206 lines
8.7 KiB
Text
206 lines
8.7 KiB
Text
/-
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Copyright (c) 2015 Leonardo de Moura. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Authors: Leonardo de Moura
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Finite type (type class)
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-/
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import data.list data.bool
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open list bool unit decidable option function
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structure fintype [class] (A : Type) : Type :=
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(elems : list A) (unique : nodup elems) (complete : ∀ a, a ∈ elems)
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definition elements_of (A : Type) [h : fintype A] : list A :=
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@fintype.elems A h
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definition fintype_unit [instance] : fintype unit :=
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fintype.mk [star] dec_trivial (λ u, match u with star := dec_trivial end)
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definition fintype_bool [instance] : fintype bool :=
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fintype.mk [ff, tt]
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dec_trivial
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(λ b, match b with | tt := dec_trivial | ff := dec_trivial end)
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definition fintype_product [instance] {A B : Type} : Π [h₁ : fintype A] [h₂ : fintype B], fintype (A × B)
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| (fintype.mk e₁ u₁ c₁) (fintype.mk e₂ u₂ c₂) :=
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fintype.mk
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(cross_product e₁ e₂)
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(nodup_cross_product u₁ u₂)
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(λ p,
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match p with
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(a, b) := mem_cross_product (c₁ a) (c₂ b)
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end)
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/- auxiliary function for finding 'a' s.t. f a ≠ g a -/
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section find_discr
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variables {A B : Type}
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variable [h : decidable_eq B]
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include h
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definition find_discr (f g : A → B) : list A → option A
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| [] := none
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| (a::l) := if f a = g a then find_discr l else some a
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theorem find_discr_nil (f g : A → B) : find_discr f g [] = none :=
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rfl
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theorem find_discr_cons_of_ne {f g : A → B} {a : A} (l : list A) : f a ≠ g a → find_discr f g (a::l) = some a :=
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assume ne, if_neg ne
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theorem find_discr_cons_of_eq {f g : A → B} {a : A} (l : list A) : f a = g a → find_discr f g (a::l) = find_discr f g l :=
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assume eq, if_pos eq
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theorem ne_of_find_discr_eq_some {f g : A → B} {a : A} : ∀ {l}, find_discr f g l = some a → f a ≠ g a
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| [] e := option.no_confusion e
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| (x::l) e := by_cases
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(λ h : f x = g x,
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have aux : find_discr f g l = some a, by rewrite [find_discr_cons_of_eq l h at e]; exact e,
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ne_of_find_discr_eq_some aux)
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(λ h : f x ≠ g x,
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have aux : some x = some a, by rewrite [find_discr_cons_of_ne l h at e]; exact e,
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option.no_confusion aux (λ xeqa : x = a, eq.rec_on xeqa h))
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theorem all_eq_of_find_discr_eq_none {f g : A → B} : ∀ {l}, find_discr f g l = none → ∀ a, a ∈ l → f a = g a
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| [] e a i := absurd i !not_mem_nil
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| (x::l) e a i := by_cases
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(λ fx_eq_gx : f x = g x,
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have aux : find_discr f g l = none, by rewrite [find_discr_cons_of_eq l fx_eq_gx at e]; exact e,
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or.elim (eq_or_mem_of_mem_cons i)
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(λ aeqx : a = x, by rewrite [-aeqx at fx_eq_gx]; exact fx_eq_gx)
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(λ ainl : a ∈ l, all_eq_of_find_discr_eq_none aux a ainl))
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(λ fx_ne_gx : f x ≠ g x,
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have aux : some x = none, by rewrite [find_discr_cons_of_ne l fx_ne_gx at e]; exact e,
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option.no_confusion aux)
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end find_discr
