lean2/library/data/tuple.lean

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/-
Copyright (c) 2015 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Leonardo de Moura
Tuples are lists of a fixed size.
It is implemented as a subtype.
-/
import logic data.list data.fin
open nat list subtype function algebra
definition tuple [reducible] (A : Type) (n : nat) := {l : list A | length l = n}
namespace tuple
variables {A B C : Type}
theorem induction_on [recursor 4] {P : ∀ {n}, tuple A n → Prop}
: ∀ {n} (v : tuple A n), (∀ (l : list A) {n : nat} (h : length l = n), P (tag l h)) → P v
| n (tag l h) H := @H l n h
definition nil : tuple A 0 :=
tag [] rfl
lemma length_succ {n : nat} {l : list A} (a : A) : length l = n → length (a::l) = succ n :=
λ h, congr_arg succ h
definition cons {n : nat} : A → tuple A n → tuple A (succ n)
| a (tag v h) := tag (a::v) (length_succ a h)
notation a :: b := cons a b
protected definition is_inhabited [instance] [h : inhabited A] : ∀ (n : nat), inhabited (tuple A n)
| 0 := inhabited.mk nil
| (succ n) := inhabited.mk (inhabited.value h :: inhabited.value (is_inhabited n))
protected definition has_decidable_eq [instance] [h : decidable_eq A] : ∀ (n : nat), decidable_eq (tuple A n) :=
λ n, subtype.has_decidable_eq
definition head {n : nat} : tuple A (succ n) → A
| (tag [] h) := by contradiction
| (tag (a::v) h) := a
definition tail {n : nat} : tuple A (succ n) → tuple A n
| (tag [] h) := by contradiction
| (tag (a::v) h) := tag v (succ.inj h)
theorem head_cons {n : nat} (a : A) (v : tuple A n) : head (a :: v) = a :=
by induction v; reflexivity
theorem tail_cons {n : nat} (a : A) (v : tuple A n) : tail (a :: v) = v :=
by induction v; reflexivity
theorem head_lcons {n : nat} (a : A) (l : list A) (h : length (a::l) = succ n) : head (tag (a::l) h) = a :=
rfl
theorem tail_lcons {n : nat} (a : A) (l : list A) (h : length (a::l) = succ n) : tail (tag (a::l) h) = tag l (succ.inj h) :=
rfl
definition last {n : nat} : tuple A (succ n) → A
| (tag l h) := list.last l (ne_nil_of_length_eq_succ h)
theorem eta : ∀ {n : nat} (v : tuple A (succ n)), head v :: tail v = v
| 0 (tag [] h) := by contradiction
| 0 (tag (a::l) h) := rfl
| (n+1) (tag [] h) := by contradiction
| (n+1) (tag (a::l) h) := rfl
definition of_list (l : list A) : tuple A (list.length l) :=
tag l rfl
definition to_list {n : nat} : tuple A n → list A
| (tag l h) := l
theorem to_list_of_list (l : list A) : to_list (of_list l) = l :=
rfl
theorem to_list_nil : to_list nil = ([] : list A) :=
rfl
theorem length_to_list {n : nat} : ∀ (v : tuple A n), list.length (to_list v) = n
| (tag l h) := h
theorem heq_of_list_eq {n m} : ∀ {v₁ : tuple A n} {v₂ : tuple A m}, to_list v₁ = to_list v₂ → n = m → v₁ == v₂
| (tag l₁ h₁) (tag l₂ h₂) e₁ e₂ := begin
clear heq_of_list_eq,
subst e₂, subst h₁,
unfold to_list at e₁,
subst l₁
end
theorem list_eq_of_heq {n m} {v₁ : tuple A n} {v₂ : tuple A m} : v₁ == v₂ → n = m → to_list v₁ = to_list v₂ :=
begin
intro h₁ h₂, revert v₁ v₂ h₁,
subst n, intro v₁ v₂ h₁, rewrite [heq.to_eq h₁]
end
