| author | wenzelm |
| Sat, 29 Mar 2008 19:14:13 +0100 | |
| changeset 26491 | c93ff30790fe |
| parent 26300 | 03def556e26e |
| child 26748 | 4d51ddd6aa5c |
| permissions | -rw-r--r-- |
| 3366 | 1 |
(* Title: HOL/Divides.thy |
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ID: $Id$ |
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Author: Lawrence C Paulson, Cambridge University Computer Laboratory |
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now div and mod are overloaded; dvd is polymorphic
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Copyright 1999 University of Cambridge |
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*) |
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header {* The division operators div, mod and the divides relation dvd *}
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theory Divides |
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imports Nat Power Product_Type Wellfounded_Recursion |
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uses "~~/src/Provers/Arith/cancel_div_mod.ML" |
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begin |
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subsection {* Syntactic division operations *}
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class div = times + |
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fixes div :: "'a \<Rightarrow> 'a \<Rightarrow> 'a" (infixl "div" 70) |
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fixes mod :: "'a \<Rightarrow> 'a \<Rightarrow> 'a" (infixl "mod" 70) |
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begin |
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definition |
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dvd :: "'a \<Rightarrow> 'a \<Rightarrow> bool" (infixl "dvd" 50) |
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where |
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[code func del]: "m dvd n \<longleftrightarrow> (\<exists>k. n = m * k)" |
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end |
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subsection {* Abstract divisibility in commutative semirings. *}
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class semiring_div = comm_semiring_1_cancel + div + |
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assumes mod_div_equality: "a div b * b + a mod b = a" |
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and div_by_0: "a div 0 = 0" |
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and mult_div: "b \<noteq> 0 \<Longrightarrow> a * b div b = a" |
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begin |
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text {* @{const div} and @{const mod} *}
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lemma div_by_1: "a div 1 = a" |
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using mult_div [of 1 a] zero_neq_one by simp |
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lemma mod_by_1: "a mod 1 = 0" |
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proof - |
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from mod_div_equality [of a one] div_by_1 have "a + a mod 1 = a" by simp |
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then have "a + a mod 1 = a + 0" by simp |
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then show ?thesis by (rule add_left_imp_eq) |
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qed |
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lemma mod_by_0: "a mod 0 = a" |
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using mod_div_equality [of a zero] by simp |
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lemma mult_mod: "a * b mod b = 0" |
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proof (cases "b = 0") |
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case True then show ?thesis by (simp add: mod_by_0) |
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next |
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case False with mult_div have abb: "a * b div b = a" . |
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from mod_div_equality have "a * b div b * b + a * b mod b = a * b" . |
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with abb have "a * b + a * b mod b = a * b + 0" by simp |
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then show ?thesis by (rule add_left_imp_eq) |
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qed |
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lemma mod_self: "a mod a = 0" |
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using mult_mod [of one] by simp |
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lemma div_self: "a \<noteq> 0 \<Longrightarrow> a div a = 1" |
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using mult_div [of _ one] by simp |
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lemma div_0: "0 div a = 0" |
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proof (cases "a = 0") |
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case True then show ?thesis by (simp add: div_by_0) |
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next |
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case False with mult_div have "0 * a div a = 0" . |
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then show ?thesis by simp |
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qed |
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lemma mod_0: "0 mod a = 0" |
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using mod_div_equality [of zero a] div_0 by simp |
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lemma mod_div_equality2: "b * (a div b) + a mod b = a" |
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unfolding mult_commute [of b] |
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by (rule mod_div_equality) |
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lemma div_mod_equality: "((a div b) * b + a mod b) + c = a + c" |
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by (simp add: mod_div_equality) |
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lemma div_mod_equality2: "(b * (a div b) + a mod b) + c = a + c" |