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definition decidable_eq_fun [instance] {A B : Type} [h₁ : fintype A] [h₂ : decidable_eq B] : decidable_eq (A → B) :=
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λ f g,
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match h₁ with
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| fintype.mk e u c :=
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match find_discr f g e with
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| some a := λ h : find_discr f g e = some a, inr (λ f_eq_g : f = g, absurd (by rewrite f_eq_g) (ne_of_find_discr_eq_some h))
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| none := λ h : find_discr f g e = none, inl (show f = g, from funext (λ a : A, all_eq_of_find_discr_eq_none h a (c a)))
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end rfl
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end
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section check_pred
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variables {A : Type}
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definition check_pred (p : A → Prop) [h : decidable_pred p] : list A → bool
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| [] := tt
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| (a::l) := if p a then check_pred l else ff
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definition check_pred_cons_of_pos {p : A → Prop} [h : decidable_pred p] {a : A} (l : list A) : p a → check_pred p (a::l) = check_pred p l :=
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assume pa, if_pos pa
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definition check_pred_cons_of_neg {p : A → Prop} [h : decidable_pred p] {a : A} (l : list A) : ¬ p a → check_pred p (a::l) = ff :=
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assume npa, if_neg npa
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definition all_of_check_pred_eq_tt {p : A → Prop} [h : decidable_pred p] : ∀ {l : list A}, check_pred p l = tt → ∀ {a}, a ∈ l → p a
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| [] eqtt a ainl := absurd ainl !not_mem_nil
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| (b::l) eqtt a ainbl := by_cases
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(λ pb : p b, or.elim (eq_or_mem_of_mem_cons ainbl)
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(λ aeqb : a = b, by rewrite [aeqb]; exact pb)
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(λ ainl : a ∈ l,
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have eqtt₁ : check_pred p l = tt, by rewrite [check_pred_cons_of_pos _ pb at eqtt]; exact eqtt,
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all_of_check_pred_eq_tt eqtt₁ ainl))
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(λ npb : ¬ p b,
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by rewrite [check_pred_cons_of_neg _ npb at eqtt]; exact (bool.no_confusion eqtt))
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definition ex_of_check_pred_eq_ff {p : A → Prop} [h : decidable_pred p] : ∀ {l : list A}, check_pred p l = ff → ∃ w, ¬ p w
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| [] eqtt := bool.no_confusion eqtt
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| (a::l) eqtt := by_cases
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(λ pa : p a,
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have eqtt₁ : check_pred p l = ff, by rewrite [check_pred_cons_of_pos _ pa at eqtt]; exact eqtt,
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ex_of_check_pred_eq_ff eqtt₁)
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(λ npa : ¬ p a, exists.intro a npa)
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end check_pred
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definition decidable_forall_finite [instance] {A : Type} {p : A → Prop} [h₁ : fintype A] [h₂ : decidable_pred p]
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: decidable (∀ x : A, p x) :=
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match h₁ with
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| fintype.mk e u c :=
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match check_pred p e with
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| tt := λ h : check_pred p e = tt, inl (λ a : A, all_of_check_pred_eq_tt h (c a))
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| ff := λ h : check_pred p e = ff,
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inr (λ n : (∀ x, p x),
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obtain (a : A) (w : ¬ p a), from ex_of_check_pred_eq_ff h,
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absurd (n a) w)
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end rfl
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end
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definition decidable_exists_finite [instance] {A : Type} {p : A → Prop} [h₁ : fintype A] [h₂ : decidable_pred p]
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: decidable (∃ x : A, p x) :=
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match h₁ with
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| fintype.mk e u c :=
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match check_pred (λ a, ¬ p a) e with
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| tt := λ h : check_pred (λ a, ¬ p a) e = tt, inr (λ ex : (∃ x, p x),
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obtain x px, from ex,
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absurd px (all_of_check_pred_eq_tt h (c x)))
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| ff := λ h : check_pred (λ a, ¬ p a) e = ff, inl (
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assert aux₁ : ∃ x, ¬¬p x, from ex_of_check_pred_eq_ff h,
