393 lines
15 KiB
Text
393 lines
15 KiB
Text
/-
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Copyright (c) 2015 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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Author: Floris van Doorn
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Theorems about sums/coproducts/disjoint unions
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-/
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import .pi .equiv logic
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open lift eq is_equiv equiv prod prod.ops is_trunc sigma bool
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namespace sum
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universe variables u v u' v'
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variables {A : Type.{u}} {B : Type.{v}} (z z' : A + B) {P : A → Type.{u'}} {Q : A → Type.{v'}}
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protected definition eta : sum.rec inl inr z = z :=
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by induction z; all_goals reflexivity
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protected definition code [unfold 3 4] : A + B → A + B → Type.{max u v}
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| code (inl a) (inl a') := lift (a = a')
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| code (inr b) (inr b') := lift (b = b')
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| code _ _ := lift empty
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protected definition decode [unfold 3 4] : Π(z z' : A + B), sum.code z z' → z = z'
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| decode (inl a) (inl a') := λc, ap inl (down c)
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| decode (inl a) (inr b') := λc, empty.elim (down c) _
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| decode (inr b) (inl a') := λc, empty.elim (down c) _
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| decode (inr b) (inr b') := λc, ap inr (down c)
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protected definition mem_cases : (Σ a, z = inl a) + (Σ b, z = inr b) :=
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by cases z with a b; exact inl ⟨a, idp⟩; exact inr ⟨b, idp⟩
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protected definition eqrec {A B : Type} {C : A + B → Type}
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(x : A + B) (cl : Π a, x = inl a → C (inl a)) (cr : Π b, x = inr b → C (inr b)) : C x :=
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by cases x with a b; exact cl a idp; exact cr b idp
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variables {z z'}
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protected definition encode [unfold 3 4 5] (p : z = z') : sum.code z z' :=
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by induction p; induction z; all_goals exact up idp
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variables (z z')
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definition sum_eq_equiv [constructor] : (z = z') ≃ sum.code z z' :=
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equiv.MK sum.encode
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!sum.decode
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abstract begin
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intro c, induction z with a b, all_goals induction z' with a' b',
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all_goals (esimp at *; induction c with c),
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all_goals induction c, -- c either has type empty or a path
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all_goals reflexivity
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end end
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abstract begin
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intro p, induction p, induction z, all_goals reflexivity
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end end
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section
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variables {a a' : A} {b b' : B}
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definition eq_of_inl_eq_inl [unfold 5] (p : inl a = inl a' :> A + B) : a = a' :=
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down (sum.encode p)
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definition eq_of_inr_eq_inr [unfold 5] (p : inr b = inr b' :> A + B) : b = b' :=
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down (sum.encode p)
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definition empty_of_inl_eq_inr (p : inl a = inr b) : empty := down (sum.encode p)
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definition empty_of_inr_eq_inl (p : inr b = inl a) : empty := down (sum.encode p)
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/- Transport -/
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definition sum_transport (p : a = a') (z : P a + Q a)
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: p ▸ z = sum.rec (λa, inl (p ▸ a)) (λb, inr (p ▸ b)) z :=
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by induction p; induction z; all_goals reflexivity
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/- Pathovers -/
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definition etao (p : a = a') (z : P a + Q a)
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: z =[p] sum.rec (λa, inl (p ▸ a)) (λb, inr (p ▸ b)) z :=
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by induction p; induction z; all_goals constructor
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protected definition codeo (p : a = a') : P a + Q a → P a' + Q a' → Type.{max u' v'}
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| codeo (inl x) (inl x') := lift.{u' v'} (x =[p] x')
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| codeo (inr y) (inr y') := lift.{v' u'} (y =[p] y')
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| codeo _ _ := lift empty
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protected definition decodeo (p : a = a') : Π(z : P a + Q a) (z' : P a' + Q a'),
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sum.codeo p z z' → z =[p] z'
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| decodeo (inl x) (inl x') := λc, apo (λa, inl) (down c)
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| decodeo (inl x) (inr y') := λc, empty.elim (down c) _
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| decodeo (inr y) (inl x') := λc, empty.elim (down c) _
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| decodeo (inr y) (inr y') := λc, apo (λa, inr) (down c)
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variables {z z'}
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protected definition encodeo {p : a = a'} {z : P a + Q a} {z' : P a' + Q a'} (q : z =[p] z')
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: sum.codeo p z z' :=
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by induction q; induction z; all_goals exact up idpo
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variables (z z')
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definition sum_pathover_equiv [constructor] (p : a = a') (z : P a + Q a) (z' : P a' + Q a')
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: (z =[p] z') ≃ sum.codeo p z z' :=
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equiv.MK sum.encodeo
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!sum.decodeo
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abstract begin
