lean2/library/hott/equiv_precomp.lean
2014-11-28 22:50:43 -08:00

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-- Copyright (c) 2014 Jakob von Raumer. All rights reserved.
-- Released under Apache 2.0 license as described in the file LICENSE.
-- Author: Jakob von Raumer
-- Ported from Coq HoTT
import hott.equiv hott.axioms.funext
open path function funext
namespace is_equiv
context
--Precomposition of arbitrary functions with f
definition precomp {A B : Type} (f : A → B) (C : Type) (h : B → C) : A → C := h ∘ f
--Postcomposition of arbitrary functions with f
definition postcomp {A B : Type} (f : A → B) (C : Type) (l : C → A) : C → B := f ∘ l
--Precomposing with an equivalence is an equivalence
definition precomp_closed [instance] {A B : Type} (f : A → B) [F : funext] [Hf : is_equiv f] (C : Type)
: is_equiv (precomp f C) :=
adjointify (precomp f C) (λh, h ∘ f⁻¹)
(λh, path_forall _ _ (λx, ap h (sect f x)))
(λg, path_forall _ _ (λy, ap g (retr f y)))
--Postcomposing with an equivalence is an equivalence
definition postcomp_closed [instance] {A B : Type} (f : A → B) [F : funext] [Hf : is_equiv f] (C : Type)
: is_equiv (postcomp f C) :=
adjointify (postcomp f C) (λl, f⁻¹ ∘ l)
(λh, path_forall _ _ (λx, retr f (h x)))
(λg, path_forall _ _ (λy, sect f (g y)))
--Conversely, if pre- or post-composing with a function is always an equivalence,
--then that function is also an equivalence. It's convenient to know
--that we only need to assume the equivalence when the other type is
--the domain or the codomain.
protected definition isequiv_precompose_eq {A B : Type} (f : A → B) (C D : Type)
(Ceq : is_equiv (precomp f C)) (Deq : is_equiv (precomp f D)) (k : C → D) (h : A → C) :
k ∘ (inv (precomp f C)) h ≈ (inv (precomp f D)) (k ∘ h) :=
let invD := inv (precomp f D) in
let invC := inv (precomp f C) in
have eq1 : invD (k ∘ h) ≈ k ∘ (invC h),
from calc invD (k ∘ h) ≈ invD (k ∘ (precomp f C (invC h))) : retr (precomp f C) h
... ≈ k ∘ (invC h) : !sect,
eq1⁻¹
definition from_isequiv_precomp {A B : Type} (f : A → B) (Aeq : is_equiv (precomp f A))
(Beq : is_equiv (precomp f B)) : (is_equiv f) :=
let invA := inv (precomp f A) in
let invB := inv (precomp f B) in
let sect' : f ∘ (invA id) id := (λx,
calc f (invA id x) ≈ (f ∘ invA id) x : idp
... ≈ invB (f ∘ id) x : apD10 (!isequiv_precompose_eq)
... ≈ invB (precomp f B id) x : idp
... ≈ x : apD10 (sect (precomp f B) id))
in
let retr' : (invA id) ∘ f id := (λx,
calc invA id (f x) ≈ precomp f A (invA id) x : idp
... ≈ x : apD10 (retr (precomp f A) id)) in
adjointify f (invA id) sect' retr'
end
end is_equiv
--Bundled versions of the previous theorems
namespace equiv
definition precomp_closed [F : funext] {A B C : Type} {eqf : A ≃ B}
: (B → C) ≃ (A → C) :=
let f := to_fun eqf in
let Hf := to_is_equiv eqf in
equiv.mk (is_equiv.precomp f C)
(@is_equiv.precomp_closed A B f F Hf C)
definition postcomp_closed [F : funext] {A B C : Type} {eqf : A ≃ B}
: (C → A) ≃ (C → B) :=
let f := to_fun eqf in
let Hf := to_is_equiv eqf in
equiv.mk (is_equiv.postcomp f C)
(@is_equiv.postcomp_closed A B f F Hf C)
end equiv