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obtain x nnpx, from aux₁, exists.intro x (not_not_elim nnpx))
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end rfl
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end
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open list.as_type
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-- Auxiliary function for returning a list with all elements of the type: (list.as_type l)
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-- Remark ⟪s⟫ is notation for (list.as_type l)
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-- We use this function to define the instance for (fintype ⟪s⟫)
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private definition ltype_elems {A : Type} {s : list A} : Π {l : list A}, l ⊆ s → list ⟪s⟫
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| [] h := []
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| (a::l) h := lval a (h a !mem_cons) :: ltype_elems (sub_of_cons_sub h)
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private theorem mem_of_mem_ltype_elems {A : Type} {a : A} {s : list A}
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: Π {l : list A} {h : l ⊆ s} {m : a ∈ s}, mk a m ∈ ltype_elems h → a ∈ l
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| [] h m lin := absurd lin !not_mem_nil
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| (b::l) h m lin := or.elim (eq_or_mem_of_mem_cons lin)
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(λ leq : mk a m = mk b (h b (mem_cons b l)),
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as_type.no_confusion leq (λ aeqb em, by rewrite [aeqb]; exact !mem_cons))
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(λ linl : mk a m ∈ ltype_elems (sub_of_cons_sub h),
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have ainl : a ∈ l, from mem_of_mem_ltype_elems linl,
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mem_cons_of_mem _ ainl)
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private theorem nodup_ltype_elems {A : Type} {s : list A} : Π {l : list A} (d : nodup l) (h : l ⊆ s), nodup (ltype_elems h)
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| [] d h := nodup_nil
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| (a::l) d h :=
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have d₁ : nodup l, from nodup_of_nodup_cons d,
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have nainl : a ∉ l, from not_mem_of_nodup_cons d,
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let h₁ : l ⊆ s := sub_of_cons_sub h in
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have d₂ : nodup (ltype_elems h₁), from nodup_ltype_elems d₁ h₁,
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have nin : mk a (h a (mem_cons a l)) ∉ ltype_elems h₁, from
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assume ab, absurd (mem_of_mem_ltype_elems ab) nainl,
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nodup_cons nin d₂
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private theorem mem_ltype_elems {A : Type} {s : list A} {a : ⟪s⟫}
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: Π {l : list A} (h : l ⊆ s), value a ∈ l → a ∈ ltype_elems h
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| [] h vainl := absurd vainl !not_mem_nil
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| (b::l) h vainbl := or.elim (eq_or_mem_of_mem_cons vainbl)
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(λ vaeqb : value a = b,
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begin
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reverts [vaeqb, h],
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-- TODO(Leo): check why 'cases a with [va, ma]' produces an incorrect proof
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apply (as_type.cases_on a),
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intros [va, ma, vaeqb],
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rewrite -vaeqb, intro h,
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apply mem_cons
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end)
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(λ vainl : value a ∈ l,
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have s₁ : l ⊆ s, from sub_of_cons_sub h,
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have aux : a ∈ ltype_elems (sub_of_cons_sub h), from mem_ltype_elems s₁ vainl,
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mem_cons_of_mem _ aux)
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definition fintype_list_as_type [instance] {A : Type} [h : decidable_eq A] {s : list A} : fintype ⟪s⟫ :=
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let nds : list A := erase_dup s in
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have sub₁ : nds ⊆ s, from erase_dup_sub s,
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have sub₂ : s ⊆ nds, from sub_erase_dup s,
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have dnds : nodup nds, from nodup_erase_dup s,
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let e : list ⟪s⟫ := ltype_elems sub₁ in
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fintype.mk
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e
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(nodup_ltype_elems dnds sub₁)
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(λ a : ⟪s⟫, show a ∈ e, from
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have vains : value a ∈ s, from is_member a,
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have vainnds : value a ∈ nds, from sub₂ vains,
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mem_ltype_elems sub₁ vainnds)
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