lean2/library/data/int/order.lean

/-
Copyright (c) 2014 Floris van Doorn. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Floris van Doorn, Jeremy Avigad

The order relation on the integers. We show that int is an instance of linear_comm_ordered_ring
and transfer the results.
-/
import .basic algebra.ordered_ring
open nat
open algebra
open decidable
open int eq.ops

namespace int

private definition nonneg (a : ℤ) : Prop := int.cases_on a (take n, true) (take n, false)
protected definition le (a b : ℤ) : Prop := nonneg (b - a)

definition int_has_le [instance] [reducible] [priority int.prio]: has_le int :=
has_le.mk int.le

protected definition lt (a b : ℤ) : Prop := (a + 1) ≤ b

definition int_has_lt [instance] [reducible] [priority int.prio]: has_lt int :=
has_lt.mk int.lt

local attribute nonneg [reducible]
private definition decidable_nonneg [instance] (a : ℤ) : decidable (nonneg a) := int.cases_on a _ _
definition decidable_le [instance] (a b : ℤ) : decidable (a ≤ b) := decidable_nonneg _
definition decidable_lt [instance] (a b : ℤ) : decidable (a < b) := decidable_nonneg _

private theorem nonneg.elim {a : ℤ} : nonneg a → ∃n : ℕ, a = n :=
int.cases_on a (take n H, exists.intro n rfl) (take n', false.elim)

private theorem nonneg_or_nonneg_neg (a : ℤ) : nonneg a ∨ nonneg (-a) :=
int.cases_on a (take n, or.inl trivial) (take n, or.inr trivial)

theorem le.intro {a b : ℤ} {n : ℕ} (H : a + n = b) : a ≤ b :=
have n = b - a, from eq_add_neg_of_add_eq (begin rewrite [add.comm, H] end), -- !add.comm ▸ H),
show nonneg (b - a), from this ▸ trivial

theorem le.elim {a b : ℤ} (H : a ≤ b) : ∃n : ℕ, a + n = b :=
obtain (n : ℕ) (H1 : b - a = n), from nonneg.elim H,
exists.intro n (!add.comm ▸ iff.mpr !add_eq_iff_eq_add_neg (H1⁻¹))

protected theorem le_total (a b : ℤ) : a ≤ b ∨ b ≤ a :=
or.imp_right
  (assume H : nonneg (-(b - a)),
   have -(b - a) = a - b, from !neg_sub,
   show nonneg (a - b), from this ▸ H)
  (nonneg_or_nonneg_neg (b - a))

theorem of_nat_le_of_nat_of_le {m n : ℕ} (H : #nat m ≤ n) : of_nat m ≤ of_nat n :=
obtain (k : ℕ) (Hk : m + k = n), from nat.le.elim H,
le.intro (Hk ▸ (of_nat_add m k)⁻¹)

theorem le_of_of_nat_le_of_nat {m n : ℕ} (H : of_nat m ≤ of_nat n) : (#nat m ≤ n) :=
obtain (k : ℕ) (Hk : of_nat m + of_nat k = of_nat n), from le.elim H,
have m + k = n, from of_nat.inj (of_nat_add m k ⬝ Hk),
nat.le.intro this

theorem of_nat_le_of_nat_iff (m n : ℕ) : of_nat m ≤ of_nat n ↔ m ≤ n :=
iff.intro le_of_of_nat_le_of_nat of_nat_le_of_nat_of_le

theorem lt_add_succ (a : ℤ) (n : ℕ) : a < a + succ n :=
le.intro (show a + 1 + n = a + succ n, from
  calc
    a + 1 + n = a + (1 + n) : add.assoc
      ... = a + (n + 1)     : by rewrite (int.add_comm 1 n)
      ... = a + succ n      : rfl)

theorem lt.intro {a b : ℤ} {n : ℕ} (H : a + succ n = b) : a < b :=
H ▸ lt_add_succ a n

theorem lt.elim {a b : ℤ} (H : a < b) : ∃n : ℕ, a + succ n = b :=
obtain (n : ℕ) (Hn : a + 1 + n = b), from le.elim H,
have a + succ n = b, from
  calc
    a + succ n = a + 1 + n : by rewrite [add.assoc, int.add_comm 1 n]
           ... = b         : Hn,
exists.intro n this

theorem of_nat_lt_of_nat_iff (n m : ℕ) : of_nat n < of_nat m ↔ n < m :=
calc
  of_nat n < of_nat m ↔ of_nat n + 1 ≤ of_nat m : iff.refl
    ... ↔ of_nat (nat.succ n) ≤ of_nat m        : of_nat_succ n ▸ !iff.refl
    ... ↔ nat.succ n ≤ m                        : of_nat_le_of_nat_iff
    ... ↔ n < m                                 : iff.symm (lt_iff_succ_le _ _)

theorem lt_of_of_nat_lt_of_nat {m n : ℕ} (H : of_nat m < of_nat n) : #nat m < n :=
iff.mp !of_nat_lt_of_nat_iff H

theorem of_nat_lt_of_nat_of_lt {m n : ℕ} (H : #nat m < n) : of_nat m < of_nat n :=
iff.mpr !of_nat_lt_of_nat_iff H

/- show that the integers form an ordered additive group -/

protected theorem le_refl (a : ℤ) : a ≤ a :=
le.intro (add_zero a)

protected theorem le_trans {a b c : ℤ} (H1 : a ≤ b) (H2 : b ≤ c) : a ≤ c :=
obtain (n : ℕ) (Hn : a + n = b), from le.elim H1,
obtain (m : ℕ) (Hm : b + m = c), from le.elim H2,
have a + of_nat (n + m) = c, from
  calc
    a + of_nat (n + m) = a + (of_nat n + m) : {of_nat_add n m}
      ... = a + n + m : (add.assoc a n m)⁻¹
      ... = b + m : {Hn}
      ... = c : Hm,
le.intro this

protected theorem le_antisymm : ∀ {a b : ℤ}, a ≤ b → b ≤ a → a = b :=
take a b : ℤ, assume (H₁ : a ≤ b) (H₂ : b ≤ a),
obtain (n : ℕ) (Hn : a + n = b), from le.elim H₁,
obtain (m : ℕ) (Hm : b + m = a), from le.elim H₂,
have a + of_nat (n + m) = a + 0, from
  calc
    a + of_nat (n + m) = a + (of_nat n + m) : by rewrite of_nat_add
      ... = a + n + m                       : by rewrite add.assoc
      ... = b + m                           : by rewrite Hn
      ... = a                               : by rewrite Hm
      ... = a + 0                           : by rewrite add_zero,
have of_nat (n + m) = of_nat 0, from add.left_cancel this,
have n + m = 0,                 from of_nat.inj this,
assert n = 0,                     from nat.eq_zero_of_add_eq_zero_right this,
show a = b, from
  calc
    a = a + 0    : add_zero
  ... = a + n    : by rewrite this
  ... = b        : Hn

protected theorem lt_irrefl (a : ℤ) : ¬ a < a :=
(suppose a < a,
  obtain (n : ℕ) (Hn : a + succ n = a), from lt.elim this,
  have a + succ n = a + 0, from
    Hn ⬝ !add_zero⁻¹,
  !succ_ne_zero (of_nat.inj (add.left_cancel this)))

protected theorem ne_of_lt {a b : ℤ} (H : a < b) : a ≠ b :=
(suppose a = b, absurd (this ▸ H) (int.lt_irrefl b))

theorem le_of_lt {a b : ℤ} (H : a < b) : a ≤ b :=
obtain (n : ℕ) (Hn : a + succ n = b), from lt.elim H,
le.intro Hn

