/- Copyright (c) 2014 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Module: data.num Author: Leonardo de Moura -/ import data.bool open bool eq.ops decidable namespace pos_num theorem succ_not_is_one (a : pos_num) : is_one (succ a) = ff := pos_num.induction_on a rfl (take n iH, rfl) (take n iH, rfl) theorem succ_one_eq_bit0_one : succ one = bit0 one := rfl theorem succ_bit1_eq_bit0_succ (a : pos_num) : succ (bit1 a) = bit0 (succ a) := rfl theorem succ_bit0_eq_bit1 (a : pos_num) : succ (bit0 a) = bit1 a := rfl theorem ne_of_bit0_ne_bit0 {a b : pos_num} (H₁ : bit0 a ≠ bit0 b) : a ≠ b := assume H : a = b, absurd rfl (H ▸ H₁) theorem ne_of_bit1_ne_bit1 {a b : pos_num} (H₁ : bit1 a ≠ bit1 b) : a ≠ b := assume H : a = b, absurd rfl (H ▸ H₁) theorem pred_bit0_eq_cond (a : pos_num) : pred (bit0 a) = cond (is_one a) one (bit1 (pred a)) := rfl theorem pred_succ : ∀ (a : pos_num), pred (succ a) = a | pred_succ one := rfl | pred_succ (bit0 a) := by rewrite succ_bit0_eq_bit1 | pred_succ (bit1 a) := calc pred (succ (bit1 a)) = cond (is_one (succ a)) one (bit1 (pred (succ a))) : rfl ... = cond ff one (bit1 (pred (succ a))) : succ_not_is_one ... = bit1 (pred (succ a)) : rfl ... = bit1 a : pred_succ a section variables (a b : pos_num) theorem add.one_one : one + one = bit0 one := rfl theorem add.one_bit0 : one + (bit0 a) = bit1 a := rfl theorem add.one_bit1 : one + (bit1 a) = succ (bit1 a) := rfl theorem add.bit0_one : (bit0 a) + one = bit1 a := rfl theorem add.bit1_one : (bit1 a) + one = succ (bit1 a) := rfl theorem add.bit0_bit0 : (bit0 a) + (bit0 b) = bit0 (a + b) := rfl theorem add.bit0_bit1 : (bit0 a) + (bit1 b) = bit1 (a + b) := rfl theorem add.bit1_bit0 : (bit1 a) + (bit0 b) = bit1 (a + b) := rfl theorem add.bit1_bit1 : (bit1 a) + (bit1 b) = succ (bit1 (a + b)) := rfl end theorem mul.one_left (a : pos_num) : one * a = a := rfl theorem mul.one_right (a : pos_num) : a * one = a := pos_num.induction_on a rfl (take (n : pos_num) (iH : n * one = n), calc bit1 n * one = bit0 (n * one) + one : rfl ... = bit0 n + one : iH ... = bit1 n : add.bit0_one) (take (n : pos_num) (iH : n * one = n), calc bit0 n * one = bit0 (n * one) : rfl ... = bit0 n : iH) theorem decidable_eq [instance] : ∀ (a b : pos_num), decidable (a = b) | decidable_eq one one := inl rfl | decidable_eq one (bit0 b) := inr (λ H, pos_num.no_confusion H) | decidable_eq one (bit1 b) := inr (λ H, pos_num.no_confusion H) | decidable_eq (bit0 a) one := inr (λ H, pos_num.no_confusion H) | decidable_eq (bit0 a) (bit0 b) := match decidable_eq a b with | inl H₁ := inl (eq.rec_on H₁ rfl) | inr H₁ := inr (λ H, pos_num.no_confusion H (λ H₂, absurd H₂ H₁)) end | decidable_eq (bit0 a) (bit1 b) := inr (λ H, pos_num.no_confusion H) | decidable_eq (bit1 a) one := inr (λ H, pos_num.no_confusion H) | decidable_eq (bit1 