lean2/library/algebra/field.lean

/-
Copyright (c) 2014 Robert Lewis. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Robert Lewis

Structures with multiplicative and additive components, including division rings and fields.
The development is modeled after Isabelle's library.
-/
import logic.eq logic.connectives data.unit data.sigma data.prod
import algebra.binary algebra.group algebra.ring
open eq eq.ops

namespace algebra

variable {A : Type}

structure division_ring [class] (A : Type) extends ring A, has_inv A, zero_ne_one_class A :=
  (mul_inv_cancel : ∀{a}, a ≠ zero → mul a (inv a) = one)
  (inv_mul_cancel : ∀{a}, a ≠ zero → mul (inv a) a = one)

section division_ring
  variables [s : division_ring A] {a b c : A}
  include s

  protected definition div (a b : A) : A := a * b⁻¹

  definition division_ring_has_div [reducible] [instance] : has_div A :=
  has_div.mk algebra.div

  lemma division.def (a b : A) : a / b = a * b⁻¹ :=
  rfl

  theorem mul_inv_cancel (H : a ≠ 0) : a * a⁻¹ = 1 :=
  division_ring.mul_inv_cancel H

  theorem inv_mul_cancel (H : a ≠ 0) : a⁻¹ * a = 1 :=
  division_ring.inv_mul_cancel H

  theorem inv_eq_one_div (a : A) : a⁻¹ = 1 / a := !one_mul⁻¹

  theorem div_eq_mul_one_div (a b : A) : a / b = a * (1 / b) :=
    by rewrite [*division.def, one_mul]

  theorem mul_one_div_cancel (H : a ≠ 0) : a * (1 / a) = 1 :=
    by rewrite [-inv_eq_one_div, (mul_inv_cancel H)]

  theorem one_div_mul_cancel (H : a ≠ 0) : (1 / a) * a = 1 :=
    by rewrite [-inv_eq_one_div, (inv_mul_cancel H)]

  theorem div_self (H : a ≠ 0) : a / a = 1 := mul_inv_cancel H

  theorem one_div_one : 1 / 1 = (1:A) := div_self (ne.symm zero_ne_one)

  theorem mul_div_assoc (a b : A) : (a * b) / c = a * (b / c) := !mul.assoc

  theorem one_div_ne_zero (H : a ≠ 0) : 1 / a ≠ 0 :=
    assume H2 : 1 / a = 0,
    have C1 : 0 = (1:A), from symm (by rewrite [-(mul_one_div_cancel H), H2, mul_zero]),
    absurd C1 zero_ne_one

  theorem one_inv_eq : 1⁻¹ = (1:A) :=
  by rewrite [-mul_one, inv_mul_cancel (ne.symm (@zero_ne_one A _))]

  theorem div_one (a : A) : a / 1 = a :=
    by rewrite [*division.def, one_inv_eq, mul_one]

  theorem zero_div (a : A) : 0 / a = 0 := !zero_mul

  -- note: integral domain has a "mul_ne_zero". A commutative division ring is an integral
  -- domain, but let's not define that class for now.
  theorem division_ring.mul_ne_zero (Ha : a ≠ 0) (Hb : b ≠ 0) : a * b ≠ 0 :=
    assume H : a * b = 0,
    have C1 : a = 0, by rewrite [-mul_one, -(mul_one_div_cancel Hb), -mul.assoc, H, zero_mul],
      absurd C1 Ha

  theorem mul_ne_zero_comm (H : a * b ≠ 0) : b * a ≠ 0 :=
    have H2 : a ≠ 0 ∧ b ≠ 0, from ne_zero_and_ne_zero_of_mul_ne_zero H,
    division_ring.mul_ne_zero (and.right H2) (and.left H2)

  theorem eq_one_div_of_mul_eq_one (H : a * b = 1) : b = 1 / a :=
    have a ≠ 0, from
      (suppose a = 0,
       have 0 = (1:A), by rewrite [-(zero_mul b), -this, H],
       absurd this zero_ne_one),
    show b = 1 / a, from symm (calc
      1 / a = (1 / a) * 1       : mul_one
        ... = (1 / a) * (a * b) : H
        ... = (1 / a) * a * b   : mul.assoc
        ... = 1 * b             : one_div_mul_cancel this
        ... = b                 : one_mul)

  theorem eq_one_div_of_mul_eq_one_left (H : b * a = 1) : b = 1 / a :=
    have a ≠ 0, from
      (suppose a = 0,
       have 0 = 1, from symm (calc
          1 = b * a : symm H
        ... = b * 0 : this
        ... = 0     : mul_zero),
      absurd this zero_ne_one),
    show b = 1 / a, from symm (calc
      1 / a = 1 * (1 / a)       : one_mul
        ... = b * a * (1 / a)   : H
        ... = b * (a * (1 / a)) : mul.assoc
        ... = b * 1             : mul_one_div_cancel this
        ... = b                 : mul_one)

  theorem division_ring.one_div_mul_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) :
      (1 / a) * (1 / b) = 1 / (b * a) :=
    have (b * a) * ((1 / a) * (1 / b)) = 1, by
      rewrite [mul.assoc, -(mul.assoc a), (mul_one_div_cancel Ha), one_mul,
               (mul_one_div_cancel Hb)],
    eq_one_div_of_mul_eq_one this

  theorem one_div_neg_one_eq_neg_one : (1:A) / (-1) = -1 :=
    have (-1) * (-1) = (1:A), by rewrite [-neg_eq_neg_one_mul, neg_neg],
    symm (eq_one_div_of_mul_eq_one this)

  theorem division_ring.one_div_neg_eq_neg_one_div (H : a ≠ 0) : 1 / (- a) = - (1 / a) :=
    have -1 ≠ 0, from
      (suppose -1 = 0, absurd (symm (calc
          1 = -(-1) : neg_neg
        ... = -0    : this
        ... = (0:A) : neg_zero)) zero_ne_one),
    calc
      1 / (- a) = 1 / ((-1) * a)        : neg_eq_neg_one_mul
            ... = (1 / a) * (1 / (- 1)) : division_ring.one_div_mul_one_div H this
            ... = (1 / a) * (-1)        : one_div_neg_one_eq_neg_one
            ... = - (1 / a)             : mul_neg_one_eq_neg

  theorem div_neg_eq_neg_div (b : A) (Ha : a ≠ 0) : b / (- a) = - (b / a) :=
    calc
      b / (- a) = b * (1 / (- a)) : by rewrite -inv_eq_one_div
            ... = b * -(1 / a)    : division_ring.one_div_neg_eq_neg_one_div Ha
            ... = -(b * (1 / a))  : neg_mul_eq_mul_neg
            ... = - (b * a⁻¹)     : inv_eq_one_div

  theorem neg_div (a b : A) : (-b) / a = - (b / a) :=
    by rewrite [neg_eq_neg_one_mul, mul_div_assoc, -neg_eq_neg_one_mul]

  theorem division_ring.neg_div_neg_eq (a : A) {b : A} (Hb : b ≠ 0) : (-a) / (-b) = a / b :=
    by rewrite [(div_neg_eq_neg_div _ Hb), neg_div, neg_neg]

  theorem division_ring.one_div_one_div (H : a ≠ 0) : 1 / (1 / a) = a :=
    symm (eq_one_div_of_mul_eq_one_left (mul_one_div_cancel H))

  theorem division_ring.eq_of_one_div_eq_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) (H : 1 / a = 1 / b) :
      a = b :=
    by rewrite [-(division_ring.one_div_one_div Ha), H, (division_ring.one_div_one_div Hb)]

