module Cat.Functor.Kan.Unique where
Uniqueness of Kan extensions🔗
Kan extensions (both left and right) are universal constructions, so they are unique when they exist. To get a theorem out of this intuition, we must be careful about how the structure and the properties are separated: Informally, we refer to the functor as “the Kan extension”, but in reality, the data associated with “the Kan extension of along ” also includes the natural transformation. For accuracy, using the setup from the diagram below, we should say “ is the Kan extension of along ”.
private variable o ℓ : Level C C' D E : Precategory o ℓ module Lan-unique {p : Functor C C'} {F : Functor C D} {G₁ G₂ : Functor C' D} {η₁ η₂} (l₁ : is-lan p F G₁ η₁) (l₂ : is-lan p F G₂ η₂) where private module l₁ = is-lan l₁ module l₂ = is-lan l₂ module D = Cat.Reasoning D module C'D = Cat.Reasoning Cat[ C' , D ] open C'D._≅_ open C'D.Inverses
To show uniqueness, suppose that and and both left extensions of along Diagramming this with both natural transformations shown is a bit of a nightmare: the option which doesn’t result in awful crossed arrows is to duplicate the span So, to be clear: The upper triangle and the lower triangle are the same.
Recall that being a left extension means we can (uniquely) factor natural transformations through transformations We want a map for which it will suffice to find a map — but is right there! In the other direction, we can factor to get a map Since these factorisations are unique, we have a natural isomorphism.
σ-inversesp : ∀ {α : G₁ => G₂} {β : G₂ => G₁} → (α ◂ p) ∘nt η₁ ≡ η₂ → (β ◂ p) ∘nt η₂ ≡ η₁ → Inversesⁿ α β σ-inversesp α-factor β-factor = C'D.make-inverses (l₂.σ-uniq₂ η₂ (ext λ j → sym (D.pullr (β-factor ηₚ j) ∙ α-factor ηₚ j)) (ext λ j → sym (D.idl _))) (l₁.σ-uniq₂ η₁ (ext λ j → sym (D.pullr (α-factor ηₚ j) ∙ β-factor ηₚ j)) (ext λ j → sym (D.idl _)))
σ-is-invertiblep : ∀ {α : G₁ => G₂} → (α ◂ p) ∘nt η₁ ≡ η₂ → is-invertibleⁿ α σ-is-invertiblep {α = α} α-factor = C'D.inverses→invertible (σ-inversesp {α} α-factor l₂.σ-comm) σ-inverses : Inversesⁿ (l₁.σ η₂) (l₂.σ η₁) σ-inverses = σ-inversesp l₁.σ-comm l₂.σ-comm σ-is-invertible : is-invertibleⁿ (l₁.σ η₂) σ-is-invertible = σ-is-invertiblep l₁.σ-comm unique : G₁ ≅ⁿ G₂ unique = C'D.invertible→iso (l₁.σ η₂) (σ-is-invertiblep l₁.σ-comm)
It’s immediate from the construction that this isomorphism “sends to ”.
unit : (l₁.σ η₂ ◂ p) ∘nt η₁ ≡ η₂ unit = l₁.σ-comm
module _ {p : Functor C C'} {F : Functor C D} {G : Functor C' D} {eta} (lan : is-lan p F G eta) where private module lan = is-lan lan module D = Cat.Reasoning D module C'D = Cat.Reasoning Cat[ C' , D ] open _=>_
Another uniqueness-like result we can state for left extensions is the following: Given any functor and candidate “unit” transformation if a left extension sends to a natural isomorphism, then is also a left extension of along