a) (bit0 b) := inr (λ H, pos_num.no_confusion H) | decidable_eq (bit1 a) (bit1 b) := match decidable_eq a b with | inl H₁ := inl (eq.rec_on H₁ rfl) | inr H₁ := inr (λ H, pos_num.no_confusion H (λ H₂, absurd H₂ H₁)) end local notation a < b := (lt a b = tt) local notation a `≮`:50 b:50 := (lt a b = ff) theorem lt_one_right_eq_ff : ∀ a : pos_num, a ≮ one | lt_one_right_eq_ff one := rfl | lt_one_right_eq_ff (bit0 a) := rfl | lt_one_right_eq_ff (bit1 a) := rfl theorem lt_one_succ_eq_tt : ∀ a : pos_num, one < succ a | lt_one_succ_eq_tt one := rfl | lt_one_succ_eq_tt (bit0 a) := rfl | lt_one_succ_eq_tt (bit1 a) := rfl theorem lt_of_lt_bit0_bit0 {a b : pos_num} (H : bit0 a < bit0 b) : a < b := H theorem lt_of_lt_bit0_bit1 {a b : pos_num} (H : bit1 a < bit0 b) : a < b := H theorem lt_of_lt_bit1_bit1 {a b : pos_num} (H : bit1 a < bit1 b) : a < b := H theorem lt_of_lt_bit1_bit0 {a b : pos_num} (H : bit0 a < bit1 b) : a < succ b := H theorem lt_bit0_bit0_eq_lt (a b : pos_num) : lt (bit0 a) (bit0 b) = lt a b := rfl theorem lt_bit1_bit1_eq_lt (a b : pos_num) : lt (bit1 a) (bit1 b) = lt a b := rfl theorem lt_bit1_bit0_eq_lt (a b : pos_num) : lt (bit1 a) (bit0 b) = lt a b := rfl theorem lt_bit0_bit1_eq_lt_succ (a b : pos_num) : lt (bit0 a) (bit1 b) = lt a (succ b) := rfl theorem lt_irrefl : ∀ (a : pos_num), a ≮ a | lt_irrefl one := rfl | lt_irrefl (bit0 a) := begin rewrite lt_bit0_bit0_eq_lt, apply lt_irrefl end | lt_irrefl (bit1 a) := begin rewrite lt_bit1_bit1_eq_lt, apply lt_irrefl end theorem ne_of_lt_eq_tt : ∀ {a b : pos_num}, a < b → a = b → false | @ne_of_lt_eq_tt one ⌞one⌟ H₁ (eq.refl one) := absurd H₁ ff_ne_tt | @ne_of_lt_eq_tt (bit0 a) ⌞(bit0 a)⌟ H₁ (eq.refl (bit0 a)) := begin rewrite lt_bit0_bit0_eq_lt at H₁, apply (ne_of_lt_eq_tt H₁ (eq.refl a)) end | @ne_of_lt_eq_tt (bit1 a) ⌞(bit1 a)⌟ H₁ (eq.refl (bit1 a)) := begin rewrite lt_bit1_bit1_eq_lt at H₁, apply (ne_of_lt_eq_tt H₁ (eq.refl a)) end theorem lt_base : ∀ a : pos_num, a < succ a | lt_base one := rfl | lt_base (bit0 a) := begin rewrite [succ_bit0_eq_bit1, lt_bit0_bit1_eq_lt_succ], apply lt_base end | lt_base (bit1 a) := begin rewrite [succ_bit1_eq_bit0_succ, lt_bit1_bit0_eq_lt], apply lt_base end theorem lt_step : ∀ {a b : pos_num}, a < b → a < succ b | @lt_step one one H := rfl | @lt_step one (bit0 b) H := rfl | @lt_step one (bit1 b) H := rfl | @lt_step (bit0 a) one H := absurd H ff_ne_tt | @lt_step (bit0 a) (bit0 b) H := begin rewrite [succ_bit0_eq_bit1, lt_bit0_bit1_eq_lt_succ, lt_bit0_bit0_eq_lt at H], apply (lt_step H) end | @lt_step (bit0 a) (bit1 b) H := begin rewrite [succ_bit1_eq_bit0_succ, lt_bit0_bit0_eq_lt, lt_bit0_bit1_eq_lt_succ at H], exact H end | @lt_step (bit1 a) one H := absurd H ff_ne_tt | @lt_step (bit1 a) (bit0 b) H := begin rewrite [succ_bit0_eq_bit1, lt_bit1_bit1_eq_lt, lt_bit1_bit0_eq_lt