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by (simp add: mod_div_equality2) |
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text {* The @{const dvd} relation *}
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lemma dvdI [intro?]: "a = b * c \<Longrightarrow> b dvd a" |
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unfolding dvd_def .. |
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lemma dvdE [elim?]: "b dvd a \<Longrightarrow> (\<And>c. a = b * c \<Longrightarrow> P) \<Longrightarrow> P" |
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unfolding dvd_def by blast |
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lemma dvd_def_mod [code func]: "a dvd b \<longleftrightarrow> b mod a = 0" |
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proof |
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assume "b mod a = 0" |
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with mod_div_equality [of b a] have "b div a * a = b" by simp |
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then have "b = a * (b div a)" unfolding mult_commute .. |
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then have "\<exists>c. b = a * c" .. |
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then show "a dvd b" unfolding dvd_def . |
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next |
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assume "a dvd b" |
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then have "\<exists>c. b = a * c" unfolding dvd_def . |
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then obtain c where "b = a * c" .. |
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then have "b mod a = a * c mod a" by simp |
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then have "b mod a = c * a mod a" by (simp add: mult_commute) |
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then show "b mod a = 0" by (simp add: mult_mod) |
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qed |
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lemma dvd_refl: "a dvd a" |
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unfolding dvd_def_mod mod_self .. |
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lemma dvd_trans: |
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assumes "a dvd b" and "b dvd c" |
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shows "a dvd c" |
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proof - |
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from assms obtain v where "b = a * v" unfolding dvd_def by auto |
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moreover from assms obtain w where "c = b * w" unfolding dvd_def by auto |
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ultimately have "c = a * (v * w)" by (simp add: mult_assoc) |
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then show ?thesis unfolding dvd_def .. |
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qed |
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lemma zero_dvd_iff [noatp]: "0 dvd a \<longleftrightarrow> a = 0" |
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unfolding dvd_def by simp |
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lemma dvd_0: "a dvd 0" |
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unfolding dvd_def proof |
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show "0 = a * 0" by simp |
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qed |
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lemma one_dvd: "1 dvd a" |
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unfolding dvd_def by simp |
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lemma dvd_mult: "a dvd c \<Longrightarrow> a dvd (b * c)" |
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unfolding dvd_def by (blast intro: mult_left_commute) |
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lemma dvd_mult2: "a dvd b \<Longrightarrow> a dvd (b * c)" |
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apply (subst mult_commute) |
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apply (erule dvd_mult) |
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done |
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lemma dvd_triv_right: "a dvd b * a" |
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by (rule dvd_mult) (rule dvd_refl) |
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lemma dvd_triv_left: "a dvd a * b" |
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by (rule dvd_mult2) (rule dvd_refl) |
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lemma mult_dvd_mono: "a dvd c \<Longrightarrow> b dvd d \<Longrightarrow> a * b dvd c * d" |
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apply (unfold dvd_def, clarify) |
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apply (rule_tac x = "k * ka" in exI) |
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apply (simp add: mult_ac) |
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done |
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lemma dvd_mult_left: "a * b dvd c \<Longrightarrow> a dvd c" |
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by (simp add: dvd_def mult_assoc, blast) |
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lemma dvd_mult_right: "a * b dvd c \<Longrightarrow> b dvd c" |
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unfolding mult_ac [of a] by (rule dvd_mult_left) |
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end |
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subsection {* Division on @{typ nat} *}
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text {*
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We define @{const div} and @{const mod} on @{typ nat} by means
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of a characteristic relation with two input arguments |
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@{term "m\<Colon>nat"}, @{term "n\<Colon>nat"} and two output arguments
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@{term "q\<Colon>nat"}(uotient) and @{term "r\<Colon>nat"}(emainder).