is-invertible→is-lan : ∀ {G' : Functor C' D} {eta' : F => G' F∘ p} → is-invertibleⁿ (lan.σ eta') → is-lan p F G' eta' is-invertible→is-lan {G' = G'} {eta'} invert = lan' where open is-lan open C'D.is-invertible invert lan' : is-lan p F G' eta' lan' .σ α = lan.σ α ∘nt inv lan' .σ-comm {M} {α} = ext λ j → (lan.σ α .η _ D.∘ inv .η _) D.∘ eta' .η j ≡˘⟨ D.refl⟩∘⟨ (lan.σ-comm ηₚ _) ⟩≡˘ (lan.σ α .η _ D.∘ inv .η _) D.∘ (lan.σ eta' .η _ D.∘ eta .η j) ≡⟨ D.cancel-inner (invr ηₚ _) ⟩≡ lan.σ α .η _ D.∘ eta .η j ≡⟨ lan.σ-comm ηₚ _ ⟩≡ α .η j ∎ lan' .σ-uniq {M} {α} {σ'} p = ext λ j → lan.σ α .η j D.∘ inv .η j ≡⟨ (lan.σ-uniq {σ' = σ' ∘nt lan.σ eta'} (ext λ j → p ηₚ j ∙ D.pushr (sym (lan.σ-comm ηₚ j))) ηₚ j) D.⟩∘⟨refl ⟩≡ (σ' .η j D.∘ lan.σ eta' .η j) D.∘ inv .η _ ≡⟨ D.cancelr (invl ηₚ _) ⟩≡ σ' .η j ∎
natural-iso-of→is-lan : {F' : Functor C D} → (isos : F ≅ⁿ F') → is-lan p F' G (eta ∘nt Isoⁿ.from isos) natural-iso-of→is-lan {F' = F'} isos = lan' where open is-lan module isos = Isoⁿ isos lan' : is-lan p F' G (eta ∘nt isos.from) lan' .σ α = lan.σ (α ∘nt isos.to) lan' .σ-comm {M} {α} = ext λ j → lan.σ (α ∘nt isos.to) .η _ D.∘ eta .η j D.∘ isos.from .η j ≡⟨ D.pulll (lan.σ-comm ηₚ j) ⟩≡ (α .η j D.∘ isos.to .η j) D.∘ isos.from .η j ≡⟨ D.cancelr (isos.invl ηₚ _) ⟩≡ α .η j ∎ lan' .σ-uniq {M} {α} {σ'} p = lan.σ-uniq $ ext λ j → α .η j D.∘ isos.to .η j ≡⟨ (p ηₚ j) D.⟩∘⟨refl ⟩≡ (σ' .η _ D.∘ eta .η j D.∘ isos.from .η j) D.∘ isos.to .η j ≡⟨ D.deleter (isos.invr ηₚ _) ⟩≡ σ' .η _ D.∘ eta .η j ∎ natural-iso-ext→is-lan : {G' : Functor C' D} → (isos : G ≅ⁿ G') → is-lan p F G' ((Isoⁿ.to isos ◂ p) ∘nt eta) natural-iso-ext→is-lan {G' = G'} isos = lan' where open is-lan module isos = Isoⁿ isos lan' : is-lan p F G' ((isos.to ◂ p) ∘nt eta) lan' .σ α = lan.σ α ∘nt isos.from lan' .σ-comm {M} {α} = ext λ j → (lan.σ α .η _ D.∘ isos.from .η _) D.∘ isos.to .η _ D.∘ eta .η j ≡⟨ D.cancel-inner (isos.invr ηₚ _) ⟩≡ lan.σ α .η _ D.∘ eta .η j ≡⟨ lan.σ-comm ηₚ _ ⟩≡ α .η j ∎ lan' .σ-uniq {M} {α} {σ'} p = ext λ j → lan.σ α .η j D.∘ isos.from .η j ≡⟨ D.pushl (lan.σ-uniq {σ' = σ' ∘nt isos.to} (ext λ j → p ηₚ j ∙ D.assoc _ _ _) ηₚ j) ⟩≡ σ' .η j D.∘ isos.to .η j D.∘ isos.from .η j ≡⟨ D.elimr (isos.invl ηₚ _) ⟩≡ σ' .η j ∎ natural-iso-along→is-lan : {p' : Functor C C'} → (isos : p ≅ⁿ p') → is-lan p' F G ((G ▸ Isoⁿ.to isos) ∘nt eta) natural-iso-along→is-lan {p'} isos = lan' where open is-lan module isos = Isoⁿ isos open Cat.Functor.Reasoning lan' : is-lan p' F G ((G ▸ Isoⁿ.to isos) ∘nt eta) lan' .σ {M} α = lan.σ ((M ▸ isos.from) ∘nt α) lan' .σ-comm {M = M} = ext λ j → D.pulll ((lan.σ _ .is-natural _ _ _)) ∙ D.pullr (lan.σ-comm ηₚ _) ∙ cancell M (isos.invl ηₚ _) lan' .σ-uniq {M = M} {α = α} {σ' = σ'} q = ext λ c' → lan.