at H], exact H end | @lt_step (bit1 a) (bit1 b) H := begin rewrite [succ_bit1_eq_bit0_succ, lt_bit1_bit0_eq_lt, lt_bit1_bit1_eq_lt at H], apply (lt_step H) end theorem lt_of_lt_succ_succ : ∀ {a b : pos_num}, succ a < succ b → a < b | @lt_of_lt_succ_succ one one H := absurd H ff_ne_tt | @lt_of_lt_succ_succ one (bit0 b) H := rfl | @lt_of_lt_succ_succ one (bit1 b) H := rfl | @lt_of_lt_succ_succ (bit0 a) one H := begin rewrite [succ_bit0_eq_bit1 at H, succ_one_eq_bit0_one at H, lt_bit1_bit0_eq_lt at H], apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff a) H) end | @lt_of_lt_succ_succ (bit0 a) (bit0 b) H := by exact H | @lt_of_lt_succ_succ (bit0 a) (bit1 b) H := by exact H | @lt_of_lt_succ_succ (bit1 a) one H := begin rewrite [succ_bit1_eq_bit0_succ at H, succ_one_eq_bit0_one at H, lt_bit0_bit0_eq_lt at H], apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff (succ a)) H) end | @lt_of_lt_succ_succ (bit1 a) (bit0 b) H := begin rewrite [succ_bit1_eq_bit0_succ at H, succ_bit0_eq_bit1 at H, lt_bit0_bit1_eq_lt_succ at H], rewrite lt_bit1_bit0_eq_lt, apply (lt_of_lt_succ_succ H) end | @lt_of_lt_succ_succ (bit1 a) (bit1 b) H := begin rewrite [lt_bit1_bit1_eq_lt, *succ_bit1_eq_bit0_succ at H, lt_bit0_bit0_eq_lt at H], apply (lt_of_lt_succ_succ H) end theorem lt_succ_succ : ∀ {a b : pos_num}, a < b → succ a < succ b | @lt_succ_succ one one H := absurd H ff_ne_tt | @lt_succ_succ one (bit0 b) H := begin rewrite [succ_bit0_eq_bit1, succ_one_eq_bit0_one, lt_bit0_bit1_eq_lt_succ], apply lt_one_succ_eq_tt end | @lt_succ_succ one (bit1 b) H := begin rewrite [succ_one_eq_bit0_one, succ_bit1_eq_bit0_succ, lt_bit0_bit0_eq_lt], apply lt_one_succ_eq_tt end | @lt_succ_succ (bit0 a) one H := absurd H ff_ne_tt | @lt_succ_succ (bit0 a) (bit0 b) H := by exact H | @lt_succ_succ (bit0 a) (bit1 b) H := by exact H | @lt_succ_succ (bit1 a) one H := absurd H ff_ne_tt | @lt_succ_succ (bit1 a) (bit0 b) H := begin rewrite [succ_bit1_eq_bit0_succ, succ_bit0_eq_bit1, lt_bit0_bit1_eq_lt_succ, lt_bit1_bit0_eq_lt at H], apply (lt_succ_succ H) end | @lt_succ_succ (bit1 a) (bit1 b) H := begin rewrite [lt_bit1_bit1_eq_lt at H, *succ_bit1_eq_bit0_succ, lt_bit0_bit0_eq_lt], apply (lt_succ_succ H) end theorem lt_of_lt_succ : ∀ {a b : pos_num}, succ a < b → a < b | @lt_of_lt_succ one one H := absurd_of_eq_ff_of_eq_tt !lt_one_right_eq_ff H | @lt_of_lt_succ one (bit0 b) H := rfl | @lt_of_lt_succ one (bit1 b) H := rfl | @lt_of_lt_succ (bit0 a) one H := absurd_of_eq_ff_of_eq_tt !lt_one_right_eq_ff H | @lt_of_lt_succ (bit0 a) (bit0 b) H := by exact H | @lt_of_lt_succ (bit0 a) (bit1 b) H := begin rewrite [succ_bit0_eq_bit1 at H, lt_bit1_bit1_eq_lt at H, lt_bit0_bit1_eq_lt_succ], apply (lt_step H) end | @lt_of_lt_succ (bit1 a) one H := absurd_of_eq_ff_of_eq_tt !lt_one_right_eq_ff H | @lt_of_lt_succ (bit1 a) (bit0 b) H := begin rewrite [lt_bit1_bit0_eq_lt, succ_bit1_eq_bit0_succ at H, lt_bit0_bit0_eq_lt at H], apply (lt_of_lt_succ H) end | @lt_of_lt_succ (bit1 a) (bit1 b) H := begin rewrite [succ_bit1_eq_bit0_succ at H, lt_bit0_bit1_eq_lt_succ at H, lt_bit1_bit1_eq_lt], apply (lt_of_lt_succ_succ H) end theorem lt_of_lt_succ_of_ne : ∀ {a b : pos_num}, a < succ b → a ≠ b → a < b | @lt_of_lt_succ_of_ne one one H₁ H₂ := absurd rfl H₂ | @lt_of_lt_succ_of_ne one (bit0 b) H₁ H₂ := rfl | @lt_of_lt_succ_of_ne one (bit1 b) H₁ H₂ := rfl | @lt_of_lt_succ_of_ne (bit0 a) one H₁ H₂ := begin rewrite [succ_one_eq_bit0_one at H₁, lt_bit0_bit0_eq_lt at H₁], apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff _) H₁) end | @lt_of_lt_succ_of_ne (bit0 a) (bit0 b) H₁ H₂ := begin rewrite [lt_bit0_bit0_eq_lt, succ_bit0_eq_bit1 at H₁, lt_bit0_bit1_eq_lt_succ at H₁], apply (lt_of_lt_succ_of_ne H₁ (ne_of_bit0_ne_bit0 H₂)) end | @lt_of_lt_succ_of_ne (bit0 a) (bit1 b) H₁ H₂ := begin rewrite [succ_bit1_eq_bit0_succ at H₁, lt_bit0_bit0_eq_lt at H₁, lt_bit0_bit1_eq_lt_succ], exact H₁ end | @lt_of_lt_succ_of_ne (bit1 a) one H₁ H₂ := begin rewrite [succ_one_eq_bit0_one at H₁, lt_bit1_bit0_eq_lt at H₁], apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff _) H₁) end | @lt_of_lt_succ_of_ne (bit1 a) (bit0 b) H₁ H₂ := begin rewrite [succ_bit0_eq_bit1 at H₁, lt_bit1_bit1_eq_lt at H₁, lt_bit1_bit0_eq_lt], exact H₁ end | @lt_of_lt_succ_of_ne (bit1 a) (bit1 b) H₁ H₂ := begin rewrite [succ_bit1_eq_bit0_succ at H₁, lt_bit1_bit0_eq_lt at H₁, lt_bit1_bit1_eq_lt], apply (lt_of_lt_succ_of_ne H₁ (ne_of_bit1_ne_bit1 H₂)) end theorem lt_trans : ∀ {a b c : pos_num}, a < b → b < c → a < c | @lt_trans one b (bit0 c) H₁ H₂ := rfl | @lt_trans one b (bit1 c) H₁ H₂ := rfl | @lt_trans a (bit0 b) one H₁ H₂ := absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff _) H₂ | @lt_trans a (bit1 b) one H₁ H₂ := absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff _) H₂ | @lt_trans (bit0 a) (bit0 b) (bit0 c) H₁ H₂ := begin rewrite lt_bit0_bit0_eq_lt at *, apply (lt_trans H₁ H₂) end | @lt_trans (bit0 a) (bit0 b) (bit1 c) H₁ H₂ := begin rewrite [lt_bit0_bit1_eq_lt_succ at *, lt_bit0_bit0_eq_lt at H₁], apply (lt_trans H₁ H₂) end | @lt_trans (bit0 a) (bit1 b) (bit0 c) H₁ H₂ := begin rewrite [lt_bit0_bit1_eq_lt_succ at H₁, lt_bit1_bit0_eq_lt at H₂, lt_bit0_bit0_eq_lt], apply (@by_cases (a = b)), begin intro H, rewrite -H at H₂, exact H₂ end, begin intro H, apply (lt_trans (lt_of_lt_succ_of_ne H₁ H) H₂) end end | @lt_trans (bit0 a) (bit1 b) (bit1 c) H₁ H₂ := begin rewrite [lt_bit0_bit1_eq_lt_succ at *, lt_bit1_bit1_eq_lt at H₂], apply (lt_trans H₁ (lt_succ_succ H₂)) end | @lt_trans (bit1 a) (bit0 b) (bit0 c) H₁ H₂ := begin rewrite [lt_bit0_bit0_eq_lt at H₂, lt_bit1_bit0_eq_lt at *], apply (lt_trans