lean2/library/hott/funext_varieties.lean

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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.
-- Authors: Jakob von Raumer
-- Ported from Coq HoTT
import hott.path hott.trunc hott.equiv
open path truncation sigma function
/- In hott.axioms.funext, we defined function extensionality to be the assertion
that the map apD10 is an equivalence. We now prove that this follows
from a couple of weaker-looking forms of function extensionality. We do
require eta conversion, which Coq 8.4+ has judgmentally.
This proof is originally due to Voevodsky; it has since been simplified
by Peter Lumsdaine and Michael Shulman. -/
-- Naive funext is the simple assertion that pointwise equal functions are equal.
-- TODO think about universe levels
definition naive_funext.{l} :=
Π {A : Type.{l+1}} {P : A → Type.{l+2}} (f g : Πx, P x), (f g) → f ≈ g
-- Weak funext says that a product of contractible types is contractible.
definition weak_funext.{l} :=
Π {A : Type.{l+1}} (P : A → Type.{l+2}) [H: Πx, is_contr (P x)], is_contr (Πx, P x)
-- We define a variant of [Funext] which does not invoke an axiom.
definition funext_type.{l} :=
Π {A : Type.{l+1}} {P : A → Type.{l+2}} (f g : Πx, P x), IsEquiv (@apD10 A P f g)
-- The obvious implications are Funext -> NaiveFunext -> WeakFunext
-- TODO: Get class inference to work locally
definition funext_implies_naive_funext : funext_type → naive_funext :=
(λ Fe A P f g h,
have Fefg: IsEquiv (@apD10 A P f g), from Fe A P f g,
have eq1 : _, from (@IsEquiv.inv _ _ (@apD10 A P f g) Fefg h),
eq1
)
definition naive_funext_implies_weak_funext : naive_funext → weak_funext :=
(λ nf A P (Pc : Πx, is_contr (P x)),
let c := λx, center (P x) in
is_contr.mk c (λ f,
have eq' : (λx, center (P x)) f,
from (λx, contr (f x)),
have eq : (λx, center (P x)) ≈ f,
from nf A P (λx, center (P x)) f eq',
eq
)
)
/- The less obvious direction is that WeakFunext implies Funext
(and hence all three are logically equivalent). The point is that under weak
funext, the space of "pointwise homotopies" has the same universal property as
the space of paths. -/
context
universe l
parameters (wf : weak_funext.{l}) {A : Type.{l+1}} {B : A → Type.{l+2}} (f : Π x, B x)
protected definition idhtpy : f f := (λ x, idp)
definition contr_basedhtpy [instance] : is_contr (Σ (g : Π x, B x), f g) :=
is_contr.mk (dpair f idhtpy)
(λ dp, sigma.rec_on dp
(λ (g : Π x, B x) (h : f g),
let r := λ (k : Π x, Σ y, f x ≈ y),
@dpair _ (λg, f g)
(λx, dpr1 (k x)) (λx, dpr2 (k x)) in
let s := λ g h x, @dpair _ (λy, f x ≈ y) (g x) (h x) in
have t1 : Πx, is_contr (Σ y, f x ≈ y),
from (λx, !contr_basedpaths),
have t2 : is_contr (Πx, Σ y, f x ≈ y),
from !wf,
have t3 : (λ x, @dpair _ (λ y, f x ≈ y) (f x) idp) ≈ s g h,
from @path_contr (Π x, Σ y, f x ≈ y) t2 _ _,
have t4 : r (λ x, dpair (f x) idp) ≈ r (s g h),
from ap r t3,
have endt : dpair f idhtpy ≈ dpair g h,
from t4,
endt
)
)
parameters (Q : Π g (h : f g), Type) (d : Q f idhtpy)
definition htpy_ind (g : Πx, B x) (h : f g) : Q g h :=
@transport _ (λ gh, Q (dpr1 gh) (dpr2 gh)) (dpair f idhtpy) (dpair g h)
(@path_contr _ contr_basedhtpy _ _) d
definition htpy_ind_beta : htpy_ind f idhtpy ≈ d :=
(@path2_contr _ _ _ _ !path_contr idp)⁻¹ ▹ idp
end
-- Now the proof is fairly easy; we can just use the same induction principle on both sides.
universe variable l
theorem weak_funext_implies_funext : weak_funext.{l} → funext_type.{l} :=
(λ wf A B f g,
let eq_to_f := (λ g' x, f ≈ g') in
let sim2path := htpy_ind wf f eq_to_f idp in
have t1 : sim2path f (idhtpy f) ≈ idp,
proof htpy_ind_beta wf f eq_to_f idp qed,
have t2 : apD10 (sim2path f (idhtpy f)) ≈ (idhtpy f),
proof ap apD10 t1 qed,
have sect : Sect (sim2path g) apD10,
proof (htpy_ind wf f (λ g' x, apD10 (sim2path g' x) ≈ x) t2) g qed,
have retr : Sect apD10 (sim2path g),
from (λ h, path.rec_on h (htpy_ind_beta wf f _ idp)),
IsEquiv.adjointify apD10 (sim2path g) sect retr)
definition naive_funext_implies_funext : naive_funext -> funext_type :=
compose weak_funext_implies_funext naive_funext_implies_weak_funext