lean2/library/data/list/basic.lean

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----------------------------------------------------------------------------------------------------
--- Copyright (c) 2014 Parikshit Khanna. All rights reserved.
--- Released under Apache 2.0 license as described in the file LICENSE.
--- Authors: Parikshit Khanna, Jeremy Avigad
----------------------------------------------------------------------------------------------------
-- Theory list
-- ===========
--
-- Basic properties of lists.
import tools.tactic
import data.nat
import logic tools.helper_tactics
import logic.core.identities
open nat
open eq_ops
open helper_tactics
inductive list (T : Type) : Type :=
nil {} : list T,
cons : T → list T → list T
namespace list
-- Type
-- ----
infix `::` := cons
section
variable {T : Type}
theorem induction_on [protected] {P : list T → Prop} (l : list T) (Hnil : P nil)
(Hind : ∀ (x : T) (l : list T), P l → P (x :: l)) : P l :=
rec Hnil Hind l
theorem cases_on [protected] {P : list T → Prop} (l : list T) (Hnil : P nil)
(Hcons : ∀ (x : T) (l : list T), P (x :: l)) : P l :=
induction_on l Hnil (take x l IH, Hcons x l)
abbreviation rec_on [protected] {A : Type} {C : list A → Type} (l : list A)
(H1 : C nil) (H2 : Π (h : A) (t : list A), C t → C (h :: t)) : C l :=
rec H1 H2 l
notation `[` l:(foldr `,` (h t, h :: t) nil) `]` := l
-- Concat
-- ------
definition append (s t : list T) : list T :=
rec t (λx l u, x :: u) s
infixl `++` : 65 := append
theorem nil_append {t : list T} : nil ++ t = t
theorem cons_append {x : T} {s t : list T} : (x :: s) ++ t = x :: (s ++ t)
theorem append_nil {t : list T} : t ++ nil = t :=
induction_on t rfl
(take (x : T) (l : list T) (H : append l nil = l),
H ▸ rfl)
theorem append_assoc {s t u : list T} : s ++ t ++ u = s ++ (t ++ u) :=
induction_on s
rfl
(take x l, assume H : (l ++ t) ++ u = l ++ (t ++ u),
calc
(x :: l) ++ t ++ u = x :: (l ++ t ++ u) : rfl
... = x :: (l ++ (t ++ u)) : {H}
... = (x :: l) ++ (t ++ u) : rfl)
-- Length
-- ------
definition length : list T → :=
rec 0 (λx l m, succ m)
theorem length_nil : length (@nil T) = 0
theorem length_cons {x : T} {t : list T} : length (x :: t) = succ (length t)
theorem length_append {s t : list T} : length (s ++ t) = length s + length t :=
induction_on s
(calc
length (nil ++ t) = length t : rfl
... = 0 + length t : {add_zero_left⁻¹}
... = length nil + length t : rfl)
(take x s,
assume H : length (s ++ t) = length s + length t,
calc
length ((x :: s) ++ t ) = succ (length (s ++ t)) : rfl
... = succ (length s + length t) : {H}
... = succ (length s) + length t : {add_succ_left⁻¹}
... = length (x :: s) + length t : rfl)
-- add_rewrite length_nil length_cons
-- Append
-- ------
definition concat (x : T) : list T → list T :=
rec [x] (λy l l', y :: l')
theorem concat_nil {x : T} : concat x nil = [x]
theorem concat_cons {x y : T} {l : list T} : concat x (y :: l) = y :: (concat x l)