  theorem mul_inv_eq (Ha : a ≠ 0) (Hb : b ≠ 0) : (b * a)⁻¹ = a⁻¹ * b⁻¹ :=
    eq.symm (calc
      a⁻¹ * b⁻¹ = (1 / a) * b⁻¹ : inv_eq_one_div
      ... = (1 / a) * (1 / b)   : inv_eq_one_div
      ... = (1 / (b * a))       : division_ring.one_div_mul_one_div Ha Hb
      ... = (b * a)⁻¹           : inv_eq_one_div)

  theorem mul_div_cancel (a : A) {b : A} (Hb : b ≠ 0) : a * b / b = a :=
    by rewrite [*division.def, mul.assoc, (mul_inv_cancel Hb), mul_one]

  theorem div_mul_cancel (a : A) {b : A} (Hb : b ≠ 0) : a / b * b = a :=
    by rewrite [*division.def, mul.assoc, (inv_mul_cancel Hb), mul_one]

  theorem div_add_div_same (a b c : A) : a / c + b / c = (a + b) / c := !right_distrib⁻¹

  theorem div_sub_div_same (a b c : A) : (a / c) - (b / c) = (a - b) / c :=
    by rewrite [sub_eq_add_neg, -neg_div, div_add_div_same]

  theorem one_div_mul_add_mul_one_div_eq_one_div_add_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) :
          (1 / a) * (a + b) * (1 / b) = 1 / a + 1 / b :=
    by rewrite [(left_distrib (1 / a)), (one_div_mul_cancel Ha), right_distrib, one_mul,
      mul.assoc, (mul_one_div_cancel Hb), mul_one, add.comm]

  theorem one_div_mul_sub_mul_one_div_eq_one_div_add_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) :
          (1 / a) * (b - a) * (1 / b) = 1 / a - 1 / b :=
    by rewrite [(mul_sub_left_distrib (1 / a)), (one_div_mul_cancel Ha), mul_sub_right_distrib,
      one_mul, mul.assoc, (mul_one_div_cancel Hb), mul_one]

  theorem div_eq_one_iff_eq (a : A) {b : A} (Hb : b ≠ 0) : a / b = 1 ↔ a = b :=
    iff.intro
    (suppose a / b = 1, symm (calc
      b   = 1 * b     : one_mul
      ... = a / b * b : this
      ... = a         : div_mul_cancel _ Hb))
    (suppose a = b, calc
      a / b = b / b : this
        ... = 1     : div_self Hb)

  theorem eq_of_div_eq_one (a : A) {b : A} (Hb : b ≠ 0) : a / b = 1 → a = b :=
    iff.mp (!div_eq_one_iff_eq Hb)

  theorem eq_div_iff_mul_eq (a : A) {b : A} (Hc : c ≠ 0) : a = b / c ↔ a * c = b :=
    iff.intro
      (suppose a = b / c, by rewrite [this, (!div_mul_cancel Hc)])
      (suppose a * c = b, by rewrite [-(!mul_div_cancel Hc), this])

  theorem eq_div_of_mul_eq (a b : A) {c : A} (Hc : c ≠ 0) : a * c = b → a = b / c :=
    iff.mpr (!eq_div_iff_mul_eq Hc)

  theorem mul_eq_of_eq_div (a b: A) {c : A} (Hc : c ≠ 0) : a = b / c → a * c = b :=
    iff.mp (!eq_div_iff_mul_eq Hc)

  theorem add_div_eq_mul_add_div (a b : A) {c : A} (Hc : c ≠ 0) : a + b / c = (a * c + b) / c :=
    have (a + b / c) * c = a * c + b, by rewrite [right_distrib, (!div_mul_cancel Hc)],
    (iff.elim_right (!eq_div_iff_mul_eq Hc)) this

  theorem mul_mul_div (a : A) {c : A} (Hc : c ≠ 0) : a = a * c * (1 / c) :=
    calc
      a   = a * 1             : mul_one
      ... = a * (c * (1 / c)) : mul_one_div_cancel Hc
      ... = a * c * (1 / c)   : mul.assoc

  -- There are many similar rules to these last two in the Isabelle library
  -- that haven't been ported yet. Do as necessary.
end division_ring

structure field [class] (A : Type) extends division_ring A, comm_ring A

section field
  variables [s : field A] {a b c d: A}
  include s

  theorem field.one_div_mul_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) : (1 / a) * (1 / b) =  1 / (a * b) :=
     by rewrite [(division_ring.one_div_mul_one_div Ha Hb), mul.comm b]

  theorem field.div_mul_right (Hb : b ≠ 0) (H : a * b ≠ 0) : a / (a * b) = 1 / b :=
    have a ≠ 0, from and.left (ne_zero_and_ne_zero_of_mul_ne_zero H),
    symm (calc
      1 / b = 1 * (1 / b)             : one_mul
        ... = (a * a⁻¹) * (1 / b)     : mul_inv_cancel this
        ... = a * (a⁻¹ * (1 / b))     : mul.assoc
        ... = a * ((1 / a) * (1 / b)) : inv_eq_one_div
        ... = a * (1 / (b * a))       : division_ring.one_div_mul_one_div this Hb
        ... = a * (1 / (a * b))       : mul.comm
        ... = a * (a * b)⁻¹           : inv_eq_one_div)

  theorem field.div_mul_left (Ha : a ≠ 0) (H : a * b ≠ 0) : b / (a * b) = 1 / a :=
    let H1 : b * a ≠ 0 := mul_ne_zero_comm H in
    by rewrite [mul.comm a, (field.div_mul_right Ha H1)]

  theorem mul_div_cancel_left (Ha : a ≠ 0) : a * b / a = b :=
    by rewrite [mul.comm a, (!mul_div_cancel Ha)]

  theorem mul_div_cancel' (Hb : b ≠ 0) : b * (a / b) = a :=
    by rewrite [mul.comm, (!div_mul_cancel Hb)]

  theorem one_div_add_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) : 1 / a + 1 / b = (a + b) / (a * b) :=
    assert a * b ≠ 0, from (division_ring.mul_ne_zero Ha Hb),
    by rewrite [add.comm, -(field.div_mul_left Ha this), -(field.div_mul_right Hb this), *division.def,
                -right_distrib]

  theorem field.div_mul_div (a : A) {b : A} (c : A) {d : A} (Hb : b ≠ 0) (Hd : d ≠ 0) :
      (a / b) * (c / d) = (a * c) / (b * d) :=
     by rewrite [*division.def, 2 mul.assoc, (mul.comm b⁻¹), mul.assoc, (mul_inv_eq Hd Hb)]

  theorem mul_div_mul_left (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
      (c * a) / (c * b) = a / b :=
    by rewrite [-(!field.div_mul_div Hc Hb), (div_self Hc), one_mul]

  theorem mul_div_mul_right (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
      (a * c) / (b * c) = a / b :=
    by rewrite [(mul.comm a), (mul.comm b), (!mul_div_mul_left Hb Hc)]

  theorem div_mul_eq_mul_div (a b c : A) : (b / c) * a = (b * a) / c :=
    by rewrite [*division.def, mul.assoc, (mul.comm c⁻¹), -mul.assoc]

  theorem field.div_mul_eq_mul_div_comm (a b : A) {c : A} (Hc : c ≠ 0) :
      (b / c) * a = b * (a / c) :=
    by rewrite [(div_mul_eq_mul_div), -(one_mul c), -(!field.div_mul_div (ne.symm zero_ne_one) Hc),
                div_one, one_mul]

  theorem div_add_div (a : A) {b : A} (c : A) {d : A} (Hb : b ≠ 0) (Hd : d ≠ 0) :
      (a / b) + (c / d) = ((a * d) + (b * c)) / (b * d) :=
    by rewrite [-(!mul_div_mul_right Hb Hd), -(!mul_div_mul_left Hd Hb), div_add_div_same]