σ-uniq {α = (M ▸ isos.from) ∘nt α} {σ' = σ'} (ext λ j → D.pushr (q ηₚ _) ∙ D.pulll ( D.pullr (σ' .is-natural _ _ _) ∙ cancell M (isos.invr ηₚ _))) ηₚ c' universal-path→is-lan : ∀ {eta'} → eta ≡ eta' → is-lan p F G eta' universal-path→is-lan {eta'} q = lan' where open is-lan lan' : is-lan p F G eta' lan' .σ = lan.σ lan' .σ-comm = ap (_ ∘nt_) (sym q) ∙ lan.σ-comm lan' .σ-uniq r = lan.σ-uniq (r ∙ ap (_ ∘nt_) (sym q)) module _ {p p' : Functor C C'} {F F' : Functor C D} {G G' : Functor C' D} {eps eps'} where private module C' = Cat.Reasoning C' module D = Cat.Reasoning D open Cat.Functor.Reasoning open _=>_
Left Kan extensions are also invariant under arbitrary natural isomorphisms. To get better definitional control, we allow “adjusting” the resulting construction to talk about any natural transformation which is propositionally equal to the whiskering:
natural-isos→is-lan : (p-iso : p ≅ⁿ p') → (F-iso : F ≅ⁿ F') → (G-iso : G ≅ⁿ G') → (Isoⁿ.to G-iso ◆ Isoⁿ.to p-iso) ∘nt eps ∘nt Isoⁿ.from F-iso ≡ eps' → is-lan p F G eps → is-lan p' F' G' eps'
natural-isos→is-lan p-iso F-iso G-iso q lan = universal-path→is-lan (natural-iso-ext→is-lan (natural-iso-of→is-lan (natural-iso-along→is-lan lan p-iso) F-iso) G-iso) (ext λ x → D.extendl (D.pulll (G-iso .to .is-natural _ _ _)) ∙ q ηₚ _) where open Isoⁿ module _ {p p' : Functor C C'} {F F' : Functor C D} {G G' : Functor C' D} {eps eps'} where open Cat.Reasoning Cat[ C , D ] private module ◆ = Cat.Functor.Reasoning (F∘-functor {B = C'} {C = D} {A = C}) natural-isos→lan-equiv : (p-iso : p ≅ⁿ p') → (F-iso : F ≅ⁿ F') → (G-iso : G ≅ⁿ G') → (Isoⁿ.to G-iso ◆ Isoⁿ.to p-iso) ∘nt eps ∘nt Isoⁿ.from F-iso ≡ eps' → is-lan p F G eps ≃ is-lan p' F' G' eps' natural-isos→lan-equiv p-iso F-iso G-iso q = prop-ext! (natural-isos→is-lan p-iso F-iso G-iso q) (natural-isos→is-lan (p-iso ni⁻¹) (F-iso ni⁻¹) (G-iso ni⁻¹) (lswizzle (rswizzle (sym q ∙ assoc _ _ _) (F-iso .Isoⁿ.invr)) (◆.annihilate (G-iso .Isoⁿ.invr ,ₚ p-iso .Isoⁿ.invr))))
As a consequence of uniqueness, if a functor preserves a given Kan extension, then it preserves all extensions for the same diagram.
preserves-is-lan→preserves-lan : ∀ (H : Functor D E) {p : Functor C C'} {F : Functor C D} → ∀ {G} {eta : F => G F∘ p} (lan : is-lan p F G eta) → preserves-is-lan H lan → preserves-lan p F H preserves-is-lan→preserves-lan {E = E} {C' = C'} H lan pres {G'} lan' = natural-isos→is-lan idni idni (F∘-iso-r One.unique) (ext λ c → (H.₁ (G'.₁ C'.id) E.∘ H.₁ _) E.∘ H.₁ _ E.∘ E.id ≡⟨ E.pullr (H.pulll (One.unit ηₚ c)) ⟩≡ H.₁ (G'.₁ C'.id) E.∘ H.₁ _ E.∘ E.id ≡⟨ H.eliml G'.F-id ∙ E.idr _ ⟩≡ H.₁ _ ∎) pres where module C' = Cat.Reasoning C' module E = Cat.Reasoning E module H = Cat.Functor.Reasoning H module G' = Cat.Functor.Reasoning G' module One = Lan-unique lan lan'
Into univalent categories🔗
As traditional with universal constructions, if takes values in a univalent category, we can sharpen our result: the type of left extensions of along is a proposition.