H₁ H₂) end | @lt_trans (bit1 a) (bit0 b) (bit1 c) H₁ H₂ := begin rewrite [lt_bit1_bit0_eq_lt at H₁, lt_bit0_bit1_eq_lt_succ at H₂, lt_bit1_bit1_eq_lt], apply (@by_cases (b = c)), begin intro H, rewrite H at H₁, exact H₁ end, begin intro H, apply (lt_trans H₁ (lt_of_lt_succ_of_ne H₂ H)) end end | @lt_trans (bit1 a) (bit1 b) (bit0 c) H₁ H₂ := begin rewrite [lt_bit1_bit1_eq_lt at H₁, lt_bit1_bit0_eq_lt at H₂, lt_bit1_bit0_eq_lt], apply (lt_trans H₁ H₂) end | @lt_trans (bit1 a) (bit1 b) (bit1 c) H₁ H₂ := begin rewrite lt_bit1_bit1_eq_lt at *, apply (lt_trans H₁ H₂) end theorem lt_antisymm : ∀ {a b : pos_num}, a < b → b ≮ a | @lt_antisymm one one H := rfl | @lt_antisymm one (bit0 b) H := rfl | @lt_antisymm one (bit1 b) H := rfl | @lt_antisymm (bit0 a) one H := absurd H ff_ne_tt | @lt_antisymm (bit0 a) (bit0 b) H := begin rewrite lt_bit0_bit0_eq_lt at *, apply (lt_antisymm H) end | @lt_antisymm (bit0 a) (bit1 b) H := begin rewrite lt_bit1_bit0_eq_lt, rewrite lt_bit0_bit1_eq_lt_succ at H, have H₁ : succ b ≮ a, from lt_antisymm H, apply eq_ff_of_ne_tt, intro H₂, apply (@by_cases (succ b = a)), show succ b = a → false, begin intro Hp, rewrite -Hp at H, apply (absurd_of_eq_ff_of_eq_tt (lt_irrefl (succ b)) H) end, show succ b ≠ a → false, begin intro Hn, have H₃ : succ b < succ a, from lt_succ_succ H₂, have H₄ : succ b < a, from lt_of_lt_succ_of_ne H₃ Hn, apply (absurd_of_eq_ff_of_eq_tt H₁ H₄) end, end | @lt_antisymm (bit1 a) one H := absurd H ff_ne_tt | @lt_antisymm (bit1 a) (bit0 b) H := begin rewrite lt_bit0_bit1_eq_lt_succ, rewrite lt_bit1_bit0_eq_lt at H, have H₁ : lt b a = ff, from lt_antisymm H, apply eq_ff_of_ne_tt, intro H₂, apply (@by_cases (b = a)), show b = a → false, begin intro Hp, rewrite -Hp at H, apply (absurd_of_eq_ff_of_eq_tt (lt_irrefl b) H) end, show b ≠ a → false, begin intro Hn, have H₃ : b < a, from lt_of_lt_succ_of_ne H₂ Hn, apply (absurd_of_eq_ff_of_eq_tt H₁ H₃) end, end | @lt_antisymm (bit1 a) (bit1 b) H := begin rewrite lt_bit1_bit1_eq_lt at *, apply (lt_antisymm H) end local notation a ≤ b := (le a b = tt) theorem le_refl : ∀ a : pos_num, a ≤ a := lt_base theorem le_eq_lt_succ {a b : pos_num} : le a b = lt a (succ b) := rfl theorem not_lt_of_le : ∀ {a b : pos_num}, a ≤ b → b < a → false | @not_lt_of_le one one H₁ H₂ := absurd H₂ ff_ne_tt | @not_lt_of_le one (bit0 b) H₁ H₂ := absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff _) H₂ | @not_lt_of_le one (bit1 b) H₁ H₂ := absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff _) H₂ | @not_lt_of_le (bit0 a) one H₁ H₂ := begin rewrite [le_eq_lt_succ at H₁, succ_one_eq_bit0_one at H₁, lt_bit0_bit0_eq_lt at H₁], apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff _) H₁) end | @not_lt_of_le (bit0 a) (bit0 b) H₁ H₂ := begin rewrite [le_eq_lt_succ at H₁, succ_bit0_eq_bit1 at