  theorem div_sub_div (a : A) {b : A} (c : A) {d : A} (Hb : b ≠ 0) (Hd : d ≠ 0) :
      (a / b) - (c / d) = ((a * d) - (b * c)) / (b * d) :=
      by rewrite [*sub_eq_add_neg, neg_eq_neg_one_mul, -mul_div_assoc, (!div_add_div Hb Hd),
         -mul.assoc, (mul.comm b), mul.assoc, -neg_eq_neg_one_mul]

  theorem mul_eq_mul_of_div_eq_div (a : A) {b : A} (c : A) {d : A} (Hb : b ≠ 0)
      (Hd : d ≠ 0) (H : a / b = c / d) : a * d = c * b :=
    by rewrite [-mul_one, mul.assoc, (mul.comm d), -mul.assoc, -(div_self Hb),
         -(!field.div_mul_eq_mul_div_comm Hb), H, (div_mul_eq_mul_div), (!div_mul_cancel Hd)]

  theorem field.one_div_div (Ha : a ≠ 0) (Hb : b ≠ 0) : 1 / (a / b) = b / a :=
    have (a / b) * (b / a) = 1, from calc
      (a / b) * (b / a) = (a * b) / (b * a) : !field.div_mul_div Hb Ha
      ... = (a * b) / (a * b) : mul.comm
      ... = 1 : div_self (division_ring.mul_ne_zero Ha Hb),
    symm (eq_one_div_of_mul_eq_one this)

  theorem field.div_div_eq_mul_div (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
      a / (b / c) = (a * c) / b :=
    by rewrite [div_eq_mul_one_div, (field.one_div_div Hb Hc), -mul_div_assoc]

  theorem field.div_div_eq_div_mul (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
      (a / b) / c = a / (b * c) :=
    by rewrite [div_eq_mul_one_div, (!field.div_mul_div Hb Hc), mul_one]

  theorem field.div_div_div_div_eq (a : A) {b c d : A} (Hb : b ≠ 0) (Hc : c ≠ 0) (Hd : d ≠ 0) :
       (a / b) / (c / d) = (a * d) / (b * c) :=
    by rewrite [(!field.div_div_eq_mul_div Hc Hd), (div_mul_eq_mul_div),
                (!field.div_div_eq_div_mul Hb Hc)]

  theorem field.div_mul_eq_div_mul_one_div (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
      a / (b * c) = (a / b) * (1 / c) :=
    by rewrite [-!field.div_div_eq_div_mul Hb Hc, -div_eq_mul_one_div]
end field

structure discrete_field [class] (A : Type) extends field A :=
  (has_decidable_eq : decidable_eq A)
  (inv_zero : inv zero = zero)

attribute discrete_field.has_decidable_eq [instance]

section discrete_field
  variable [s : discrete_field A]
  include s
  variables {a b c d : A}

  -- many of the theorems in discrete_field are the same as theorems in field or division ring,
  -- but with fewer hypotheses since 0⁻¹ = 0 and equality is decidable.

  theorem discrete_field.eq_zero_or_eq_zero_of_mul_eq_zero
    (x y : A) (H : x * y = 0) : x = 0 ∨ y = 0 :=
  decidable.by_cases
    (suppose x = 0, or.inl this)
    (suppose x ≠ 0,
      or.inr (by rewrite [-one_mul, -(inv_mul_cancel this), mul.assoc, H, mul_zero]))

  definition discrete_field.to_integral_domain [trans_instance] [reducible] :
    integral_domain A :=
  ⦃ integral_domain, s,
    eq_zero_or_eq_zero_of_mul_eq_zero := discrete_field.eq_zero_or_eq_zero_of_mul_eq_zero⦄

  theorem inv_zero : 0⁻¹ = (0:A) := !discrete_field.inv_zero

  theorem one_div_zero : 1 / 0 = (0:A) :=
    calc
      1 / 0 = 1 * 0⁻¹ : refl
        ... = 1 * 0   : inv_zero
        ... = 0 : mul_zero

  theorem div_zero (a : A) : a / 0 = 0 := by rewrite [div_eq_mul_one_div, one_div_zero, mul_zero]

  theorem ne_zero_of_one_div_ne_zero (H : 1 / a ≠ 0) : a ≠ 0 :=
    assume Ha : a = 0, absurd (Ha⁻¹ ▸ one_div_zero) H

  theorem eq_zero_of_one_div_eq_zero (H : 1 / a = 0) : a = 0 :=
    decidable.by_cases
      (assume Ha, Ha)
      (assume Ha, false.elim ((one_div_ne_zero Ha) H))

  variables (a b)
  theorem one_div_mul_one_div' : (1 / a) * (1 / b) = 1 / (b * a) :=
    decidable.by_cases
      (suppose a = 0,
        by rewrite [this, div_zero, zero_mul, -(@div_zero A s 1), mul_zero b])
      (assume Ha : a ≠ 0,
        decidable.by_cases
          (suppose b = 0,
            by rewrite [this, div_zero, mul_zero, -(@div_zero A s 1), zero_mul a])
          (suppose b ≠ 0, division_ring.one_div_mul_one_div Ha this))

  theorem one_div_neg_eq_neg_one_div : 1 / (- a) = - (1 / a) :=
    decidable.by_cases
      (suppose a = 0, by rewrite [this, neg_zero, 2 div_zero, neg_zero])
      (suppose a ≠ 0, division_ring.one_div_neg_eq_neg_one_div this)

  theorem neg_div_neg_eq : (-a) / (-b) = a / b :=
    decidable.by_cases
      (assume Hb : b = 0, by rewrite [Hb, neg_zero, 2 div_zero])
      (assume Hb : b ≠ 0, !division_ring.neg_div_neg_eq Hb)

  theorem one_div_one_div : 1 / (1 / a) = a :=
    decidable.by_cases
      (assume Ha : a = 0, by rewrite [Ha, 2 div_zero])
      (assume Ha : a ≠ 0, division_ring.one_div_one_div Ha)

  variables {a b}
  theorem eq_of_one_div_eq_one_div (H : 1 / a = 1 / b) : a = b :=
    decidable.by_cases
      (assume Ha : a = 0,
      have Hb : b = 0, from eq_zero_of_one_div_eq_zero (by rewrite [-H, Ha, div_zero]),
      Hb⁻¹ ▸ Ha)
      (assume Ha : a ≠ 0,
      have Hb : b ≠ 0, from ne_zero_of_one_div_ne_zero (H ▸ (one_div_ne_zero Ha)),
      division_ring.eq_of_one_div_eq_one_div Ha Hb H)

  variables (a b)
  theorem mul_inv' : (b * a)⁻¹ = a⁻¹ * b⁻¹ :=
    decidable.by_cases
      (assume Ha : a = 0, by rewrite [Ha, mul_zero, 2 inv_zero, zero_mul])
      (assume Ha : a ≠ 0,
        decidable.by_cases
          (assume Hb : b = 0, by rewrite [Hb, zero_mul, 2 inv_zero, mul_zero])
          (assume Hb : b ≠ 0, mul_inv_eq Ha Hb))

-- the following are specifically for fields
  theorem one_div_mul_one_div : (1 / a) * (1 / b) =  1 / (a * b) :=
     by rewrite [one_div_mul_one_div', mul.comm b]

  variable {a}
  theorem div_mul_right (Ha : a ≠ 0) : a / (a * b) = 1 / b :=
    decidable.by_cases
      (assume Hb : b = 0, by rewrite [Hb, mul_zero, 2 div_zero])
      (assume Hb : b ≠ 0, field.div_mul_right Hb (mul_ne_zero Ha Hb))

  variables (a) {b}
  theorem div_mul_left (Hb : b ≠ 0) : b / (a * b) = 1 / a :=
    by rewrite [mul.comm a, div_mul_right _ Hb]

  variables (a b c)
  theorem div_mul_div : (a / b) * (c / d) = (a * c) / (b * d) :=
    decidable.by_cases
      (assume Hb : b = 0, by rewrite [Hb, div_zero, zero_mul, -(@div_zero A s (a * c)), zero_mul])
      (assume Hb : b ≠ 0,
        decidable.by_cases
          (assume Hd : d = 0, by rewrite [Hd, div_zero, mul_zero, -(@div_zero A s (a * c)),
                                          mul_zero])
          (assume Hd : d ≠ 0, !field.div_mul_div Hb Hd))

  variable {c}
  theorem mul_div_mul_left' (Hc : c ≠ 0) : (c * a) / (c * b) = a / b :=
    decidable.by_cases
      (assume Hb : b = 0, by rewrite [Hb, mul_zero, 2 div_zero])
      (assume Hb : b ≠ 0, !mul_div_mul_left Hb Hc)

  theorem mul_div_mul_right' (Hc : c ≠ 0) : (a * c) / (b * c) = a / b :=
    by rewrite [(mul.comm a), (mul.comm b), (!mul_div_mul_left' Hc)]

  variables (a b c d)
  theorem div_mul_eq_mul_div_comm : (b / c) * a = b * (a / c) :=
    decidable.by_cases
      (assume Hc : c = 0, by rewrite [Hc, div_zero, zero_mul, -(mul_zero b), -(@div_zero A s a)])
      (assume Hc : c ≠ 0, !field.div_mul_eq_mul_div_comm Hc)

  theorem one_div_div : 1 / (a / b) = b / a :=
    decidable.by_cases
      (assume Ha : a = 0, by rewrite [Ha, zero_div, 2 div_zero])
      (assume Ha : a ≠ 0,
      decidable.by_cases
        (assume Hb : b = 0, by rewrite [Hb, 2 div_zero, zero_div])
        (assume Hb : b ≠ 0, field.one_div_div Ha Hb))

  theorem div_div_eq_mul_div : a / (b / c) = (a * c) / b :=
    by rewrite [div_eq_mul_one_div, one_div_div, -mul_div_assoc]

  theorem div_div_eq_div_mul : (a / b) / c = a / (b * c) :=
    by rewrite [div_eq_mul_one_div, div_mul_div, mul_one]

  theorem div_div_div_div_eq : (a / b) / (c / d) = (a * d) / (b * c) :=
    by rewrite [div_div_eq_mul_div, div_mul_eq_mul_div, div_div_eq_div_mul]

  variable {a}
  theorem div_helper (H : a ≠ 0) : (1 / (a * b)) * a = 1 / b :=
    by rewrite [div_mul_eq_mul_div, one_mul, !div_mul_right H]

  variable (a)
  theorem div_mul_eq_div_mul_one_div : a / (b * c) = (a / b) * (1 / c) :=
    by rewrite [-div_div_eq_div_mul, -div_eq_mul_one_div]
end discrete_field

end algebra
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								/-
 								Copyright (c) 2014 Robert Lewis. All rights reserved.
 								Released under Apache 2.0 license as described in the file LICENSE.
 								Authors: Robert Lewis
-												feat(library/algebra/field): add theorems about division rings

											
										
										
											2015-02-18 22:33:41 +00:00
+								Structures with multiplicative and additive components, including division rings and fields.
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								The development is modeled after Isabelle's library.
 								-/
 								import logic.eq logic.connectives data.unit data.sigma data.prod
-												refactor(library/algebra/function): move function.lean to init folder

Motivation: this file defines basic things such as function composition.
In the HoTT library, it is located in the init folder.

											
										
										
											2015-07-06 14:29:56 +00:00
+								import algebra.binary algebra.group algebra.ring
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								open eq eq.ops
 								namespace algebra
 								variable {A : Type}
-												fix(library/algebra/ring.lean): allow degenerate semirings and rings, but not degenerate ordered_semirings and ordered_rings. Closes #478.

											
										
										
											2015-03-25 21:08:36 +00:00
+								structure division_ring [class] (A : Type) extends ring A, has_inv A, zero_ne_one_class A :=
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								  (mul_inv_cancel : ∀{a}, a ≠ zero → mul a (inv a) = one)
 								  (inv_mul_cancel : ∀{a}, a ≠ zero → mul (inv a) a = one)
 								section division_ring
 								  variables [s : division_ring A] {a b c : A}
 								  include s
-												refactor(library/*): use type classes for div and mod

											
										
										
											2015-10-29 19:36:26 +00:00
+								  protected definition div (a b : A) : A := a * b⁻¹
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/*): use type classes for div and mod

											
										
										
											2015-10-29 19:36:26 +00:00
+								  definition division_ring_has_div [reducible] [instance] : has_div A :=
 								  has_div.mk algebra.div
-												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
 								  lemma division.def (a b : A) : a / b = a * b⁻¹ :=
 								  rfl
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								  theorem mul_inv_cancel (H : a ≠ 0) : a * a⁻¹ = 1 :=
 								  division_ring.mul_inv_cancel H
 								  theorem inv_mul_cancel (H : a ≠ 0) : a⁻¹ * a = 1 :=
 								  division_ring.inv_mul_cancel H
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem inv_eq_one_div (a : A) : a⁻¹ = 1 / a := !one_mul⁻¹
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_eq_mul_one_div (a b : A) : 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
+								    by rewrite [*division.def, one_mul]
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								  theorem mul_one_div_cancel (H : a ≠ 0) : a * (1 / a) = 1 :=
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								    by rewrite [-inv_eq_one_div, (mul_inv_cancel H)]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
 								  theorem one_div_mul_cancel (H : a ≠ 0) : (1 / a) * a = 1 :=
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								    by rewrite [-inv_eq_one_div, (inv_mul_cancel H)]
-												fix(library/algebra/ring.lean): allow degenerate semirings and rings, but not degenerate ordered_semirings and ordered_rings. Closes #478.

											
										
										
											2015-03-25 21:08:36 +00:00
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
+								  theorem div_self (H : a ≠ 0) : a / a = 1 := mul_inv_cancel H
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												feat(library/unifier): do not fire type class resolution as last resort when type contains metavariables

see discussion at #604

											
										
										
											2015-05-18 22:45:23 +00:00
+								  theorem one_div_one : 1 / 1 = (1:A) := div_self (ne.symm zero_ne_one)
-												feat(library/algebra/ordered_field): prove more theorems

											
										
										
											2015-03-19 15:53:04 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem mul_div_assoc (a b : A) : (a * b) / c = a * (b / c) := !mul.assoc
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
 								  theorem one_div_ne_zero (H : a ≠ 0) : 1 / a ≠ 0 :=
 								    assume H2 : 1 / a = 0,
-												feat(library/unifier): do not fire type class resolution as last resort when type contains metavariables

see discussion at #604

											
										
										
											2015-05-18 22:45:23 +00:00
+								    have C1 : 0 = (1:A), from symm (by rewrite [-(mul_one_div_cancel H), H2, mul_zero]),
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								    absurd C1 zero_ne_one
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												fix({hott,library}/algebra/*): fix names

											
										
										
											2015-05-23 04:05:06 +00:00
+								  theorem one_inv_eq : 1⁻¹ = (1:A) :=
-												feat(library/unifier): do not fire type class resolution as last resort when type contains metavariables

see discussion at #604

											
										