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intro c, induction z with a b, all_goals induction z' with a' b',
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all_goals (esimp at *; induction c with c),
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all_goals induction c, -- c either has type empty or a pathover
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all_goals reflexivity
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end end
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abstract begin
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intro q, induction q, induction z, all_goals reflexivity
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end end
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end
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/- Functorial action -/
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variables {A' B' : Type} (f : A → A') (g : B → B')
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definition sum_functor [unfold 7] : A + B → A' + B'
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| sum_functor (inl a) := inl (f a)
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| sum_functor (inr b) := inr (g b)
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/- Equivalences -/
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definition is_equiv_sum_functor [constructor] [Hf : is_equiv f] [Hg : is_equiv g]
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: is_equiv (sum_functor f g) :=
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adjointify (sum_functor f g)
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(sum_functor f⁻¹ g⁻¹)
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abstract begin
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intro z, induction z,
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all_goals (esimp; (apply ap inl | apply ap inr); apply right_inv)
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end end
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abstract begin
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intro z, induction z,
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all_goals (esimp; (apply ap inl | apply ap inr); apply right_inv)
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end end
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definition sum_equiv_sum_of_is_equiv [constructor] [Hf : is_equiv f] [Hg : is_equiv g]
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: A + B ≃ A' + B' :=
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equiv.mk _ (is_equiv_sum_functor f g)
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definition sum_equiv_sum [constructor] (f : A ≃ A') (g : B ≃ B') : A + B ≃ A' + B' :=
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equiv.mk _ (is_equiv_sum_functor f g)
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definition sum_equiv_sum_left [constructor] (g : B ≃ B') : A + B ≃ A + B' :=
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sum_equiv_sum equiv.rfl g
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definition sum_equiv_sum_right [constructor] (f : A ≃ A') : A + B ≃ A' + B :=
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sum_equiv_sum f equiv.rfl
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definition flip [unfold 3] : A + B → B + A
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| flip (inl a) := inr a
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| flip (inr b) := inl b
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definition sum_comm_equiv [constructor] (A B : Type) : A + B ≃ B + A :=
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begin
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fapply equiv.MK,
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exact flip,
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exact flip,
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all_goals (intro z; induction z; all_goals reflexivity)
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end
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definition sum_assoc_equiv [constructor] (A B C : Type) : A + (B + C) ≃ (A + B) + C :=
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begin
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fapply equiv.MK,
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all_goals try (intro z; induction z with u v;
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all_goals try induction u; all_goals try induction v),
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exact inl (inl u),
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exact inl (inr a),
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exact inr a,
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exact inl a,
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exact inr (inl a),
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exact inr (inr v),
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all_goals reflexivity
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end
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definition sum_empty_equiv [constructor] (A : Type) : A + empty ≃ A :=
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begin
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fapply equiv.MK,
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{ intro z, induction z, assumption, contradiction},
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{ exact inl},
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{ intro a, reflexivity},
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{ intro z, induction z, reflexivity, contradiction}
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end
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definition empty_sum_equiv [constructor] (A : Type) : empty + A ≃ A :=
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!sum_comm_equiv ⬝e !sum_empty_equiv
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definition bool_equiv_unit_sum_unit [constructor] : bool ≃ unit + unit :=
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begin
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fapply equiv.MK,
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{ intro b, cases b, exact inl unit.star, exact inr unit.star },
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{ intro s, cases s, exact bool.ff, exact bool.tt },
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{ intro s, cases s, do 2 (cases a; reflexivity) },
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{ intro b, cases b, do 2 reflexivity },
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end
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definition sum_prod_right_distrib [constructor] (A B C : Type) :
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(A + B) × C ≃ (A × C) + (B × C) :=
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begin
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fapply equiv.MK,
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{ intro x, cases x with ab c, cases ab with a b, exact inl (a, c), exact inr (b, c) },
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{ intro x, cases x with ac bc, cases ac with a c, exact (inl a, c),
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cases bc with b c, exact (inr b, c) },
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{ intro x, cases x with ac bc, cases ac with a c, reflexivity, cases bc, reflexivity },
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{ intro x, cases x with ab c, cases ab with a b, do 2 reflexivity }
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end