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*} |
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definition divmod_rel :: "nat \<Rightarrow> nat \<Rightarrow> nat \<Rightarrow> nat \<Rightarrow> bool" where |
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"divmod_rel m n q r \<longleftrightarrow> m = q * n + r \<and> (if n > 0 then 0 \<le> r \<and> r < n else q = 0)" |
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text {* @{const divmod_rel} is total: *}
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lemma divmod_rel_ex: |
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obtains q r where "divmod_rel m n q r" |
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proof (cases "n = 0") |
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case True with that show thesis |
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by (auto simp add: divmod_rel_def) |
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next |
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case False |
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have "\<exists>q r. m = q * n + r \<and> r < n" |
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proof (induct m) |
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case 0 with `n \<noteq> 0` |
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have "(0\<Colon>nat) = 0 * n + 0 \<and> 0 < n" by simp |
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then show ?case by blast |
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next |
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case (Suc m) then obtain q' r' |
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where m: "m = q' * n + r'" and n: "r' < n" by auto |
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then show ?case proof (cases "Suc r' < n") |
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case True |
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from m n have "Suc m = q' * n + Suc r'" by simp |
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with True show ?thesis by blast |
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next |
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case False then have "n \<le> Suc r'" by auto |
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moreover from n have "Suc r' \<le> n" by auto |
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ultimately have "n = Suc r'" by auto |
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with m have "Suc m = Suc q' * n + 0" by simp |
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with `n \<noteq> 0` show ?thesis by blast |
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qed |
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qed |
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with that show thesis |
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using `n \<noteq> 0` by (auto simp add: divmod_rel_def) |
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qed |
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text {* @{const divmod_rel} is injective: *}
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lemma divmod_rel_unique_div: |
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assumes "divmod_rel m n q r" |
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and "divmod_rel m n q' r'" |
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shows "q = q'" |
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proof (cases "n = 0") |
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case True with assms show ?thesis |
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by (simp add: divmod_rel_def) |
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next |
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case False |
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have aux: "\<And>q r q' r'. q' * n + r' = q * n + r \<Longrightarrow> r < n \<Longrightarrow> q' \<le> (q\<Colon>nat)" |
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apply (rule leI) |
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apply (subst less_iff_Suc_add) |
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apply (auto simp add: add_mult_distrib) |
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done |
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from `n \<noteq> 0` assms show ?thesis |
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by (auto simp add: divmod_rel_def |
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intro: order_antisym dest: aux sym) |
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qed |
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lemma divmod_rel_unique_mod: |
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assumes "divmod_rel m n q r" |
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|
233 |
and "divmod_rel m n q' r'" |
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234 |
shows "r = r'" |
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|
235 |
proof - |
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|
236 |
from assms have "q = q'" by (rule divmod_rel_unique_div) |
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237 |
with assms show ?thesis by (simp add: divmod_rel_def) |
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|
238 |
qed |
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|
239 |
|
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|
240 |
text {*
|
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241 |
We instantiate divisibility on the natural numbers by |
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242 |
means of @{const divmod_rel}:
|
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243 |
*} |
| 25942 | 244 |
|
245 |
instantiation nat :: semiring_div |
|
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246 |
begin |
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247 |
|
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definition divmod :: "nat \<Rightarrow> nat \<Rightarrow> nat \<times> nat" where |
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249 |
[code func del]: "divmod m n = (THE (q, r). divmod_rel m n q r)" |