										
											2015-05-18 22:45:23 +00:00
+								  by rewrite [-mul_one, inv_mul_cancel (ne.symm (@zero_ne_one A _))]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_one (a : A) : a / 1 = 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
+								    by rewrite [*division.def, one_inv_eq, mul_one]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem zero_div (a : A) : 0 / a = 0 := !zero_mul
-												feat(library/algebra/fields): prove more theorems about division rings

											
										
										
											2015-02-23 18:05:24 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  -- note: integral domain has a "mul_ne_zero". A commutative division ring is an integral
 								  -- domain, but let's not define that class for now.
 								  theorem division_ring.mul_ne_zero (Ha : a ≠ 0) (Hb : b ≠ 0) : a * b ≠ 0 :=
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								    assume H : a * b = 0,
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								    have C1 : a = 0, by rewrite [-mul_one, -(mul_one_div_cancel Hb), -mul.assoc, H, zero_mul],
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								      absurd C1 Ha
 								  theorem mul_ne_zero_comm (H : a * b ≠ 0) : b * a ≠ 0 :=
-												fix({hott,library}/algebra/*): fix names

											
										
										
											2015-05-23 04:05:06 +00:00
+								    have H2 : a ≠ 0 ∧ b ≠ 0, from ne_zero_and_ne_zero_of_mul_ne_zero H,
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								    division_ring.mul_ne_zero (and.right H2) (and.left H2)
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
 								  theorem eq_one_div_of_mul_eq_one (H : a * b = 1) : b = 1 / a :=
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    have a ≠ 0, from
 								      (suppose a = 0,
 								       have 0 = (1:A), by rewrite [-(zero_mul b), -this, H],
 								       absurd this zero_ne_one),
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								    show b = 1 / a, from symm (calc
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+/ a = (1 / a) * 1       : mul_one
 								        ... = (1 / a) * (a * b) : H
 								        ... = (1 / a) * a * b   : mul.assoc
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								        ... = 1 * b             : one_div_mul_cancel this
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								        ... = b                 : one_mul)
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
 								  theorem eq_one_div_of_mul_eq_one_left (H : b * a = 1) : b = 1 / a :=
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    have a ≠ 0, from
 								      (suppose a = 0,
 								       have 0 = 1, from symm (calc
 = b * a : symm H
 								        ... = b * 0 : this
 								        ... = 0     : mul_zero),
 								      absurd this zero_ne_one),
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								    show b = 1 / a, from symm (calc
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+/ a = 1 * (1 / a)       : one_mul
 								        ... = b * a * (1 / a)   : H
 								        ... = b * (a * (1 / a)) : mul.assoc
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								        ... = b * 1             : mul_one_div_cancel this
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								        ... = b                 : mul_one)
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem division_ring.one_div_mul_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) :
 								      (1 / a) * (1 / b) = 1 / (b * a) :=
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    have (b * a) * ((1 / a) * (1 / b)) = 1, by
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      rewrite [mul.assoc, -(mul.assoc a), (mul_one_div_cancel Ha), one_mul,
 								               (mul_one_div_cancel Hb)],
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    eq_one_div_of_mul_eq_one this
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												feat(library/unifier): do not fire type class resolution as last resort when type contains metavariables

see discussion at #604

											
										
										
											2015-05-18 22:45:23 +00:00
+								  theorem one_div_neg_one_eq_neg_one : (1:A) / (-1) = -1 :=
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    have (-1) * (-1) = (1:A), by rewrite [-neg_eq_neg_one_mul, neg_neg],
 								    symm (eq_one_div_of_mul_eq_one this)
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem division_ring.one_div_neg_eq_neg_one_div (H : a ≠ 0) : 1 / (- a) = - (1 / a) :=
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    have -1 ≠ 0, from
 								      (suppose -1 = 0, absurd (symm (calc
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+= -(-1) : neg_neg
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								        ... = -0    : this
-												feat(library/unifier): do not fire type class resolution as last resort when type contains metavariables

see discussion at #604

											
										
										
											2015-05-18 22:45:23 +00:00
+								        ... = (0:A) : neg_zero)) zero_ne_one),
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								    calc
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+/ (- a) = 1 / ((-1) * a)        : neg_eq_neg_one_mul
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								            ... = (1 / a) * (1 / (- 1)) : division_ring.one_div_mul_one_div H this
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								            ... = (1 / a) * (-1)        : one_div_neg_one_eq_neg_one
 								            ... = - (1 / a)             : mul_neg_one_eq_neg
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_neg_eq_neg_div (b : A) (Ha : a ≠ 0) : b / (- a) = - (b / a) :=
-												feat(library/algebra/fields): prove more theorems about division rings

											
										
										
											2015-02-23 18:05:24 +00:00
+								    calc
-												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
+								      b / (- a) = b * (1 / (- a)) : by rewrite -inv_eq_one_div
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								            ... = b * -(1 / a)    : division_ring.one_div_neg_eq_neg_one_div Ha
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								            ... = -(b * (1 / a))  : neg_mul_eq_mul_neg
 								            ... = - (b * a⁻¹)     : inv_eq_one_div
-												feat(library/algebra/fields): prove more theorems about division rings

											
										
										
											2015-02-23 18:05:24 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem neg_div (a b : A) : (-b) / a = - (b / a) :=
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								    by rewrite [neg_eq_neg_one_mul, mul_div_assoc, -neg_eq_neg_one_mul]
-												feat(library/algebra/fields): prove more theorems about division rings

											
										
										
											2015-02-23 18:05:24 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem division_ring.neg_div_neg_eq (a : A) {b : A} (Hb : b ≠ 0) : (-a) / (-b) = a / b :=
 								    by rewrite [(div_neg_eq_neg_div _ Hb), neg_div, neg_neg]
-												feat(library/algebra/fields): prove more theorems about division rings

											
										
										
											2015-02-23 18:05:24 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem division_ring.one_div_one_div (H : a ≠ 0) : 1 / (1 / a) = a :=
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								    symm (eq_one_div_of_mul_eq_one_left (mul_one_div_cancel H))
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem division_ring.eq_of_one_div_eq_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) (H : 1 / a = 1 / b) :
 								      a = b :=
 								    by rewrite [-(division_ring.one_div_one_div Ha), H, (division_ring.one_div_one_div Hb)]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												fix({hott,library}/algebra/*): fix names

											
										
										
											2015-05-23 04:05:06 +00:00
+								  theorem mul_inv_eq (Ha : a ≠ 0) (Hb : b ≠ 0) : (b * a)⁻¹ = a⁻¹ * b⁻¹ :=
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								    eq.symm (calc
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
+								      a⁻¹ * b⁻¹ = (1 / a) * b⁻¹ : inv_eq_one_div
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								      ... = (1 / a) * (1 / b)   : inv_eq_one_div
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      ... = (1 / (b * a))       : division_ring.one_div_mul_one_div Ha Hb
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								      ... = (b * a)⁻¹           : inv_eq_one_div)
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem mul_div_cancel (a : A) {b : A} (Hb : b ≠ 0) : a * b / b = 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
+								    by rewrite [*division.def, mul.assoc, (mul_inv_cancel Hb), mul_one]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_mul_cancel (a : A) {b : A} (Hb : b ≠ 0) : a / b * b = 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
+								    by rewrite [*division.def, mul.assoc, (inv_mul_cancel Hb), mul_one]
-												fix(library/algebra/ring.lean): allow degenerate semirings and rings, but not degenerate ordered_semirings and ordered_rings. Closes #478.

