/- Copyright (c) 2016 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Robert Lewis and Leonardo de Moura -/ prelude import init.algebra.field init.algebra.ordered_ring import init.data.nat.lemmas namespace norm_num universe u variable {α : Type u} def add1 [has_add α] [has_one α] (a : α) : α := a + 1 local attribute [reducible] bit0 bit1 add1 local attribute [simp] right_distrib left_distrib private meta def u : tactic unit := `[unfold bit0 bit1 add1] private meta def usimp : tactic unit := u >> `[simp] lemma mul_zero [mul_zero_class α] (a : α) : a * 0 = 0 := by simp lemma zero_mul [mul_zero_class α] (a : α) : 0 * a = 0 := by simp lemma mul_one [monoid α] (a : α) : a * 1 = a := by simp lemma mul_bit0 [distrib α] (a b : α) : a * (bit0 b) = bit0 (a * b) := by simp lemma mul_bit0_helper [distrib α] (a b t : α) (h : a * b = t) : a * (bit0 b) = bit0 t := begin rw [-h], simp end lemma mul_bit1 [semiring α] (a b : α) : a * (bit1 b) = bit0 (a * b) + a := by simp lemma mul_bit1_helper [semiring α] (a b s t : α) (hs : a * b = s) (ht : bit0 s + a = t) : a * (bit1 b) = t := by simp [hs, ht] lemma subst_into_prod [has_mul α] (l r tl tr t : α) (prl : l = tl) (prr : r = tr) (prt : tl * tr = t) : l * r = t := by simp [prl, prr, prt] lemma mk_cong (op : α → α) (a b : α) (h : a = b) : op a = op b := by simp [h] lemma neg_add_neg_eq_of_add_add_eq_zero [add_comm_group α] (a b c : α) (h : c + a + b = 0) : -a + -b = c := begin apply add_neg_eq_of_eq_add, apply neg_eq_of_add_eq_zero, simp at h, simp, assumption end lemma neg_add_neg_helper [add_comm_group α] (a b c : α) (h : a + b = c) : -a + -b = -c := begin apply @neg_inj α, simp [neg_add, neg_neg], assumption end lemma neg_add_pos_eq_of_eq_add [add_comm_group α] (a b c : α) (h : b = c + a) : -a + b = c := begin apply neg_add_eq_of_eq_add, simp at h, assumption end lemma neg_add_pos_helper1 [add_comm_group α] (a b c : α) (h : b + c = a) : -a + b = -c := begin apply neg_add_eq_of_eq_add, apply eq_add_neg_of_add_eq h end lemma neg_add_pos_helper2 [add_comm_group α] (a b c : α) (h : a + c = b) : -a + b = c := begin apply neg_add_eq_of_eq_add, rw h end lemma pos_add_neg_helper [add_comm_group α] (a b c : α) (h : b + a = c) : a + b = c := by rw [-h, add_comm a b] lemma subst_into_subtr [add_group α] (l r t : α) (h : l + -r = t) : l - r = t := by simp [h] lemma neg_neg_helper [add_group α] (a b : α) (h : a = -b) : -a = b := by simp [h] lemma neg_mul_neg_helper [ring α] (a b c : α) (h : a * b = c) : (-a) * (-b) = c := by simp [h] lemma neg_mul_pos_helper [ring α] (a b c : α) (h : a * b = c) : (-a) * b = -c := by simp [h] lemma pos_mul_neg_helper [ring α] (a b c : α) (h : a * b = c) : a * (-b) = -c := by simp [h] lemma div_add_helper [field α] (n d b c val : α) (hd : d ≠ 0) (h : n + b * d = val) (h2 : c * d = val) : n / d + b = c := begin apply eq_of_mul_eq_mul_of_nonzero_right hd, rw [h2, -h, right_distrib, div_mul_cancel _ hd] end lemma add_div_helper [field α] (n d b c val : α) (hd : d ≠ 0) (h : d * b + n = val) (h2 : d * c = val) : b + n / d = c := begin apply eq_of_mul_eq_mul_of_nonzero_left hd, rw [h2, -h, left_distrib, mul_div_cancel' _ hd] end lemma div_mul_helper [field α] (n d c v : α) (hd : d ≠ 0) (h : (n * c) / d = v) : (n / d) * c = v := by rw [-h, field.div_mul_eq_mul_div_comm _ _ hd, mul_div_assoc] lemma mul_div_helper [field α] (a n d v : α) (hd : d ≠ 0) (h : (a * n) / d = v) : a * (n / d) = v := by rw [-h, mul_div_assoc] lemma nonzero_of_div_helper [field α] (a b : α) (ha : a ≠ 0) (hb : b ≠ 0) : a / b ≠ 0 := begin intro hab, assert habb : (a / b) * b = 0, rw [hab, zero_mul], rw [div_mul_cancel _ hb] at habb, exact ha habb end lemma div_helper [field α] (n d v : α) (hd : d ≠ 0) (h : v * d = n) : n / d = v := begin apply eq_of_mul_eq_mul_of_nonzero_right hd, rw (div_mul_cancel _ hd), exact eq.symm h end lemma div_eq_div_helper [field α] (a b c d v : α) (h1 : a * d = v) (h2 : c * b = v) (hb : b ≠ 0) (hd : d ≠ 0) : a / b = c / d := begin apply eq_div_of_mul_eq, exact hd, rw div_mul_eq_mul_div, apply eq.symm, apply eq_div_of_mul_eq, exact hb, rw [h1, h2] end lemma subst_into_div [has_div α] (a₁ b₁ a₂ b₂ v : α) (h : a₁ / b₁ = v) (h1 : a₂ = a₁) (h2 : b₂ = b₁) : a₂ / b₂ = v := by rw [h1, h2, h] lemma add_comm_four [add_comm_semigroup α] (a b : α) : a + a + (b + b) = (a + b) + (a + b) := by simp lemma add_comm_middle [add_comm_semigroup α] (a b c : α) : a + b + c = a + c + b := by simp lemma bit0_add_bit0 [add_comm_semigroup α] (a b : α) : bit0 a + bit0 b = bit0 (a + b) := by usimp lemma bit0_add_bit0_helper [add_comm_semigroup α] (a b t : α) (h : a + b = t) : bit0 a + bit0 b = bit0 t := begin rw -h, usimp end lemma bit1_add_bit0 [add_comm_semigroup α] [has_one α] (a b : α) : bit1 a + bit0 b = bit1 (a + b) := by usimp lemma bit1_add_bit0_helper [add_comm_semigroup α] [has_one α] (a b t : α) (h : a + b = t) : bit1 a + bit0 b = bit1 t := begin rw -h, usimp end lemma bit0_add_bit1 [add_comm_semigroup α] [has_one α] (a b : α) : bit0 a + bit1 b = bit1 (a + b) := by usimp lemma bit0_add_bit1_helper [add_comm_semigroup α] [has_one α] (a b t : α) (h : a + b = t) : bit0 a + bit1 b = bit1 t := begin rw -h, usimp end lemma bit1_add_bit1 [add_comm_semigroup α] [has_one α] (a b : α) : bit1 a + bit1 b = bit0 (add1 (a + b)) := by usimp lemma bit1_add_bit1_helper [add_comm_semigroup α] [has_one α] (a b t s : α) (h : (a + b) = t) (h2 : add1 t = s) : bit1 a + bit1 b = bit0 s := begin rw -h at h2, rw -h2, usimp end lemma bin_add_zero [add_monoid α] (a : α) : a + zero = a := by simp lemma bin_zero_add [add_monoid α] (a : α) : zero + a = a := by simp lemma one_add_bit0 [add_comm_semigroup α] [has_one α] (a : α) : one + bit0 a = bit1 a := begin unfold bit0 bit1, simp end lemma bit0_add_one [has_add α] [has_one α] (a : α) : bit0 a + one = bit1 a := rfl lemma bit1_add_one [has_add α] [has_one α] (a : α) : bit1 a + one = add1 (bit1 a) := rfl lemma bit1_add_one_helper [has_add α] [has_one α] (a t : α) (h : add1 (bit1 a) = t) : bit1 a + one = t := by rw -h lemma one_add_bit1 [add_comm_semigroup α] [has_one α] (a : α) : one + bit1 a = add1 (bit1 a) := begin unfold bit0 bit1 add1, simp end lemma one_add_bit1_helper [add_comm_semigroup α] [has_one α] (a t : α) (h : add1 (bit1 a) = t) : one + bit1 a = t := begin rw -h, usimp end lemma add1_bit0 [has_add α] [has_one α] (a : α) : add1 (bit0 a) = bit1 a := rfl lemma add1_bit1 [add_comm_semigroup α] [has_one α] (a : α) : add1 (bit1 a) = bit0 (add1 a) := by usimp lemma add1_bit1_helper [add_comm_semigroup α] [has_one α] (a t : α) (h : add1 a = t) : add1 (bit1 a) = bit0 t := begin rw -h, usimp end lemma add1_one [has_add α] [has_one α] : add1 (one : α) = bit0 one := rfl lemma add1_zero [add_monoid α] [has_one α] : add1 (zero : α) = one := by usimp lemma one_add_one [has_add α] [has_one α] : (one : α) + one = bit0 one := rfl lemma subst_into_sum [has_add α] (l r tl tr t : α) (prl : l = tl) (prr : r = tr) (prt : tl + tr = t) : l + r = t := by rw [-prt, prr, prl] lemma neg_zero_helper [add_group α] (a : α) (h : a = 0) : - a = 0 := begin rw h, simp end lemma pos_bit0_helper [linear_ordered_semiring α] (a : α) (h : a > 0) : bit0 a > 0 := begin u, apply add_pos h h end lemma nonneg_bit0_helper [linear_ordered_semiring α] (a : α) (h : a ≥ 0) : bit0 a ≥ 0 := begin u, apply add_nonneg h h end lemma pos_bit1_helper [linear_ordered_semiring α] (a : α) (h : a ≥ 0) : bit1 a > 0 := begin u, apply add_pos_of_nonneg_of_pos, apply nonneg_bit0_helper _ h, apply zero_lt_one end lemma nonneg_bit1_helper [linear_ordered_semiring α] (a : α) (h : a ≥ 0) : bit1 a ≥ 0 := begin apply le_of_lt, apply pos_bit1_helper _ h end lemma nonzero_of_pos_helper [linear_ordered_semiring α] (a : α) (h : a > 0) : a ≠ 0 := ne_of_gt h lemma nonzero_of_neg_helper [linear_ordered_ring α] (a : α) (h : a ≠ 0) : -a ≠ 0 := begin intro ha, apply h, apply neg_inj, rwa neg_zero end lemma sub_nat_zero_helper {a b c d: ℕ} (hac : a = c) (hbd : b = d) (hcd : c < d) : a - b = 0 := begin simp_using_hs, apply nat.sub_eq_zero_of_le, apply le_of_lt, assumption end lemma sub_nat_pos_helper {a b c d e : ℕ} (hac : a = c) (hbd : b = d) (hced : e + d = c) : a - b = e := begin simp_using_hs, rw [-hced, nat.add_sub_cancel] end end norm_num