2016-11-06 10:01:14 +00:00
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/-
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Copyright (c) 2016 Ulrik Buchholtz. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Authors: Ulrik Buchholtz
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-/
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2017-02-18 21:56:38 +00:00
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import .move_to_lib
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2016-11-06 10:01:14 +00:00
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open eq pointed equiv sigma
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/-
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The goal of this file is to give the truncation level
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of the type of pointed maps, giving the connectivity of
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the domain and the truncation level of the codomain.
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This is is_trunc_pmap at the end.
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2016-11-24 04:54:57 +00:00
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2016-11-06 10:01:14 +00:00
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First we define the type of dependent pointed maps
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as a tool, because these appear in the more general
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statement is_trunc_ppi (the generality needed for induction).
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Unfortunately, some of these names (ppi) and notations (Π*)
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clash with those in types.pi in the pi namespace.
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-/
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namespace pointed
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abbreviation ppi_resp_pt [unfold 3] := @ppi.resp_pt
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definition pointed_ppi [instance] [constructor] {A : Type*}
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(P : A → Type*) : pointed (ppi A P) :=
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pointed.mk (ppi.mk (λ a, pt) idp)
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definition pppi [constructor] {A : Type*} (P : A → Type*) : Type* :=
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pointed.mk' (ppi A P)
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notation `Π*` binders `, ` r:(scoped P, pppi P) := r
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structure ppi_homotopy {A : Type*} {P : A → Type*} (f g : Π*(a : A), P a) :=
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(homotopy : f ~ g)
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(homotopy_pt : homotopy pt ⬝ ppi_resp_pt g = ppi_resp_pt f)
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variables {A : Type*} {P : A → Type*} {f g : Π*(a : A), P a}
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infix ` ~~* `:50 := ppi_homotopy
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abbreviation ppi_to_homotopy_pt [unfold 5] := @ppi_homotopy.homotopy_pt
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abbreviation ppi_to_homotopy [coercion] [unfold 5] (p : f ~~* g) : Πa, f a = g a :=
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ppi_homotopy.homotopy p
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definition ppi_equiv_pmap (A B : Type*) : (Π*(a : A), B) ≃ (A →* B) :=
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begin
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fapply equiv.MK,
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{ intro f, induction f with f p, exact pmap.mk f p },
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{ intro f, induction f with f p, exact ppi.mk f p },
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{ intro f, induction f with f p, reflexivity },
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{ intro f, induction f with f p, reflexivity }
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end
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definition ppi.sigma_char [constructor] {A : Type*} (P : A → Type*)
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: (Π*(a : A), P a) ≃ Σ(f : (Π (a : A), P a)), f pt = pt :=
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begin
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fapply equiv.MK : intros f,
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{ exact ⟨ f , ppi_resp_pt f ⟩ },
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all_goals cases f with f p,
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{ exact ppi.mk f p },
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all_goals reflexivity
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end
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-- the same as pmap_eq
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definition ppi_eq (h : f ~ g) : ppi_resp_pt f = h pt ⬝ ppi_resp_pt g → f = g :=
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begin
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cases f with f p, cases g with g q, intro r,
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esimp at *,
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fapply apd011 ppi.mk,
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{ apply eq_of_homotopy h },
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{ esimp, apply concato_eq, apply eq_pathover_Fl, apply inv_con_eq_of_eq_con,
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rewrite [ap_eq_apd10, apd10_eq_of_homotopy], exact r }
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end
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variables (f g)
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definition ppi_homotopy.sigma_char [constructor]
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: (f ~~* g) ≃ Σ(p : f ~ g), p pt ⬝ ppi_resp_pt g = ppi_resp_pt f :=
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begin
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fapply equiv.MK : intros h,
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{ exact ⟨h , ppi_to_homotopy_pt h⟩ },
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all_goals cases h with h p,
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{ exact ppi_homotopy.mk h p },
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all_goals reflexivity
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end
