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Mathlib.CategoryTheory.Limits.FinallySmall

Finally small categories #

A category given by (J : Type u) [Category.{v} J] is w-finally small if there exists a FinalModel J : Type w equipped with [SmallCategory (FinalModel J)] and a final functor FinalModel J ⥤ J.

This means that if a category C has colimits of size w and J is w-finally small, then C has colimits of shape J. In this way, the notion of "finally small" can be seen of a generalization of the notion of "essentially small" for indexing categories of colimits.

Dually, we have a notion of initially small category.

We show that a finally small category admits a small weakly terminal set, i.e., a small set s of objects such that from every object there a morphism to a member of s. We also show that the converse holds if J is filtered.

class CategoryTheory.FinallySmall (J : Type u) [Category.{v, u} J] :

A category is FinallySmall.{w} if there is a final functor from a w-small category.

final_smallCategory : ∃ (S : Type w) (x : SmallCategory S) (F : Functor S J), F.Final
There is a final functor from a small category.

Instances

theorem CategoryTheory.FinallySmall.mk' {J : Type u} [Category.{v, u} J] {S : Type w} [SmallCategory S] (F : Functor S J) [F.Final] :

Constructor for FinallySmall C from an explicit small category witness.

def CategoryTheory.FinalModel (J : Type u) [Category.{v, u} J] [FinallySmall J] :

An arbitrarily chosen small model for a finally small category.

Equations

CategoryTheory.FinalModel J = Classical.choose ⋯

noncomputable instance CategoryTheory.smallCategoryFinalModel (J : Type u) [Category.{v, u} J] [FinallySmall J] :

SmallCategory (FinalModel J)

Equations

CategoryTheory.smallCategoryFinalModel J = Classical.choose ⋯

noncomputable def CategoryTheory.fromFinalModel (J : Type u) [Category.{v, u} J] [FinallySmall J] :

Functor (FinalModel J) J

An arbitrarily chosen final functor FinalModel J ⥤ J.

Equations

CategoryTheory.fromFinalModel J = Classical.choose ⋯

instance CategoryTheory.final_fromFinalModel (J : Type u) [Category.{v, u} J] [FinallySmall J] :

(fromFinalModel J).Final

theorem CategoryTheory.finallySmall_of_essentiallySmall (J : Type u) [Category.{v, u} J] [EssentiallySmall.{w, v, u} J] :

theorem CategoryTheory.finallySmall_of_final_of_finallySmall {J : Type u} [Category.{v, u} J] {K : Type u₁} [Category.{v₁, u₁} K] [FinallySmall K] (F : Functor K J) [F.Final] :

theorem CategoryTheory.finallySmall_of_final_of_essentiallySmall {J : Type u} [Category.{v, u} J] {K : Type u₁} [Category.{v₁, u₁} K] [EssentiallySmall.{w, v₁, u₁} K] (F : Functor K J) [F.Final] :

class CategoryTheory.InitiallySmall (J : Type u) [Category.{v, u} J] :

A category is InitiallySmall.{w} if there is an initial functor from a w-small category.

initial_smallCategory : ∃ (S : Type w) (x : SmallCategory S) (F : Functor S J), F.Initial
There is an initial functor from a small category.

Instances

theorem CategoryTheory.InitiallySmall.mk' {J : Type u} [Category.{v, u} J] {S : Type w} [SmallCategory S] (F : Functor S J) [F.Initial] :

InitiallySmall J

Constructor for InitialSmall C from an explicit small category witness.

def CategoryTheory.InitialModel (J : Type u) [Category.{v, u} J] [InitiallySmall J] :

An arbitrarily chosen small model for an initially small category.

Equations

CategoryTheory.InitialModel J = Classical.choose ⋯

noncomputable instance CategoryTheory.smallCategoryInitialModel (J : Type u) [Category.{v, u} J] [InitiallySmall J] :

SmallCategory (InitialModel J)

Equations

CategoryTheory.smallCategoryInitialModel J = Classical.choose ⋯

noncomputable def CategoryTheory.fromInitialModel (J : Type u) [Category.{v, u} J] [InitiallySmall J] :

Functor (InitialModel J) J

An arbitrarily chosen initial functor InitialModel J ⥤ J.

