302 lines
13 KiB
Text
302 lines
13 KiB
Text
/- equalities between pointed homotopies and other facts about pointed types/functions/homotopies -/
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-- Author: Floris van Doorn
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import types.pointed2 .move_to_lib
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open pointed eq equiv function is_equiv unit is_trunc trunc nat algebra sigma group lift option
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namespace pointed
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-- /- the pointed type of (unpointed) dependent maps -/
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-- definition pupi [constructor] {A : Type} (P : A → Type*) : Type* :=
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-- pointed.mk' (Πa, P a)
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-- definition loop_pupi_commute {A : Type} (B : A → Type*) : Ω(pupi B) ≃* pupi (λa, Ω (B a)) :=
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-- pequiv_of_equiv eq_equiv_homotopy rfl
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-- definition equiv_pupi_right {A : Type} {P Q : A → Type*} (g : Πa, P a ≃* Q a)
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-- : pupi P ≃* pupi Q :=
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-- pequiv_of_equiv (pi_equiv_pi_right g)
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-- begin esimp, apply eq_of_homotopy, intros a, esimp, exact (respect_pt (g a)) end
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-- definition pmap_eq_equiv {X Y : Type*} (f g : X →* Y) : (f = g) ≃ (f ~* g) :=
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-- begin
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-- refine eq_equiv_fn_eq_of_equiv (@pmap.sigma_char X Y) f g ⬝e _,
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-- refine !sigma_eq_equiv ⬝e _,
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-- refine _ ⬝e (phomotopy.sigma_char f g)⁻¹ᵉ,
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-- fapply sigma_equiv_sigma,
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-- { esimp, apply eq_equiv_homotopy },
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-- { induction g with g gp, induction Y with Y y0, esimp, intro p, induction p, esimp at *,
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-- refine !pathover_idp ⬝e _, refine _ ⬝e !eq_equiv_eq_symm,
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-- apply equiv_eq_closed_right, exact !idp_con⁻¹ }
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-- end
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/- remove some duplicates: loop_ppmap_commute, loop_ppmap_pequiv, loop_ppmap_pequiv', pfunext -/
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definition pfunext (X Y : Type*) : ppmap X (Ω Y) ≃* Ω (ppmap X Y) :=
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(loop_ppmap_commute X Y)⁻¹ᵉ*
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definition loop_phomotopy [constructor] {A B : Type*} (f : A →* B) : Type* :=
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pointed.MK (f ~* f) phomotopy.rfl
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definition ppcompose_left_loop_phomotopy [constructor] {A B C : Type*} (g : B →* C) {f : A →* B}
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{h : A →* C} (p : g ∘* f ~* h) : loop_phomotopy f →* loop_phomotopy h :=
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pmap.mk (λq, p⁻¹* ⬝* pwhisker_left g q ⬝* p)
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(idp ◾** !pwhisker_left_refl ◾** idp ⬝ !trans_refl ◾** idp ⬝ !trans_left_inv)
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definition ppcompose_left_loop_phomotopy' [constructor] {A B C : Type*} (g : B →* C) (f : A →* B)
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: loop_phomotopy f →* loop_phomotopy (g ∘* f) :=
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pmap.mk (λq, pwhisker_left g q) !pwhisker_left_refl
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definition loop_ppmap_pequiv' [constructor] (A B : Type*) :
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Ω(ppmap A B) ≃* loop_phomotopy (pconst A B) :=
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pequiv_of_equiv (pmap_eq_equiv _ _) idp
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definition ppmap_loop_pequiv' [constructor] (A B : Type*) :
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loop_phomotopy (pconst A B) ≃* ppmap A (Ω B) :=
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pequiv_of_equiv (!phomotopy.sigma_char ⬝e !pmap.sigma_char⁻¹ᵉ) idp
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definition loop_ppmap_pequiv [constructor] (A B : Type*) : Ω(ppmap A B) ≃* ppmap A (Ω B) :=
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loop_ppmap_pequiv' A B ⬝e* ppmap_loop_pequiv' A B
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definition loop_ppmap_pequiv'_natural_right' {X X' : Type} (x₀ : X) (A : Type*) (f : X → X') :
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psquare (loop_ppmap_pequiv' A _) (loop_ppmap_pequiv' A _)
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(Ω→ (ppcompose_left (pmap_of_map f x₀)))
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(ppcompose_left_loop_phomotopy' (pmap_of_map f x₀) !pconst) :=
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begin
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fapply phomotopy.mk,
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{ esimp, intro p,
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refine _ ⬝ ap011 (λx y, phomotopy_of_eq (ap1_gen _ x y _))
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proof !eq_of_phomotopy_refl⁻¹ qed proof !eq_of_phomotopy_refl⁻¹ qed,
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refine _ ⬝ ap phomotopy_of_eq !ap1_gen_idp_left⁻¹,
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exact !phomotopy_of_eq_pcompose_left⁻¹ },
