lean2/hott/arity.hlean

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/-
Copyright (c) 2014 Floris van Doorn. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Floris van Doorn
Theorems about functions with multiple arguments
-/
variables {A U V W X Y Z : Type} {B : A → Type} {C : Πa, B a → Type} {D : Πa b, C a b → Type}
{E : Πa b c, D a b c → Type} {F : Πa b c d, E a b c d → Type}
{G : Πa b c d e, F a b c d e → Type} {H : Πa b c d e f, G a b c d e f → Type}
variables {a a' : A} {u u' : U} {v v' : V} {w w' : W} {x x' x'' : X} {y y' : Y} {z z' : Z}
{b : B a} {b' : B a'}
{c : C a b} {c' : C a' b'}
{d : D a b c} {d' : D a' b' c'}
{e : E a b c d} {e' : E a' b' c' d'}
{ff : F a b c d e} {f' : F a' b' c' d' e'}
{g : G a b c d e ff} {g' : G a' b' c' d' e' f'}
{h : H a b c d e ff g} {h' : H a' b' c' d' e' f' g'}
namespace eq
/-
Naming convention:
The theorem which states how to construct an path between two function applications is
api₀i₁...iₙ.
Here i₀, ... iₙ are digits, n is the arity of the function(s),
and iⱼ specifies the dimension of the path between the jᵗʰ argument
(i₀ specifies the dimension of the path between the functions).
A value iⱼ ≡ 0 means that the jᵗʰ arguments are definitionally equal
The functions are non-dependent, except when the theorem name contains trailing zeroes
(where the function is dependent only in the arguments where it doesn't result in any
transports in the theorem statement).
For the fully-dependent versions (except that the conclusion doesn't contain a transport)
we write
apdi₀i₁...iₙ.
For versions where only some arguments depend on some other arguments,
or for versions with transport in the conclusion (like apd), we don't have a
consistent naming scheme (yet).
We don't prove each theorem systematically, but prove only the ones which we actually need.
-/
definition homotopy2 [reducible] (f g : Πa b, C a b) : Type :=
Πa b, f a b = g a b
definition homotopy3 [reducible] (f g : Πa b c, D a b c) : Type :=
Πa b c, f a b c = g a b c
definition homotopy4 [reducible] (f g : Πa b c d, E a b c d) : Type :=
Πa b c d, f a b c d = g a b c d
notation f `~2`:50 g := homotopy2 f g
notation f `~3`:50 g := homotopy3 f g
definition ap011 (f : U → V → W) (Hu : u = u') (Hv : v = v') : f u v = f u' v' :=
by cases Hu; congruence; repeat assumption
definition ap0111 (f : U → V → W → X) (Hu : u = u') (Hv : v = v') (Hw : w = w')
: f u v w = f u' v' w' :=
by cases Hu; congruence; repeat assumption
definition ap01111 (f : U → V → W → X → Y) (Hu : u = u') (Hv : v = v') (Hw : w = w') (Hx : x = x')
: f u v w x = f u' v' w' x' :=
by cases Hu; congruence; repeat assumption
definition ap011111 (f : U → V → W → X → Y → Z)
(Hu : u = u') (Hv : v = v') (Hw : w = w') (Hx : x = x') (Hy : y = y')
: f u v w x y = f u' v' w' x' y' :=
by cases Hu; congruence; repeat assumption
definition ap0111111 (f : U → V → W → X → Y → Z → A)
(Hu : u = u') (Hv : v = v') (Hw : w = w') (Hx : x = x') (Hy : y = y') (Hz : z = z')
: f u v w x y z = f u' v' w' x' y' z' :=
by cases Hu; congruence; repeat assumption
definition ap010 (f : X → Πa, B a) (Hx : x = x') : f x ~ f x' :=
by intros; cases Hx; reflexivity
definition ap0100 (f : X → Πa b, C a b) (Hx : x = x') : f x ~2 f x' :=
by intros; cases Hx; reflexivity