theorem concat_eq_append {x : T} {l : list T} : concat x l = l ++ [x]
-- add_rewrite append_nil append_cons
-- Reverse
-- -------
definition reverse : list T → list T :=
rec nil (λx l r, r ++ [x])
theorem reverse_nil : reverse (@nil T) = nil
theorem reverse_cons {x : T} {l : list T} : reverse (x :: l) = concat x (reverse l)
theorem reverse_singleton {x : T} : reverse [x] = [x]
theorem reverse_append {s t : list T} : reverse (s ++ t) = (reverse t) ++ (reverse s) :=
induction_on s
(append_nil⁻¹)
(take x s, assume IH : reverse (s ++ t) = (reverse t) ++ (reverse s),
calc
reverse ((x :: s) ++ t) = reverse (s ++ t) ++ [x] : rfl
... = reverse t ++ reverse s ++ [x] : {IH}
... = reverse t ++ (reverse s ++ [x]) : append_assoc
... = reverse t ++ (reverse (x :: s)) : rfl)
theorem reverse_reverse {l : list T} : reverse (reverse l) = l :=
induction_on l
rfl
(take x l',
assume H: reverse (reverse l') = l',
show reverse (reverse (x :: l')) = x :: l', from
calc
reverse (reverse (x :: l')) = reverse (reverse l' ++ [x]) : rfl
... = reverse [x] ++ reverse (reverse l') : reverse_append
... = [x] ++ l' : {H}
... = x :: l' : rfl)
theorem concat_eq_reverse_cons {x : T} {l : list T} : concat x l = reverse (x :: reverse l) :=
induction_on l
rfl
(take y l',
assume H : concat x l' = reverse (x :: reverse l'),
calc
concat x (y :: l') = (y :: l') ++ [x] : concat_eq_append
... = reverse (reverse (y :: l')) ++ [x] : {reverse_reverse⁻¹}
... = reverse (x :: (reverse (y :: l'))) : rfl)
-- Head and tail
-- -------------
definition head (x : T) : list T → T :=
rec x (λx l h, x)
theorem head_nil {x : T} : head x nil = x
theorem head_cons {x x' : T} {t : list T} : head x' (x :: t) = x
theorem head_concat {s t : list T} {x : T} : s ≠ nil → (head x (s ++ t) = head x s) :=
cases_on s
(take H : nil ≠ nil, absurd rfl H)
(take x s, take H : x :: s ≠ nil,
calc
head x ((x :: s) ++ t) = head x (x :: (s ++ t)) : {cons_append}
... = x : {head_cons}
... = head x (x :: s) : {head_cons⁻¹})
definition tail : list T → list T :=
rec nil (λx l b, l)
theorem tail_nil : tail (@nil T) = nil
theorem tail_cons {x : T} {l : list T} : tail (x :: l) = l
theorem cons_head_tail {x : T} {l : list T} : l ≠ nil → (head x l) :: (tail l) = l :=
cases_on l
(assume H : nil ≠ nil, absurd rfl H)
(take x l, assume H : x :: l ≠ nil, rfl)
-- List membership
-- ---------------
definition mem (x : T) : list T → Prop :=
rec false (λy l H, x = y H)
infix `∈` := mem
theorem mem_nil {x : T} : x ∈ nil ↔ false :=
iff.rfl
theorem mem_cons {x y : T} {l : list T} : mem x (y :: l) ↔ (x = y mem x l) :=
iff.rfl
theorem mem_concat_imp_or {x : T} {s t : list T} : x ∈ s ++ t → x ∈ s x ∈ t :=
induction_on s or.inr
(take y s,
assume IH : x ∈ s ++ t → x ∈ s x ∈ t,
assume H1 : x ∈ (y :: s) ++ t,
have H2 : x = y x ∈ s ++ t, from H1,
have H3 : x = y x ∈ s x ∈ t, from or.imp_or_right H2 IH,
iff.elim_right or.assoc H3)
