ >>> (#(pmon_cancelr _) ⋉ _ ⋉ _) ~~ _ ⋊ #(pmon_cancell _) >>> α _ _ _). - set (pmon_triangle EI (c⊗d)) as tria. + assert (α (a⊗b) EI EI >>> α _ _ _ >>> (_ ⋊ (_ ⋊ #(pmon_cancell _))) ~~ #(pmon_cancelr _) ⋉ _ >>> α _ _ _). + set (pmon_triangle (a⊗b) EI) as tria. simpl in tria. - setoid_rewrite <- tria. - clear tria. unfold α; simpl. - set (ni_commutes (pmon_assoc_rr c d) #(pmon_cancelr EI)) as x. - simpl in x. - setoid_rewrite pmon_coherent_r in x. - simpl in x. + setoid_rewrite tria. + clear tria. setoid_rewrite associativity. - setoid_rewrite x. - clear x. - reflexivity. + apply comp_respects; try reflexivity. + set (ni_commutes (pmon_assoc_ll a b) #(pmon_cancell EI)) as x. + simpl in x. + setoid_rewrite pmon_coherent_l in x. + apply x. (* bottom 3/5ths *) - assert (_ ⋊ α _ _ _ >>> α EI (EI⊗c) d >>> α _ _ _ ⋉ _ >>> (#(pmon_cancelr _) ⋉ _ ⋉ _) ~~ - _ ⋊ α _ _ _ >>> _ ⋊ (#(pmon_cancell _) ⋉ _) >>> α _ _ _ ). + assert (((#((pmon_assoc a EI) b) ⋉ EI >>> #((pmon_assoc a EI) (b ⊗ EI))) >>> + a ⋊ #((pmon_assoc b EI) EI)) >>> a ⋊ (b ⋊ #(pmon_cancell EI)) + ~~ α _ _ _ ⋉ _ >>> (_ ⋊ #(pmon_cancelr _)) ⋉ _ >>> α _ _ _). + unfold α; simpl. repeat setoid_rewrite associativity. apply comp_respects; try reflexivity. - set (ni_commutes (pmon_assoc EI d) (#(pmon_cancell c) )) as x. + set (ni_commutes (pmon_assoc a EI) (#(pmon_cancelr b) )) as x. simpl in x. setoid_rewrite <- associativity. - apply iso_shift_right' in x. - symmetry in x. - setoid_rewrite <- associativity in x. - apply iso_shift_left' in x. simpl in x. setoid_rewrite <- x. clear x. setoid_rewrite associativity. apply comp_respects; try reflexivity. - setoid_rewrite (fmor_preserves_comp (-⋉d)). - apply (fmor_respects (-⋉d)). + setoid_rewrite (fmor_preserves_comp (a⋊-)). + apply (fmor_respects (a⋊-)). - set (pmon_triangle EI c) as tria. + set (pmon_triangle b EI) as tria. simpl in tria. + symmetry. apply tria. - set (pmon_pentagon EI EI c d) as penta. unfold pmon_pentagon in penta. simpl in penta. + set (pmon_pentagon a b EI EI) as penta. unfold pmon_pentagon in penta. simpl in penta. - set (@comp_respects _ _ _ _ _ _ _ _ penta (#(pmon_cancelr EI) ⋉ c ⋉ d) (#(pmon_cancelr EI) ⋉ c ⋉ d)) as qq. + set (@comp_respects _ _ _ _ _ _ _ _ penta (a ⋊ (b ⋊ #(pmon_cancell EI))) (a ⋊ (b ⋊ #(pmon_cancell EI)))) as qq. unfold α in H. setoid_rewrite H in qq. unfold α in H0. setoid_rewrite H0 in qq. clear H0 H. - assert (EI⋊(iso_backward ((pmon_assoc EI d) c) >>> #(pmon_cancell c) ⋉ d) ~~ EI⋊ #(pmon_cancell (c ⊗ d)) ). - apply (@monic _ _ _ _ _ _ (iso_monic (iso_inv _ _ ((pmon_assoc EI d) c)))). - - symmetry. - setoid_rewrite <- fmor_preserves_comp. - apply qq; try reflexivity. + unfold α. + apply (monic _ (iso_monic ((pmon_assoc a EI) b))). + apply qq. clear qq penta. - - setoid_rewrite fmor_preserves_comp. - apply H. - + reflexivity. Qed. Class PreMonoidalFunctor