protected theorem lt_iff_le_and_ne (a b : ℤ) : a < b ↔ (a ≤ b ∧ a ≠ b) :=
iff.intro
  (assume H, and.intro (le_of_lt H) (int.ne_of_lt H))
  (assume H,
    have a ≤ b, from and.elim_left H,
    have a ≠ b, from and.elim_right H,
    obtain (n : ℕ) (Hn : a + n = b), from le.elim `a ≤ b`,
    have n ≠ 0, from (assume H' : n = 0, `a ≠ b` (!add_zero ▸ H' ▸ Hn)),
    obtain (k : ℕ) (Hk : n = nat.succ k), from nat.exists_eq_succ_of_ne_zero this,
    lt.intro (Hk ▸ Hn))

protected theorem le_iff_lt_or_eq (a b : ℤ) : a ≤ b ↔ (a < b ∨ a = b) :=
iff.intro
  (assume H,
    by_cases
      (suppose a = b, or.inr this)
      (suppose a ≠ b,
        obtain (n : ℕ) (Hn : a + n = b), from le.elim H,
        have n ≠ 0, from (assume H' : n = 0, `a ≠ b` (!add_zero ▸ H' ▸ Hn)),
        obtain (k : ℕ) (Hk : n = nat.succ k), from nat.exists_eq_succ_of_ne_zero this,
        or.inl (lt.intro (Hk ▸ Hn))))
  (assume H,
    or.elim H
      (assume H1, le_of_lt H1)
      (assume H1, H1 ▸ !int.le_refl))

theorem lt_succ (a : ℤ) : a < a + 1 :=
int.le_refl (a + 1)

protected theorem add_le_add_left {a b : ℤ} (H : a ≤ b) (c : ℤ) : c + a ≤ c + b :=
obtain (n : ℕ) (Hn : a + n = b), from le.elim H,
have H2 : c + a + n = c + b, from
  calc
    c + a + n = c + (a + n) : add.assoc c a n
      ... = c + b : {Hn},
le.intro H2

protected theorem add_lt_add_left {a b : ℤ} (H : a < b) (c : ℤ) : c + a < c + b :=
let H' := le_of_lt H in
(iff.mpr (int.lt_iff_le_and_ne _ _)) (and.intro (int.add_le_add_left H' _)
                                  (take Heq, let Heq' := add_left_cancel Heq in
                                   !int.lt_irrefl (Heq' ▸ H)))

protected theorem mul_nonneg {a b : ℤ} (Ha : 0 ≤ a) (Hb : 0 ≤ b) : 0 ≤ a * b :=
obtain (n : ℕ) (Hn : 0 + n = a), from le.elim Ha,
obtain (m : ℕ) (Hm : 0 + m = b), from le.elim Hb,
le.intro
  (eq.symm
    (calc
      a * b = (0 + n) * b : by rewrite Hn
        ... = n * b       : by rewrite zero_add
        ... = n * (0 + m) : by rewrite Hm
        ... = n * m       : by rewrite zero_add
        ... = 0 + n * m   : by rewrite zero_add))

protected theorem mul_pos {a b : ℤ} (Ha : 0 < a) (Hb : 0 < b) : 0 < a * b :=
obtain (n : ℕ) (Hn : 0 + nat.succ n = a), from lt.elim Ha,
obtain (m : ℕ) (Hm : 0 + nat.succ m = b), from lt.elim Hb,
lt.intro
  (eq.symm
    (calc
      a * b = (0 + nat.succ n) * b                     : by rewrite Hn
        ... = nat.succ n * b                           : by rewrite zero_add
        ... = nat.succ n * (0 + nat.succ m)            : by rewrite Hm
        ... = nat.succ n * nat.succ m                  : by rewrite zero_add
        ... = of_nat (nat.succ n * nat.succ m)         : by rewrite of_nat_mul
        ... = of_nat (nat.succ n * m + nat.succ n)     : by rewrite nat.mul_succ
        ... = of_nat (nat.succ (nat.succ n * m + n))   : by rewrite nat.add_succ
        ... = 0 + nat.succ (nat.succ n * m + n)        : by rewrite zero_add))

protected theorem zero_lt_one : (0 : ℤ) < 1 := trivial

protected theorem not_le_of_gt {a b : ℤ} (H : a < b) : ¬ b ≤ a :=
  assume Hba,
  let Heq := int.le_antisymm (le_of_lt H) Hba in
  !int.lt_irrefl (Heq ▸ H)

protected theorem lt_of_lt_of_le {a b c : ℤ} (Hab : a < b) (Hbc : b ≤ c) : a < c :=
  let Hab' := le_of_lt Hab in
  let Hac := int.le_trans Hab' Hbc in
  (iff.mpr !int.lt_iff_le_and_ne) (and.intro Hac
    (assume Heq, int.not_le_of_gt (Heq ▸ Hab) Hbc))

protected theorem lt_of_le_of_lt  {a b c : ℤ} (Hab : a ≤ b) (Hbc : b < c) : a < c :=
  let Hbc' := le_of_lt Hbc in
  let Hac := int.le_trans Hab Hbc' in
  (iff.mpr !int.lt_iff_le_and_ne) (and.intro Hac
    (assume Heq, int.not_le_of_gt (Heq⁻¹ ▸ Hbc) Hab))

protected definition linear_ordered_comm_ring [reducible] [trans_instance] :
    algebra.linear_ordered_comm_ring int :=
⦃algebra.linear_ordered_comm_ring, int.integral_domain,
  le               := int.le,
  le_refl          := int.le_refl,
  le_trans         := @int.le_trans,
  le_antisymm      := @int.le_antisymm,
  lt               := int.lt,
  le_of_lt         := @int.le_of_lt,
  lt_irrefl        := int.lt_irrefl,
  lt_of_lt_of_le   := @int.lt_of_lt_of_le,
  lt_of_le_of_lt   := @int.lt_of_le_of_lt,
  add_le_add_left  := @int.add_le_add_left,
  mul_nonneg       := @int.mul_nonneg,
  mul_pos          := @int.mul_pos,
  le_iff_lt_or_eq  := int.le_iff_lt_or_eq,
  le_total         := int.le_total,
  zero_ne_one      := int.zero_ne_one,
  zero_lt_one      := int.zero_lt_one,
  add_lt_add_left  := @int.add_lt_add_left⦄

protected definition decidable_linear_ordered_comm_ring [reducible] [instance] :
    algebra.decidable_linear_ordered_comm_ring int :=
⦃algebra.decidable_linear_ordered_comm_ring,
 int.linear_ordered_comm_ring,
 decidable_lt := decidable_lt⦄

/- more facts specific to int -/

theorem of_nat_nonneg (n : ℕ) : 0 ≤ of_nat n := trivial

theorem of_nat_pos {n : ℕ} (Hpos : #nat n > 0) : of_nat n > 0 :=
of_nat_lt_of_nat_of_lt Hpos

theorem of_nat_succ_pos (n : nat) : of_nat (nat.succ n) > 0 :=
of_nat_pos !nat.succ_pos

theorem exists_eq_of_nat {a : ℤ} (H : 0 ≤ a) : ∃n : ℕ, a = of_nat n :=
obtain (n : ℕ) (H1 : 0 + of_nat n = a), from le.elim H,
exists.intro n (!zero_add ▸ (H1⁻¹))

theorem exists_eq_neg_of_nat {a : ℤ} (H : a ≤ 0) : ∃n : ℕ, a = -(of_nat n) :=
have -a ≥ 0, from iff.mpr !neg_nonneg_iff_nonpos H,
obtain (n : ℕ) (Hn : -a = of_nat n), from exists_eq_of_nat this,
exists.intro n (eq_neg_of_eq_neg (Hn⁻¹))

theorem of_nat_nat_abs_of_nonneg {a : ℤ} (H : a ≥ 0) : of_nat (nat_abs a) = a :=
obtain (n : ℕ) (Hn : a = of_nat n), from exists_eq_of_nat H,
Hn⁻¹ ▸ congr_arg of_nat (nat_abs_of_nat n)

theorem of_nat_nat_abs_of_nonpos {a : ℤ} (H : a ≤ 0) : of_nat (nat_abs a) = -a :=
have -a ≥ 0, from iff.mpr !neg_nonneg_iff_nonpos H,
calc
  of_nat (nat_abs a) = of_nat (nat_abs (-a)) : nat_abs_neg
                 ... = -a                    : of_nat_nat_abs_of_nonneg this

