204 lines
8 KiB
Text
204 lines
8 KiB
Text
/-
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Copyright (c) 2014 Floris van Doorn. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Module: init.path
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Author: Floris van Doorn
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Theorems about functions with multiple arguments
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-/
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variables {A U V W X Y Z : Type} {B : A → Type} {C : Πa, B a → Type} {D : Πa b, C a b → Type}
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{E : Πa b c, D a b c → Type}
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variables {a a' : A} {u u' : U} {v v' : V} {w w' : W} {x x' x'' : X} {y y' : Y} {z z' : Z}
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{b : B a} {b' : B a'}
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{c : C a b} {c' : C a' b'}
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{d : D a b c} {d' : D a' b' c'}
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{e : E a b c d} {e' : E a' b' c' d'}
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namespace eq
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/-
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Naming convention:
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The theorem which states how to construct an path between two function applications is
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api₀i₁...iₙ.
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Here i₀, ... iₙ are digits, n is the arity of the function(s),
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and iⱼ specifies the dimension of the path between the jᵗʰ argument
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(i₀ specifies the dimension of the path between the functions).
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A value iⱼ ≡ 0 means that the jᵗʰ arguments are definitionally equal
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The functions are non-dependent, except when the theorem name contains trailing zeroes
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(where the function is dependent only in the arguments where it doesn't result in any
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transports in the theorem statement).
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For the fully-dependent versions (except that the conclusion doesn't contain a transport)
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we write
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apdi₀i₁...iₙ.
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For versions where only some arguments depend on some other arguments,
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or for versions with transport in the conclusion (like apd), we don't have a
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consistent naming scheme (yet).
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We don't prove each theorem systematically, but prove only the ones which we actually need.
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-/
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definition homotopy2 [reducible] (f g : Πa b, C a b) : Type :=
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Πa b, f a b = g a b
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definition homotopy3 [reducible] (f g : Πa b c, D a b c) : Type :=
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Πa b c, f a b c = g a b c
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definition homotopy4 [reducible] (f g : Πa b c d, E a b c d) : Type :=
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Πa b c d, f a b c d = g a b c d
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notation f `∼2`:50 g := homotopy2 f g
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notation f `∼3`:50 g := homotopy3 f g
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definition ap011 (f : U → V → W) (Hu : u = u') (Hv : v = v') : f u v = f u' v' :=
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by cases Hu; congruence; repeat assumption
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definition ap0111 (f : U → V → W → X) (Hu : u = u') (Hv : v = v') (Hw : w = w')
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: f u v w = f u' v' w' :=
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by cases Hu; congruence; repeat assumption
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definition ap01111 (f : U → V → W → X → Y) (Hu : u = u') (Hv : v = v') (Hw : w = w') (Hx : x = x')
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: f u v w x = f u' v' w' x' :=
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by cases Hu; congruence; repeat assumption
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definition ap011111 (f : U → V → W → X → Y → Z)
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(Hu : u = u') (Hv : v = v') (Hw : w = w') (Hx : x = x') (Hy : y = y')
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: f u v w x y = f u' v' w' x' y' :=
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by cases Hu; congruence; repeat assumption
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definition ap0111111 (f : U → V → W → X → Y → Z → A)
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(Hu : u = u') (Hv : v = v') (Hw : w = w') (Hx : x = x') (Hy : y = y') (Hz : z = z')
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: f u v w x y z = f u' v' w' x' y' z' :=
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by cases Hu; congruence; repeat assumption
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definition ap010 (f : X → Πa, B a) (Hx : x = x') : f x ∼ f x' :=
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by intros; cases Hx; reflexivity
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definition ap0100 (f : X → Πa b, C a b) (Hx : x = x') : f x ∼2 f x' :=
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by intros; cases Hx; reflexivity
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definition ap01000 (f : X → Πa b c, D a b c) (Hx : x = x') : f x ∼3 f x' :=
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by intros; cases Hx; reflexivity
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definition apd011 (f : Πa, B a → Z) (Ha : a = a') (Hb : (Ha ▸ b) = b')
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: f a b = f a' b' :=
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by cases Ha; cases Hb; reflexivity
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definition apd0111 (f : Πa b, C a b → Z) (Ha : a = a') (Hb : (Ha ▸ b) = b')
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(Hc : apd011 C Ha Hb ▸ c = c')
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: f a b c = f a' b' c' :=
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by cases Ha; cases Hb; cases Hc; reflexivity
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definition apd01111 (f : Πa b c, D a b c → Z) (Ha : a = a') (Hb : (Ha ▸ b) = b')
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(Hc : apd011 C Ha Hb ▸ c = c') (Hd : apd0111 D Ha Hb Hc ▸ d = d')
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: f a b c d = f a' b' c' d' :=
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by cases Ha; cases Hb; cases Hc; cases Hd; reflexivity
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definition apd011111 (f : Πa b c d, E a b c d → Z) (Ha : a = a') (Hb : (Ha ▸ b) = b')
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(Hc : apd011 C Ha Hb ▸ c = c') (Hd : apd0111 D Ha Hb Hc ▸ d = d')
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(He : apd01111 E Ha Hb Hc Hd ▸ e = e')
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: f a b c d e = f a' b' c' d' e' :=