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250 |
|
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251 |
definition div_nat where |
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"m div n = fst (divmod m n)" |
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253 |
|
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254 |
definition mod_nat where |
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"m mod n = snd (divmod m n)" |
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256 |
|
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257 |
lemma divmod_div_mod: |
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258 |
"divmod m n = (m div n, m mod n)" |
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|
259 |
unfolding div_nat_def mod_nat_def by simp |
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260 |
|
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261 |
lemma divmod_eq: |
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262 |
assumes "divmod_rel m n q r" |
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263 |
shows "divmod m n = (q, r)" |
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264 |
using assms by (auto simp add: divmod_def |
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265 |
dest: divmod_rel_unique_div divmod_rel_unique_mod) |
| 25942 | 266 |
|
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lemma div_eq: |
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268 |
assumes "divmod_rel m n q r" |
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269 |
shows "m div n = q" |
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270 |
using assms by (auto dest: divmod_eq simp add: div_nat_def) |
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271 |
|
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272 |
lemma mod_eq: |
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273 |
assumes "divmod_rel m n q r" |
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274 |
shows "m mod n = r" |
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275 |
using assms by (auto dest: divmod_eq simp add: mod_nat_def) |
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276 |
|
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277 |
lemma divmod_rel: "divmod_rel m n (m div n) (m mod n)" |
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|
278 |
proof - |
|
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|
279 |
from divmod_rel_ex |
|
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280 |
obtain q r where rel: "divmod_rel m n q r" . |
|
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281 |
moreover with div_eq mod_eq have "m div n = q" and "m mod n = r" |
|
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|
282 |
by simp_all |
|
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|
283 |
ultimately show ?thesis by simp |
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|
284 |
qed |
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|
285 |
|
|
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|
286 |
lemma divmod_zero: |
|
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|
287 |
"divmod m 0 = (0, m)" |
|
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|
288 |
proof - |
|
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|
289 |
from divmod_rel [of m 0] show ?thesis |
|
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|
290 |
unfolding divmod_div_mod divmod_rel_def by simp |
|
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|
291 |
qed |
| 25942 | 292 |
|
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|
293 |
lemma divmod_base: |
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|
294 |
assumes "m < n" |
|
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|
295 |
shows "divmod m n = (0, m)" |
|
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|
296 |
proof - |
|
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|
297 |
from divmod_rel [of m n] show ?thesis |
|
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|
298 |
unfolding divmod_div_mod divmod_rel_def |
|
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|
299 |
using assms by (cases "m div n = 0") |
|
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|
300 |
(auto simp add: gr0_conv_Suc [of "m div n"]) |
|
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|
301 |
qed |
| 25942 | 302 |
|
|
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|
303 |
lemma divmod_step: |
|
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|
304 |
assumes "0 < n" and "n \<le> m" |
|
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|
305 |
shows "divmod m n = (Suc ((m - n) div n), (m - n) mod n)" |
|
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|
306 |
proof - |
|
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|
307 |
from divmod_rel have divmod_m_n: "divmod_rel m n (m div n) (m mod n)" . |
|
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|
308 |
with assms have m_div_n: "m div n \<ge> 1" |
|
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|
309 |
by (cases "m div n") (auto simp add: divmod_rel_def) |
|
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|
310 |
from assms divmod_m_n have "divmod_rel (m - n) n (m div n - 1) (m mod n)" |
|
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|
311 |
by (cases "m div n") (auto simp add: divmod_rel_def) |
|
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|
312 |
with divmod_eq have "divmod (m - n) n = (m div n - 1, m mod n)" by simp |
|
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|
313 |
moreover from divmod_div_mod have "divmod (m - n) n = ((m - n) div n, (m - n) mod n)" . |
|
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|
314 |
ultimately have "m div n = Suc ((m - n) div n)" |
|
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|
315 |
and "m mod n = (m - n) mod n" using m_div_n by simp_all |
|
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|
316 |
then show ?thesis using divmod_div_mod by simp |
|
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|
317 |
qed |
| 25942 | 318 |
|
| 26300 | 319 |
text {* The ''recursion'' equations for @{const div} and @{const mod} *}
|
|