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{ refine _ ⬝ !idp_con⁻¹, exact sorry }
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end
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definition loop_ppmap_pequiv'_natural_right {X X' : Type*} (A : Type*) (f : X →* X') :
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psquare (loop_ppmap_pequiv' A X) (loop_ppmap_pequiv' A X')
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(Ω→ (ppcompose_left f)) (ppcompose_left_loop_phomotopy f !pcompose_pconst) :=
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begin
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induction X' with X' x₀', induction f with f f₀, esimp at f, esimp at f₀, induction f₀,
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apply psquare_of_phomotopy,
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exact sorry
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end
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definition ppmap_loop_pequiv'_natural_right {X X' : Type*} (A : Type*) (f : X →* X') :
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psquare (ppmap_loop_pequiv' A X) (ppmap_loop_pequiv' A X')
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(ppcompose_left_loop_phomotopy f !pcompose_pconst) (ppcompose_left (Ω→ f)) :=
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begin
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exact sorry
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end
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definition loop_pmap_commute_natural_right_direct {X X' : Type*} (A : Type*) (f : X →* X') :
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psquare (loop_ppmap_pequiv A X) (loop_ppmap_pequiv A X')
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(Ω→ (ppcompose_left f)) (ppcompose_left (Ω→ f)) :=
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begin
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induction X' with X' x₀', induction f with f f₀, esimp at f, esimp at f₀, induction f₀,
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-- refine _ ⬝* _ ◾* _, rotate 4,
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fapply phomotopy.mk,
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{ intro p, esimp, esimp [pmap_eq_equiv, pcompose_pconst], exact sorry },
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{ exact sorry }
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end
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definition loop_pmap_commute_natural_left {A A' : Type*} (X : Type*) (f : A' →* A) :
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psquare (loop_ppmap_commute A X) (loop_ppmap_commute A' X)
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(Ω→ (ppcompose_right f)) (ppcompose_right f) :=
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sorry
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definition loop_pmap_commute_natural_right {X X' : Type*} (A : Type*) (f : X →* X') :
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psquare (loop_ppmap_commute A X) (loop_ppmap_commute A X')
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(Ω→ (ppcompose_left f)) (ppcompose_left (Ω→ f)) :=
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loop_ppmap_pequiv'_natural_right A f ⬝h* ppmap_loop_pequiv'_natural_right A f
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/-
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Do we want to use a structure of homotopies between pointed homotopies? Or are equalities fine?
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If we set up things more generally, we could define this as
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"pointed homotopies between the dependent pointed maps p and q"
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-/
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structure phomotopy2 {A B : Type*} {f g : A →* B} (p q : f ~* g) : Type :=
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(homotopy_eq : p ~ q)
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(homotopy_pt_eq : whisker_right (respect_pt g) (homotopy_eq pt) ⬝ to_homotopy_pt q =
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to_homotopy_pt p)
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/- this sets it up more generally, for illustrative purposes -/
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structure ppi' (A : Type*) (P : A → Type) (p : P pt) :=
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(to_fun : Π a : A, P a)
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(resp_pt : to_fun (Point A) = p)
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attribute ppi'.to_fun [coercion]
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definition phomotopy' {A : Type*} {P : A → Type} {x : P pt} (f g : ppi' A P x) : Type :=
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ppi' A (λa, f a = g a) (ppi'.resp_pt f ⬝ (ppi'.resp_pt g)⁻¹)
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definition phomotopy2' {A : Type*} {P : A → Type} {x : P pt} {f g : ppi' A P x}
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(p q : phomotopy' f g) : Type :=
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phomotopy' p q
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-- infix ` ~*2 `:50 := phomotopy2
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-- variables {A B : Type*} {f g : A →* B} (p q : f ~* g)
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-- definition phomotopy_eq_equiv_phomotopy2 : p = q ≃ p ~*2 q :=
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-- sorry
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/- Homotopy between a function and its eta expansion -/
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definition pmap_eta {X Y : Type*} (f : X →* Y) : f ~* pmap.mk f (respect_pt f) :=
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begin
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fapply phomotopy.mk,