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definition sum_prod_left_distrib [constructor] (A B C : Type) :
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A × (B + C) ≃ (A × B) + (A × C) :=
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calc A × (B + C) ≃ (B + C) × A : prod_comm_equiv
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... ≃ (B × A) + (C × A) : sum_prod_right_distrib
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... ≃ (A × B) + (C × A) : sum_equiv_sum_right !prod_comm_equiv
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... ≃ (A × B) + (A × C) : sum_equiv_sum_left !prod_comm_equiv
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section
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variables (H : unit + A ≃ unit + B)
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include H
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open unit decidable sigma.ops
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definition unit_sum_equiv_cancel_map : A → B :=
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begin
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intro a, cases sum.mem_cases (H (inr a)) with u b, rotate 1, exact b.1,
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cases u with u Hu, cases sum.mem_cases (H (inl ⋆)) with u' b, rotate 1, exact b.1,
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cases u' with u' Hu', exfalso, apply empty_of_inl_eq_inr,
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calc inl ⋆ = H⁻¹ (H (inl ⋆)) : (to_left_inv H (inl ⋆))⁻¹
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... = H⁻¹ (inl u') : {Hu'}
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... = H⁻¹ (inl u) : is_prop.elim
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... = H⁻¹ (H (inr a)) : {Hu⁻¹}
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... = inr a : to_left_inv H (inr a)
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end
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definition unit_sum_equiv_cancel_inv (b : B) :
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unit_sum_equiv_cancel_map H (unit_sum_equiv_cancel_map H⁻¹ᵉ b) = b :=
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begin
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esimp[unit_sum_equiv_cancel_map], apply sum.rec,
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{ intro x, cases x with u Hu, esimp, apply sum.rec,
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{ intro x, exfalso, cases x with u' Hu', apply empty_of_inl_eq_inr,
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calc inl ⋆ = H⁻¹ (H (inl ⋆)) : (to_left_inv H (inl ⋆))⁻¹
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... = H⁻¹ (inl u') : ap H⁻¹ Hu'
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... = H⁻¹ (inl u) : {!is_prop.elim}
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... = H⁻¹ (H (inr _)) : {Hu⁻¹}
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... = inr _ : to_left_inv H },
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{ intro x, cases x with b' Hb', esimp, cases sum.mem_cases (H⁻¹ (inr b)) with x x,
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{ cases x with u' Hu', cases u', apply eq_of_inr_eq_inr,
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calc inr b' = H (inl ⋆) : Hb'⁻¹
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... = H (H⁻¹ (inr b)) : (ap H Hu')⁻¹
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... = inr b : to_right_inv H (inr b)},
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{ exfalso, cases x with a Ha, apply empty_of_inl_eq_inr,
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cases u, apply concat, apply Hu⁻¹, apply concat, rotate 1, apply !(to_right_inv H),
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apply ap H,
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apply concat, rotate 1, apply Ha⁻¹, apply ap inr, esimp,
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apply sum.rec, intro x, exfalso, apply empty_of_inl_eq_inr,
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apply concat, exact x.2⁻¹, apply Ha,
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intro x, cases x with a' Ha', esimp, apply eq_of_inr_eq_inr, apply Ha'⁻¹ ⬝ Ha } } },
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{ intro x, cases x with b' Hb', esimp, apply eq_of_inr_eq_inr, refine Hb'⁻¹ ⬝ _,
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cases sum.mem_cases (H⁻¹ (inr b)) with x x,
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{ cases x with u Hu, esimp, cases sum.mem_cases (H⁻¹ (inl ⋆)) with x x,
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{ cases x with u' Hu', exfalso, apply empty_of_inl_eq_inr,
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calc inl ⋆ = H (H⁻¹ (inl ⋆)) : (to_right_inv H (inl ⋆))⁻¹
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... = H (inl u') : ap H Hu'
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... = H (inl u) : by rewrite [is_prop.elim u' u]
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... = H (H⁻¹ (inr b)) : ap H Hu⁻¹
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... = inr b : to_right_inv H (inr b) },
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{ cases x with a Ha, exfalso, apply empty_of_inl_eq_inr,
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apply concat, rotate 1, exact Hb',
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have Ha' : inl ⋆ = H (inr a), by apply !(to_right_inv H)⁻¹ ⬝ ap H Ha,
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apply concat Ha', apply ap H, apply ap inr, apply sum.rec,
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intro x, cases x with u' Hu', esimp, apply sum.rec,
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intro x, cases x with u'' Hu'', esimp, apply empty.rec,
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intro x, cases x with a'' Ha'', esimp, krewrite Ha' at Ha'', apply eq_of_inr_eq_inr,
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apply !(to_left_inv H)⁻¹ ⬝ Ha'',
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intro x, exfalso, cases x with a'' Ha'', apply empty_of_inl_eq_inr,
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apply Hu⁻¹ ⬝ Ha'', } },
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{ cases x with a' Ha', esimp, refine _ ⬝ !(to_right_inv H), apply ap H,
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apply Ha'⁻¹ } }
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end
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definition unit_sum_equiv_cancel : A ≃ B :=
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begin
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fapply equiv.MK, apply unit_sum_equiv_cancel_map H,
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apply unit_sum_equiv_cancel_map H⁻¹ᵉ,
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intro b, apply unit_sum_equiv_cancel_inv,
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{ intro a, have H = (H⁻¹ᵉ)⁻¹ᵉ, from !equiv.symm_symm⁻¹, rewrite this at {2},
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apply unit_sum_equiv_cancel_inv }
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end
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end
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/- universal property -/
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definition sum_rec_unc [unfold 5] {P : A + B → Type} (fg : (Πa, P (inl a)) × (Πb, P (inr b)))
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: Πz, P z :=