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|
320 |
|
|
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haftmann
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|
321 |
lemma div_less [simp]: |
|
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|
322 |
fixes m n :: nat |
|
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|
323 |
assumes "m < n" |
|
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parents:
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changeset
|
324 |
shows "m div n = 0" |
|
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haftmann
parents:
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changeset
|
325 |
using assms divmod_base divmod_div_mod by simp |
| 25942 | 326 |
|
|
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|
327 |
lemma le_div_geq: |
|
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|
328 |
fixes m n :: nat |
|
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|
329 |
assumes "0 < n" and "n \<le> m" |
|
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|
330 |
shows "m div n = Suc ((m - n) div n)" |
|
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|
331 |
using assms divmod_step divmod_div_mod by simp |
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
332 |
|
|
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changeset
|
333 |
lemma mod_less [simp]: |
|
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parents:
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diff
changeset
|
334 |
fixes m n :: nat |
|
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parents:
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changeset
|
335 |
assumes "m < n" |
|
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haftmann
parents:
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diff
changeset
|
336 |
shows "m mod n = m" |
|
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haftmann
parents:
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changeset
|
337 |
using assms divmod_base divmod_div_mod by simp |
|
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parents:
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changeset
|
338 |
|
|
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haftmann
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|
339 |
lemma le_mod_geq: |
|
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diff
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|
340 |
fixes m n :: nat |
|
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changeset
|
341 |
assumes "n \<le> m" |
|
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haftmann
parents:
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changeset
|
342 |
shows "m mod n = (m - n) mod n" |
|
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|
343 |
using assms divmod_step divmod_div_mod by (cases "n = 0") simp_all |
|
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changeset
|
344 |
|
| 25942 | 345 |
instance proof |
|
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|
346 |
fix m n :: nat show "m div n * n + m mod n = m" |
|
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|
347 |
using divmod_rel [of m n] by (simp add: divmod_rel_def) |
| 25942 | 348 |
next |
|
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|
349 |
fix n :: nat show "n div 0 = 0" |
|
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|
350 |
using divmod_zero divmod_div_mod [of n 0] by simp |
| 25942 | 351 |
next |
|
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changeset
|
352 |
fix m n :: nat assume "n \<noteq> 0" then show "m * n div n = m" |
| 25942 | 353 |
by (induct m) (simp_all add: le_div_geq) |
354 |
qed |
|
|
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|
355 |
|
| 25942 | 356 |
end |
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
357 |
|
|
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|
358 |
text {* Simproc for cancelling @{const div} and @{const mod} *}
|
| 25942 | 359 |
|
360 |
lemmas mod_div_equality = semiring_div_class.times_div_mod_plus_zero_one.mod_div_equality [of "m\<Colon>nat" n, standard] |
|
| 26062 | 361 |
lemmas mod_div_equality2 = mod_div_equality2 [of "n\<Colon>nat" m, standard] |
362 |
lemmas div_mod_equality = div_mod_equality [of "m\<Colon>nat" n k, standard] |
|
363 |
lemmas div_mod_equality2 = div_mod_equality2 [of "m\<Colon>nat" n k, standard] |
|
| 25942 | 364 |
|
365 |
ML {*
|
|
366 |
structure CancelDivModData = |
|
367 |
struct |
|
368 |
||
|
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|
369 |
val div_name = @{const_name div};
|
|
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|
370 |
val mod_name = @{const_name mod};
|
| 25942 | 371 |
val mk_binop = HOLogic.mk_binop; |
|
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|
372 |
val mk_sum = ArithData.mk_sum; |
|
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|
373 |
val dest_sum = ArithData.dest_sum; |
| 25942 | 374 |
|
375 |
(*logic*) |
|
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376 |
|
| 25942 | 377 |
val div_mod_eqs = map mk_meta_eq [@{thm div_mod_equality}, @{thm div_mod_equality2}]
|
378 |
||
379 |
val trans = trans |
|
380 |
||
381 |
val prove_eq_sums = |
|
382 |
let val simps = @{thm add_0} :: @{thm add_0_right} :: @{thms add_ac}
|
|
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383 |
in ArithData.prove_conv all_tac (ArithData.simp_all_tac simps) end; |
| 25942 | 384 |
|
385 |
end; |
|
386 |
||
387 |
structure CancelDivMod = CancelDivModFun(CancelDivModData); |
|
388 |
||
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389 |
val cancel_div_mod_proc = Simplifier.simproc @{theory}
|
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390 |
"cancel_div_mod" ["(m::nat) + n"] (K CancelDivMod.proc); |
| 25942 | 391 |
|
392 |
Addsimprocs[cancel_div_mod_proc]; |
|
393 |
*} |
|
394 |
||
|
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|
395 |
text {* code generator setup *}
|
|
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|
396 |
|
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397 |
lemma divmod_if [code]: "divmod m n = (if n = 0 \<or> m < n then (0, m) else |
|
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398 |