theorem of_list_to_list {n : nat} (v : tuple A n) : of_list (to_list v) == v :=
begin
apply heq_of_list_eq, rewrite to_list_of_list, rewrite length_to_list
end
/- append -/
definition append {n m : nat} : tuple A n → tuple A m → tuple A (n + m)
| (tag l₁ h₁) (tag l₂ h₂) := tag (list.append l₁ l₂) (by rewrite [length_append, h₁, h₂])
infix ++ := append
open eq.ops
lemma push_eq_rec : ∀ {n m : nat} {l : list A} (h₁ : n = m) (h₂ : length l = n), h₁ ▹ (tag l h₂) = tag l (h₁ ▹ h₂)
| n n l (eq.refl n) h₂ := rfl
theorem append_nil_right {n : nat} (v : tuple A n) : v ++ nil = v :=
induction_on v (λ l n h, by unfold [tuple.append, tuple.nil]; congruence; apply list.append_nil_right)
theorem append_nil_left {n : nat} (v : tuple A n) : !zero_add ▹ (nil ++ v) = v :=
induction_on v (λ l n h, begin unfold [tuple.append, tuple.nil], rewrite [push_eq_rec] end)
theorem append_nil_left_heq {n : nat} (v : tuple A n) : nil ++ v == v :=
heq_of_eq_rec_left !zero_add (append_nil_left v)
theorem append.assoc {n₁ n₂ n₃} : ∀ (v₁ : tuple A n₁) (v₂ : tuple A n₂) (v₃ : tuple A n₃), !add.assoc ▹ ((v₁ ++ v₂) ++ v₃) = v₁ ++ (v₂ ++ v₃)
| (tag l₁ h₁) (tag l₂ h₂) (tag l₃ h₃) := begin
unfold tuple.append, rewrite push_eq_rec,
congruence,
apply list.append.assoc
end
theorem append.assoc_heq {n₁ n₂ n₃} (v₁ : tuple A n₁) (v₂ : tuple A n₂) (v₃ : tuple A n₃) : (v₁ ++ v₂) ++ v₃ == v₁ ++ (v₂ ++ v₃) :=
heq_of_eq_rec_left !add.assoc (append.assoc v₁ v₂ v₃)
/- reverse -/
definition reverse {n : nat} : tuple A n → tuple A n
| (tag l h) := tag (list.reverse l) (by rewrite [length_reverse, h])
theorem reverse_reverse {n : nat} (v : tuple A n) : reverse (reverse v) = v :=
induction_on v (λ l n h, begin unfold reverse, congruence, apply list.reverse_reverse end)
theorem tuple0_eq_nil : ∀ (v : tuple A 0), v = nil
| (tag [] h) := rfl
| (tag (a::l) h) := by contradiction
/- mem -/
definition mem {n : nat} (a : A) (v : tuple A n) : Prop :=
a ∈ elt_of v
notation e ∈ s := mem e s
notation e ∉ s := ¬ e ∈ s
theorem not_mem_nil (a : A) : a ∉ nil :=
list.not_mem_nil a
theorem mem_cons [simp] {n : nat} (a : A) (v : tuple A n) : a ∈ a :: v :=
induction_on v (λ l n h, !list.mem_cons)
theorem mem_cons_of_mem {n : nat} (y : A) {x : A} {v : tuple A n} : x ∈ v → x ∈ y :: v :=
induction_on v (λ l n h₁ h₂, list.mem_cons_of_mem y h₂)
theorem eq_or_mem_of_mem_cons {n : nat} {x y : A} {v : tuple A n} : x ∈ y::v → x = y x ∈ v :=
induction_on v (λ l n h₁ h₂, eq_or_mem_of_mem_cons h₂)
theorem mem_singleton {n : nat} {x a : A} : x ∈ (a::nil : tuple A 1) → x = a :=
assume h, list.mem_singleton h
/- map -/
definition map {n : nat} (f : A → B) : tuple A n → tuple B n
| (tag l h) := tag (list.map f l) (by clear map; substvars; rewrite length_map)
theorem map_nil (f : A → B) : map f nil = nil :=
rfl
theorem map_cons {n : nat} (f : A → B) (a : A) (v : tuple A n) : map f (a::v) = f a :: map f v :=
by induction v; reflexivity
theorem map_tag {n : nat} (f : A → B) (l : list A) (h : length l = n)
: map f (tag l h) = tag (list.map f l) (by substvars; rewrite length_map) :=
by reflexivity