theorem of_nat_nat_abs (b : ℤ) : nat_abs b = abs b :=
or.elim (le.total 0 b)
  (assume H : b ≥ 0, of_nat_nat_abs_of_nonneg H ⬝ (abs_of_nonneg H)⁻¹)
  (assume H : b ≤ 0, of_nat_nat_abs_of_nonpos H ⬝ (abs_of_nonpos H)⁻¹)

theorem nat_abs_abs (a : ℤ) : nat_abs (abs a) = nat_abs a :=
abs.by_cases rfl !nat_abs_neg

theorem lt_of_add_one_le {a b : ℤ} (H : a + 1 ≤ b) : a < b :=
obtain (n : nat) (H1 : a + 1 + n = b), from le.elim H,
have a + succ n = b, by rewrite [-H1, add.assoc, add.comm 1],
lt.intro this

theorem add_one_le_of_lt {a b : ℤ} (H : a < b) : a + 1 ≤ b :=
obtain (n : nat) (H1 : a + succ n = b), from lt.elim H,
have a + 1 + n = b, by rewrite [-H1, add.assoc, add.comm 1],
le.intro this

theorem lt_add_one_of_le {a b : ℤ} (H : a ≤ b) : a < b + 1 :=
lt_add_of_le_of_pos H trivial

theorem le_of_lt_add_one {a b : ℤ} (H : a < b + 1) : a ≤ b :=
have H1 : a + 1 ≤ b + 1, from add_one_le_of_lt H,
le_of_add_le_add_right H1

theorem sub_one_le_of_lt {a b : ℤ} (H : a ≤ b) : a - 1 < b :=
lt_of_add_one_le (begin rewrite algebra.sub_add_cancel, exact H end)

theorem lt_of_sub_one_le {a b : ℤ} (H : a - 1 < b) : a ≤ b :=
!sub_add_cancel ▸ add_one_le_of_lt H

theorem le_sub_one_of_lt {a b : ℤ} (H : a < b) : a ≤ b - 1 :=
le_of_lt_add_one begin rewrite algebra.sub_add_cancel, exact H end

theorem lt_of_le_sub_one {a b : ℤ} (H : a ≤ b - 1) : a < b :=
!sub_add_cancel ▸ (lt_add_one_of_le H)

theorem sign_of_succ (n : nat) : sign (nat.succ n) = 1 :=
sign_of_pos (of_nat_pos !nat.succ_pos)

theorem exists_eq_neg_succ_of_nat {a : ℤ} : a < 0 → ∃m : ℕ, a = -[1+m] :=
int.cases_on a
  (take (m : nat) H, absurd (of_nat_nonneg m : 0 ≤ m) (not_le_of_gt H))
  (take (m : nat) H, exists.intro m rfl)

theorem eq_one_of_mul_eq_one_right {a b : ℤ} (H : a ≥ 0) (H' : a * b = 1) : a = 1 :=
have a * b > 0, by rewrite H'; apply trivial,
have b > 0, from pos_of_mul_pos_left this H,
have a > 0, from pos_of_mul_pos_right `a * b > 0` (le_of_lt `b > 0`),
or.elim (le_or_gt a 1)
  (suppose a ≤ 1,
    show a = 1, from le.antisymm this (add_one_le_of_lt `a > 0`))
  (suppose a > 1,
    assert a * b ≥ 2 * 1,
      from mul_le_mul (add_one_le_of_lt `a > 1`) (add_one_le_of_lt `b > 0`) trivial H,
    have false, by rewrite [H' at this]; exact this,
    false.elim this)

theorem eq_one_of_mul_eq_one_left {a b : ℤ} (H : b ≥ 0) (H' : a * b = 1) : b = 1 :=
eq_one_of_mul_eq_one_right H (!mul.comm ▸ H')

theorem eq_one_of_mul_eq_self_left {a b : ℤ} (Hpos : a ≠ 0) (H : b * a = a) : b = 1 :=
eq_of_mul_eq_mul_right Hpos (H ⬝ (one_mul a)⁻¹)

theorem eq_one_of_mul_eq_self_right {a b : ℤ} (Hpos : b ≠ 0) (H : b * a = b) : a = 1 :=
eq_one_of_mul_eq_self_left Hpos (!mul.comm ▸ H)

theorem eq_one_of_dvd_one {a : ℤ} (H : a ≥ 0) (H' : a ∣ 1) : a = 1 :=
dvd.elim H'
  (take b,
    suppose 1 = a * b,
    eq_one_of_mul_eq_one_right H this⁻¹)

theorem exists_least_of_bdd {P : ℤ → Prop} [HP : decidable_pred P]
    (Hbdd : ∃ b : ℤ, ∀ z : ℤ, z ≤ b → ¬ P z)
        (Hinh : ∃ z : ℤ, P z) : ∃ lb : ℤ, P lb ∧ (∀ z : ℤ, z < lb → ¬ P z) :=
  begin
    cases Hbdd with [b, Hb],
    cases Hinh with [elt, Helt],
    existsi b + of_nat (least (λ n, P (b + of_nat n)) (nat.succ (nat_abs (elt - b)))),
    have Heltb : elt > b, begin
      apply lt_of_not_ge,
      intro Hge,
      apply (Hb _ Hge) Helt
    end,
    have H' : P (b + of_nat (nat_abs (elt - b))), begin
      rewrite [of_nat_nat_abs_of_nonneg (int.le_of_lt (iff.mpr !sub_pos_iff_lt Heltb)),
              add.comm, algebra.sub_add_cancel],
      apply Helt
    end,
    apply and.intro,
    apply least_of_lt _ !lt_succ_self H',
    intros z Hz,
    cases em (z ≤ b) with [Hzb, Hzb],
    apply Hb _ Hzb,
    let Hzb' := lt_of_not_ge Hzb,
    let Hpos := iff.mpr !sub_pos_iff_lt Hzb',
    have Hzbk : z = b + of_nat (nat_abs (z - b)),
      by rewrite [of_nat_nat_abs_of_nonneg (int.le_of_lt Hpos), int.add_comm, algebra.sub_add_cancel],
    have Hk : nat_abs (z - b) < least (λ n, P (b + of_nat n)) (nat.succ (nat_abs (elt - b))), begin
     let Hz' := iff.mp !lt_add_iff_sub_lt_left Hz,
     rewrite [-of_nat_nat_abs_of_nonneg (int.le_of_lt Hpos) at Hz'],
     apply lt_of_of_nat_lt_of_nat Hz'
    end,
    let Hk' := algebra.not_le_of_gt Hk,
    rewrite Hzbk,
    apply λ p, mt (ge_least_of_lt _ p) Hk',
    apply nat.lt_trans Hk,
    apply least_lt _ !lt_succ_self H'
  end