let (q, r) = divmod (m - n) n in (Suc q, r))" |
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|
399 |
by (simp add: divmod_zero divmod_base divmod_step) |
|
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400 |
(simp add: divmod_div_mod) |
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|
401 |
|
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|
402 |
code_modulename SML |
|
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403 |
Divides Nat |
|
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|
404 |
|
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|
405 |
code_modulename OCaml |
|
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406 |
Divides Nat |
|
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|
407 |
|
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|
408 |
code_modulename Haskell |
|
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|
409 |
Divides Nat |
|
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|
410 |
|
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parents:
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|
411 |
|
|
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|
412 |
subsubsection {* Quotient *}
|
|
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|
413 |
|
|
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414 |
lemmas DIVISION_BY_ZERO_DIV [simp] = div_by_0 [of "a\<Colon>nat", standard] |
|
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415 |
lemmas div_0 [simp] = semiring_div_class.div_0 [of "n\<Colon>nat", standard] |
|
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|
416 |
|
|
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parents:
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417 |
lemma div_geq: "0 < n \<Longrightarrow> \<not> m < n \<Longrightarrow> m div n = Suc ((m - n) div n)" |
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418 |
by (simp add: le_div_geq linorder_not_less) |
|
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parents:
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|
419 |
|
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parents:
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|
420 |
lemma div_if: "0 < n \<Longrightarrow> m div n = (if m < n then 0 else Suc ((m - n) div n))" |
|
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parents:
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changeset
|
421 |
by (simp add: div_geq) |
|
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parents:
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changeset
|
422 |
|
|
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parents:
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|
423 |
lemma div_mult_self_is_m [simp]: "0<n ==> (m*n) div n = (m::nat)" |
|
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parents:
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changeset
|
424 |
by (rule mult_div) simp |
|
fbc60cd02ae2
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parents:
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changeset
|
425 |
|
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parents:
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|
426 |
lemma div_mult_self1_is_m [simp]: "0<n ==> (n*m) div n = (m::nat)" |
|
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changeset
|
427 |
by (simp add: mult_commute) |
|
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haftmann
parents:
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changeset
|
428 |
|
| 25942 | 429 |
|
430 |
subsubsection {* Remainder *}
|
|
431 |
||
432 |
lemmas DIVISION_BY_ZERO_MOD [simp] = mod_by_0 [of "a\<Colon>nat", standard] |
|
|
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|
433 |
lemmas mod_0 [simp] = semiring_div_class.mod_0 [of "n\<Colon>nat", standard] |
| 25942 | 434 |
|
|
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|
435 |
lemma mod_less_divisor [simp]: |
|
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|
436 |
fixes m n :: nat |
|
fbc60cd02ae2
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parents:
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changeset
|
437 |
assumes "n > 0" |
|
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|
438 |
shows "m mod n < (n::nat)" |
|
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using only an relation predicate to construct div and mod
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parents:
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diff
changeset
|
439 |
using assms divmod_rel unfolding divmod_rel_def by auto |
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
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parents:
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diff
changeset
|
440 |
|
|
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|
441 |
lemma mod_less_eq_dividend [simp]: |
|
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parents:
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|
442 |
fixes m n :: nat |
|
fbc60cd02ae2
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haftmann
parents:
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changeset
|
443 |
shows "m mod n \<le> m" |
|
fbc60cd02ae2
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|
444 |
proof (rule add_leD2) |
|
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haftmann
parents:
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diff
changeset
|
445 |
from mod_div_equality have "m div n * n + m mod n = m" . |
|
fbc60cd02ae2
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haftmann
parents:
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changeset
|
446 |
then show "m div n * n + m mod n \<le> m" by auto |
|
fbc60cd02ae2
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haftmann
parents:
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diff
changeset
|
447 |
qed |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
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diff
changeset
|
448 |
|
|
fbc60cd02ae2
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haftmann
parents:
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|
449 |
