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Mathlib.CategoryTheory.Limits.Opposites

Limits in C give colimits in Cᵒᵖ. #

We also give special cases for (co)products, (co)equalizers, and pullbacks / pushouts.

Turn a colimit for F : J ⥤ Cᵒᵖ into a limit for F.leftOp : Jᵒᵖ ⥤ C.

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    Turn a limit of F : J ⥤ Cᵒᵖ into a colimit of F.leftOp : Jᵒᵖ ⥤ C.

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      Turn a colimit for F : Jᵒᵖ ⥤ C into a limit for F.rightOp : J ⥤ Cᵒᵖ.

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        Turn a limit for F : Jᵒᵖ ⥤ C into a colimit for F.rightOp : J ⥤ Cᵒᵖ.

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          Turn a limit of F : Jᵒᵖ ⥤ Cᵒᵖ into a colimit of F.unop : J ⥤ C.

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            Turn a limit of F.leftOp : Jᵒᵖ ⥤ C into a colimit of F : J ⥤ Cᵒᵖ.

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              Turn a colimit for F.rightOp : J ⥤ Cᵒᵖ into a limit for F : Jᵒᵖ ⥤ C.

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                Turn a limit for F.rightOp : J ⥤ Cᵒᵖ into a limit for F : Jᵒᵖ ⥤ C.

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                  If F.leftOp : Jᵒᵖ ⥤ C has a colimit, we can construct a limit for F : J ⥤ Cᵒᵖ.

                  If F.leftOp : Jᵒᵖ ⥤ C has a limit, we can construct a colimit for F : J ⥤ Cᵒᵖ.

                  If C has products indexed by X, then Cᵒᵖ has coproducts indexed by X.

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                  If C has coproducts indexed by X, then Cᵒᵖ has products indexed by X.

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                  A Cofan gives a Fan in the opposite category.

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                    If a Cofan is colimit, then its opposite is limit.

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                      The canonical isomorphism from the opposite of an abstract coproduct to the corresponding product in the opposite category.

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                        The canonical isomorphism from the opposite of the coproduct to the product in the opposite category.

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                          A Fan gives a Cofan in the opposite category.

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                            If a Fan is limit, then its opposite is colimit.

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                              The canonical isomorphism from the opposite of an abstract product to the corresponding coproduct in the opposite category.

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                                The canonical isomorphism from the opposite of the product to the coproduct in the opposite category.

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                                  The canonical isomorphism relating Span f.op g.op and (Cospan f g).op

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                                    The canonical isomorphism relating (Cospan f g).op and Span f.op g.op

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                                      The canonical isomorphism relating Cospan f.op g.op and (Span f g).op

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                                        The canonical isomorphism relating (Span f g).op and Cospan f.op g.op

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                                          The obvious map PushoutCocone f g → PullbackCone f.unop g.unop

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                                            The obvious map PushoutCocone f.op g.op → PullbackCone f g

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                                              The obvious map PullbackCone f g → PushoutCocone f.unop g.unop

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                                                The obvious map PullbackCone f g → PushoutCocone f.op g.op

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                                                  If c is a pullback cone, then c.op.unop is isomorphic to c.

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                                                    If c is a pullback cone in Cᵒᵖ, then c.unop.op is isomorphic to c.

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                                                      If c is a pushout cocone, then c.op.unop is isomorphic to c.

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                                                        If c is a pushout cocone in Cᵒᵖ, then c.unop.op is isomorphic to c.

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                                                          A pushout cone is a colimit cocone if and only if the corresponding pullback cone in the opposite category is a limit cone.

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                                                            A pushout cone is a colimit cocone in Cᵒᵖ if and only if the corresponding pullback cone in C is a limit cone.

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                                                              A pullback cone is a limit cone if and only if the corresponding pushout cocone in the opposite category is a colimit cocone.

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                                                                A pullback cone is a limit cone in Cᵒᵖ if and only if the corresponding pushout cocone in C is a colimit cocone.

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                                                                  The pullback of f and g in C is isomorphic to the pushout of f.op and g.op in Cᵒᵖ.