											
										
										
											2015-03-25 21:08:36 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_add_div_same (a b c : A) : a / c + b / c = (a + b) / c := !right_distrib⁻¹
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_sub_div_same (a b c : A) : (a / c) - (b / c) = (a - b) / c :=
-												feat(library/data/real): fill in remaining sorrys in supremum property proof

											
										
										
											2015-07-28 21:44:56 +00:00
+								    by rewrite [sub_eq_add_neg, -neg_div, div_add_div_same]
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem one_div_mul_add_mul_one_div_eq_one_div_add_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) :
-												feat(library/algebra/field): add theorems about division rings

											
										
										
											2015-02-18 22:33:41 +00:00
+								          (1 / a) * (a + b) * (1 / b) = 1 / a + 1 / b :=
 								    by rewrite [(left_distrib (1 / a)), (one_div_mul_cancel Ha), right_distrib, one_mul,
 								      mul.assoc, (mul_one_div_cancel Hb), mul_one, add.comm]
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem one_div_mul_sub_mul_one_div_eq_one_div_add_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) :
-												feat(library/algebra/field): add theorems about division rings

											
										
										
											2015-02-18 22:33:41 +00:00
+								          (1 / a) * (b - a) * (1 / b) = 1 / a - 1 / b :=
 								    by rewrite [(mul_sub_left_distrib (1 / a)), (one_div_mul_cancel Ha), mul_sub_right_distrib,
-												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
+								      one_mul, mul.assoc, (mul_one_div_cancel Hb), mul_one]
-												feat(library/algebra/field): add theorems about division rings

											
										
										
											2015-02-18 22:33:41 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_eq_one_iff_eq (a : A) {b : A} (Hb : b ≠ 0) : a / b = 1 ↔ a = b :=
-												feat(library/algebra/field): add theorems about division rings

											
										
										
											2015-02-18 22:33:41 +00:00
+								    iff.intro
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    (suppose a / b = 1, symm (calc
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								      b   = 1 * b     : one_mul
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								      ... = a / b * b : this
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      ... = a         : div_mul_cancel _ Hb))
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    (suppose a = b, calc
 								      a / b = b / b : this
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								        ... = 1     : div_self Hb)
-												feat(library/algebra/field): add theorems about division rings

											
										
										
											2015-02-18 22:33:41 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem eq_of_div_eq_one (a : A) {b : A} (Hb : b ≠ 0) : a / b = 1 → a = b :=
 								    iff.mp (!div_eq_one_iff_eq Hb)
-												feat(library/algebra): finish adding one-directional versions of iff theorems

											
										
										
											2015-08-05 21:03:46 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem eq_div_iff_mul_eq (a : A) {b : A} (Hc : c ≠ 0) : a = b / c ↔ a * c = b :=
-												feat(library/algebra/fields): prove more theorems about division rings

											
										
										
											2015-02-23 18:05:24 +00:00
+								    iff.intro
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      (suppose a = b / c, by rewrite [this, (!div_mul_cancel Hc)])
 								      (suppose a * c = b, by rewrite [-(!mul_div_cancel Hc), this])
-												feat(library/algebra/fields): prove more theorems about division rings

											
										
										
											2015-02-23 18:05:24 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem eq_div_of_mul_eq (a b : A) {c : A} (Hc : c ≠ 0) : a * c = b → a = b / c :=
 								    iff.mpr (!eq_div_iff_mul_eq Hc)
-												feat(library/algebra): finish adding one-directional versions of iff theorems

											
										
										
											2015-08-05 21:03:46 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem mul_eq_of_eq_div (a b: A) {c : A} (Hc : c ≠ 0) : a = b / c → a * c = b :=
 								    iff.mp (!eq_div_iff_mul_eq Hc)
-												feat(library/algebra): finish adding one-directional versions of iff theorems

											
										
										
											2015-08-05 21:03:46 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem add_div_eq_mul_add_div (a b : A) {c : A} (Hc : c ≠ 0) : a + b / c = (a * c + b) / c :=
 								    have (a + b / c) * c = a * c + b, by rewrite [right_distrib, (!div_mul_cancel Hc)],
 								    (iff.elim_right (!eq_div_iff_mul_eq Hc)) this
-												feat(library/algebra/fields): prove more theorems about division rings

											
										
										
											2015-02-23 18:05:24 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem mul_mul_div (a : A) {c : A} (Hc : c ≠ 0) : a = a * c * (1 / c) :=
-												style(library/algebra/ordered_field):fix indentation, shorten calc statements

											
										
										
											2015-03-20 15:20:12 +00:00
+								    calc
 								      a   = a * 1             : mul_one
 								      ... = a * (c * (1 / c)) : mul_one_div_cancel Hc
 								      ... = a * c * (1 / c)   : mul.assoc
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								  -- There are many similar rules to these last two in the Isabelle library
 								  -- that haven't been ported yet. Do as necessary.
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								end division_ring
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
+								structure field [class] (A : Type) extends division_ring A, comm_ring A
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
 								section field
 								  variables [s : field A] {a b c d: A}
 								  include s
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.one_div_mul_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) : (1 / a) * (1 / b) =  1 / (a * b) :=
 								     by rewrite [(division_ring.one_div_mul_one_div Ha Hb), mul.comm b]
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.div_mul_right (Hb : b ≠ 0) (H : a * b ≠ 0) : a / (a * b) = 1 / b :=
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    have a ≠ 0, from and.left (ne_zero_and_ne_zero_of_mul_ne_zero H),
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								    symm (calc
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+/ b = 1 * (1 / b)             : one_mul
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								        ... = (a * a⁻¹) * (1 / b)     : mul_inv_cancel this
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								        ... = a * (a⁻¹ * (1 / b))     : mul.assoc
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								        ... = a * ((1 / a) * (1 / b)) : inv_eq_one_div
 								        ... = a * (1 / (b * a))       : division_ring.one_div_mul_one_div this Hb
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								        ... = a * (1 / (a * b))       : mul.comm
 								        ... = a * (a * b)⁻¹           : inv_eq_one_div)
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.div_mul_left (Ha : a ≠ 0) (H : a * b ≠ 0) : b / (a * b) = 1 / a :=
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								    let H1 : b * a ≠ 0 := mul_ne_zero_comm H in
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								    by rewrite [mul.comm a, (field.div_mul_right Ha H1)]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
 								  theorem mul_div_cancel_left (Ha : a ≠ 0) : a * b / a = b :=
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								    by rewrite [mul.comm a, (!mul_div_cancel Ha)]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
 								  theorem mul_div_cancel' (Hb : b ≠ 0) : b * (a / b) = a :=
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								    by rewrite [mul.comm, (!div_mul_cancel Hb)]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
 								  theorem one_div_add_one_div (Ha : a ≠ 0) (Hb : b ≠ 0) : 1 / a + 1 / b = (a + b) / (a * b) :=
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								    assert a * b ≠ 0, from (division_ring.mul_ne_zero Ha Hb),
-												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 [add.comm, -(field.div_mul_left Ha this), -(field.div_mul_right Hb this), *division.def,
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								                -right_distrib]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.div_mul_div (a : A) {b : A} (c : A) {d : A} (Hb : b ≠ 0) (Hd : d ≠ 0) :
 								      (a / b) * (c / d) = (a * c) / (b * d) :=
-												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 [*division.def, 2 mul.assoc, (mul.comm b⁻¹), mul.assoc, (mul_inv_eq Hd Hb)]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem mul_div_mul_left (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
 								      (c * a) / (c * b) = a / b :=
 								    by rewrite [-(!field.div_mul_div Hc Hb), (div_self Hc), one_mul]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem mul_div_mul_right (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
 								      (a * c) / (b * c) = a / b :=
 								    by rewrite [(mul.comm a), (mul.comm b), (!mul_div_mul_left Hb Hc)]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_mul_eq_mul_div (a b c : A) : (b / c) * a = (b * a) / c :=
-												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 [*division.def, mul.assoc, (mul.comm c⁻¹), -mul.assoc]
-												fix(library/algebra/ring.lean): allow degenerate semirings and rings, but not degenerate ordered_semirings and ordered_rings. Closes #478.