Equations

CategoryTheory.fromInitialModel J = Classical.choose ⋯

instance CategoryTheory.initial_fromInitialModel (J : Type u) [Category.{v, u} J] [InitiallySmall J] :

(fromInitialModel J).Initial

theorem CategoryTheory.initiallySmall_of_essentiallySmall (J : Type u) [Category.{v, u} J] [EssentiallySmall.{w, v, u} J] :

InitiallySmall J

theorem CategoryTheory.initiallySmall_of_initial_of_initiallySmall {J : Type u} [Category.{v, u} J] {K : Type u₁} [Category.{v₁, u₁} K] [InitiallySmall K] (F : Functor K J) [F.Initial] :

InitiallySmall J

theorem CategoryTheory.initiallySmall_of_initial_of_essentiallySmall {J : Type u} [Category.{v, u} J] {K : Type u₁} [Category.{v₁, u₁} K] [EssentiallySmall.{w, v₁, u₁} K] (F : Functor K J) [F.Initial] :

InitiallySmall J

theorem CategoryTheory.FinallySmall.exists_small_weakly_terminal_set (J : Type u) [Category.{v, u} J] [FinallySmall J] :

∃ (s : Set J) (_ : Small.{w, u} ↑s), ∀ (i : J), ∃ j ∈ s, Nonempty (i ⟶ j)

The converse is true if J is filtered, see finallySmall_of_small_weakly_terminal_set.

theorem CategoryTheory.finallySmall_of_small_weakly_terminal_set {J : Type u} [Category.{v, u} J] [IsFilteredOrEmpty J] (s : Set J) [Small.{v, u} ↑s] (hs : ∀ (i : J), ∃ j ∈ s, Nonempty (i ⟶ j)) :

theorem CategoryTheory.finallySmall_iff_exists_small_weakly_terminal_set (J : Type u) [Category.{v, u} J] [IsFilteredOrEmpty J] :

FinallySmall J ↔ ∃ (s : Set J) (_ : Small.{v, u} ↑s), ∀ (i : J), ∃ j ∈ s, Nonempty (i ⟶ j)

theorem CategoryTheory.InitiallySmall.exists_small_weakly_initial_set (J : Type u) [Category.{v, u} J] [InitiallySmall J] :

∃ (s : Set J) (_ : Small.{w, u} ↑s), ∀ (i : J), ∃ j ∈ s, Nonempty (j ⟶ i)

The converse is true if J is cofiltered, see initiallySmall_of_small_weakly_initial_set.

theorem CategoryTheory.initiallySmall_of_small_weakly_initial_set {J : Type u} [Category.{v, u} J] [IsCofilteredOrEmpty J] (s : Set J) [Small.{v, u} ↑s] (hs : ∀ (i : J), ∃ j ∈ s, Nonempty (j ⟶ i)) :

InitiallySmall J

theorem CategoryTheory.initiallySmall_iff_exists_small_weakly_initial_set (J : Type u) [Category.{v, u} J] [IsCofilteredOrEmpty J] :

InitiallySmall J ↔ ∃ (s : Set J) (_ : Small.{v, u} ↑s), ∀ (i : J), ∃ j ∈ s, Nonempty (j ⟶ i)

theorem CategoryTheory.Limits.hasColimitsOfShape_of_finallySmall (J : Type u) [Category.{v, u} J] [FinallySmall J] (C : Type u₁) [Category.{v₁, u₁} C] [HasColimitsOfSize.{w, w, v₁, u₁} C] :

HasColimitsOfShape J C

theorem CategoryTheory.Limits.hasLimitsOfShape_of_initiallySmall (J : Type u) [Category.{v, u} J] [InitiallySmall J] (C : Type u₁) [Category.{v₁, u₁} C] [HasLimitsOfSize.{w, w, v₁, u₁} C] :

HasLimitsOfShape J C