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                                                                    theorem CategoryTheory.Limits.pullbackIsoUnopPushout_inv_fst {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] {X : C} {Y : C} {Z : C} (f : X Z) (g : Y Z) [CategoryTheory.Limits.HasPullback f g] [CategoryTheory.Limits.HasPushout f.op g.op] :
                                                                    CategoryTheory.CategoryStruct.comp (CategoryTheory.Limits.pullbackIsoUnopPushout f g).inv CategoryTheory.Limits.pullback.fst = CategoryTheory.Limits.pushout.inl.unop
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                                                                    theorem CategoryTheory.Limits.pullbackIsoUnopPushout_inv_snd {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] {X : C} {Y : C} {Z : C} (f : X Z) (g : Y Z) [CategoryTheory.Limits.HasPullback f g] [CategoryTheory.Limits.HasPushout f.op g.op] :
                                                                    CategoryTheory.CategoryStruct.comp (CategoryTheory.Limits.pullbackIsoUnopPushout f g).inv CategoryTheory.Limits.pullback.snd = CategoryTheory.Limits.pushout.inr.unop
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                                                                    theorem CategoryTheory.Limits.pullbackIsoUnopPushout_hom_inl {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] {X : C} {Y : C} {Z : C} (f : X Z) (g : Y Z) [CategoryTheory.Limits.HasPullback f g] [CategoryTheory.Limits.HasPushout f.op g.op] :
                                                                    CategoryTheory.CategoryStruct.comp CategoryTheory.Limits.pushout.inl (CategoryTheory.Limits.pullbackIsoUnopPushout f g).hom.op = CategoryTheory.Limits.pullback.fst.op
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                                                                    theorem CategoryTheory.Limits.pullbackIsoUnopPushout_hom_inr {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] {X : C} {Y : C} {Z : C} (f : X Z) (g : Y Z) [CategoryTheory.Limits.HasPullback f g] [CategoryTheory.Limits.HasPushout f.op g.op] :
                                                                    CategoryTheory.CategoryStruct.comp CategoryTheory.Limits.pushout.inr (CategoryTheory.Limits.pullbackIsoUnopPushout f g).hom.op = CategoryTheory.Limits.pullback.snd.op

                                                                    The pushout of f and g in C is isomorphic to the pullback of f.op and g.op in Cᵒᵖ.

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                                                                      theorem CategoryTheory.Limits.pushoutIsoUnopPullback_inl_hom {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] {X : C} {Y : C} {Z : C} (f : X Z) (g : X Y) [CategoryTheory.Limits.HasPushout f g] [CategoryTheory.Limits.HasPullback f.op g.op] :
                                                                      CategoryTheory.CategoryStruct.comp CategoryTheory.Limits.pushout.inl (CategoryTheory.Limits.pushoutIsoUnopPullback f g).hom = CategoryTheory.Limits.pullback.fst.unop
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                                                                      theorem CategoryTheory.Limits.pushoutIsoUnopPullback_inr_hom {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] {X : C} {Y : C} {Z : C} (f : X Z) (g : X Y) [CategoryTheory.Limits.HasPushout f g] [CategoryTheory.Limits.HasPullback f.op g.op] :
                                                                      CategoryTheory.CategoryStruct.comp CategoryTheory.Limits.pushout.inr (CategoryTheory.Limits.pushoutIsoUnopPullback f g).hom = CategoryTheory.Limits.pullback.snd.unop
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                                                                      theorem CategoryTheory.Limits.pushoutIsoUnopPullback_inv_fst {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] {X : C} {Y : C} {Z : C} (f : X Z) (g : X Y) [CategoryTheory.Limits.HasPushout f g] [CategoryTheory.Limits.HasPullback f.op g.op] :
                                                                      CategoryTheory.CategoryStruct.comp (CategoryTheory.Limits.pushoutIsoUnopPullback f g).inv.op CategoryTheory.Limits.pullback.fst = CategoryTheory.Limits.pushout.inl.op
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                                                                      theorem CategoryTheory.Limits.pushoutIsoUnopPullback_inv_snd {C : Type u₁} [CategoryTheory.Category.{v₁, u₁} C] {X : C} {Y : C} {Z : C} (f : X Z) (g : X Y) [CategoryTheory.Limits.HasPushout f g] [CategoryTheory.Limits.HasPullback f.op g.op] :
                                                                      CategoryTheory.CategoryStruct.comp (CategoryTheory.Limits.pushoutIsoUnopPullback f g).inv.op CategoryTheory.Limits.pullback.snd = CategoryTheory.Limits.pushout.inr.op

                                                                      A colimit cokernel cofork gives a limit kernel fork in the opposite category

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                                                                        A colimit cokernel cofork in the opposite category gives a limit kernel fork in the original category

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                                                                          A limit kernel fork gives a colimit cokernel cofork in the opposite category

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                                                                            A limit kernel fork in the opposite category gives a colimit cokernel cofork in the original category

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