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by cases Ha; cases Hb; cases Hc; cases Hd; cases He; reflexivity
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definition apd100 {f g : Πa b, C a b} (p : f = g) : f ∼2 g :=
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λa b, apd10 (apd10 p a) b
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definition apd1000 {f g : Πa b c, D a b c} (p : f = g) : f ∼3 g :=
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λa b c, apd100 (apd10 p a) b c
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/- some properties of these variants of ap -/
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-- we only prove what is needed somewhere
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definition ap010_con (f : X → Πa, B a) (p : x = x') (q : x' = x'') :
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ap010 f (p ⬝ q) a = ap010 f p a ⬝ ap010 f q a :=
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eq.rec_on q (eq.rec_on p idp)
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definition ap010_ap (f : X → Πa, B a) (g : Y → X) (p : y = y') :
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ap010 f (ap g p) a = ap010 (λy, f (g y)) p a :=
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eq.rec_on p idp
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/- the following theorems are function extentionality for functions with multiple arguments -/
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definition eq_of_homotopy2 {f g : Πa b, C a b} (H : f ∼2 g) : f = g :=
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eq_of_homotopy (λa, eq_of_homotopy (H a))
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definition eq_of_homotopy3 {f g : Πa b c, D a b c} (H : f ∼3 g) : f = g :=
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eq_of_homotopy (λa, eq_of_homotopy2 (H a))
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definition eq_of_homotopy2_id (f : Πa b, C a b)
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: eq_of_homotopy2 (λa b, idpath (f a b)) = idpath f :=
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begin
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transitivity eq_of_homotopy (λ a, idpath (f a)),
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{apply (ap eq_of_homotopy), apply eq_of_homotopy, intros, apply eq_of_homotopy_idp},
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apply eq_of_homotopy_idp
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end
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definition eq_of_homotopy3_id (f : Πa b c, D a b c)
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: eq_of_homotopy3 (λa b c, idpath (f a b c)) = idpath f :=
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begin
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transitivity _,
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{apply (ap eq_of_homotopy), apply eq_of_homotopy, intros, apply eq_of_homotopy2_id},
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apply eq_of_homotopy_idp
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end
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end eq
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open eq is_equiv
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namespace funext
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definition is_equiv_apd100 [instance] (f g : Πa b, C a b) : is_equiv (@apd100 A B C f g) :=
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adjointify _
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eq_of_homotopy2
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begin
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intro H, esimp [apd100, eq_of_homotopy2, function.compose],
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apply eq_of_homotopy, intro a,
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apply concat, apply (ap (λx, apd10 (x a))), apply (right_inv apd10),
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apply (right_inv apd10)
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end
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begin
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intro p, cases p, apply eq_of_homotopy2_id
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end
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definition is_equiv_apd1000 [instance] (f g : Πa b c, D a b c)
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: is_equiv (@apd1000 A B C D f g) :=
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adjointify _
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eq_of_homotopy3
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begin
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intro H, apply eq_of_homotopy, intro a,
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apply concat,
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{apply (ap (λx, @apd100 _ _ (λ(b : B a)(c : C a b), _) _ _ (x a))),
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apply (right_inv apd10)},
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--TODO: remove implicit argument after #469 is closed
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apply (@right_inv _ _ apd100 !is_equiv_apd100) --is explicit argument needed here?
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end
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begin
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intro p, cases p, apply eq_of_homotopy3_id
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end
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end funext
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namespace eq
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open funext
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local attribute funext.is_equiv_apd100 [instance]
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protected definition homotopy2.rec_on {f g : Πa b, C a b} {P : (f ∼2 g) → Type}
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(p : f ∼2 g) (H : Π(q : f = g), P (apd100 q)) : P p :=
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right_inv apd100 p ▸ H (eq_of_homotopy2 p)
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protected definition homotopy3.rec_on {f g : Πa b c, D a b c} {P : (f ∼3 g) → Type}
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(p : f ∼3 g) (H : Π(q : f = g), P (apd1000 q)) : P p :=
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right_inv apd1000 p ▸ H (eq_of_homotopy3 p)
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definition apd10_ap (f : X → Πa, B a) (p : x = x')
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: apd10 (ap f p) = ap010 f p :=
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eq.rec_on p idp
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definition eq_of_homotopy_ap010 (f : X → Πa, B a) (p : x = x')
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: eq_of_homotopy (ap010 f p) = ap f p :=
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inv_eq_of_eq !apd10_ap⁻¹
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definition ap_eq_ap_of_homotopy {f : X → Πa, B a} {p q : x = x'} (H : ap010 f p ∼ ap010 f q)
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: ap f p = ap f q :=
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calc
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ap f p = eq_of_homotopy (ap010 f p) : eq_of_homotopy_ap010
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... = eq_of_homotopy (ap010 f q) : eq_of_homotopy H
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... = ap f q : eq_of_homotopy_ap010
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end eq
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