theorem exists_greatest_of_bdd {P : ℤ → Prop} [HP : decidable_pred P]
    (Hbdd : ∃ b : ℤ, ∀ z : ℤ, z ≥ b → ¬ P z)
        (Hinh : ∃ z : ℤ, P z) : ∃ ub : ℤ, P ub ∧ (∀ z : ℤ, z > ub → ¬ P z) :=
  begin
    cases Hbdd with [b, Hb],
    cases Hinh with [elt, Helt],
    existsi b - of_nat (least (λ n, P (b - of_nat n)) (nat.succ (nat_abs (b - elt)))),
    have Heltb : elt < b, begin
      apply lt_of_not_ge,
      intro Hge,
      apply (Hb _ Hge) Helt
    end,
    have H' : P (b - of_nat (nat_abs (b - elt))), begin
      rewrite [of_nat_nat_abs_of_nonneg (int.le_of_lt (iff.mpr !sub_pos_iff_lt Heltb)),
              sub_sub_self],
      apply Helt
    end,
    apply and.intro,
    apply least_of_lt _ !lt_succ_self H',
    intros z Hz,
    cases em (z ≥ b) with [Hzb, Hzb],
    apply Hb _ Hzb,
    let Hzb' := lt_of_not_ge Hzb,
    let Hpos := iff.mpr !sub_pos_iff_lt Hzb',
    have Hzbk : z = b - of_nat (nat_abs (b - z)),
      by rewrite [of_nat_nat_abs_of_nonneg (int.le_of_lt Hpos), sub_sub_self],
    have Hk : nat_abs (b - z) < least (λ n, P (b - of_nat n)) (nat.succ (nat_abs (b - elt))), begin
      let Hz' := iff.mp !lt_add_iff_sub_lt_left (iff.mpr !lt_add_iff_sub_lt_right Hz),
      rewrite [-of_nat_nat_abs_of_nonneg (int.le_of_lt Hpos) at Hz'],
      apply lt_of_of_nat_lt_of_nat Hz'
    end,
    let Hk' := algebra.not_le_of_gt Hk,
    rewrite Hzbk,
    apply λ p, mt (ge_least_of_lt _ p) Hk',
    apply nat.lt_trans Hk,
    apply least_lt _ !lt_succ_self H'
  end

end int
-												feat(library/data/int): replace int definition with structure and better computational behavior

											
										
										
											2014-12-05 22:03:24 +00:00
+								/-
 								Copyright (c) 2014 Floris van Doorn. All rights reserved.
 								Released under Apache 2.0 license as described in the file LICENSE.
 								Authors: Floris van Doorn, Jeremy Avigad
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								The order relation on the integers. We show that int is an instance of linear_comm_ordered_ring
 								and transfer the results.
-												feat(library/data/int): replace int definition with structure and better computational behavior

											
										
										
											2014-12-05 22:03:24 +00:00
+								-/
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								import .basic algebra.ordered_ring
-												refactor(library/data/nat): rename theorems

											
										
										
											2014-12-23 22:34:16 +00:00
+								open nat
-												fix(library): remove "-[notations]" hack at "open -[notations] algebra"

											
										
										
											2015-10-12 03:35:45 +00:00
+								open algebra
-												feat(frontends/lean): rename 'using' command to 'open'

Signed-off-by: Leonardo de Moura <leonardo@microsoft.com>

											
										
										
											2014-09-03 23:00:38 +00:00
+								open decidable
-												refactor(library): rename namespace eq_ops to eq.ops

											
										
										
											2014-10-02 00:51:17 +00:00
+								open int eq.ops
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
 								namespace int
-												feat(frontends/lean): new semantics for "protected" declarations

closes #426

											
										
										
											2015-02-11 20:49:27 +00:00
+								private definition nonneg (a : ℤ) : Prop := int.cases_on a (take n, true) (take n, false)
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								protected definition le (a b : ℤ) : Prop := nonneg (b - a)
-												refactor(library/data/int): make int instance of integral domain

											
										
										
											2014-12-22 19:21:22 +00:00
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								definition int_has_le [instance] [reducible] [priority int.prio]: has_le int :=
 								has_le.mk int.le
 								protected definition lt (a b : ℤ) : Prop := (a + 1) ≤ b
 								definition int_has_lt [instance] [reducible] [priority int.prio]: has_lt int :=
 								has_lt.mk int.lt
-												refactor(library/data/int): make int instance of integral domain

											
										
										
											2014-12-22 19:21:22 +00:00
-												feat(library/tactic/class_instance_synth): conservative class-instance resolution: expand only definitions marked as reducible

closes #442

											
										
										
											2015-02-24 22:09:20 +00:00
+								local attribute nonneg [reducible]
-												feat(frontends/lean): new semantics for "protected" declarations

closes #426

											
										
										
											2015-02-11 20:49:27 +00:00
+								private definition decidable_nonneg [instance] (a : ℤ) : decidable (nonneg a) := int.cases_on a _ _
-												refactor(library/data/int): make int instance of integral domain

											
										
										
											2014-12-22 19:21:22 +00:00
+								definition decidable_le [instance] (a b : ℤ) : decidable (a ≤ b) := decidable_nonneg _
 								definition decidable_lt [instance] (a b : ℤ) : decidable (a < b) := decidable_nonneg _
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								private theorem nonneg.elim {a : ℤ} : nonneg a → ∃n : ℕ, a = n :=
-												feat(library): clean up "sorry"s in library

Breaking changes: pnat was redefined to use subtype instead of a custom inductive type, which affects the notation for pnat 2 and 3

											
										
										
											2015-07-24 15:56:18 +00:00
+								int.cases_on a (take n H, exists.intro n rfl) (take n', false.elim)
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								private theorem nonneg_or_nonneg_neg (a : ℤ) : nonneg a ∨ nonneg (-a) :=
-												feat(frontends/lean): new semantics for "protected" declarations

closes #426

											
										
										
											2015-02-11 20:49:27 +00:00
+								int.cases_on a (take n, or.inl trivial) (take n, or.inr trivial)
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
 								theorem le.intro {a b : ℤ} {n : ℕ} (H : a + n = b) : a ≤ b :=
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								have n = b - a, from eq_add_neg_of_add_eq (begin rewrite [add.comm, H] end), -- !add.comm ▸ H),
-												feat(library): clean up "sorry"s in library

Breaking changes: pnat was redefined to use subtype instead of a custom inductive type, which affects the notation for pnat 2 and 3

											
										
										
											2015-07-24 15:56:18 +00:00
+								show nonneg (b - a), from this ▸ trivial
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								theorem le.elim {a b : ℤ} (H : a ≤ b) : ∃n : ℕ, a + n = b :=
 								obtain (n : ℕ) (H1 : b - a = n), from nonneg.elim H,
-												refactor(library): rename iff.mp' to iff.mpr

											
										
										
											2015-07-18 09:28:53 +00:00
+								exists.intro n (!add.comm ▸ iff.mpr !add_eq_iff_eq_add_neg (H1⁻¹))
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem le_total (a b : ℤ) : a ≤ b ∨ b ≤ a :=
-												feat(library): clean up "sorry"s in library

Breaking changes: pnat was redefined to use subtype instead of a custom inductive type, which affects the notation for pnat 2 and 3

											
										
										
											2015-07-24 15:56:18 +00:00
+								or.imp_right
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								  (assume H : nonneg (-(b - a)),
-												feat(library): clean up "sorry"s in library

Breaking changes: pnat was redefined to use subtype instead of a custom inductive type, which affects the notation for pnat 2 and 3

											
										
										
											2015-07-24 15:56:18 +00:00
+								   have -(b - a) = a - b, from !neg_sub,
-												refactor(library/data/{int,rat}/*): clean up casts between nat, int, and rat

											
										
										
											2015-09-12 14:00:34 +00:00
+								   show nonneg (a - b), from this ▸ H)
-												feat(library): clean up "sorry"s in library

Breaking changes: pnat was redefined to use subtype instead of a custom inductive type, which affects the notation for pnat 2 and 3

											
										
										
											2015-07-24 15:56:18 +00:00
+								  (nonneg_or_nonneg_neg (b - a))
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												feat/refactor(library/data/{int,rat}/*): improve casting from nat to int to rat

											
										
										
											2015-05-25 11:52:20 +00:00
+								theorem of_nat_le_of_nat_of_le {m n : ℕ} (H : #nat m ≤ n) : of_nat m ≤ of_nat n :=
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
+								obtain (k : ℕ) (Hk : m + k = n), from nat.le.elim H,
-												refactor(library/data/int/*): use better direction for of_nat theorems

											
										
										
											2015-05-25 10:00:41 +00:00
+								le.intro (Hk ▸ (of_nat_add m k)⁻¹)
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
 								theorem le_of_of_nat_le_of_nat {m n : ℕ} (H : of_nat m ≤ of_nat n) : (#nat m ≤ n) :=
 								obtain (k : ℕ) (Hk : of_nat m + of_nat k = of_nat n), from le.elim H,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have m + k = n, from of_nat.inj (of_nat_add m k ⬝ Hk),
 								nat.le.intro this
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
-												refactor(library/data/{int,rat}/*): clean up casts between nat, int, and rat