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reflexivity,
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esimp, exact !idp_con
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end
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-- this should replace pnatural_square
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definition pnatural_square2 {A B : Type} (X : B → Type*) (Y : B → Type*) {f g : A → B}
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(h : Πa, X (f a) →* Y (g a)) {a a' : A} (p : a = a') :
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h a' ∘* ptransport X (ap f p) ~* ptransport Y (ap g p) ∘* h a :=
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by induction p; exact !pcompose_pid ⬝* !pid_pcompose⁻¹*
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definition ptransport_ap {A B : Type} (X : B → Type*) (f : A → B) {a a' : A} (p : a = a') :
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ptransport X (ap f p) ~* ptransport (X ∘ f) p :=
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by induction p; reflexivity
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definition ptransport_constant (A : Type) (B : Type*) {a a' : A} (p : a = a') :
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ptransport (λ(a : A), B) p ~* pid B :=
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by induction p; reflexivity
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definition ptransport_natural {A : Type} (X : A → Type*) (Y : A → Type*)
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(h : Πa, X a →* Y a) {a a' : A} (p : a = a') :
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h a' ∘* ptransport X p ~* ptransport Y p ∘* h a :=
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by induction p; exact !pcompose_pid ⬝* !pid_pcompose⁻¹*
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section psquare
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variables {A A' A₀₀ A₂₀ A₄₀ A₀₂ A₂₂ A₄₂ A₀₄ A₂₄ A₄₄ : Type*}
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{f₁₀ f₁₀' : A₀₀ →* A₂₀} {f₃₀ : A₂₀ →* A₄₀}
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{f₀₁ f₀₁' : A₀₀ →* A₀₂} {f₂₁ f₂₁' : A₂₀ →* A₂₂} {f₄₁ : A₄₀ →* A₄₂}
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{f₁₂ f₁₂' : A₀₂ →* A₂₂} {f₃₂ : A₂₂ →* A₄₂}
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{f₀₃ : A₀₂ →* A₀₄} {f₂₃ : A₂₂ →* A₂₄} {f₄₃ : A₄₂ →* A₄₄}
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{f₁₄ : A₀₄ →* A₂₄} {f₃₄ : A₂₄ →* A₄₄}
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definition ptranspose (p : psquare f₁₀ f₁₂ f₀₁ f₂₁) : psquare f₀₁ f₂₁ f₁₀ f₁₂ :=
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p⁻¹*
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definition hsquare_of_psquare (p : psquare f₁₀ f₁₂ f₀₁ f₂₁) : hsquare f₁₀ f₁₂ f₀₁ f₂₁ :=
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p
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definition homotopy_group_functor_hsquare (n : ℕ) (h : psquare f₁₀ f₁₂ f₀₁ f₂₁) :
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psquare (π→[n] f₁₀) (π→[n] f₁₂)
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(π→[n] f₀₁) (π→[n] f₂₁) :=
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sorry
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end psquare
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definition ap1_pequiv_ap {A : Type} (B : A → Type*) {a a' : A} (p : a = a') :
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Ω→ (pequiv_ap B p) ~* pequiv_ap (Ω ∘ B) p :=
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begin induction p, apply ap1_pid end
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definition pequiv_ap_natural {A : Type} (B C : A → Type*) {a a' : A} (p : a = a')
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(f : Πa, B a →* C a) :
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psquare (pequiv_ap B p) (pequiv_ap C p) (f a) (f a') :=
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begin induction p, exact phrfl end
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definition is_contr_loop (A : Type*) [is_set A] : is_contr (Ω A) :=
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is_contr.mk idp (λa, !is_prop.elim)
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definition is_contr_loop_of_is_contr {A : Type*} (H : is_contr A) : is_contr (Ω A) :=
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is_contr_loop A
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definition is_contr_punit [instance] : is_contr punit :=
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is_contr_unit
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definition pequiv_of_is_contr (A B : Type*) (HA : is_contr A) (HB : is_contr B) : A ≃* B :=
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pequiv_punit_of_is_contr A _ ⬝e* (pequiv_punit_of_is_contr B _)⁻¹ᵉ*
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definition loop_pequiv_punit_of_is_set (X : Type*) [is_set X] : Ω X ≃* punit :=
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pequiv_punit_of_is_contr _ (is_contr_loop X)
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definition loop_punit : Ω punit ≃* punit :=
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loop_pequiv_punit_of_is_set punit
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definition add_point_functor' [unfold 4] {A B : Type} (e : A → B) (a : A₊) : B₊ :=
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begin induction a with a, exact none, exact some (e a) end
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definition add_point_functor [constructor] {A B : Type} (e : A → B) : A₊ →* B₊ :=
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pmap.mk (add_point_functor' e) idp
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definition add_point_functor_compose {A B C : Type} (f : B → C) (e : A → B) :
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add_point_functor (f ∘ e) ~* add_point_functor f ∘* add_point_functor e :=