definition ap01000 (f : X → Πa b c, D a b c) (Hx : x = x') : f x ~3 f x' :=
by intros; cases Hx; reflexivity
definition apd011 (f : Πa, B a → Z) (Ha : a = a') (Hb : transport B Ha b = b')
: f a b = f a' b' :=
by cases Ha; cases Hb; reflexivity
definition apd0111 (f : Πa b, C a b → Z) (Ha : a = a') (Hb : transport B Ha b = b')
(Hc : cast (apd011 C Ha Hb) c = c')
: f a b c = f a' b' c' :=
by cases Ha; cases Hb; cases Hc; reflexivity
definition apd01111 (f : Πa b c, D a b c → Z) (Ha : a = a') (Hb : transport B Ha b = b')
(Hc : cast (apd011 C Ha Hb) c = c') (Hd : cast (apd0111 D Ha Hb Hc) d = d')
: f a b c d = f a' b' c' d' :=
by cases Ha; cases Hb; cases Hc; cases Hd; reflexivity
definition apd011111 (f : Πa b c d, E a b c d → Z) (Ha : a = a') (Hb : transport B Ha b = b')
(Hc : cast (apd011 C Ha Hb) c = c') (Hd : cast (apd0111 D Ha Hb Hc) d = d')
(He : cast (apd01111 E Ha Hb Hc Hd) e = e')
: f a b c d e = f a' b' c' d' e' :=
by cases Ha; cases Hb; cases Hc; cases Hd; cases He; reflexivity
definition apd0111111 (f : Πa b c d e, F a b c d e → Z) (Ha : a = a') (Hb : transport B Ha b = b')
(Hc : cast (apd011 C Ha Hb) c = c') (Hd : cast (apd0111 D Ha Hb Hc) d = d')
(He : cast (apd01111 E Ha Hb Hc Hd) e = e') (Hf : cast (apd011111 F Ha Hb Hc Hd He) ff = f')
: f a b c d e ff = f a' b' c' d' e' f' :=
begin cases Ha, cases Hb, cases Hc, cases Hd, cases He, cases Hf, reflexivity end
-- definition apd0111111 (f : Πa b c d e ff, G a b c d e ff → Z) (Ha : a = a') (Hb : transport B Ha b = b')
-- (Hc : cast (apd011 C Ha Hb) c = c') (Hd : cast (apd0111 D Ha Hb Hc) d = d')
-- (He : cast (apd01111 E Ha Hb Hc Hd) e = e') (Hf : cast (apd011111 F Ha Hb Hc Hd He) ff = f')
-- (Hg : cast (apd0111111 G Ha Hb Hc Hd He Hf) g = g')
-- : f a b c d e ff g = f a' b' c' d' e' f' g' :=
-- by cases Ha; cases Hb; cases Hc; cases Hd; cases He; cases Hf; cases Hg; reflexivity
-- definition apd01111111 (f : Πa b c d e ff g, G a b c d e ff g → Z) (Ha : a = a') (Hb : transport B Ha b = b')
-- (Hc : cast (apd011 C Ha Hb) c = c') (Hd : cast (apd0111 D Ha Hb Hc) d = d')
-- (He : cast (apd01111 E Ha Hb Hc Hd) e = e') (Hf : cast (apd011111 F Ha Hb Hc Hd He) ff = f')
-- (Hg : cast (apd0111111 G Ha Hb Hc Hd He Hf) g = g') (Hh : cast (apd01111111 H Ha Hb Hc Hd He Hf Hg) h = h')
-- : f a b c d e ff g h = f a' b' c' d' e' f' g' h' :=
-- by cases Ha; cases Hb; cases Hc; cases Hd; cases He; cases Hf; cases Hg; cases Hh; reflexivity
definition apd100 [unfold-c 6] {f g : Πa b, C a b} (p : f = g) : f ~2 g :=
λa b, apd10 (apd10 p a) b
definition apd1000 [unfold-c 7] {f g : Πa b c, D a b c} (p : f = g) : f ~3 g :=
λa b c, apd100 (apd10 p a) b c
/- some properties of these variants of ap -/
-- we only prove what we currently need
definition ap010_con (f : X → Πa, B a) (p : x = x') (q : x' = x'') :
ap010 f (p ⬝ q) a = ap010 f p a ⬝ ap010 f q a :=
eq.rec_on q (eq.rec_on p idp)
definition ap010_ap (f : X → Πa, B a) (g : Y → X) (p : y = y') :
ap010 f (ap g p) a = ap010 (λy, f (g y)) p a :=
eq.rec_on p idp
/- the following theorems are function extentionality for functions with multiple arguments -/
definition eq_of_homotopy2 {f g : Πa b, C a b} (H : f ~2 g) : f = g :=
eq_of_homotopy (λa, eq_of_homotopy (H a))
definition eq_of_homotopy3 {f g : Πa b c, D a b c} (H : f ~3 g) : f = g :=