lemma mod_geq: "\<not> m < (n\<Colon>nat) \<Longrightarrow> m mod n = (m - n) mod n" |
| 25942 | 450 |
by (simp add: le_mod_geq linorder_not_less) |
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
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parents:
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changeset
|
451 |
|
|
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452 |
lemma mod_if: "m mod (n\<Colon>nat) = (if m < n then m else (m - n) mod n)" |
|
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haftmann
parents:
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changeset
|
453 |
by (simp add: le_mod_geq) |
|
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haftmann
parents:
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diff
changeset
|
454 |
|
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
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changeset
|
455 |
lemma mod_1 [simp]: "m mod Suc 0 = 0" |
| 22718 | 456 |
by (induct m) (simp_all add: mod_geq) |
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
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changeset
|
457 |
|
| 25942 | 458 |
lemmas mod_self [simp] = semiring_div_class.mod_self [of "n\<Colon>nat", standard] |
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
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diff
changeset
|
459 |
|
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
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diff
changeset
|
460 |
lemma mod_add_self2 [simp]: "(m+n) mod n = m mod (n::nat)" |
| 22718 | 461 |
apply (subgoal_tac "(n + m) mod n = (n+m-n) mod n") |
462 |
apply (simp add: add_commute) |
|
| 25942 | 463 |
apply (subst le_mod_geq [symmetric], simp_all) |
| 22718 | 464 |
done |
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
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diff
changeset
|
465 |
|
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
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diff
changeset
|
466 |
lemma mod_add_self1 [simp]: "(n+m) mod n = m mod (n::nat)" |
| 22718 | 467 |
by (simp add: add_commute mod_add_self2) |
|
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paulson
parents:
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changeset
|
468 |
|
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
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diff
changeset
|
469 |
lemma mod_mult_self1 [simp]: "(m + k*n) mod n = m mod (n::nat)" |
| 22718 | 470 |
by (induct k) (simp_all add: add_left_commute [of _ n]) |
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
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changeset
|
471 |
|
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
472 |
lemma mod_mult_self2 [simp]: "(m + n*k) mod n = m mod (n::nat)" |
| 22718 | 473 |
by (simp add: mult_commute mod_mult_self1) |
|
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
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diff
changeset
|
474 |
|
|
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haftmann
parents:
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diff
changeset
|
475 |
lemma mod_mult_distrib: "(m mod n) * (k\<Colon>nat) = (m * k) mod (n * k)" |
| 22718 | 476 |
apply (cases "n = 0", simp) |
477 |
apply (cases "k = 0", simp) |
|
478 |
apply (induct m rule: nat_less_induct) |
|
479 |
apply (subst mod_if, simp) |
|
480 |
apply (simp add: mod_geq diff_mult_distrib) |
|
481 |
done |
|
|
14267
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
482 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
483 |
lemma mod_mult_distrib2: "(k::nat) * (m mod n) = (k*m) mod (k*n)" |
| 22718 | 484 |
by (simp add: mult_commute [of k] mod_mult_distrib) |
|
14267
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
485 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
486 |
lemma mod_mult_self_is_0 [simp]: "(m*n) mod n = (0::nat)" |
| 22718 | 487 |
apply (cases "n = 0", simp) |
488 |
apply (induct m, simp) |
|
489 |
apply (rename_tac k) |
|
490 |
apply (cut_tac m = "k * n" and n = n in mod_add_self2) |
|
491 |
apply (simp add: add_commute) |
|
492 |
done |
|
|
14267
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
493 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
494 |
lemma mod_mult_self1_is_0 [simp]: "(n*m) mod n = (0::nat)" |
| 22718 | 495 |
by (simp add: mult_commute mod_mult_self_is_0) |
|
14267
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
496 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
497 |
(* a simple rearrangement of mod_div_equality: *) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
498 |
lemma mult_div_cancel: "(n::nat) * (m div n) = m - (m mod n)" |
| 22718 | 499 |
by (cut_tac m = m and n = n in mod_div_equality2, arith) |
|
14267
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
500 |
|
| 15439 | 501 |
lemma mod_le_divisor[simp]: "0 < n \<Longrightarrow> m mod n \<le> (n::nat)" |
| 22718 | 502 |
apply (drule mod_less_divisor [where m = m]) |
503 |
apply simp |
|
504 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
505 |
|
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
506 |
subsubsection {* Quotient and Remainder *}
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
507 |
|
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
508 |
lemma mod_div_decomp: |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
509 |
fixes n k :: nat |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
510 |
obtains m q where "m = n div k" and "q = n mod k" |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
511 |
and "n = m * k + q" |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
512 |
proof - |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
513 |
from mod_div_equality have "n = n div k * k + n mod k" by auto |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
514 |
moreover have "n div k = n div k" .. |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
515 |
moreover have "n mod k = n mod k" .. |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
516 |
note that ultimately show thesis by blast |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
517 |
qed |
|
14267
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More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
