/- Copyright (c) 2017 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura, Mario Carneiro -/ prelude import .basic init.data.nat init.data.list.lemmas universes u w namespace array variables {α : Type u} {β : Type w} {n : nat} protected def ext : ∀ {a b : array α n} (h : ∀ i, read a i = read b i), a = b | ⟨f⟩ ⟨g⟩ h := congr_arg array.mk (funext h) lemma read_eq_read' [inhabited α] (a : array α n) (i : nat) (h : i < n) : read a ⟨i, h⟩ = read' a i := by unfold read'; rw [dif_pos h] lemma write_eq_write' (a : array α n) (i : nat) (h : i < n) (v : α) : write a ⟨i, h⟩ v = write' a i v := by unfold write'; rw [dif_pos h] lemma read_write (a : array α n) (i j : fin n) (v : α) : read (write a i v) j = if i = j then v else a.read j := rfl lemma read_write_eq (a : array α n) (i : fin n) (v : α) : read (write a i v) i = v := by rw [read_write, if_pos rfl] lemma read_write_ne (a : array α n) (i j : fin n) (v : α) (h : i ≠ j) : read (write a i v) j = read a j := by rw [read_write, if_neg h] theorem rev_list_reverse_core (a : array α n) : Π i (h : i ≤ n) (t : list α), (a.iterate_aux (λ _ v l, v :: l) i h []).reverse_core t = a.rev_iterate_aux (λ _ v l, v :: l) i h t | 0 h t := rfl | (i+1) h t := rev_list_reverse_core i _ _ theorem rev_list_reverse (a : array α n) : a.rev_list.reverse = a.to_list := rev_list_reverse_core a _ _ _ theorem to_list_reverse (a : array α n) : a.to_list.reverse = a.rev_list := by rw [← rev_list_reverse, list.reverse_reverse] theorem rev_list_length_aux (a : array α n) (i h) : (a.iterate_aux (λ _ v l, v :: l) i h []).length = i := by induction i; simp [*, iterate_aux] theorem rev_list_length (a : array α n) : a.rev_list.length = n := rev_list_length_aux a _ _ theorem to_list_length (a : array α n) : a.to_list.length = n := by rw[← rev_list_reverse, list.length_reverse, rev_list_length] theorem to_list_nth_core (a : array α n) (i : ℕ) (ih : i < n) : Π (j) {jh t h'}, (∀k tl, j + k = i → list.nth_le t k tl = a.read ⟨i, ih⟩) → (a.rev_iterate_aux (λ _ v l, v :: l) j jh t).nth_le i h' = a.read ⟨i, ih⟩ | 0 _ _ _ al := al i _ $ zero_add _ | (j+1) jh t h' al := to_list_nth_core j $ λk tl hjk, show list.nth_le (a.read ⟨j, jh⟩ :: t) k tl = a.read ⟨i, ih⟩, from match k, hjk, tl with | 0, e, tl := match i, e, ih with ._, rfl, _ := rfl end | k'+1, _, tl := by simp[list.nth_le]; exact al _ _ (by simp [*]) end theorem to_list_nth (a : array α n) (i : ℕ) (h h') : list.nth_le a.to_list i h' = a.read ⟨i, h⟩ := to_list_nth_core _ _ _ _ (λk tl, absurd tl $ nat.not_lt_zero _) theorem mem_iff_rev_list_mem_core (a : array α n) (v : α) : Π i (h : i ≤ n), (∃ (j : fin n), j.1 < i ∧ read a j = v) ↔ v ∈ a.iterate_aux (λ _ v l, v :: l) i h [] | 0 _ := ⟨λ⟨_, n, _⟩, absurd n $ nat.not_lt_zero _, false.elim⟩ | (i+1) h := let IH := mem_iff_rev_list_mem_core i (le_of_lt h) in ⟨λ⟨j, ji1, e⟩, or.elim (lt_or_eq_of_le $ nat.le_of_succ_le_succ ji1) (λji, list.mem_cons_of_mem _ $ IH.1 ⟨j, ji, e⟩) (λje, by simp[iterate_aux]; apply or.inl; have H : j = ⟨i, h⟩ := fin.eq_of_veq je; rwa [← H, e]), λm, begin simp[iterate_aux, list.mem] at m, cases m with e m', exact ⟨⟨i, h⟩, nat.lt_succ_self _, eq.symm