H₁, lt_bit0_bit1_eq_lt_succ at H₁], rewrite [lt_bit0_bit0_eq_lt at H₂], apply (not_lt_of_le H₁ H₂) end | @not_lt_of_le (bit0 a) (bit1 b) H₁ H₂ := begin rewrite [le_eq_lt_succ at H₁, succ_bit1_eq_bit0_succ at H₁, lt_bit0_bit0_eq_lt at H₁], rewrite [lt_bit1_bit0_eq_lt at H₂], apply (not_lt_of_le H₁ H₂) end | @not_lt_of_le (bit1 a) one H₁ H₂ := begin rewrite [le_eq_lt_succ at H₁, succ_one_eq_bit0_one at H₁, lt_bit1_bit0_eq_lt at H₁], apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff _) H₁) end | @not_lt_of_le (bit1 a) (bit0 b) H₁ H₂ := begin rewrite [le_eq_lt_succ at H₁, succ_bit0_eq_bit1 at H₁, lt_bit1_bit1_eq_lt at H₁], rewrite lt_bit0_bit1_eq_lt_succ at H₂, have H₃ : a < succ b, from lt_step H₁, apply (@by_cases (b = a)), begin intro Hba, rewrite -Hba at H₁, apply (absurd_of_eq_ff_of_eq_tt (lt_irrefl b) H₁) end, begin intro Hnba, have H₄ : b < a, from lt_of_lt_succ_of_ne H₂ Hnba, apply (not_lt_of_le H₃ H₄) end end | @not_lt_of_le (bit1 a) (bit1 b) H₁ H₂ := begin rewrite [le_eq_lt_succ at H₁, succ_bit1_eq_bit0_succ at H₁, lt_bit1_bit0_eq_lt at H₁], rewrite [lt_bit1_bit1_eq_lt at H₂], apply (not_lt_of_le H₁ H₂) end theorem le_antisymm : ∀ {a b : pos_num}, a ≤ b → b ≤ a → a = b | @le_antisymm one one H₁ H₂ := rfl | @le_antisymm one (bit0 b) H₁ H₂ := by apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff b) H₂) | @le_antisymm one (bit1 b) H₁ H₂ := by apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff b) H₂) | @le_antisymm (bit0 a) one H₁ H₂ := by apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff a) H₁) | @le_antisymm (bit0 a) (bit0 b) H₁ H₂ := begin rewrite [le_eq_lt_succ at *, succ_bit0_eq_bit1 at *, lt_bit0_bit1_eq_lt_succ at *], have H : a = b, from le_antisymm H₁ H₂, rewrite H end | @le_antisymm (bit0 a) (bit1 b) H₁ H₂ := begin rewrite [le_eq_lt_succ at *, succ_bit1_eq_bit0_succ at H₁, succ_bit0_eq_bit1 at H₂], rewrite [lt_bit0_bit0_eq_lt at H₁, lt_bit1_bit1_eq_lt at H₂], apply (false.rec _ (not_lt_of_le H₁ H₂)) end | @le_antisymm (bit1 a) one H₁ H₂ := by apply (absurd_of_eq_ff_of_eq_tt (lt_one_right_eq_ff a) H₁) | @le_antisymm (bit1 a) (bit0 b) H₁ H₂ := begin rewrite [le_eq_lt_succ at *, succ_bit0_eq_bit1 at H₁, succ_bit1_eq_bit0_succ at H₂], rewrite [lt_bit1_bit1_eq_lt at H₁, lt_bit0_bit0_eq_lt at H₂], apply (false.rec _ (not_lt_of_le H₂ H₁)) end | @le_antisymm (bit1 a) (bit1 b) H₁ H₂ := begin rewrite [le_eq_lt_succ at *, succ_bit1_eq_bit0_succ at *, lt_bit1_bit0_eq_lt at *], have H : a = b, from le_antisymm H₁ H₂, rewrite H end theorem le_trans {a b c : pos_num} : a ≤ b → b ≤ c → a ≤ c := begin intros (H₁, H₂), rewrite [le_eq_lt_succ at *], apply (@by_cases (a = b)), begin intro Hab, rewrite Hab, exact H₂ end, begin intro Hnab, have Haltb : a < b, from lt_of_lt_succ_of_ne H₁ Hnab, apply (lt_trans Haltb H₂) end, end end pos_num