											
										
										
											2015-09-12 14:00:34 +00:00
+								theorem of_nat_le_of_nat_iff (m n : ℕ) : of_nat m ≤ of_nat n ↔ m ≤ n :=
-												feat/refactor(library/data/{int,rat}/*): improve casting from nat to int to rat

											
										
										
											2015-05-25 11:52:20 +00:00
+								iff.intro le_of_of_nat_le_of_nat of_nat_le_of_nat_of_le
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
 								theorem lt_add_succ (a : ℤ) (n : ℕ) : a < a + succ n :=
 								le.intro (show a + 1 + n = a + succ n, from
 								  calc
 								    a + 1 + n = a + (1 + n) : add.assoc
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								      ... = a + (n + 1)     : by rewrite (int.add_comm 1 n)
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								      ... = a + succ n      : rfl)
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								theorem lt.intro {a b : ℤ} {n : ℕ} (H : a + succ n = b) : a < b :=
 								H ▸ lt_add_succ a n
 								theorem lt.elim {a b : ℤ} (H : a < b) : ∃n : ℕ, a + succ n = b :=
 								obtain (n : ℕ) (Hn : a + 1 + n = b), from le.elim H,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have a + succ n = b, from
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								  calc
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								    a + succ n = a + 1 + n : by rewrite [add.assoc, int.add_comm 1 n]
-												refactor(library): remove 'simp' hack

											
										
										
											2015-07-22 17:13:19 +00:00
+								           ... = b         : Hn,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								exists.intro n this
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
-												refactor(library/data/{int,rat}/*): clean up casts between nat, int, and rat

											
										
										
											2015-09-12 14:00:34 +00:00
+								theorem of_nat_lt_of_nat_iff (n m : ℕ) : of_nat n < of_nat m ↔ n < m :=
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								calc
 								  of_nat n < of_nat m ↔ of_nat n + 1 ≤ of_nat m : iff.refl
-												feat(library.data.int.basic): move theorems about successor and predecessor from HoTT to standard library

											
										
										
											2015-05-15 00:18:29 +00:00
+								    ... ↔ of_nat (nat.succ n) ≤ of_nat m        : of_nat_succ n ▸ !iff.refl
-												refactor(library/data/{int,rat}/*): clean up casts between nat, int, and rat

											
										
										
											2015-09-12 14:00:34 +00:00
+								    ... ↔ nat.succ n ≤ m                        : of_nat_le_of_nat_iff
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								    ... ↔ n < m                                 : iff.symm (lt_iff_succ_le _ _)
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
+								theorem lt_of_of_nat_lt_of_nat {m n : ℕ} (H : of_nat m < of_nat n) : #nat m < n :=
-												refactor(library/data/{int,rat}/*): clean up casts between nat, int, and rat

											
										
										
											2015-09-12 14:00:34 +00:00
+								iff.mp !of_nat_lt_of_nat_iff H
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
-												feat/refactor(library/data/{int,rat}/*): improve casting from nat to int to rat

											
										
										
											2015-05-25 11:52:20 +00:00
+								theorem of_nat_lt_of_nat_of_lt {m n : ℕ} (H : #nat m < n) : of_nat m < of_nat n :=
-												refactor(library/data/{int,rat}/*): clean up casts between nat, int, and rat

											
										
										
											2015-09-12 14:00:34 +00:00
+								iff.mpr !of_nat_lt_of_nat_iff H
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								/- show that the integers form an ordered additive group -/
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem le_refl (a : ℤ) : a ≤ a :=
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								le.intro (add_zero a)
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem le_trans {a b c : ℤ} (H1 : a ≤ b) (H2 : b ≤ c) : a ≤ c :=
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								obtain (n : ℕ) (Hn : a + n = b), from le.elim H1,
 								obtain (m : ℕ) (Hm : b + m = c), from le.elim H2,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have a + of_nat (n + m) = c, from
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
+								  calc
-												refactor(library/data/int/*): use better direction for of_nat theorems

											
										
										
											2015-05-25 10:00:41 +00:00
+								    a + of_nat (n + m) = a + (of_nat n + m) : {of_nat_add n m}
-												refactor(library/data/int/basic): make the integers an instance of ring

											
										
										
											2014-12-17 18:32:38 +00:00
+								      ... = a + n + m : (add.assoc a n m)⁻¹
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
+								      ... = b + m : {Hn}
 								      ... = c : Hm,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								le.intro this
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem le_antisymm : ∀ {a b : ℤ}, a ≤ b → b ≤ a → a = b :=
-												refactor(library/data/int/order): cleanup

											
										
										
											2015-03-28 19:50:28 +00:00
+								take a b : ℤ, assume (H₁ : a ≤ b) (H₂ : b ≤ a),
 								obtain (n : ℕ) (Hn : a + n = b), from le.elim H₁,
 								obtain (m : ℕ) (Hm : b + m = a), from le.elim H₂,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have a + of_nat (n + m) = a + 0, from
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
+								  calc
-												fix(library/data): hf, int, nat, pnat

											
										
										
											2015-10-09 19:47:55 +00:00
+								    a + of_nat (n + m) = a + (of_nat n + m) : by rewrite of_nat_add
 								      ... = a + n + m                       : by rewrite add.assoc
 								      ... = b + m                           : by rewrite Hn
 								      ... = a                               : by rewrite Hm
 								      ... = a + 0                           : by rewrite add_zero,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have of_nat (n + m) = of_nat 0, from add.left_cancel this,
 								have n + m = 0,                 from of_nat.inj this,
-												feat(*): new numeral encoding

											
										
										
											2015-10-12 03:29:31 +00:00
+								assert n = 0,                     from nat.eq_zero_of_add_eq_zero_right this,
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
+								show a = b, from
 								  calc
-												feat(*): new numeral encoding

											
										
										
											2015-10-12 03:29:31 +00:00
+								    a = a + 0    : add_zero
 								  ... = a + n    : by rewrite this
 								  ... = b        : Hn
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem lt_irrefl (a : ℤ) : ¬ a < a :=
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								(suppose a < a,
 								  obtain (n : ℕ) (Hn : a + succ n = a), from lt.elim this,
 								  have a + succ n = a + 0, from
-												feat(library): clean up "sorry"s in library

Breaking changes: pnat was redefined to use subtype instead of a custom inductive type, which affects the notation for pnat 2 and 3

											
										
										
											2015-07-24 15:56:18 +00:00
+								    Hn ⬝ !add_zero⁻¹,
 								  !succ_ne_zero (of_nat.inj (add.left_cancel this)))
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem ne_of_lt {a b : ℤ} (H : a < b) : a ≠ b :=
 								(suppose a = b, absurd (this ▸ H) (int.lt_irrefl b))
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								theorem le_of_lt {a b : ℤ} (H : a < b) : a ≤ b :=
 								obtain (n : ℕ) (Hn : a + succ n = b), from lt.elim H,
 								le.intro Hn
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem lt_iff_le_and_ne (a b : ℤ) : a < b ↔ (a ≤ b ∧ a ≠ b) :=
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								iff.intro
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								  (assume H, and.intro (le_of_lt H) (int.ne_of_lt H))
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								  (assume H,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								    have a ≤ b, from and.elim_left H,
 								    have a ≠ b, from and.elim_right H,
 								    obtain (n : ℕ) (Hn : a + n = b), from le.elim `a ≤ b`,
 								    have n ≠ 0, from (assume H' : n = 0, `a ≠ b` (!add_zero ▸ H' ▸ Hn)),
 								    obtain (k : ℕ) (Hk : n = nat.succ k), from nat.exists_eq_succ_of_ne_zero this,
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								    lt.intro (Hk ▸ Hn))
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem le_iff_lt_or_eq (a b : ℤ) : a ≤ b ↔ (a < b ∨ a = b) :=
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								iff.intro
 								  (assume H,
 								    by_cases
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								      (suppose a = b, or.inr this)
 								      (suppose a ≠ b,
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								        obtain (n : ℕ) (Hn : a + n = b), from le.elim H,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								        have n ≠ 0, from (assume H' : n = 0, `a ≠ b` (!add_zero ▸ H' ▸ Hn)),
 								        obtain (k : ℕ) (Hk : n = nat.succ k), from nat.exists_eq_succ_of_ne_zero this,
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								        or.inl (lt.intro (Hk ▸ Hn))))
 								  (assume H,
 								    or.elim H
 								      (assume H1, le_of_lt H1)
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								      (assume H1, H1 ▸ !int.le_refl))
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								theorem lt_succ (a : ℤ) : a < a + 1 :=
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								int.le_refl (a + 1)
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem add_le_add_left {a b : ℤ} (H : a ≤ b) (c : ℤ) : c + a ≤ c + b :=
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								obtain (n : ℕ) (Hn : a + n = b), from le.elim H,
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
+								have H2 : c + a + n = c + b, from
 								  calc
-												refactor(library/data/int/basic): make the integers an instance of ring