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sum.rec fg.1 fg.2
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definition is_equiv_sum_rec [constructor] (P : A + B → Type)
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: is_equiv (sum_rec_unc : (Πa, P (inl a)) × (Πb, P (inr b)) → Πz, P z) :=
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begin
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apply adjointify sum_rec_unc (λf, (λa, f (inl a), λb, f (inr b))),
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intro f, apply eq_of_homotopy, intro z, focus (induction z; all_goals reflexivity),
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intro h, induction h with f g, reflexivity
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end
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definition equiv_sum_rec [constructor] (P : A + B → Type)
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: (Πa, P (inl a)) × (Πb, P (inr b)) ≃ Πz, P z :=
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equiv.mk _ !is_equiv_sum_rec
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definition imp_prod_imp_equiv_sum_imp [constructor] (A B C : Type)
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: (A → C) × (B → C) ≃ (A + B → C) :=
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!equiv_sum_rec
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/- truncatedness -/
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variables (A B)
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theorem is_trunc_sum (n : trunc_index) [HA : is_trunc (n.+2) A] [HB : is_trunc (n.+2) B]
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: is_trunc (n.+2) (A + B) :=
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begin
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apply is_trunc_succ_intro, intro z z',
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apply is_trunc_equiv_closed_rev, apply sum_eq_equiv,
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induction z with a b, all_goals induction z' with a' b', all_goals esimp,
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all_goals exact _,
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end
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theorem is_trunc_sum_excluded (n : trunc_index) [HA : is_trunc n A] [HB : is_trunc n B]
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(H : A → B → empty) : is_trunc n (A + B) :=
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begin
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induction n with n IH,
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{ exfalso, exact H !center !center},
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{ clear IH, induction n with n IH,
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{ apply is_prop.mk, intros x y,
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induction x, all_goals induction y, all_goals esimp,
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all_goals try (exfalso;apply H;assumption;assumption), all_goals apply ap _ !is_prop.elim},
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{ apply is_trunc_sum}}
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end
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variable {B}
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definition is_contr_sum_left [HA : is_contr A] (H : ¬B) : is_contr (A + B) :=
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is_contr.mk (inl !center)
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(λx, sum.rec_on x (λa, ap inl !center_eq) (λb, empty.elim (H b)))
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/-
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Sums are equivalent to dependent sigmas where the first component is a bool.
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The current construction only works for A and B in the same universe.
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If we need it for A and B in different universes, we need to insert some lifts.
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-/
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definition sum_of_sigma_bool {A B : Type.{u}} (v : Σ(b : bool), bool.rec A B b) : A + B :=
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by induction v with b x; induction b; exact inl x; exact inr x
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definition sigma_bool_of_sum {A B : Type.{u}} (z : A + B) : Σ(b : bool), bool.rec A B b :=
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by induction z with a b; exact ⟨ff, a⟩; exact ⟨tt, b⟩
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definition sum_equiv_sigma_bool [constructor] (A B : Type.{u})
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: A + B ≃ Σ(b : bool), bool.rec A B b :=
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equiv.MK sigma_bool_of_sum
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sum_of_sigma_bool
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begin intro v, induction v with b x, induction b, all_goals reflexivity end
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begin intro z, induction z with a b, all_goals reflexivity end
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/- pointed sums. We arbitrarily choose (inl pt) as basepoint for the sum -/
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open pointed
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definition psum [constructor] (A B : Type*) : Type* :=
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pointed.MK (A ⊎ B) (inl pt)
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infixr ` +* `:30 := psum
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end sum
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open sum pi
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namespace decidable
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definition decidable_equiv [constructor] (A : Type) : decidable A ≃ A + ¬A :=
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begin
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fapply equiv.MK:intro a;induction a:try (constructor;assumption;now),
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all_goals reflexivity
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end
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definition is_trunc_decidable [constructor] (A : Type) (n : trunc_index) [H : is_trunc n A] :
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is_trunc n (decidable A) :=
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begin
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apply is_trunc_equiv_closed_rev,
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apply decidable_equiv,
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induction n with n IH,
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{ apply is_contr_sum_left, exact λna, na !center},
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{ apply is_trunc_sum_excluded, exact λa na, na a}
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end
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end decidable
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attribute sum.is_trunc_sum [instance] [priority 1480]
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definition tsum [constructor] {n : trunc_index} (A B : (n.+2)-Type) : (n.+2)-Type :=
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trunctype.mk (A + B) _
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infixr `+t`:25 := tsum
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