136 lines
4.7 KiB
Text
136 lines
4.7 KiB
Text
/-
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Copyright (c) 2014 Jakob von Raumer. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Author: Jakob von Raumer
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-/
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import .iso
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open iso is_equiv equiv eq is_trunc sigma equiv.ops
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/-
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A category is a precategory extended by a witness
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that the function from paths to isomorphisms is an equivalence.
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-/
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namespace category
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/-
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TODO: restructure this. Should is_univalent be a class with as argument
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(C : Precategory). Or is that problematic if we want to apply this to cases where e.g.
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a b are functors, and we need to synthesize ? : precategory (functor C D).
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-/
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definition is_univalent [class] {ob : Type} (C : precategory ob) :=
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Π(a b : ob), is_equiv (iso_of_eq : a = b → a ≅ b)
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definition is_equiv_of_is_univalent [instance] {ob : Type} [C : precategory ob]
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[H : is_univalent C] (a b : ob) : is_equiv (iso_of_eq : a = b → a ≅ b) :=
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H a b
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structure category [class] (ob : Type) extends parent : precategory ob :=
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mk' :: (iso_of_path_equiv : is_univalent parent)
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-- Remark: category and precategory are classes. So, the structure command
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-- does not create a coercion between them automatically.
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-- This coercion is needed for definitions such as category_eq_of_equiv
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-- without it, we would have to explicitly use category.to_precategory
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attribute category.to_precategory [coercion]
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attribute category [multiple_instances]
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abbreviation iso_of_path_equiv := @category.iso_of_path_equiv
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attribute category.iso_of_path_equiv [instance]
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definition category.mk [reducible] [unfold 2] {ob : Type} (C : precategory ob)
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(H : is_univalent C) : category ob :=
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precategory.rec_on C category.mk' H
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section basic
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variables {ob : Type} [C : category ob]
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include C
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-- Make iso_of_path_equiv a class instance
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attribute iso_of_path_equiv [instance]
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definition eq_equiv_iso [constructor] (a b : ob) : (a = b) ≃ (a ≅ b) :=
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equiv.mk iso_of_eq _
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definition eq_of_iso [reducible] {a b : ob} : a ≅ b → a = b :=
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iso_of_eq⁻¹ᶠ
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definition iso_of_eq_eq_of_iso {a b : ob} (p : a ≅ b) : iso_of_eq (eq_of_iso p) = p :=
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right_inv iso_of_eq p
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definition hom_of_eq_eq_of_iso {a b : ob} (p : a ≅ b) : hom_of_eq (eq_of_iso p) = to_hom p :=
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ap to_hom !iso_of_eq_eq_of_iso
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definition inv_of_eq_eq_of_iso {a b : ob} (p : a ≅ b) : inv_of_eq (eq_of_iso p) = to_inv p :=
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ap to_inv !iso_of_eq_eq_of_iso
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theorem eq_of_iso_refl {a : ob} : eq_of_iso (iso.refl a) = idp :=
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inv_eq_of_eq idp
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definition is_trunc_1_ob : is_trunc 1 ob :=
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begin
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apply is_trunc_succ_intro, intro a b,
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fapply is_trunc_is_equiv_closed,
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exact (@eq_of_iso _ _ a b),
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apply is_equiv_inv,
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end
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end basic
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-- Bundled version of categories
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-- we don't use Category.carrier explicitly, but rather use Precategory.carrier (to_Precategory C)
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structure Category : Type :=
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(carrier : Type)
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(struct : category carrier)
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attribute Category.struct [instance] [coercion]
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definition Category.to_Precategory [constructor] [coercion] [reducible] (C : Category)
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: Precategory :=
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Precategory.mk (Category.carrier C) _
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definition category.Mk [constructor] [reducible] := Category.mk
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definition category.MK [constructor] [reducible] (C : Precategory)
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(H : is_univalent C) : Category := Category.mk C (category.mk C H)
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definition Category.eta (C : Category) : Category.mk C C = C :=
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Category.rec (λob c, idp) C
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protected definition category.sigma_char.{u v} [constructor] (ob : Type)
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: category.{u v} ob ≃ Σ(C : precategory.{u v} ob), is_univalent C :=
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begin
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fapply equiv.MK,
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{ intro x, induction x, constructor, assumption},
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{ intro y, induction y with y1 y2, induction y1, constructor, assumption},
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{ intro y, induction y with y1 y2, induction y1, reflexivity},
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{ intro x, induction x, reflexivity}
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end
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definition category_eq {ob : Type}
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{C D : category ob}
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(p : Π{a b}, @hom ob C a b = @hom ob D a b)
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(q : Πa b c g f, cast p (@comp ob C a b c g f) = @comp ob D a b c (cast p g) (cast p f))
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: C = D :=
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begin
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apply eq_of_fn_eq_fn !category.sigma_char,
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fapply sigma_eq,
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{ induction C, induction D, esimp, exact precategory_eq @p q},
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{ unfold is_univalent, apply is_prop.elimo},
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end
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definition category_eq_of_equiv {ob : Type}
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{C D : category ob}
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(p : Π⦃a b⦄, @hom ob C a b ≃ @hom ob D a b)
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(q : Π{a b c} g f, p (@comp ob C a b c g f) = @comp ob D a b c (p g) (p f))
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: C = D :=
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begin
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fapply category_eq,
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{ intro a b, exact ua !@p},
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{ intros, refine !cast_ua ⬝ !q ⬝ _, unfold [category.to_precategory],
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apply ap011 !@category.comp !cast_ua⁻¹ᵖ !cast_ua⁻¹ᵖ},
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end
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-- TODO: Category_eq[']
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end category
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