											
										
										
											2014-12-17 18:32:38 +00:00
+								    c + a + n = c + (a + n) : add.assoc c a n
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
+								      ... = c + b : {Hn},
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								le.intro H2
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem add_lt_add_left {a b : ℤ} (H : a < b) (c : ℤ) : c + a < c + b :=
-												feat/refactor(library/*): various additions and improvements

											
										
										
											2015-06-01 01:39:59 +00:00
+								let H' := le_of_lt H in
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								(iff.mpr (int.lt_iff_le_and_ne _ _)) (and.intro (int.add_le_add_left H' _)
-												feat(data): update orderings on int and nat to conform to new algebraic hierarchy

											
										
										
											2015-05-29 03:34:57 +00:00
+								                                  (take Heq, let Heq' := add_left_cancel Heq in
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								                                   !int.lt_irrefl (Heq' ▸ H)))
-												feat(data): update orderings on int and nat to conform to new algebraic hierarchy

											
										
										
											2015-05-29 03:34:57 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem mul_nonneg {a b : ℤ} (Ha : 0 ≤ a) (Hb : 0 ≤ b) : 0 ≤ a * b :=
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								obtain (n : ℕ) (Hn : 0 + n = a), from le.elim Ha,
 								obtain (m : ℕ) (Hm : 0 + m = b), from le.elim Hb,
 								le.intro
 								  (eq.symm
 								    (calc
-												fix(library/data): hf, int, nat, pnat

											
										
										
											2015-10-09 19:47:55 +00:00
+								      a * b = (0 + n) * b : by rewrite Hn
 								        ... = n * b       : by rewrite zero_add
 								        ... = n * (0 + m) : by rewrite Hm
 								        ... = n * m       : by rewrite zero_add
 								        ... = 0 + n * m   : by rewrite zero_add))
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem mul_pos {a b : ℤ} (Ha : 0 < a) (Hb : 0 < b) : 0 < a * b :=
-												feat(library.data.int.basic): move theorems about successor and predecessor from HoTT to standard library

											
										
										
											2015-05-15 00:18:29 +00:00
+								obtain (n : ℕ) (Hn : 0 + nat.succ n = a), from lt.elim Ha,
 								obtain (m : ℕ) (Hm : 0 + nat.succ m = b), from lt.elim Hb,
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								lt.intro
 								  (eq.symm
 								    (calc
-												fix(library/data): hf, int, nat, pnat

											
										
										
											2015-10-09 19:47:55 +00:00
+								      a * b = (0 + nat.succ n) * b                     : by rewrite Hn
 								        ... = nat.succ n * b                           : by rewrite zero_add
 								        ... = nat.succ n * (0 + nat.succ m)            : by rewrite Hm
 								        ... = nat.succ n * nat.succ m                  : by rewrite zero_add
 								        ... = of_nat (nat.succ n * nat.succ m)         : by rewrite of_nat_mul
 								        ... = of_nat (nat.succ n * m + nat.succ n)     : by rewrite nat.mul_succ
 								        ... = of_nat (nat.succ (nat.succ n * m + n))   : by rewrite nat.add_succ
 								        ... = 0 + nat.succ (nat.succ n * m + n)        : by rewrite zero_add))
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem zero_lt_one : (0 : ℤ) < 1 := trivial
-												feat(data): update orderings on int and nat to conform to new algebraic hierarchy

											
										
										
											2015-05-29 03:34:57 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem not_le_of_gt {a b : ℤ} (H : a < b) : ¬ b ≤ a :=
-												feat(data): update orderings on int and nat to conform to new algebraic hierarchy

											
										
										
											2015-05-29 03:34:57 +00:00
+								  assume Hba,
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								  let Heq := int.le_antisymm (le_of_lt H) Hba in
 								  !int.lt_irrefl (Heq ▸ H)
-												feat(data): update orderings on int and nat to conform to new algebraic hierarchy

											
										
										
											2015-05-29 03:34:57 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem lt_of_lt_of_le {a b c : ℤ} (Hab : a < b) (Hbc : b ≤ c) : a < c :=
-												feat(data): update orderings on int and nat to conform to new algebraic hierarchy

											
										
										
											2015-05-29 03:34:57 +00:00
+								  let Hab' := le_of_lt Hab in
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								  let Hac := int.le_trans Hab' Hbc in
 								  (iff.mpr !int.lt_iff_le_and_ne) (and.intro Hac
 								    (assume Heq, int.not_le_of_gt (Heq ▸ Hab) Hbc))
-												feat(data): update orderings on int and nat to conform to new algebraic hierarchy

											
										
										
											2015-05-29 03:34:57 +00:00
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								protected theorem lt_of_le_of_lt  {a b c : ℤ} (Hab : a ≤ b) (Hbc : b < c) : a < c :=
-												feat(data): update orderings on int and nat to conform to new algebraic hierarchy

											
										
										
											2015-05-29 03:34:57 +00:00
+								  let Hbc' := le_of_lt Hbc in
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								  let Hac := int.le_trans Hab Hbc' in
 								  (iff.mpr !int.lt_iff_le_and_ne) (and.intro Hac
 								    (assume Heq, int.not_le_of_gt (Heq⁻¹ ▸ Hbc) Hab))
-												feat(data): update orderings on int and nat to conform to new algebraic hierarchy

											
										
										
											2015-05-29 03:34:57 +00:00
-												fix(library/data/int,library/data/rat): int and rat

											
										
										
											2015-10-09 21:50:17 +00:00
+								protected definition linear_ordered_comm_ring [reducible] [trans_instance] :
-												fix(library/data/nat,int): make structure instances reducible

											
										
										
											2015-01-26 17:01:19 +00:00
+								    algebra.linear_ordered_comm_ring int :=
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								⦃algebra.linear_ordered_comm_ring, int.integral_domain,
 								  le               := int.le,
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								  le_refl          := int.le_refl,
 								  le_trans         := @int.le_trans,
 								  le_antisymm      := @int.le_antisymm,
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								  lt               := int.lt,
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								  le_of_lt         := @int.le_of_lt,
 								  lt_irrefl        := int.lt_irrefl,
 								  lt_of_lt_of_le   := @int.lt_of_lt_of_le,
 								  lt_of_le_of_lt   := @int.lt_of_le_of_lt,
 								  add_le_add_left  := @int.add_le_add_left,
 								  mul_nonneg       := @int.mul_nonneg,
 								  mul_pos          := @int.mul_pos,
 								  le_iff_lt_or_eq  := int.le_iff_lt_or_eq,
 								  le_total         := int.le_total,
 								  zero_ne_one      := int.zero_ne_one,
 								  zero_lt_one      := int.zero_lt_one,
 								  add_lt_add_left  := @int.add_lt_add_left⦄
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
 								protected definition decidable_linear_ordered_comm_ring [reducible] [instance] :
-												feat(library/algebra/ordered_ring,library/data/int/): add sign and theorems about abs, make int an instance, port theorems

