2023-04-24 22:19:03 +00:00
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import Mathlib.Data.Fintype.Basic
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import Mathlib.Tactic.NormNum
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2023-04-18 17:29:19 +00:00
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2023-05-08 19:37:02 +00:00
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/-! # Common.List.Basic
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2023-05-04 22:37:54 +00:00
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Additional theorems and definitions useful in the context of `List`s.
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-/
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namespace List
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/-! ## Indexing -/
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/--
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Getting the `(i + 1)`st entry of a `List` is equivalent to getting the `i`th
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entry of the `List`'s tail.
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-/
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theorem get_cons_succ_self_eq_get_tail_self
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: get (x :: xs) (Fin.succ i) = get xs i := by
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conv => lhs; unfold get; simp only
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/-! ### Length -/
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/--
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A `List` is nonempty **iff** it can be written as some head concatenated with
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some tail.
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-/
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theorem self_neq_nil_imp_exists_mem : xs ≠ [] ↔ (∃ a as, xs = a :: as) := by
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apply Iff.intro
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· intro h
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cases hx : xs with
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| nil => rw [hx] at h; simp at h
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| cons a as => exact ⟨a, ⟨as, rfl⟩⟩
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· intro ⟨a, ⟨as, hx⟩⟩
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rw [hx]
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simp
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/--
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A `List` is empty **iff** it has length zero.
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-/
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theorem eq_nil_iff_length_zero : xs = [] ↔ length xs = 0 := by
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apply Iff.intro
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· intro h
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rw [h]
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simp
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· intro h
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cases xs with
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| nil => rfl
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| cons a as => simp at h
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/--
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A `List` is nonempty **iff** it has length greater than zero.
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-/
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theorem neq_nil_iff_length_gt_zero : xs ≠ [] ↔ xs.length > 0 := by
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have : ¬xs = [] ↔ ¬length xs = 0 := Iff.not eq_nil_iff_length_zero
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rwa [
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show ¬xs = [] ↔ xs ≠ [] from Iff.rfl,
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show ¬length xs = 0 ↔ length xs ≠ 0 from Iff.rfl,
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← zero_lt_iff
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] at this
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/-! ### Membership -/
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/--
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There exists a member of a `List` **iff** the `List` is nonempty.
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-/
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theorem exists_mem_iff_neq_nil : (∃ x, x ∈ xs) ↔ xs ≠ [] := by
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apply Iff.intro
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· intro ⟨x, hx⟩
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induction hx <;> simp
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· intro hx
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cases xs with
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| nil => simp at hx
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| cons a as => exact ⟨a, by simp⟩
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/--
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If `i` is a valid index of `List` `xs`, then `xs[i]` is a member of `xs`.
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-/
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theorem get_mem_self {xs : List α} {i : Fin xs.length} : get xs i ∈ xs := by
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induction xs with
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| nil => have ⟨_, hj⟩ := i; simp at hj
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| cons a as ih =>
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by_cases hk : i = ⟨0, by simp⟩
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· -- If `i = 0`, we are `get`ting the head of our list. This entry is
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-- trivially a member of `xs`.
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conv => lhs; unfold get; rw [hk]; simp only
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simp
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· -- Otherwise we are `get`ting an entry in the tail. Our induction
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-- hypothesis closes this case.
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have ⟨k', hk'⟩ : ∃ k', i = Fin.succ k' := by
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have ni : ↑i ≠ (0 : ℕ) := fun hi => hk (Fin.ext hi)
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have ⟨j, hj⟩ := Nat.exists_eq_succ_of_ne_zero ni
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refine ⟨⟨j, ?_⟩, Fin.ext hj⟩
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have hi : ↑i < length (a :: as) := i.2
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unfold length at hi
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rwa [hj, show Nat.succ j = j + 1 by rfl, add_lt_add_iff_right] at hi
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conv => lhs; rw [hk', get_cons_succ_self_eq_get_tail_self]
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exact mem_append_of_mem_right [a] ih
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/--
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A value `x` is a member of `List` `xs` **iff** there exists some index `i` such
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that `x = xs[i]`.