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begin
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fapply phomotopy.mk,
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{ intro x, induction x: reflexivity },
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reflexivity
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end
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definition add_point_functor_id (A : Type) :
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add_point_functor id ~* pid A₊ :=
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begin
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fapply phomotopy.mk,
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{ intro x, induction x: reflexivity },
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reflexivity
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end
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definition add_point_functor_phomotopy {A B : Type} {e e' : A → B} (p : e ~ e') :
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add_point_functor e ~* add_point_functor e' :=
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begin
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fapply phomotopy.mk,
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{ intro x, induction x with a, reflexivity, exact ap some (p a) },
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reflexivity
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end
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definition add_point_pequiv {A B : Type} (e : A ≃ B) : A₊ ≃* B₊ :=
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pequiv.MK (add_point_functor e) (add_point_functor e⁻¹ᵉ)
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abstract !add_point_functor_compose⁻¹* ⬝* add_point_functor_phomotopy (left_inv e) ⬝*
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!add_point_functor_id end
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abstract !add_point_functor_compose⁻¹* ⬝* add_point_functor_phomotopy (right_inv e) ⬝*
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!add_point_functor_id end
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definition add_point_over [unfold 3] {A : Type} (B : A → Type*) : A₊ → Type*
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| (some a) := B a
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| none := plift punit
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definition add_point_over_pequiv {A : Type} {B B' : A → Type*} (e : Πa, B a ≃* B' a) :
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Π(a : A₊), add_point_over B a ≃* add_point_over B' a
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| (some a) := e a
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| none := pequiv.rfl
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definition phomotopy_group_plift_punit.{u} (n : ℕ) [H : is_at_least_two n] :
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πag[n] (plift.{0 u} punit) ≃g trivial_ab_group_lift.{u} :=
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begin
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induction H with n,
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have H : 0 <[ℕ] n+2, from !zero_lt_succ,
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have is_set unit, from _,
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have is_trunc (trunc_index.of_nat 0) punit, from this,
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exact isomorphism_of_is_contr (@trivial_homotopy_group_of_is_trunc _ _ _ !is_trunc_lift H)
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!is_trunc_lift
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end
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definition pmap_of_map_pt [constructor] {A : Type*} {B : Type} (f : A → B) :
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A →* pointed.MK B (f pt) :=
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pmap.mk f idp
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/- TODO: computation rule -/
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open pi
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definition fiberwise_pointed_map_rec {A : Type} {B : A → Type*}
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(P : Π(C : A → Type*) (g : Πa, B a →* C a), Type)
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(H : Π(C : A → Type) (g : Πa, B a → C a), P _ (λa, pmap_of_map_pt (g a))) :
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Π⦃C : A → Type*⦄ (g : Πa, B a →* C a), P C g :=
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begin
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refine equiv_rect (!sigma_pi_equiv_pi_sigma ⬝e
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arrow_equiv_arrow_right A !pType.sigma_char⁻¹ᵉ) _ _,
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intro R, cases R with R r₀,
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refine equiv_rect (!sigma_pi_equiv_pi_sigma ⬝e
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pi_equiv_pi_right (λa, !pmap.sigma_char⁻¹ᵉ)) _ _,
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intro g, cases g with g g₀, esimp at (g, g₀),
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revert g₀, change (Π(g : (λa, g a (Point (B a))) ~ r₀), _),
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refine homotopy.rec_idp _ _, esimp,
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apply H
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end
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definition ap1_gen_idp_eq {A B : Type} (f : A → B) {a : A} (q : f a = f a) (r : q = idp) :
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ap1_gen_idp f q = ap (λx, ap1_gen f x x idp) r :=
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begin cases r, reflexivity end
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end pointed
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