											
										
										
											2015-01-21 20:50:42 +00:00
+								    algebra.decidable_linear_ordered_comm_ring int :=
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								⦃algebra.decidable_linear_ordered_comm_ring,
 								 int.linear_ordered_comm_ring,
 								 decidable_lt := decidable_lt⦄
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
 								/- more facts specific to int -/
-												feat/refactor(library/data/{int,rat}/*): improve casting from nat to int to rat

											
										
										
											2015-05-25 11:52:20 +00:00
+								theorem of_nat_nonneg (n : ℕ) : 0 ≤ of_nat n := trivial
 								theorem of_nat_pos {n : ℕ} (Hpos : #nat n > 0) : of_nat n > 0 :=
 								of_nat_lt_of_nat_of_lt Hpos
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
-												feat(library/rat/basic.lean): add reduce for rat, and num and denom

											
										
										
											2015-06-10 02:46:30 +00:00
+								theorem of_nat_succ_pos (n : nat) : of_nat (nat.succ n) > 0 :=
 								of_nat_pos !nat.succ_pos
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								theorem exists_eq_of_nat {a : ℤ} (H : 0 ≤ a) : ∃n : ℕ, a = of_nat n :=
 								obtain (n : ℕ) (H1 : 0 + of_nat n = a), from le.elim H,
 								exists.intro n (!zero_add ▸ (H1⁻¹))
 								theorem exists_eq_neg_of_nat {a : ℤ} (H : a ≤ 0) : ∃n : ℕ, a = -(of_nat n) :=
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have -a ≥ 0, from iff.mpr !neg_nonneg_iff_nonpos H,
 								obtain (n : ℕ) (Hn : -a = of_nat n), from exists_eq_of_nat this,
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								exists.intro n (eq_neg_of_eq_neg (Hn⁻¹))
 								theorem of_nat_nat_abs_of_nonneg {a : ℤ} (H : a ≥ 0) : of_nat (nat_abs a) = a :=
 								obtain (n : ℕ) (Hn : a = of_nat n), from exists_eq_of_nat H,
 								Hn⁻¹ ▸ congr_arg of_nat (nat_abs_of_nat n)
 								theorem of_nat_nat_abs_of_nonpos {a : ℤ} (H : a ≤ 0) : of_nat (nat_abs a) = -a :=
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have -a ≥ 0, from iff.mpr !neg_nonneg_iff_nonpos H,
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
+								calc
 								  of_nat (nat_abs a) = of_nat (nat_abs (-a)) : nat_abs_neg
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								                 ... = -a                    : of_nat_nat_abs_of_nonneg this
-												refactor(library/data/int,library/algebra): make int an instnance of ordered ring, rename theorems

											
										
										
											2014-12-26 21:25:05 +00:00
-												refactor(*): modify '|' binding power, use 'abs a' instead of '|a|', and '(a | b)' instead of 'a | b'

											
										
										
											2015-02-25 23:18:21 +00:00
+								theorem of_nat_nat_abs (b : ℤ) : nat_abs b = abs b :=
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
+								or.elim (le.total 0 b)
 								  (assume H : b ≥ 0, of_nat_nat_abs_of_nonneg H ⬝ (abs_of_nonneg H)⁻¹)
 								  (assume H : b ≤ 0, of_nat_nat_abs_of_nonpos H ⬝ (abs_of_nonpos H)⁻¹)
-												feat/refactor(library/*): various additions and improvements

											
										
										
											2015-06-01 01:39:59 +00:00
+								theorem nat_abs_abs (a : ℤ) : nat_abs (abs a) = nat_abs a :=
 								abs.by_cases rfl !nat_abs_neg
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
+								theorem lt_of_add_one_le {a b : ℤ} (H : a + 1 ≤ b) : a < b :=
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								obtain (n : nat) (H1 : a + 1 + n = b), from le.elim H,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have a + succ n = b, by rewrite [-H1, add.assoc, add.comm 1],
 								lt.intro this
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
 								theorem add_one_le_of_lt {a b : ℤ} (H : a < b) : a + 1 ≤ b :=
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								obtain (n : nat) (H1 : a + succ n = b), from lt.elim H,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have a + 1 + n = b, by rewrite [-H1, add.assoc, add.comm 1],
 								le.intro this
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
-												feat(library/data/int/div.lean): add theorems about div

											
										
										
											2015-03-13 03:43:19 +00:00
+								theorem lt_add_one_of_le {a b : ℤ} (H : a ≤ b) : a < b + 1 :=
 								lt_add_of_le_of_pos H trivial
 								theorem le_of_lt_add_one {a b : ℤ} (H : a < b + 1) : a ≤ b :=
 								have H1 : a + 1 ≤ b + 1, from add_one_le_of_lt H,
 								le_of_add_le_add_right H1
 								theorem sub_one_le_of_lt {a b : ℤ} (H : a ≤ b) : a - 1 < b :=
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								lt_of_add_one_le (begin rewrite algebra.sub_add_cancel, exact H end)
-												feat(library/data/int/div.lean): add theorems about div

											
										
										
											2015-03-13 03:43:19 +00:00
 								theorem lt_of_sub_one_le {a b : ℤ} (H : a - 1 < b) : a ≤ b :=
 								!sub_add_cancel ▸ add_one_le_of_lt H
 								theorem le_sub_one_of_lt {a b : ℤ} (H : a < b) : a ≤ b - 1 :=
-												fix(library/data): hf, int, nat, pnat

											
										
										
											2015-10-09 19:47:55 +00:00
+								le_of_lt_add_one begin rewrite algebra.sub_add_cancel, exact H end
-												feat(library/data/int/div.lean): add theorems about div

											
										
										
											2015-03-13 03:43:19 +00:00
 								theorem lt_of_le_sub_one {a b : ℤ} (H : a ≤ b - 1) : a < b :=
 								!sub_add_cancel ▸ (lt_add_one_of_le H)
-												feat(library.data.int.basic): move theorems about successor and predecessor from HoTT to standard library

											
										
										
											2015-05-15 00:18:29 +00:00
+								theorem sign_of_succ (n : nat) : sign (nat.succ n) = 1 :=
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
+								sign_of_pos (of_nat_pos !nat.succ_pos)
-												fix(library/data/int/basic): change notation from -[n+1] to -[1+n] to avoid conflict e.g. with -[coercions]

											
										
										
											2015-06-29 05:16:58 +00:00
+								theorem exists_eq_neg_succ_of_nat {a : ℤ} : a < 0 → ∃m : ℕ, a = -[1+m] :=
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
+								int.cases_on a
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								  (take (m : nat) H, absurd (of_nat_nonneg m : 0 ≤ m) (not_le_of_gt H))
 								  (take (m : nat) H, exists.intro m rfl)
-												feat/refactor(library/data/int): revise and add theorems

											
										
										
											2015-02-25 19:14:57 +00:00
-												feat/refactor(library/*): various additions and improvements

											
										
										
											2015-06-01 01:39:59 +00:00
+								theorem eq_one_of_mul_eq_one_right {a b : ℤ} (H : a ≥ 0) (H' : a * b = 1) : a = 1 :=
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								have a * b > 0, by rewrite H'; apply trivial,
 								have b > 0, from pos_of_mul_pos_left this H,
 								have a > 0, from pos_of_mul_pos_right `a * b > 0` (le_of_lt `b > 0`),
-												feat/refactor(library/*): various additions and improvements

											
										
										
											2015-06-01 01:39:59 +00:00
+								or.elim (le_or_gt a 1)
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								  (suppose a ≤ 1,
 								    show a = 1, from le.antisymm this (add_one_le_of_lt `a > 0`))
 								  (suppose a > 1,
 								    assert a * b ≥ 2 * 1,
 								      from mul_le_mul (add_one_le_of_lt `a > 1`) (add_one_le_of_lt `b > 0`) trivial H,
 								    have false, by rewrite [H' at this]; exact this,
 								    false.elim this)
-												feat/refactor(library/*): various additions and improvements