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-/
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theorem mem_iff_exists_get {xs : List α}
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: x ∈ xs ↔ ∃ i : Fin xs.length, xs.get i = x := by
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apply Iff.intro
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· intro h
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induction h with
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| head _ => refine ⟨⟨0, ?_⟩, ?_⟩ <;> simp
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| @tail b as _ ih =>
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let ⟨i, hi⟩ := ih
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refine ⟨⟨i.1 + 1, ?_⟩, ?_⟩
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· unfold length; simp
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· simp; exact hi
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· intro ⟨i, hi⟩
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induction xs with
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| nil => have nh := i.2; simp at nh
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| cons a bs => rw [← hi]; exact get_mem_self
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/-! ## Sublists -/
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/--
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The first entry of a nonempty `List` has index `0`.
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-/
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theorem head_eq_get_zero {xs : List α} (h : xs ≠ [])
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: head xs h = get xs ⟨0, neq_nil_iff_length_gt_zero.mp h⟩ := by
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have ⟨a, ⟨as, hs⟩⟩ := self_neq_nil_imp_exists_mem.mp h
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subst hs
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simp
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/--
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The last entry of a nonempty `List` has index `1` less than its length.
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-/
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theorem getLast_eq_get_length_sub_one {xs : List α} (h : xs ≠ [])
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: getLast xs h = get xs ⟨xs.length - 1, by
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have ⟨_, ⟨_, hs⟩⟩ := self_neq_nil_imp_exists_mem.mp h
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rw [hs]
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simp⟩ := by
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induction xs with
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| nil => simp at h
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| cons _ as ih =>
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match as with
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| nil => simp
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| cons b bs => unfold getLast; rw [ih]; simp
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/--
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If a `List` has a `tail?` defined, it must be nonempty.
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-/
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theorem some_tail?_imp_cons (h : tail? xs = some ys) : ∃ x, xs = x :: ys := by
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unfold tail? at h
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cases xs with
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| nil => simp at h
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| cons r rs => exact ⟨r, by simp at h; rw [h]⟩
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/-! ### Zips -/
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/--
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The length of a zip consisting of a `List` and its tail is the length of the
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`List`'s tail.
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-/
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theorem length_zipWith_self_tail_eq_length_sub_one
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: length (zipWith f (a :: as) as) = length as := by
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rw [length_zipWith]
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simp only [length_cons, ge_iff_le, min_eq_right_iff]
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show length as ≤ length as + 1
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simp only [le_add_iff_nonneg_right, zero_le]
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/--
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The output `List` of a `zipWith` is nonempty **iff** both of its inputs are
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nonempty.
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-/
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theorem zipWith_nonempty_iff_args_nonempty
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: zipWith f as bs ≠ [] ↔ as ≠ [] ∧ bs ≠ [] := by
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apply Iff.intro
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· intro h
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rw [self_neq_nil_imp_exists_mem] at h
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have ⟨z, ⟨zs, hzs⟩⟩ := h
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refine ⟨?_, ?_⟩ <;>
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· by_contra nh
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rw [nh] at hzs
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simp at hzs
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· intro ⟨ha, hb⟩
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have ⟨a', ⟨as', has⟩⟩ := self_neq_nil_imp_exists_mem.mp ha
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have ⟨b', ⟨bs', hbs⟩⟩ := self_neq_nil_imp_exists_mem.mp hb
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rw [has, hbs]
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simp
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/--
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An index less than the length of a `zipWith` is less than the length of the left
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operand.
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-/
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theorem fin_zipWith_imp_val_lt_length_left {i : Fin (zipWith f xs ys).length}
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: ↑i < length xs := by
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have hi := i.2
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simp only [length_zipWith, ge_iff_le, lt_min_iff] at hi
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exact hi.left
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/--
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An index less than the length of a `zipWith` is less than the length of the left
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operand.
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-/
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theorem fin_zipWith_imp_val_lt_length_right {i : Fin (zipWith f xs ys).length}
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: ↑i < length ys := by
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have hi := i.2
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simp only [length_zipWith, ge_iff_le, lt_min_iff] at hi
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exact hi.right
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/-! ### Pairwise -/
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/--
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Given a `List` `xs` of length `k`, this function produces a `List` of length
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`k - 1` where the `i`th member of the resulting `List` is `f xs[i] xs[i + 1]`.