eq_of_homotopy (λa, eq_of_homotopy2 (H a))
definition eq_of_homotopy2_id (f : Πa b, C a b)
: eq_of_homotopy2 (λa b, idpath (f a b)) = idpath f :=
begin
transitivity eq_of_homotopy (λ a, idpath (f a)),
{apply (ap eq_of_homotopy), apply eq_of_homotopy, intros, apply eq_of_homotopy_idp},
apply eq_of_homotopy_idp
end
definition eq_of_homotopy3_id (f : Πa b c, D a b c)
: eq_of_homotopy3 (λa b c, idpath (f a b c)) = idpath f :=
begin
transitivity _,
{apply (ap eq_of_homotopy), apply eq_of_homotopy, intros, apply eq_of_homotopy2_id},
apply eq_of_homotopy_idp
end
definition eq_of_homotopy2_inv {f g : Πa b, C a b} (H : f ~2 g)
: eq_of_homotopy2 (λa b, (H a b)⁻¹) = (eq_of_homotopy2 H)⁻¹ :=
ap eq_of_homotopy (eq_of_homotopy (λa, !eq_of_homotopy_inv)) ⬝ !eq_of_homotopy_inv
definition eq_of_homotopy3_inv {f g : Πa b c, D a b c} (H : f ~3 g)
: eq_of_homotopy3 (λa b c, (H a b c)⁻¹) = (eq_of_homotopy3 H)⁻¹ :=
ap eq_of_homotopy (eq_of_homotopy (λa, !eq_of_homotopy2_inv)) ⬝ !eq_of_homotopy_inv
definition eq_of_homotopy2_con {f g h : Πa b, C a b} (H1 : f ~2 g) (H2 : g ~2 h)
: eq_of_homotopy2 (λa b, H1 a b ⬝ H2 a b) = eq_of_homotopy2 H1 ⬝ eq_of_homotopy2 H2 :=
ap eq_of_homotopy (eq_of_homotopy (λa, !eq_of_homotopy_con)) ⬝ !eq_of_homotopy_con
definition eq_of_homotopy3_con {f g h : Πa b c, D a b c} (H1 : f ~3 g) (H2 : g ~3 h)
: eq_of_homotopy3 (λa b c, H1 a b c ⬝ H2 a b c) = eq_of_homotopy3 H1 ⬝ eq_of_homotopy3 H2 :=
ap eq_of_homotopy (eq_of_homotopy (λa, !eq_of_homotopy2_con)) ⬝ !eq_of_homotopy_con
end eq
open eq is_equiv
namespace funext
definition is_equiv_apd100 [instance] (f g : Πa b, C a b) : is_equiv (@apd100 A B C f g) :=
adjointify _
eq_of_homotopy2
begin
intro H, esimp [apd100, eq_of_homotopy2, function.compose],
apply eq_of_homotopy, intro a,
apply concat, apply (ap (λx, apd10 (x a))), apply (right_inv apd10),
apply (right_inv apd10)
end
begin
intro p, cases p, apply eq_of_homotopy2_id
end
definition is_equiv_apd1000 [instance] (f g : Πa b c, D a b c)
: is_equiv (@apd1000 A B C D f g) :=
adjointify _
eq_of_homotopy3
begin
2015-06-10 22:45:46 +00:00
intro H, esimp,
apply eq_of_homotopy, intro a,
transitivity apd100 (eq_of_homotopy2 (H a)),
{apply ap (λx, apd100 (x a)),
apply right_inv apd10},
apply right_inv apd100
end
begin
intro p, cases p, apply eq_of_homotopy3_id
end
end funext
namespace eq
open funext
local attribute funext.is_equiv_apd100 [instance]
protected definition homotopy2.rec_on {f g : Πa b, C a b} {P : (f ~2 g) → Type}
(p : f ~2 g) (H : Π(q : f = g), P (apd100 q)) : P p :=
right_inv apd100 p ▸ H (eq_of_homotopy2 p)
protected definition homotopy3.rec_on {f g : Πa b c, D a b c} {P : (f ~3 g) → Type}
(p : f ~3 g) (H : Π(q : f = g), P (apd1000 q)) : P p :=
right_inv apd1000 p ▸ H (eq_of_homotopy3 p)
definition apd10_ap (f : X → Πa, B a) (p : x = x')
: apd10 (ap f p) = ap010 f p :=
eq.rec_on p idp
definition eq_of_homotopy_ap010 (f : X → Πa, B a) (p : x = x')
: eq_of_homotopy (ap010 f p) = ap f p :=
inv_eq_of_eq !apd10_ap⁻¹
definition ap_eq_ap_of_homotopy {f : X → Πa, B a} {p q : x = x'} (H : ap010 f p ~ ap010 f q)
: ap f p = ap f q :=
calc
ap f p = eq_of_homotopy (ap010 f p) : eq_of_homotopy_ap010
... = eq_of_homotopy (ap010 f q) : eq_of_homotopy H
... = ap f q : eq_of_homotopy_ap010
end eq