e⟩, exact let ⟨j, ji, e⟩ := IH.2 m' in ⟨j, nat.le_succ_of_le ji, e⟩ end⟩ theorem mem_iff_rev_list_mem (a : array α n) (v : α) : v ∈ a ↔ v ∈ a.rev_list := iff.trans (exists_congr $ λj, iff.symm $ show j.1 < n ∧ read a j = v ↔ read a j = v, from and_iff_right j.2) (mem_iff_rev_list_mem_core a v _ _) theorem mem_iff_list_mem (a : array α n) (v : α) : v ∈ a ↔ v ∈ a.to_list := by rw [← rev_list_reverse]; simp[mem_iff_rev_list_mem] @[simp] theorem to_list_to_array (a : array α n) : a.to_list.to_array == a := have array.mk (λ (v : fin n), list.nth_le (to_list a) (v.val) (eq.rec_on (eq.symm (to_list_length a)) (v.is_lt))) = a, from match a with ⟨f⟩ := congr_arg array.mk $ funext $ λ⟨i, h⟩, to_list_nth ⟨f⟩ i h _ end, heq_of_heq_of_eq (@eq.drec_on _ _ (λm (e : a.to_list.length = m), (array.mk (λv, a.to_list.nth_le v.1 v.2)) == (@array.mk α m $ λv, a.to_list.nth_le v.1 (eq.rec_on (eq.symm e) v.2))) _ a.to_list_length (heq.refl _)) this @[simp] theorem to_array_to_list (l : list α) : l.to_array.to_list = l := list.ext_le (to_list_length _) $ λn h1 h2, to_list_nth _ _ _ _ lemma push_back_rev_list_core (a : array α n) (v : α) : ∀ i h h', iterate_aux (a.push_back v) (λ_, list.cons) i h [] = iterate_aux a (λ_, list.cons) i h' [] | 0 h h' := rfl | (i+1) h h' := begin simp [iterate_aux]; rw push_back_rev_list_core, apply congr_fun, apply congr_arg, dsimp [read, push_back], rw [dif_neg], refl, exact ne_of_lt h' end @[simp] theorem push_back_rev_list (a : array α n) (v : α) : (a.push_back v).rev_list = v :: a.rev_list := begin unfold push_back rev_list foldl iterate, dsimp [iterate_aux, read, push_back], rw [dif_pos (eq.refl n)], apply congr_arg, apply push_back_rev_list_core end @[simp] theorem push_back_to_list (a : array α n) (v : α) : (a.push_back v).to_list = a.to_list ++ [v] := by rw [← rev_list_reverse, ← rev_list_reverse, push_back_rev_list, list.reverse_cons, list.concat_eq_append] def read_foreach_aux (f : fin n → α → α) (ai : array α n) : ∀ i h (a : array α n) (j : fin n), j.1 < i → (iterate_aux ai (λ i v a', write a' i (f i v)) i h a).read j = f j (ai.read j) | 0 hi a ⟨j, hj⟩ ji := absurd ji (nat.not_lt_zero _) | (i+1) hi a ⟨j, hj⟩ ji := begin dsimp [iterate_aux], dsimp at ji, change ite _ _ _ = _, by_cases (⟨i, hi⟩ : fin _) = ⟨j, hj⟩ with e; simp [e], rw [read_foreach_aux _ _ _ ⟨j, hj⟩], exact (lt_or_eq_of_le (nat.le_of_lt_succ ji)).resolve_right (ne.symm $ mt (@fin.eq_of_veq _ ⟨i, hi⟩ ⟨j, hj⟩) e) end def read_foreach (a : array α n) (f : fin n → α → α) (i : fin n) : (foreach a f).read i = f i (a.read i) := read_foreach_aux _ _ _ _ _ _ i.2 def read_map (f : α → α) (a : array α n) (i : fin n) : (map f a).read i = f (a.read i) := read_foreach _ _ _ def read_map₂ (f : α → α → α) (a b : array α n) (i : fin n) : (map₂ f a b).read i = f (a.read i) (b.read i) := read_foreach _ _ _ instance [decidable_eq α] : decidable_eq (array α n) := λ a b, suffices to_list a = to_list b → a = b, from decidable_of_decidable_of_iff (by apply_instance) ⟨this, congr_arg to_list⟩, λ h, eq_of_heq $ a.to_list_to_array.symm.trans $ match to_list a, h with ._, rfl := b.to_list_to_array end end array