2015-04-19 21:18:49 +00:00
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/-
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Copyright (c) 2015 Microsoft Corporation. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Module: data.encodable
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Author: Leonardo de Moura
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Type class for encodable types.
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Note that every encodable type is countable.
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-/
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import data.fintype data.list data.sum data.nat data.subtype data.countable
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open option list nat function
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structure encodable [class] (A : Type) :=
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(encode : A → nat) (decode : nat → option A) (encodek : ∀ a, decode (encode a) = some a)
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open encodable
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definition countable_of_encodable {A : Type} : encodable A → countable A :=
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assume e : encodable A,
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have inj_encode : injective encode, from
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λ (a₁ a₂ : A) (h : encode a₁ = encode a₂),
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assert aux : decode A (encode a₁) = decode A (encode a₂), by rewrite h,
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2015-05-02 01:18:29 +00:00
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by rewrite [*encodek at aux]; injection aux; assumption,
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2015-04-19 21:18:49 +00:00
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exists.intro encode inj_encode
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definition encodable_fintype [instance] {A : Type} [h₁ : fintype A] [h₂ : decidable_eq A] : encodable A :=
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encodable.mk
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(λ a, find a (elements_of A))
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(λ n, nth (elements_of A) n)
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(λ a, find_nth (fintype.complete a))
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definition encodable_nat [instance] : encodable nat :=
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encodable.mk (λ a, a) (λ n, some n) (λ a, rfl)
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definition encodable_option [instance] {A : Type} [h : encodable A] : encodable (option A) :=
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encodable.mk
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(λ o, match o with
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| some a := succ (encode a)
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| none := 0
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end)
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(λ n, if n = 0 then some none else some (decode A (pred n)))
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(λ o,
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begin
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2015-04-30 18:00:39 +00:00
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cases o with a,
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2015-04-19 21:18:49 +00:00
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begin esimp end,
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begin esimp, rewrite [if_neg !succ_ne_zero, pred_succ, encodable.encodek] end
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end)
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section sum
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variables {A B : Type}
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variables [h₁ : encodable A] [h₂ : encodable B]
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include h₁ h₂
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definition encode_sum : sum A B → nat
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| (sum.inl a) := 2 * encode a
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| (sum.inr b) := 2 * encode b + 1
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definition decode_sum (n : nat) : option (sum A B) :=
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if n mod 2 = 0 then
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match decode A (n div 2) with
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| some a := some (sum.inl a)
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| none := none
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end
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else
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match decode B ((n - 1) div 2) with
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| some b := some (sum.inr b)
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| none := none
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end
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open decidable
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theorem decode_encode_sum : ∀ s : sum A B, decode_sum (encode_sum s) = some s
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| (sum.inl a) :=
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assert aux : 2 > 0, from dec_trivial,
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begin
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esimp [encode_sum, decode_sum],
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rewrite [mul_mod_right, if_pos (eq.refl 0), mul_div_cancel_left _ aux, encodable.encodek]
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end
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| (sum.inr b) :=
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assert aux₁ : 2 > 0, from dec_trivial,
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assert aux₂ : 1 mod 2 = 1, by rewrite [modulo_def],
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assert aux₃ : 1 ≠ 0, from dec_trivial,
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begin
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esimp [encode_sum, decode_sum],
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rewrite [add.comm, add_mul_mod_self_left aux₁, aux₂, if_neg aux₃, add_sub_cancel_left,
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mul_div_cancel_left _ aux₁, encodable.encodek]
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end
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definition encodable_sum [instance] : encodable (sum A B) :=
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encodable.mk
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(λ s, encode_sum s)
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(λ n, decode_sum n)
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(λ s, decode_encode_sum s)
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end sum
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section prod
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variables {A B : Type}
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variables [h₁ : encodable A] [h₂ : encodable B]
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include h₁ h₂
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definition encode_prod : A × B → nat
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| (a, b) := mkpair (encode a) (encode b)
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definition decode_prod (n : nat) : option (A × B) :=
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match unpair n with
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| (n₁, n₂) :=
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match decode A n₁ with
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| some a :=
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match decode B n₂ with
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| some b := some (a, b)
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| none := none
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end
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| none := none
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end
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end
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theorem decode_encode_prod : ∀ p : A × B, decode_prod (encode_prod p) = some p
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| (a, b) :=
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begin
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esimp [encode_prod, decode_prod, prod.cases_on],
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rewrite [unpair_mkpair],
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esimp,
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rewrite [*encodable.encodek]
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end
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definition encodable_product [instance] : encodable (A × B) :=
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encodable.mk
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encode_prod
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decode_prod
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decode_encode_prod
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end prod
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section list
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variables {A : Type}
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variables [h : encodable A]
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include h
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definition encode_list_core : list A → nat
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| [] := 0
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| (a::l) := mkpair (encode a) (encode_list_core l)
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theorem encode_list_core_cons (a : A) (l : list A) : encode_list_core (a::l) = mkpair (encode a) (encode_list_core l) :=
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rfl
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definition encode_list (l : list A) : nat :=
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mkpair (length l) (encode_list_core l)
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definition decode_list_core : nat → nat → option (list A)
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| 0 v := some []
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| (succ n) v :=
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match unpair v with
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| (v₁, v₂) :=
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match decode A v₁ with
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| some a :=
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match decode_list_core n v₂ with
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| some l := some (a::l)
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| none := none
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end
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| none := none
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end
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end
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theorem decode_list_core_succ (n v : nat) :
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decode_list_core (succ n) v =
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match unpair v with
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| (v₁, v₂) :=
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match decode A v₁ with
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| some a :=
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match decode_list_core n v₂ with
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| some l := some (a::l)
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| none := none
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end
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| none := none
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end
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end
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:= rfl
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definition decode_list (n : nat) : option (list A) :=
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match unpair n with
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| (l, v) := decode_list_core l v
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end
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theorem decode_encode_list_core : ∀ l : list A, decode_list_core (length l) (encode_list_core l) = some l
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| [] := rfl
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| (a::l) :=
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begin
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rewrite [encode_list_core_cons, length_cons, add_one (length l), decode_list_core_succ],
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rewrite [unpair_mkpair],
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esimp [prod.cases_on],
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rewrite [decode_encode_list_core l],
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rewrite [encodable.encodek],
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end
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theorem decode_encode_list (l : list A) : decode_list (encode_list l) = some l :=
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begin
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esimp [encode_list, decode_list],
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rewrite [unpair_mkpair],
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esimp [prod.cases_on],
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apply decode_encode_list_core
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end
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definition encodable_list [instance] : encodable (list A) :=
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encodable.mk
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encode_list
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decode_list
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decode_encode_list
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end list
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definition encodable_of_left_injection
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{A B : Type} [h₁ : encodable A]
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(f : B → A) (finv : A → option B) (linv : ∀ b, finv (f b) = some b) : encodable B :=
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encodable.mk
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(λ b, encode (f b))
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(λ n,
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match decode A n with
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| some a := finv a
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| none := none
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end)
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(λ b,
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begin
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esimp,
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rewrite [encodable.encodek],
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esimp [option.cases_on],
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rewrite [linv]
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end)
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/-
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Choice function for encodable types and decidable predicates.