theorem map_map {n : nat} (g : B → C) (f : A → B) (v : tuple A n) : map g (map f v) = map (g ∘ f) v :=
begin cases v, rewrite *map_tag, apply subtype.eq, apply list.map_map end
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theorem map_id {n : nat} (v : tuple A n) : map id v = v :=
begin induction v, unfold map, congruence, apply list.map_id end
theorem mem_map {n : nat} {a : A} {v : tuple A n} (f : A → B) : a ∈ v → f a ∈ map f v :=
begin induction v, unfold map, apply list.mem_map end
theorem exists_of_mem_map {n : nat} {f : A → B} {b : B} {v : tuple A n} : b ∈ map f v → ∃a, a ∈ v ∧ f a = b :=
begin induction v, unfold map, apply list.exists_of_mem_map end
theorem eq_of_map_const {n : nat} {b₁ b₂ : B} {v : tuple A n} : b₁ ∈ map (const A b₂) v → b₁ = b₂ :=
begin induction v, unfold map, apply list.eq_of_map_const end
/- product -/
definition product {n m : nat} : tuple A n → tuple B m → tuple (A × B) (n * m)
| (tag l₁ h₁) (tag l₂ h₂) := tag (list.product l₁ l₂) (by rewrite [length_product, h₁, h₂])
theorem nil_product {m : nat} (v : tuple B m) : !zero_mul ▹ product (@nil A) v = nil :=
begin induction v, unfold [nil, product], rewrite push_eq_rec end
theorem nil_product_heq {m : nat} (v : tuple B m) : product (@nil A) v == (@nil (A × B)) :=
heq_of_eq_rec_left _ (nil_product v)
theorem product_nil {n : nat} (v : tuple A n) : product v (@nil B) = nil :=
begin induction v, unfold [nil, product], congruence, apply list.product_nil end
theorem mem_product {n m : nat} {a : A} {b : B} {v₁ : tuple A n} {v₂ : tuple B m} : a ∈ v₁ → b ∈ v₂ → (a, b) ∈ product v₁ v₂ :=
begin cases v₁, cases v₂, unfold product, apply list.mem_product end
theorem mem_of_mem_product_left {n m : nat} {a : A} {b : B} {v₁ : tuple A n} {v₂ : tuple B m} : (a, b) ∈ product v₁ v₂ → a ∈ v₁ :=
begin cases v₁, cases v₂, unfold product, apply list.mem_of_mem_product_left end
theorem mem_of_mem_product_right {n m : nat} {a : A} {b : B} {v₁ : tuple A n} {v₂ : tuple B m} : (a, b) ∈ product v₁ v₂ → b ∈ v₂ :=
begin cases v₁, cases v₂, unfold product, apply list.mem_of_mem_product_right end
/- ith -/
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open fin
definition ith {n : nat} : tuple A n → fin n → A
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| (tag l h₁) (mk i h₂) := list.ith l i (by rewrite h₁; exact h₂)
lemma ith_zero {n : nat} (a : A) (v : tuple A n) (h : 0 < succ n) : ith (a::v) (mk 0 h) = a :=
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by induction v; reflexivity
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lemma ith_fin_zero {n : nat} (a : A) (v : tuple A n) : ith (a::v) (fin.zero n) = a :=
by unfold fin.zero; apply ith_zero
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lemma ith_succ {n : nat} (a : A) (v : tuple A n) (i : nat) (h : succ i < succ n)
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: ith (a::v) (mk (succ i) h) = ith v (mk_pred i h) :=
by induction v; reflexivity
lemma ith_fin_succ {n : nat} (a : A) (v : tuple A n) (i : fin n)
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: ith (a::v) (succ i) = ith v i :=