Lan-is-prop : ∀ {p : Functor C C'} {F : Functor C D} → is-category D → is-prop (Lan p F) Lan-is-prop {C = C} {C' = C'} {D = D} {p = p} {F = F} d-cat L₁ L₂ = path where
module L₁ = Lan L₁ module L₂ = Lan L₂ module Lu = Lan-unique L₁.has-lan L₂.has-lan open Lan c'd-cat : is-category Cat[ C' , D ] c'd-cat = Functor-is-category d-cat
That’s because if is univalent, then so is , so our natural isomorphism is equivalent to an identification Then, our tiny lemma stating that this isomorphism “sends to ” is precisely the data of a dependent identification over
functor-path : L₁.Ext ≡ L₂.Ext functor-path = c'd-cat .to-path Lu.unique eta-path : PathP (λ i → F => functor-path i F∘ p) L₁.eta L₂.eta eta-path = Nat-pathp _ _ λ x → Univalent.Hom-pathp-reflr-iso d-cat (Lu.unit ηₚ _)
Since being a left extension is always a proposition when applied to even when the categories are not univalent, we can finish our proof.
path : L₁ ≡ L₂ path i .Ext = functor-path i path i .eta = eta-path i path i .has-lan = is-prop→pathp (λ i → is-lan-is-prop {p = p} {F} {functor-path i} {eta-path i}) L₁.has-lan L₂.has-lan i
module Ran-unique {p : Functor C C'} {F : Functor C D} {G₁ G₂ : Functor C' D} {ε₁ ε₂} (r₁ : is-ran p F G₁ ε₁) (r₂ : is-ran p F G₂ ε₂) where private module r₁ = is-ran r₁ module r₂ = is-ran r₂ module D = Cat.Reasoning D module C'D = Cat.Reasoning Cat[ C' , D ] open C'D._≅_ open C'D.Inverses σ-inversesp : ∀ {α : G₂ => G₁} {β : G₁ => G₂} → (ε₁ ∘nt (α ◂ p)) ≡ ε₂ → (ε₂ ∘nt (β ◂ p)) ≡ ε₁ → Inversesⁿ α β σ-inversesp α-factor β-factor = C'D.make-inverses (r₁.σ-uniq₂ ε₁ (ext λ j → sym (D.pulll (α-factor ηₚ j) ∙ β-factor ηₚ j)) (ext λ j → sym (D.idr _))) (r₂.σ-uniq₂ ε₂ (ext λ j → sym (D.pulll (β-factor ηₚ j) ∙ α-factor ηₚ j)) (ext λ j → sym (D.idr _))) σ-is-invertiblep : ∀ {α : G₂ => G₁} → (ε₁ ∘nt (α ◂ p)) ≡ ε₂ → is-invertibleⁿ α σ-is-invertiblep {α} α-factor = C'D.inverses→invertible (σ-inversesp {α} α-factor r₂.σ-comm) σ-inverses : Inversesⁿ (r₁.σ ε₂) (r₂.σ ε₁) σ-inverses = σ-inversesp r₁.σ-comm r₂.σ-comm σ-is-invertible : is-invertibleⁿ (r₁.σ ε₂) σ-is-invertible = σ-is-invertiblep r₁.σ-comm unique : G₁ ≅ⁿ G₂ unique = C'D.invertible→iso (r₁.σ ε₂) (σ-is-invertiblep r₁.σ-comm) ni⁻¹ counit : ε₁ ∘nt (r₁.σ ε₂ ◂ p) ≡ ε₂ counit = r₁.σ-comm module _ {p : Functor C C'} {F : Functor C D} {G : Functor C' D} {eps} (ran : is-ran p F G eps) where private module ran = is-ran ran module D = Cat.Reasoning D module C'D = Cat.Reasoning Cat[ C' , D ] open _=>_ -- These are more annoying to do via duality then it is to do by hand, -- due to the natural isos. is-invertible→is-ran : ∀ {G' : Functor C' D} {eps'} → is-invertibleⁿ (ran.