											
										
										
											2015-03-25 21:08:36 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.div_mul_eq_mul_div_comm (a b : A) {c : A} (Hc : c ≠ 0) :
 								      (b / c) * a = b * (a / c) :=
 								    by rewrite [(div_mul_eq_mul_div), -(one_mul c), -(!field.div_mul_div (ne.symm zero_ne_one) Hc),
 								                div_one, one_mul]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_add_div (a : A) {b : A} (c : A) {d : A} (Hb : b ≠ 0) (Hd : d ≠ 0) :
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								      (a / b) + (c / d) = ((a * d) + (b * c)) / (b * d) :=
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								    by rewrite [-(!mul_div_mul_right Hb Hd), -(!mul_div_mul_left Hd Hb), div_add_div_same]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_sub_div (a : A) {b : A} (c : A) {d : A} (Hb : b ≠ 0) (Hd : d ≠ 0) :
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								      (a / b) - (c / d) = ((a * d) - (b * c)) / (b * d) :=
-												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 [*sub_eq_add_neg, neg_eq_neg_one_mul, -mul_div_assoc, (!div_add_div Hb Hd),
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								         -mul.assoc, (mul.comm b), mul.assoc, -neg_eq_neg_one_mul]
-												fix(library/algebra/ring.lean): allow degenerate semirings and rings, but not degenerate ordered_semirings and ordered_rings. Closes #478.

											
										
										
											2015-03-25 21:08:36 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem mul_eq_mul_of_div_eq_div (a : A) {b : A} (c : A) {d : A} (Hb : b ≠ 0)
 								      (Hd : d ≠ 0) (H : a / b = c / d) : a * d = c * b :=
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								    by rewrite [-mul_one, mul.assoc, (mul.comm d), -mul.assoc, -(div_self Hb),
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								         -(!field.div_mul_eq_mul_div_comm Hb), H, (div_mul_eq_mul_div), (!div_mul_cancel Hd)]
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.one_div_div (Ha : a ≠ 0) (Hb : b ≠ 0) : 1 / (a / b) = b / a :=
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    have (a / b) * (b / a) = 1, from calc
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      (a / b) * (b / a) = (a * b) / (b * a) : !field.div_mul_div Hb Ha
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								      ... = (a * b) / (a * b) : mul.comm
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      ... = 1 : div_self (division_ring.mul_ne_zero Ha Hb),
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    symm (eq_one_div_of_mul_eq_one this)
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.div_div_eq_mul_div (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
 								      a / (b / c) = (a * c) / b :=
 								    by rewrite [div_eq_mul_one_div, (field.one_div_div Hb Hc), -mul_div_assoc]
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.div_div_eq_div_mul (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
 								      (a / b) / c = a / (b * c) :=
 								    by rewrite [div_eq_mul_one_div, (!field.div_mul_div Hb Hc), mul_one]
-												feat(library/data/real): fill in remaining sorrys in supremum property proof

											
										
										
											2015-07-28 21:44:56 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.div_div_div_div_eq (a : A) {b c d : A} (Hb : b ≠ 0) (Hc : c ≠ 0) (Hd : d ≠ 0) :
 								       (a / b) / (c / d) = (a * d) / (b * c) :=
 								    by rewrite [(!field.div_div_eq_mul_div Hc Hd), (div_mul_eq_mul_div),
 								                (!field.div_div_eq_div_mul Hb Hc)]
-												feat(library/data/real): fill in remaining sorrys in supremum property proof

											
										
										
											2015-07-28 21:44:56 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem field.div_mul_eq_div_mul_one_div (a : A) {b c : A} (Hb : b ≠ 0) (Hc : c ≠ 0) :
 								      a / (b * c) = (a / b) * (1 / c) :=
 								    by rewrite [-!field.div_div_eq_div_mul Hb Hc, -div_eq_mul_one_div]
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								end field
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
+								structure discrete_field [class] (A : Type) extends field A :=
-												refactor(library/algebra/field.lean): rename has_decidable_eq and declare instance

											
										
										
											2015-04-18 17:48:27 +00:00
+								  (has_decidable_eq : decidable_eq A)
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								  (inv_zero : inv zero = zero)
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
-												refactor(library/algebra/field.lean): rename has_decidable_eq and declare instance

											
										
										
											2015-04-18 17:48:27 +00:00
+								attribute discrete_field.has_decidable_eq [instance]
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
+								section discrete_field
 								  variable [s : discrete_field A]
 								  include s
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								  variables {a b c d : A}
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								  -- many of the theorems in discrete_field are the same as theorems in field or division ring,
 								  -- but with fewer hypotheses since 0⁻¹ = 0 and equality is decidable.
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
+								  theorem discrete_field.eq_zero_or_eq_zero_of_mul_eq_zero
 								    (x y : A) (H : x * y = 0) : x = 0 ∨ y = 0 :=
 								  decidable.by_cases
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								    (suppose x = 0, or.inl this)
 								    (suppose x ≠ 0,
 								      or.inr (by rewrite [-one_mul, -(inv_mul_cancel this), mul.assoc, H, mul_zero]))
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
-												refactor(library,hott): remove coercions between algebraic structures

They are classes, and mixing coercion with type class resolution is a
recipe for disaster (aka counterintuitive behavior).

											
										
										
											2015-11-11 19:32:05 +00:00
+								  definition discrete_field.to_integral_domain [trans_instance] [reducible] :
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
+								    integral_domain A :=
 								  ⦃ integral_domain, s,
 								    eq_zero_or_eq_zero_of_mul_eq_zero := discrete_field.eq_zero_or_eq_zero_of_mul_eq_zero⦄
-												feat(library/unifier): do not fire type class resolution as last resort when type contains metavariables

see discussion at #604

											
										
										
											2015-05-18 22:45:23 +00:00
+								  theorem inv_zero : 0⁻¹ = (0:A) := !discrete_field.inv_zero
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
-												feat(library/unifier): do not fire type class resolution as last resort when type contains metavariables

see discussion at #604

											
										
										
											2015-05-18 22:45:23 +00:00
+								  theorem one_div_zero : 1 / 0 = (0:A) :=
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								    calc
 / 0 = 1 * 0⁻¹ : refl
-												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
+								        ... = 1 * 0   : inv_zero
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								        ... = 0 : mul_zero
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_zero (a : A) : a / 0 = 0 := by rewrite [div_eq_mul_one_div, one_div_zero, mul_zero]
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
 								  theorem ne_zero_of_one_div_ne_zero (H : 1 / a ≠ 0) : a ≠ 0 :=
 								    assume Ha : a = 0, absurd (Ha⁻¹ ▸ one_div_zero) H
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem eq_zero_of_one_div_eq_zero (H : 1 / a = 0) : a = 0 :=
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
+								    decidable.by_cases
-												style(library/algebra/ordered_field):fix indentation, shorten calc statements

											
										
										
											2015-03-20 15:20:12 +00:00
+								      (assume Ha, Ha)
 								      (assume Ha, false.elim ((one_div_ne_zero Ha) H))
-												feat(library/algebra/field): fix broken theorems

											
										
										
											2015-02-27 20:44:36 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variables (a b)
 								  theorem one_div_mul_one_div' : (1 / a) * (1 / b) = 1 / (b * a) :=
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								    decidable.by_cases
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								      (suppose a = 0,
 								        by rewrite [this, div_zero, zero_mul, -(@div_zero A s 1), mul_zero b])
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								      (assume Ha : a ≠ 0,
 								        decidable.by_cases
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								          (suppose b = 0,
 								            by rewrite [this, div_zero, mul_zero, -(@div_zero A s 1), zero_mul a])
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								          (suppose b ≠ 0, division_ring.one_div_mul_one_div Ha this))
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem one_div_neg_eq_neg_one_div : 1 / (- a) = - (1 / a) :=
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								    decidable.by_cases
-												refactor(library): use new 'suppose'-expression

