/- Copyright (c) 2014 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Module: init.num Authors: Leonardo de Moura -/ prelude import init.logic init.bool open bool definition pos_num.is_inhabited [instance] : inhabited pos_num := inhabited.mk pos_num.one namespace pos_num definition is_one (a : pos_num) : bool := pos_num.rec_on a tt (λn r, ff) (λn r, ff) definition pred (a : pos_num) : pos_num := pos_num.rec_on a one (λn r, bit0 n) (λn r, cond (is_one n) one (bit1 r)) definition size (a : pos_num) : pos_num := pos_num.rec_on a one (λn r, succ r) (λn r, succ r) definition add (a b : pos_num) : pos_num := pos_num.rec_on a succ (λn f b, pos_num.rec_on b (succ (bit1 n)) (λm r, succ (bit1 (f m))) (λm r, bit1 (f m))) (λn f b, pos_num.rec_on b (bit1 n) (λm r, bit1 (f m)) (λm r, bit0 (f m))) b notation a + b := add a b definition mul (a b : pos_num) : pos_num := pos_num.rec_on a b (λn r, bit0 r + b) (λn r, bit0 r) notation a * b := mul a b definition lt (a b : pos_num) : bool := pos_num.rec_on a (λ b, pos_num.cases_on b ff (λm, tt) (λm, tt)) (λn f b, pos_num.cases_on b ff (λm, f m) (λm, f m)) (λn f b, pos_num.cases_on b ff (λm, f (succ m)) (λm, f m)) b definition le (a b : pos_num) : bool := lt a (succ b) definition equal (a b : pos_num) : bool := le a b && le b a end pos_num definition num.is_inhabited [instance] : inhabited num := inhabited.mk num.zero namespace num open pos_num definition pred (a : num) : num := num.rec_on a zero (λp, cond (is_one p) zero (pos (pred p))) definition size (a : num) : num := num.rec_on a (pos one) (λp, pos (size p)) definition add (a b : num) : num := num.rec_on a b (λpa, num.rec_on b (pos pa) (λpb, pos (pos_num.add pa pb))) definition mul (a b : num) : num := num.rec_on a zero (λpa, num.rec_on b zero (λpb, pos (pos_num.mul pa pb))) notation a + b := add a b notation a * b := mul a b definition le (a b : num) : bool := num.rec_on a tt (λpa, num.rec_on b ff (λpb, pos_num.le pa pb)) private definition psub (a b : pos_num) : num := pos_num.rec_on a (λb, zero) (λn f b, cond (pos_num.le (bit1 n) b) zero (pos_num.cases_on b (pos (bit0 n)) (λm, 2 * f m) (λm, 2 * f m + 1))) (λn f b, cond (pos_num.le (bit0 n) b) zero (pos_num.cases_on b (pos (pos_num.pred (bit0 n))) (λm, pred (2 * f m)) (λm, 2 * f m))) b definition sub (a b : num) : num := num.rec_on a zero (λpa, num.rec_on b a (λpb, psub pa pb)) notation a ≤ b := le a b notation a - b := sub a b end num -- the coercion from num to nat is defined here, -- so that it can already be used in init.trunc and init.tactic namespace nat definition add (a b : nat) : nat := nat.rec_on b a (λ b₁ r, succ r) notation a + b := add a b definition of_num [coercion] (n : num) : nat := num.rec zero (λ n, pos_num.rec (succ zero) (λ n r, r + r + (succ zero)) (λ n r, r + r) n) n end nat attribute nat.of_num [reducible] [constructor] -- of_num is also reducible if namespace "nat" is not opened