begin cases i, unfold fin.succ, rewrite ith_succ end
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lemma ith_zero_eq_head {n : nat} (v : tuple A (nat.succ n)) : ith v (fin.zero n) = head v :=
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by rewrite [-eta v, ith_fin_zero, head_cons]
lemma ith_succ_eq_ith_tail {n : nat} (v : tuple A (nat.succ n)) (i : fin n) : ith v (succ i) = ith (tail v) i :=
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by rewrite [-eta v, ith_fin_succ, tail_cons]
protected lemma ext {n : nat} (v₁ v₂ : tuple A n) (h : ∀ i : fin n, ith v₁ i = ith v₂ i) : v₁ = v₂ :=
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begin
induction n with n ih,
rewrite [tuple0_eq_nil v₁, tuple0_eq_nil v₂],
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rewrite [-eta v₁, -eta v₂], congruence,
show head v₁ = head v₂, by rewrite [-ith_zero_eq_head, -ith_zero_eq_head]; apply h,
have ∀ i : fin n, ith (tail v₁) i = ith (tail v₂) i, from
take i, by rewrite [-ith_succ_eq_ith_tail, -ith_succ_eq_ith_tail]; apply h,
show tail v₁ = tail v₂, from ih _ _ this
end
/- tabulate -/
definition tabulate : Π {n : nat}, (fin n → A) → tuple A n
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| 0 f := nil
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| (n+1) f := f (fin.zero n) :: tabulate (λ i : fin n, f (succ i))
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theorem ith_tabulate {n : nat} (f : fin n → A) (i : fin n) : ith (tabulate f) i = f i :=
begin
induction n with n ih,
apply elim0 i,
cases i with v hlt, cases v,
{unfold tabulate, rewrite ith_zero},
{unfold tabulate, rewrite [ith_succ, ih]}
end
variable {n : }
definition replicate : A → tuple A n
| a := tag (list.replicate n a) (length_replicate n a)
definition dropn : Π (i:), tuple A n → tuple A (n - i)
| i (tag l p) := tag (list.dropn i l) (p ▸ list.length_dropn i l)
definition firstn : Π (i:) {p:i ≤ n}, tuple A n → tuple A i
| i isLe (tag l p) :=
let q := calc list.length (list.firstn i l)
= min i (list.length l) : list.length_firstn_eq
... = min i n : p
... = i : min_eq_left isLe in
tag (list.firstn i l) q
definition map₂ : (A → B → C) → tuple A n → tuple B n → tuple C n
| f (tag x px) (tag y py) :=
let z : list C := list.map₂ f x y in
let p : list.length z = n := calc
list.length z = min (list.length x) (list.length y) : list.length_map₂
... = min n n : by rewrite [px, py]
... = n : min_self in
tag z p
section accum
open prod
variable {S : Type}
definition mapAccumR
: (A → S → S × B) → tuple A n → S → S × tuple B n
| f (tag x px) c :=
let z := list.mapAccumR f x c in
let p := calc
list.length (pr₂ (list.mapAccumR f x c))
= length x : length_mapAccumR
... = n : px in
(pr₁ z, tag (pr₂ z) p)
definition mapAccumR₂
: (A → B → S → S × C) → tuple A n → tuple B n → S → S × tuple C n
| f (tag x px) (tag y py) c :=
let z := list.mapAccumR₂ f x y c in
let p := calc
list.length (pr₂ (list.mapAccumR₂ f x y c))
= min (length x) (length y) : length_mapAccumR₂
... = n : by rewrite [ px, py, min_self ] in
(pr₁ z, tag (pr₂ z) p)
end accum
end tuple