											
										
										
											2015-06-01 01:39:59 +00:00
 								theorem eq_one_of_mul_eq_one_left {a b : ℤ} (H : b ≥ 0) (H' : a * b = 1) : b = 1 :=
 								eq_one_of_mul_eq_one_right H (!mul.comm ▸ H')
 								theorem eq_one_of_mul_eq_self_left {a b : ℤ} (Hpos : a ≠ 0) (H : b * a = a) : b = 1 :=
 								eq_of_mul_eq_mul_right Hpos (H ⬝ (one_mul a)⁻¹)
 								theorem eq_one_of_mul_eq_self_right {a b : ℤ} (Hpos : b ≠ 0) (H : b * a = b) : a = 1 :=
 								eq_one_of_mul_eq_self_left Hpos (!mul.comm ▸ H)
 								theorem eq_one_of_dvd_one {a : ℤ} (H : a ≥ 0) (H' : a ∣ 1) : a = 1 :=
 								dvd.elim H'
 								  (take b,
-												refactor(library/data): cleanup proofs using new features

											
										
										
											2015-07-21 16:10:56 +00:00
+								    suppose 1 = a * b,
 								    eq_one_of_mul_eq_one_right H this⁻¹)
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
-												refactor(library/data/int/order): use 'exists' instead of 'ex', 'least' instead of 'smallest', etc.

											
										
										
											2015-09-13 00:51:34 +00:00
+								theorem exists_least_of_bdd {P : ℤ → Prop} [HP : decidable_pred P]
 								    (Hbdd : ∃ b : ℤ, ∀ z : ℤ, z ≤ b → ¬ P z)
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								        (Hinh : ∃ z : ℤ, P z) : ∃ lb : ℤ, P lb ∧ (∀ z : ℤ, z < lb → ¬ P z) :=
 								  begin
 								    cases Hbdd with [b, Hb],
 								    cases Hinh with [elt, Helt],
 								    existsi b + of_nat (least (λ n, P (b + of_nat n)) (nat.succ (nat_abs (elt - b)))),
 								    have Heltb : elt > b, begin
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								      apply lt_of_not_ge,
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								      intro Hge,
 								      apply (Hb _ Hge) Helt
 								    end,
 								    have H' : P (b + of_nat (nat_abs (elt - b))), begin
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								      rewrite [of_nat_nat_abs_of_nonneg (int.le_of_lt (iff.mpr !sub_pos_iff_lt Heltb)),
 								              add.comm, algebra.sub_add_cancel],
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								      apply Helt
 								    end,
 								    apply and.intro,
 								    apply least_of_lt _ !lt_succ_self H',
 								    intros z Hz,
 								    cases em (z ≤ b) with [Hzb, Hzb],
 								    apply Hb _ Hzb,
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								    let Hzb' := lt_of_not_ge Hzb,
 								    let Hpos := iff.mpr !sub_pos_iff_lt Hzb',
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    have Hzbk : z = b + of_nat (nat_abs (z - b)),
-												refactor(library/data/int/{basic,order}): protect theorem names

											
										
										
											2015-10-22 20:36:45 +00:00
+								      by rewrite [of_nat_nat_abs_of_nonneg (int.le_of_lt Hpos), int.add_comm, algebra.sub_add_cancel],
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    have Hk : nat_abs (z - b) < least (λ n, P (b + of_nat n)) (nat.succ (nat_abs (elt - b))), begin
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								     let Hz' := iff.mp !lt_add_iff_sub_lt_left Hz,
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								     rewrite [-of_nat_nat_abs_of_nonneg (int.le_of_lt Hpos) at Hz'],
-												refactor(library/data/{int,rat}/*): clean up casts between nat, int, and rat

											
										
										
											2015-09-12 14:00:34 +00:00
+								     apply lt_of_of_nat_lt_of_nat Hz'
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    end,
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								    let Hk' := algebra.not_le_of_gt Hk,
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    rewrite Hzbk,
 								    apply λ p, mt (ge_least_of_lt _ p) Hk',
-												refactor(library/init/nat,library/data/nat/*): chagne dots to underscores in protected names

											
										
										
											2015-10-22 21:35:27 +00:00
+								    apply nat.lt_trans Hk,
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    apply least_lt _ !lt_succ_self H'
 								  end
-												refactor(library/data/int/order): use 'exists' instead of 'ex', 'least' instead of 'smallest', etc.

											
										
										
											2015-09-13 00:51:34 +00:00
+								theorem exists_greatest_of_bdd {P : ℤ → Prop} [HP : decidable_pred P]
 								    (Hbdd : ∃ b : ℤ, ∀ z : ℤ, z ≥ b → ¬ P z)
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								        (Hinh : ∃ z : ℤ, P z) : ∃ ub : ℤ, P ub ∧ (∀ z : ℤ, z > ub → ¬ P z) :=
 								  begin
 								    cases Hbdd with [b, Hb],
 								    cases Hinh with [elt, Helt],
 								    existsi b - of_nat (least (λ n, P (b - of_nat n)) (nat.succ (nat_abs (b - elt)))),
 								    have Heltb : elt < b, begin
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								      apply lt_of_not_ge,
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								      intro Hge,
 								      apply (Hb _ Hge) Helt
 								    end,
 								    have H' : P (b - of_nat (nat_abs (b - elt))), begin
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								      rewrite [of_nat_nat_abs_of_nonneg (int.le_of_lt (iff.mpr !sub_pos_iff_lt Heltb)),
 								              sub_sub_self],
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								      apply Helt
 								    end,
 								    apply and.intro,
 								    apply least_of_lt _ !lt_succ_self H',
 								    intros z Hz,
 								    cases em (z ≥ b) with [Hzb, Hzb],
 								    apply Hb _ Hzb,
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								    let Hzb' := lt_of_not_ge Hzb,
 								    let Hpos := iff.mpr !sub_pos_iff_lt Hzb',
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    have Hzbk : z = b - of_nat (nat_abs (b - z)),
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								      by rewrite [of_nat_nat_abs_of_nonneg (int.le_of_lt Hpos), sub_sub_self],
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    have Hk : nat_abs (b - z) < least (λ n, P (b - of_nat n)) (nat.succ (nat_abs (b - elt))), begin
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								      let Hz' := iff.mp !lt_add_iff_sub_lt_left (iff.mpr !lt_add_iff_sub_lt_right Hz),
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								      rewrite [-of_nat_nat_abs_of_nonneg (int.le_of_lt Hpos) at Hz'],
-												refactor(library/data/{int,rat}/*): clean up casts between nat, int, and rat

											
										
										
											2015-09-12 14:00:34 +00:00
+								      apply lt_of_of_nat_lt_of_nat Hz'
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    end,
-												refactor(library): use type classes for encoding all arithmetic operations

Before this commit we were using overloading for concrete structures and
type classes for abstract ones.

This is the first of series of commits that implement this modification

											
										
										
											2015-10-07 23:44:47 +00:00
+								    let Hk' := algebra.not_le_of_gt Hk,
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    rewrite Hzbk,
 								    apply λ p, mt (ge_least_of_lt _ p) Hk',
-												refactor(library/init/nat,library/data/nat/*): chagne dots to underscores in protected names

											
										
										
											2015-10-22 21:35:27 +00:00
+								    apply nat.lt_trans Hk,
-												refactor(library/data/real): move and rename theorems

											
										
										
											2015-09-11 03:00:18 +00:00
+								    apply least_lt _ !lt_succ_self H'
 								  end
-												feat/refactor(library/*): various additions and improvements

											
										
										
											2015-06-01 01:39:59 +00:00
-												refactor(library/standard/data/int): split basic.lean into basic.lean and order.lean

											
										
										
											2014-08-23 00:56:25 +00:00
+								end int