σ eps') → is-ran p F G' eps' is-invertible→is-ran {G' = G'} {eps'} invert = ran' where open is-ran open C'D.is-invertible invert ran' : is-ran p F G' eps' ran' .σ β = inv ∘nt ran.σ β ran' .σ-comm {M} {β} = ext λ j → sym ((ran.σ-comm ηₚ _) D.⟩∘⟨refl) ∙∙ D.cancel-inner (invl ηₚ _) ∙∙ (ran.σ-comm ηₚ _) ran' .σ-uniq {M} {β} {σ'} p = ext λ j → (D.refl⟩∘⟨ ran.σ-uniq {σ' = ran.σ eps' ∘nt σ'} (ext λ j → p ηₚ j ∙ D.pushl (sym (ran.σ-comm ηₚ j))) ηₚ _) ∙ D.cancell (invr ηₚ _) natural-iso-of→is-ran : {F' : Functor C D} → (isos : F ≅ⁿ F') → is-ran p F' G (Isoⁿ.to isos ∘nt eps) natural-iso-of→is-ran {F'} isos = ran' where open is-ran module isos = Isoⁿ isos ran' : is-ran p F' G (isos.to ∘nt eps) ran' .σ β = ran.σ (isos.from ∘nt β) ran' .σ-comm {M} {β} = ext λ j → D.pullr (ran.σ-comm ηₚ j) ∙ D.cancell (isos.invl ηₚ _) ran' .σ-uniq {M} {β} {σ'} p = ran.σ-uniq $ ext λ j → (D.refl⟩∘⟨ p ηₚ j) ∙ D.deletel (isos.invr ηₚ _) natural-iso-ext→is-ran : {G' : Functor C' D} → (isos : G ≅ⁿ G') → is-ran p F G' (eps ∘nt (Isoⁿ.from isos ◂ p)) natural-iso-ext→is-ran {G'} isos = ran' where open is-ran module isos = Isoⁿ isos ran' : is-ran p F G' (eps ∘nt (isos.from ◂ p)) ran' .σ β = isos.to ∘nt ran.σ β ran' .σ-comm {M} {β} = ext λ j → D.cancel-inner (isos.invr ηₚ _) ∙ ran.σ-comm ηₚ _ ran' .σ-uniq {M} {β} {σ'} p = ext λ j → D.pushr (ran.σ-uniq {σ' = isos.from ∘nt σ'} (ext λ j → p ηₚ j ∙ sym (D.assoc _ _ _)) ηₚ j) ∙ D.eliml (isos.invl ηₚ _) natural-iso-along→is-ran : {p' : Functor C C'} → (isos : p ≅ⁿ p') → is-ran p' F G (eps ∘nt (G ▸ Isoⁿ.from isos)) natural-iso-along→is-ran {p'} isos = ran' where open is-ran module isos = Isoⁿ isos open Cat.Functor.Reasoning ran' : is-ran p' F G (eps ∘nt (G ▸ Isoⁿ.from isos)) ran' .σ {M} β = ran.σ (β ∘nt (M ▸ Isoⁿ.to isos)) ran' .σ-comm {M = M} = ext λ j → D.pullr (sym (ran.σ _ .is-natural _ _ _)) ∙ D.pulll (ran.σ-comm ηₚ _) ∙ cancelr M (isos.invl ηₚ _) ran' .σ-uniq {M = M} {β = β} {σ' = σ'} q = ext λ c' → ran.σ-uniq {β = β ∘nt (M ▸ isos.to)} {σ' = σ'} (ext λ j → D.pushl (q ηₚ _) ∙ D.pullr ( D.pulll (sym (σ' .is-natural _ _ _)) ∙ cancelr M (isos.invr ηₚ _))) ηₚ c' universal-path→is-ran : ∀ {eps'} → eps ≡ eps' → is-ran p F G eps' universal-path→is-ran {eps'} q = ran' where open is-ran ran' : is-ran p F G eps' ran' .σ = ran.σ ran' .σ-comm = ap (_∘nt _) (sym q) ∙ ran.σ-comm ran' .σ-uniq r = ran.σ-uniq (r ∙ ap (_∘nt _) (sym q)) module _ {p p' : Functor C C'} {F F' : Functor C D} {G G' : Functor C' D} {eps eps'} where private module D = Cat.Reasoning D open _=>_ natural-isos→is-ran : (p-iso : p ≅ⁿ p') → (F-iso : F ≅ⁿ F') → (G-iso : G ≅ⁿ G') → Isoⁿ.to F-iso ∘nt eps ∘nt (Isoⁿ.from G-iso ◆ Isoⁿ.from p-iso) ≡ eps' → is-ran p F G eps → is-ran p' F' G' eps' natural-isos→is-ran p-iso F-iso G-iso p ran = universal-path→is-ran (natural-iso-ext→is-ran (natural-iso-of→is-ran (natural-iso-along→is-ran ran p-iso) F-iso) G-iso) (ext λ c → sym (D.assoc _ _ _) ∙∙ ap₂ D._∘_ refl (sym $ D.assoc _ _ _) ∙∙ p ηₚ _) module _ {p p' : Functor C C'} {F F' : Functor C D} {G G' : Functor C' D} {eps eps'} where open Cat.Reasoning Cat[ C , D ] private module ◆ = Cat.Functor.Reasoning (F∘-functor {B = C'} {C = D} {A = C}) natural-isos→ran-equiv : (p-iso : p ≅ⁿ p') → (F-iso : F ≅ⁿ F') → (G-iso : G ≅ⁿ G') → Isoⁿ.to F-iso ∘nt eps ∘nt (Isoⁿ.from G-iso ◆ Isoⁿ.from p-iso) ≡ eps' → is-ran p F G eps ≃ is-ran p' F' G' eps' natural-isos→ran-equiv p-iso F-iso G-iso q = prop-ext! (natural-isos→is-ran p-iso F-iso G-iso q) (natural-isos→is-ran (p-iso ni⁻¹) (F-iso ni⁻¹) (G-iso ni⁻¹) (lswizzle (rswizzle (sym q ∙ assoc _ _ _) (◆.annihilate (G-iso .Isoⁿ.invr ,ₚ p-iso .Isoⁿ.invr))) (F-iso .Isoⁿ.invr))) preserves-is-ran→preserves-ran : ∀ (H : Functor D E) {p : Functor C C'} {F : Functor C D} → ∀ {G} {eps : G F∘ p => F} (ran : is-ran p F G eps) → preserves-is-ran H ran → preserves-ran p F H preserves-is-ran→preserves-ran {E = E} {C' = C'} H {G = G} ran pres ran' = natural-isos→is-ran idni idni (F∘-iso-r One.unique) (ext λ c → E.id E.∘ H.₁ _ E.∘ H.₁ (G.₁ C'.id) E.∘ H.₁ _ ≡⟨ E.idl _ ∙ (E.refl⟩∘⟨ H.eliml G.F-id) ⟩ H.₁ _ E.∘ H.₁ _ ≡⟨ H.collapse (One.counit ηₚ c) ⟩ H.₁ _ ∎) pres where module C' = Cat.Reasoning C' module E = Cat.Reasoning E module H = Cat.Functor.Reasoning H module G = Cat.Functor.Reasoning G module One = Ran-unique ran ran' Ran-is-prop : ∀ {p : Functor C C'} {F : Functor C D} → is-category D → is-prop (Ran p F) Ran-is-prop {C = C} {C' = C'} {D = D} {p = p} {F = F} d-cat R₁ R₂ = path where module R₁ = Ran R₁ module R₂ = Ran R₂ module Ru = Ran-unique R₁.has-ran R₂.has-ran open Ran c'd-cat : is-category Cat[ C' , D ] c'd-cat = Functor-is-category d-cat fp : R₁.Ext ≡ R₂.Ext fp = c'd-cat .to-path Ru.unique εp : PathP (λ i → fp i F∘ p => F) R₁.eps R₂.eps εp = Nat-pathp _ _ λ x → Univalent.Hom-pathp-refll-iso d-cat (Ru.counit ηₚ _) path : R₁ ≡ R₂ path i .Ext = fp i path i .eps = εp i path i .has-ran = is-prop→pathp (λ i → is-ran-is-prop {p = p} {F} {fp i} {εp i}) R₁.has-ran R₂.has-ran i lifts→preserves-lan : ∀ {H : Functor D E} {p : Functor C C'} {F : Functor C D} → {Lan : Lan p (H F∘ F)} → lifts-lan H Lan → preserves-lan p F H lifts→preserves-lan {H = H} lifts = preserves-is-lan→preserves-lan H (Lan.has-lan lifted) preserved where open lifts-lan lifts lifts→preserves-ran : ∀ {H : Functor D E} {p : Functor C C'} {F : Functor C D} → {Ran : Ran p (H F∘ F)} → lifts-ran H Ran → preserves-ran p F H lifts→preserves-ran {H = H} lifts = preserves-is-ran→preserves-ran H (Ran.has-ran lifted) preserved where open lifts-ran lifts