theorem mem_or_imp_concat {x : T} {s t : list T} : x ∈ s x ∈ t → x ∈ s ++ t :=
induction_on s
(take H, or.elim H false_elim (assume H, H))
(take y s,
assume IH : x ∈ s x ∈ t → x ∈ s ++ t,
assume H : x ∈ y :: s x ∈ t,
or.elim H
(assume H1,
or.elim H1
(take H2 : x = y, or.inl H2)
(take H2 : x ∈ s, or.inr (IH (or.inl H2))))
(assume H1 : x ∈ t, or.inr (IH (or.inr H1))))
theorem mem_concat {x : T} {s t : list T} : x ∈ s ++ t ↔ x ∈ s x ∈ t :=
iff.intro mem_concat_imp_or mem_or_imp_concat
theorem mem_split {x : T} {l : list T} : x ∈ l → ∃s t : list T, l = s ++ (x :: t) :=
induction_on l
(take H : x ∈ nil, false_elim (iff.elim_left mem_nil H))
(take y l,
assume IH : x ∈ l → ∃s t : list T, l = s ++ (x :: t),
assume H : x ∈ y :: l,
or.elim H
(assume H1 : x = y,
exists_intro nil (exists_intro l (H1 ▸ rfl)))
(assume H1 : x ∈ l,
obtain s (H2 : ∃t : list T, l = s ++ (x :: t)), from IH H1,
obtain t (H3 : l = s ++ (x :: t)), from H2,
have H4 : y :: l = (y :: s) ++ (x :: t),
from H3 ▸ rfl,
exists_intro _ (exists_intro _ H4)))
theorem mem_is_decidable [instance] {H : decidable_eq T} {x : T} {l : list T} : decidable (mem x l) :=
rec_on l
(decidable.inr (iff.false_elim mem_nil))
(λ (h : T) (l : list T) (iH : decidable (mem x l)),
show decidable (mem x (h :: l)), from
decidable.rec_on iH
(assume Hp : mem x l,
decidable.rec_on (H x h)
(assume Heq : x = h,
decidable.inl (or.inl Heq))
(assume Hne : x ≠ h,
decidable.inl (or.inr Hp)))
(assume Hn : ¬mem x l,
decidable.rec_on (H x h)
(assume Heq : x = h,
decidable.inl (or.inl Heq))
(assume Hne : x ≠ h,
have H1 : ¬(x = h mem x l), from
assume H2 : x = h mem x l, or.elim H2
(assume Heq, absurd Heq Hne)
(assume Hp, absurd Hp Hn),
have H2 : ¬mem x (h :: l), from
iff.elim_right (iff.flip_sign mem_cons) H1,
decidable.inr H2)))
-- Find
-- ----
definition find {H : decidable_eq T} (x : T) : list T → nat :=
rec 0 (λy l b, if x = y then 0 else succ b)
theorem find_nil {H : decidable_eq T} {f : T} : find f nil = 0
theorem find_cons {H : decidable_eq T} {x y : T} {l : list T} :
find x (y :: l) = if x = y then 0 else succ (find x l)
theorem not_mem_find {H : decidable_eq T} {l : list T} {x : T} :
¬mem x l → find x l = length l :=
rec_on l
(assume P₁ : ¬mem x nil, rfl)
(take y l,
assume iH : ¬mem x l → find x l = length l,
assume P₁ : ¬mem x (y :: l),
have P₂ : ¬(x = y mem x l), from iff.elim_right (iff.flip_sign mem_cons) P₁,
have P₃ : ¬x = y ∧ ¬mem x l, from (iff.elim_left not_or P₂),
calc
find x (y :: l) = if x = y then 0 else succ (find x l) : find_cons
... = succ (find x l) : if_neg (and.elim_left P₃)
... = succ (length l) : {iH (and.elim_right P₃)}
... = length (y :: l) : length_cons⁻¹)
-- nth element
-- -----------
definition nth (x : T) (l : list T) (n : ) : T :=
nat.rec (λl, head x l) (λm f l, f (tail l)) n l
theorem nth_zero {x : T} {l : list T} : nth x l 0 = head x l
theorem nth_succ {x : T} {l : list T} {n : } : nth x l (succ n) = nth x (tail l) n
end
end list