											
										
										
											2015-07-20 04:15:20 +00:00
+								      (suppose a = 0, by rewrite [this, neg_zero, 2 div_zero, neg_zero])
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      (suppose a ≠ 0, division_ring.one_div_neg_eq_neg_one_div this)
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem neg_div_neg_eq : (-a) / (-b) = a / b :=
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								    decidable.by_cases
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								      (assume Hb : b = 0, by rewrite [Hb, neg_zero, 2 div_zero])
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      (assume Hb : b ≠ 0, !division_ring.neg_div_neg_eq Hb)
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem one_div_one_div : 1 / (1 / a) = a :=
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								    decidable.by_cases
 								      (assume Ha : a = 0, by rewrite [Ha, 2 div_zero])
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      (assume Ha : a ≠ 0, division_ring.one_div_one_div Ha)
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variables {a b}
 								  theorem eq_of_one_div_eq_one_div (H : 1 / a = 1 / b) : a = b :=
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								    decidable.by_cases
 								      (assume Ha : a = 0,
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      have Hb : b = 0, from eq_zero_of_one_div_eq_zero (by rewrite [-H, Ha, div_zero]),
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								      Hb⁻¹ ▸ Ha)
 								      (assume Ha : a ≠ 0,
 								      have Hb : b ≠ 0, from ne_zero_of_one_div_ne_zero (H ▸ (one_div_ne_zero Ha)),
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      division_ring.eq_of_one_div_eq_one_div Ha Hb H)
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variables (a b)
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								  theorem mul_inv' : (b * a)⁻¹ = a⁻¹ * b⁻¹ :=
 								    decidable.by_cases
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								      (assume Ha : a = 0, by rewrite [Ha, mul_zero, 2 inv_zero, zero_mul])
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								      (assume Ha : a ≠ 0,
 								        decidable.by_cases
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								          (assume Hb : b = 0, by rewrite [Hb, zero_mul, 2 inv_zero, mul_zero])
-												fix({hott,library}/algebra/*): fix names

											
										
										
											2015-05-23 04:05:06 +00:00
+								          (assume Hb : b ≠ 0, mul_inv_eq Ha Hb))
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
 								-- the following are specifically for fields
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem one_div_mul_one_div : (1 / a) * (1 / b) =  1 / (a * b) :=
 								     by rewrite [one_div_mul_one_div', mul.comm b]
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variable {a}
 								  theorem div_mul_right (Ha : a ≠ 0) : a / (a * b) = 1 / b :=
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								    decidable.by_cases
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								      (assume Hb : b = 0, by rewrite [Hb, mul_zero, 2 div_zero])
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      (assume Hb : b ≠ 0, field.div_mul_right Hb (mul_ne_zero Ha Hb))
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variables (a) {b}
 								  theorem div_mul_left (Hb : b ≠ 0) : b / (a * b) = 1 / a :=
 								    by rewrite [mul.comm a, div_mul_right _ Hb]
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variables (a b c)
 								  theorem div_mul_div : (a / b) * (c / d) = (a * c) / (b * d) :=
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								    decidable.by_cases
 								      (assume Hb : b = 0, by rewrite [Hb, div_zero, zero_mul, -(@div_zero A s (a * c)), zero_mul])
 								      (assume Hb : b ≠ 0,
 								        decidable.by_cases
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								          (assume Hd : d = 0, by rewrite [Hd, div_zero, mul_zero, -(@div_zero A s (a * c)),
 								                                          mul_zero])
 								          (assume Hd : d ≠ 0, !field.div_mul_div Hb Hd))
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variable {c}
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								  theorem mul_div_mul_left' (Hc : c ≠ 0) : (c * a) / (c * b) = a / b :=
 								    decidable.by_cases
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								      (assume Hb : b = 0, by rewrite [Hb, mul_zero, 2 div_zero])
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      (assume Hb : b ≠ 0, !mul_div_mul_left Hb Hc)
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
 								  theorem mul_div_mul_right' (Hc : c ≠ 0) : (a * c) / (b * c) = a / b :=
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								    by rewrite [(mul.comm a), (mul.comm b), (!mul_div_mul_left' Hc)]
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variables (a b c d)
 								  theorem div_mul_eq_mul_div_comm : (b / c) * a = b * (a / c) :=
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								    decidable.by_cases
 								      (assume Hc : c = 0, by rewrite [Hc, div_zero, zero_mul, -(mul_zero b), -(@div_zero A s a)])
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								      (assume Hc : c ≠ 0, !field.div_mul_eq_mul_div_comm Hc)
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem one_div_div : 1 / (a / b) = b / a :=
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								    decidable.by_cases
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								      (assume Ha : a = 0, by rewrite [Ha, zero_div, 2 div_zero])
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
+								      (assume Ha : a ≠ 0,
 								      decidable.by_cases
-												feat(library/algebra):refactor field and ordered_field more appropriately

											
										
										
											2015-03-27 17:11:23 +00:00
+								        (assume Hb : b = 0, by rewrite [Hb, 2 div_zero, zero_div])
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								        (assume Hb : b ≠ 0, field.one_div_div Ha Hb))
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_div_eq_mul_div : a / (b / c) = (a * c) / b :=
 								    by rewrite [div_eq_mul_one_div, one_div_div, -mul_div_assoc]
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_div_eq_div_mul : (a / b) / c = a / (b * c) :=
 								    by rewrite [div_eq_mul_one_div, div_mul_div, mul_one]
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  theorem div_div_div_div_eq : (a / b) / (c / d) = (a * d) / (b * c) :=
 								    by rewrite [div_div_eq_mul_div, div_mul_eq_mul_div, div_div_eq_div_mul]
-												feat(library/algebra/field): redefine field so that 1/0=0. Many theorems lose hypotheses in discrete setting.

											
										
										
											2015-03-16 21:05:13 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variable {a}
-												feat(library/algebra): finish/move more general theorems from reals to algebra)

											
										
										
											2015-06-16 06:54:23 +00:00
+								  theorem div_helper (H : a ≠ 0) : (1 / (a * b)) * a = 1 / b :=
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								    by rewrite [div_mul_eq_mul_div, one_mul, !div_mul_right H]
-												feat(library/data/real): fill in remaining sorrys in supremum property proof

											
										
										
											2015-07-28 21:44:56 +00:00
-												refactor(library/algebra/{field,ordered_field}, library/*): more renaming, setting implicit arguments

Many theorems for division rings and fields have stronger versions for discrete fields, where we
assume x / 0 = 0. Before, we used primes to distinguish the versions, but that has the downside
that e.g. for rat and real, all the theorems are equally present. Now, I qualified the weaker ones
with division_ring.foo or field.foo. Maybe that is not ideal, but let's try it.

I also set implicit arguments with the following convention: an argument to a theorem should be
explicit unless it can be inferred from the other arguments and hypotheses.

											
										
										
											2015-08-27 17:29:19 +00:00
+								  variable (a)
 								  theorem div_mul_eq_div_mul_one_div : a / (b * c) = (a / b) * (1 / c) :=
 								    by rewrite [-div_div_eq_div_mul, -div_eq_mul_one_div]
-												feat(library/algebra/field): define discrete field

											
										
										
											2015-02-19 20:17:21 +00:00
+								end discrete_field
-												feat(library/algebra): add field.lean

											
										
										
											2015-02-18 21:42:45 +00:00
+								end algebra