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We provide the following API
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choose {A : Type} {p : A → Prop} [c : encodable A] [d : decidable_pred p] : (∃ x, p x) → A :=
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choose_spec {A : Type} {p : A → Prop} [c : encodable A] [d : decidable_pred p] (ex : ∃ x, p x) : p (choose ex) :=
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-/
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section find_a
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parameters {A : Type} {p : A → Prop} [c : encodable A] [d : decidable_pred p]
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include c
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include d
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private definition pn (n : nat) : Prop :=
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match decode A n with
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| some a := p a
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| none := false
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end
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private definition decidable_pn : decidable_pred pn :=
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λ n,
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match decode A n with
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| some a := λ e : decode A n = some a,
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match d a with
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| decidable.inl t :=
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begin
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unfold pn, rewrite e, esimp [option.cases_on],
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exact (decidable.inl t)
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end
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| decidable.inr f :=
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begin
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unfold pn, rewrite e, esimp [option.cases_on],
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exact (decidable.inr f)
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end
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end
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| none := λ e : decode A n = none,
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begin
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unfold pn, rewrite e, esimp [option.cases_on],
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exact decidable_false
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end
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end (eq.refl (decode A n))
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private definition ex_pn_of_ex : (∃ x, p x) → (∃ x, pn x) :=
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assume ex,
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obtain (w : A) (pw : p w), from ex,
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exists.intro (encode w)
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begin
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unfold pn, rewrite [encodek], esimp, exact pw
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end
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2015-05-09 19:15:30 +00:00
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private lemma decode_ne_none_of_pn {n : nat} : pn n → decode A n ≠ none :=
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assume pnn e,
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begin
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rewrite [▸ (match decode A n with | some a := p a | none := false end) at pnn],
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rewrite [e at pnn], esimp [option.cases_on] at pnn,
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exact (false.elim pnn)
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end
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open subtype
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2015-04-26 06:10:48 +00:00
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private definition of_nat (n : nat) : pn n → { a : A | p a } :=
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match decode A n with
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| some a := λ (e : decode A n = some a),
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begin
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unfold pn, rewrite e, esimp [option.cases_on], intro pa,
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exact (tag a pa)
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end
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| none := λ (e : decode A n = none) h, absurd e (decode_ne_none_of_pn h)
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end (eq.refl (decode A n))
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private definition find_a : (∃ x, p x) → {a : A | p a} :=
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assume ex : ∃ x, p x,
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have exn : ∃ x, pn x, from ex_pn_of_ex ex,
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let r : nat := @nat.choose pn decidable_pn exn in
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have pnr : pn r, from @nat.choose_spec pn decidable_pn exn,
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of_nat r pnr
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end find_a
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namespace encodable
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open subtype
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definition choose {A : Type} {p : A → Prop} [c : encodable A] [d : decidable_pred p] : (∃ x, p x) → A :=
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assume ex, elt_of (find_a ex)
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theorem choose_spec {A : Type} {p : A → Prop} [c : encodable A] [d : decidable_pred p] (ex : ∃ x, p x) : p (choose ex) :=
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has_property (find_a ex)
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theorem axiom_of_choice {A : Type} {B : A → Type} {R : Π x, B x → Prop} [c : Π a, encodable (B a)] [d : ∀ x y, decidable (R x y)]
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: (∀x, ∃y, R x y) → ∃f, ∀x, R x (f x) :=
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assume H,
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have H₁ : ∀x, R x (choose (H x)), from take x, choose_spec (H x),
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exists.intro _ H₁
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theorem skolem {A : Type} {B : A → Type} {P : Π x, B x → Prop} [c : Π a, encodable (B a)] [d : ∀ x y, decidable (P x y)]
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: (∀x, ∃y, P x y) ↔ ∃f, (∀x, P x (f x)) :=
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iff.intro
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(assume H : (∀x, ∃y, P x y), axiom_of_choice H)
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(assume H : (∃f, (∀x, P x (f x))),
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take x, obtain (fw : ∀x, B x) (Hw : ∀x, P x (fw x)), from H,
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exists.intro (fw x) (Hw x))
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end encodable
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