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-- the same as pmap_eq_equiv
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definition ppi_eq_equiv : (f = g) ≃ (f ~~* g) :=
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calc (f = g) ≃ ppi.sigma_char P f = ppi.sigma_char P g
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: eq_equiv_fn_eq (ppi.sigma_char P) f g
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... ≃ Σ(p : ppi.to_fun f = ppi.to_fun g),
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pathover (λh, h pt = pt) (ppi_resp_pt f) p (ppi_resp_pt g)
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: sigma_eq_equiv _ _
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... ≃ Σ(p : ppi.to_fun f = ppi.to_fun g),
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ppi_resp_pt f = ap (λh, h pt) p ⬝ ppi_resp_pt g
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: sigma_equiv_sigma_right
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(λp, eq_pathover_equiv_Fl p (ppi_resp_pt f) (ppi_resp_pt g))
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... ≃ Σ(p : ppi.to_fun f = ppi.to_fun g),
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ppi_resp_pt f = apd10 p pt ⬝ ppi_resp_pt g
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: sigma_equiv_sigma_right
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(λp, equiv_eq_closed_right _ (whisker_right _ (ap_eq_apd10 p _)))
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... ≃ Σ(p : f ~ g), ppi_resp_pt f = p pt ⬝ ppi_resp_pt g
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: sigma_equiv_sigma_left' eq_equiv_homotopy
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... ≃ Σ(p : f ~ g), p pt ⬝ ppi_resp_pt g = ppi_resp_pt f
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: sigma_equiv_sigma_right (λp, eq_equiv_eq_symm _ _)
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... ≃ (f ~~* g) : ppi_homotopy.sigma_char f g
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definition ppi_loop_equiv_lemma (p : f ~ f)
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: (p pt ⬝ ppi_resp_pt f = ppi_resp_pt f) ≃ (p pt = idp) :=
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calc (p pt ⬝ ppi_resp_pt f = ppi_resp_pt f)
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≃ (p pt ⬝ ppi_resp_pt f = idp ⬝ ppi_resp_pt f)
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: equiv_eq_closed_right (p pt ⬝ ppi_resp_pt f) (inverse (idp_con (ppi_resp_pt f)))
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... ≃ (p pt = idp)
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: eq_equiv_con_eq_con_right
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definition ppi_loop_equiv : (f = f) ≃ Π*(a : A), Ω (pType.mk (P a) (f a)) :=
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calc (f = f) ≃ (f ~~* f)
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: ppi_eq_equiv
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... ≃ Σ(p : f ~ f), p pt ⬝ ppi_resp_pt f = ppi_resp_pt f
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: ppi_homotopy.sigma_char f f
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... ≃ Σ(p : f ~ f), p pt = idp
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: sigma_equiv_sigma_right
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(λ p, ppi_loop_equiv_lemma f p)
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... ≃ Π*(a : A), pType.mk (f a = f a) idp
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: ppi.sigma_char
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... ≃ Π*(a : A), Ω (pType.mk (P a) (f a))
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: erfl
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end pointed open pointed
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open is_trunc is_conn
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section
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variables (A : Type*) (n : ℕ₋₂) [H : is_conn (n.+1) A]
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include H
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definition is_contr_ppi_match (P : A → (n.+1)-Type*)
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: is_contr (Π*(a : A), P a) :=
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begin
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apply is_contr.mk pt,
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intro f, induction f with f p,
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fapply ppi_eq,
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{ apply is_conn.elim n, esimp, exact p⁻¹ },
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{ krewrite (is_conn.elim_β n), apply inverse, apply con.left_inv }
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end
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definition is_trunc_ppi (k : ℕ₋₂) (P : A → (n.+1+2+k)-Type*)
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: is_trunc k.+1 (Π*(a : A), P a) :=
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begin
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induction k with k IH,
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{ apply is_prop_of_imp_is_contr, intro f,
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apply is_contr_ppi_match },
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{ apply is_trunc_succ_of_is_trunc_loop
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(trunc_index.succ_le_succ (trunc_index.minus_two_le k)),
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intro f,
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apply @is_trunc_equiv_closed_rev _ _ k.+1
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(ppi_loop_equiv f),
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apply IH, intro a,
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apply ptrunctype.mk (Ω (pType.mk (P a) (f a))),
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{ apply is_trunc_loop, exact is_trunc_ptrunctype (P a) },
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{ exact pt } }
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end
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definition is_trunc_pmap (k : ℕ₋₂) (B : (n.+1+2+k)-Type*)
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: is_trunc k.+1 (A →* B) :=
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@is_trunc_equiv_closed _ _ k.+1 (ppi_equiv_pmap A B)
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(is_trunc_ppi A n k (λ a, B))
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end
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