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-/
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def pairwise (xs : List α) (f : α → α → β) : List β :=
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match xs.tail? with
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| none => []
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| some ys => zipWith f xs ys
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/--
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If `List` `xs` is empty, then any `pairwise` operation on `xs` yields an empty
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`List`.
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-/
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theorem len_pairwise_len_nil_eq_zero {xs : List α} (h : xs = [])
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: (xs.pairwise f).length = 0 := by
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rw [h]
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unfold pairwise tail? length
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simp
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/--
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If `List` `xs` is nonempty, then any `pairwise` operation on `xs` has length
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`xs.length - 1`.
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-/
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theorem len_pairwise_len_cons_sub_one {xs : List α} (h : xs.length > 0)
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: xs.length = (xs.pairwise f).length + 1 := by
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unfold pairwise tail?
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cases xs with
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| nil =>
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have := neq_nil_iff_length_gt_zero.mpr h
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simp at this
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| cons a bs =>
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rw [length_zipWith_self_tail_eq_length_sub_one]
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conv => lhs; unfold length
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/--
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If a `pairwise`'d `List` isn't empty, then the input `List` must have at least
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two entries.
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-/
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theorem mem_pairwise_imp_length_self_ge_two {xs : List α}
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(h : xs.pairwise f ≠ []) : xs.length ≥ 2 := by
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unfold pairwise tail? at h
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cases hx : xs with
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| nil => rw [hx] at h; simp at h
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| cons a bs =>
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rw [hx] at h
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cases hx' : bs with
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| nil => rw [hx'] at h; simp at h
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| cons a' bs' => unfold length length; rw [add_assoc]; norm_num
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2023-04-24 18:59:11 +00:00
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/--
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2023-05-04 22:37:54 +00:00
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If `x` is a member of a `pairwise`'d list, there must exist two (adjacent)
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entries of the list, say `x₁` and `x₂`, such that `x = f x₁ x₂`.
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2023-04-24 18:59:11 +00:00
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-/
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2023-04-28 13:35:58 +00:00
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theorem mem_pairwise_imp_exists_adjacent {xs : List α} (h : x ∈ xs.pairwise f)
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: ∃ i : Fin (xs.length - 1), ∃ x₁ x₂,
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x₁ = get xs ⟨i.1, Nat.lt_of_lt_pred i.2⟩ ∧
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x₂ = get xs ⟨i.1 + 1, lt_tsub_iff_right.mp i.2⟩ ∧
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x = f x₁ x₂ := by
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2023-04-24 18:59:11 +00:00
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unfold pairwise at h
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2023-04-28 13:35:58 +00:00
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cases hs : tail? xs with
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| none => rw [hs] at h; cases h
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2023-04-24 18:59:11 +00:00
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| some ys =>
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2023-04-28 13:35:58 +00:00
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rw [hs] at h
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2023-04-24 18:59:11 +00:00
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simp only at h
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2023-04-28 13:35:58 +00:00
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-- Find index `i` that corresponds to the index `x₁`. We decompose this
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-- `Fin` type into `j` and `hj` to make rewriting easier.
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have ⟨_, hy⟩ := some_tail?_imp_cons hs
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2023-04-24 22:19:03 +00:00
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have ⟨i, hx⟩ := mem_iff_exists_get.mp h
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2023-04-28 13:35:58 +00:00
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have ⟨j, hj⟩ := i
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rw [
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hy,
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length_zipWith_self_tail_eq_length_sub_one,
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show length ys = length xs - 1 by rw [hy]; simp
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] at hj
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refine
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⟨⟨j, hj⟩,
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⟨get xs ⟨j, Nat.lt_of_lt_pred hj⟩,
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⟨get xs ⟨j + 1, lt_tsub_iff_right.mp hj⟩,
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⟨rfl, ⟨rfl, ?_⟩⟩⟩⟩⟩
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rw [← hx, get_zipWith]
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subst hy
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simp only [length_cons, get, Nat.add_eq, add_zero]
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2023-04-24 22:19:03 +00:00
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end List
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