518 |
|
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
519 |
lemma divmod_rel_mult1_eq: |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
520 |
"[| divmod_rel b c q r; c > 0 |] |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
521 |
==> divmod_rel (a*b) c (a*q + a*r div c) (a*r mod c)" |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
522 |
by (auto simp add: split_ifs mult_ac divmod_rel_def add_mult_distrib2) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
523 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
524 |
lemma div_mult1_eq: "(a*b) div c = a*(b div c) + a*(b mod c) div (c::nat)" |
|
25134
3d4953e88449
Eliminated most of the neq0_conv occurrences. As a result, many
nipkow
parents:
25112
diff
changeset
|
525 |
apply (cases "c = 0", simp) |
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
526 |
apply (blast intro: divmod_rel [THEN divmod_rel_mult1_eq, THEN div_eq]) |
|
25134
3d4953e88449
Eliminated most of the neq0_conv occurrences. As a result, many
nipkow
parents:
25112
diff
changeset
|
527 |
done |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
528 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
529 |
lemma mod_mult1_eq: "(a*b) mod c = a*(b mod c) mod (c::nat)" |
|
25134
3d4953e88449
Eliminated most of the neq0_conv occurrences. As a result, many
nipkow
parents:
25112
diff
changeset
|
530 |
apply (cases "c = 0", simp) |
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
531 |
apply (blast intro: divmod_rel [THEN divmod_rel_mult1_eq, THEN mod_eq]) |
|
25134
3d4953e88449
Eliminated most of the neq0_conv occurrences. As a result, many
nipkow
parents:
25112
diff
changeset
|
532 |
done |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
533 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
534 |
lemma mod_mult1_eq': "(a*b) mod (c::nat) = ((a mod c) * b) mod c" |
| 22718 | 535 |
apply (rule trans) |
536 |
apply (rule_tac s = "b*a mod c" in trans) |
|
537 |
apply (rule_tac [2] mod_mult1_eq) |
|
538 |
apply (simp_all add: mult_commute) |
|
539 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
540 |
|
| 25162 | 541 |
lemma mod_mult_distrib_mod: |
542 |
"(a*b) mod (c::nat) = ((a mod c) * (b mod c)) mod c" |
|
543 |
apply (rule mod_mult1_eq' [THEN trans]) |
|
544 |
apply (rule mod_mult1_eq) |
|
545 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
546 |
|
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
547 |
lemma divmod_rel_add1_eq: |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
548 |
"[| divmod_rel a c aq ar; divmod_rel b c bq br; c > 0 |] |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
549 |
==> divmod_rel (a + b) c (aq + bq + (ar+br) div c) ((ar + br) mod c)" |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
550 |
by (auto simp add: split_ifs mult_ac divmod_rel_def add_mult_distrib2) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
551 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
552 |
(*NOT suitable for rewriting: the RHS has an instance of the LHS*) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
553 |
lemma div_add1_eq: |
|
25134
3d4953e88449
Eliminated most of the neq0_conv occurrences. As a result, many
nipkow
parents:
25112
diff
changeset
|
554 |
"(a+b) div (c::nat) = a div c + b div c + ((a mod c + b mod c) div c)" |
|
3d4953e88449
Eliminated most of the neq0_conv occurrences. As a result, many
nipkow
parents:
25112
diff
changeset
|
555 |
apply (cases "c = 0", simp) |
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
556 |
apply (blast intro: divmod_rel_add1_eq [THEN div_eq] divmod_rel) |
|
25134
3d4953e88449
Eliminated most of the neq0_conv occurrences. As a result, many
nipkow
parents:
25112
diff
changeset
|
557 |
done |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
558 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
559 |
lemma mod_add1_eq: "(a+b) mod (c::nat) = (a mod c + b mod c) mod c" |
|
25134
3d4953e88449
Eliminated most of the neq0_conv occurrences. As a result, many
nipkow
parents:
25112
diff
changeset
|
560 |
apply (cases "c = 0", simp) |
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
561 |
apply (blast intro: divmod_rel_add1_eq [THEN mod_eq] divmod_rel) |
|
25134
3d4953e88449
Eliminated most of the neq0_conv occurrences. As a result, many
nipkow
parents:
25112
diff
changeset
|
562 |
done |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
563 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
564 |
lemma mod_lemma: "[| (0::nat) < c; r < b |] ==> b * (q mod c) + r < b * c" |
| 22718 | 565 |
apply (cut_tac m = q and n = c in mod_less_divisor) |
566 |
apply (drule_tac [2] m = "q mod c" in less_imp_Suc_add, auto) |
|
567 |
apply (erule_tac P = "%x. ?lhs < ?rhs x" in ssubst) |
|
568 |
apply (simp add: add_mult_distrib2) |
|
569 |
done |
|
|
10559
d3fd54fc659b
many new div and mod properties (borrowed from Integ/IntDiv)
paulson
parents:
10214
diff
changeset
|
570 |
|
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
571 |
lemma divmod_rel_mult2_eq: "[| divmod_rel a b q r; 0 < b; 0 < c |] |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
572 |
==> divmod_rel a (b*c) (q div c) (b*(q mod c) + r)" |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
573 |
by (auto simp add: mult_ac divmod_rel_def add_mult_distrib2 [symmetric] mod_lemma) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
574 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
575 |
lemma div_mult2_eq: "a div (b*c) = (a div b) div (c::nat)" |
| 22718 | 576 |
apply (cases "b = 0", simp) |
577 |
apply (cases "c = 0", simp) |
|
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
578 |
apply (force simp add: divmod_rel [THEN divmod_rel_mult2_eq, THEN div_eq]) |
| 22718 | 579 |
done |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
580 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
581 |
lemma mod_mult2_eq: "a mod (b*c) = b*(a div b mod c) + a mod (b::nat)" |
| 22718 | 582 |
apply (cases "b = 0", simp) |
583 |
apply (cases "c = 0", simp) |
|
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
584 |
apply (auto simp add: mult_commute divmod_rel [THEN divmod_rel_mult2_eq, THEN mod_eq]) |
| 22718 | 585 |
done |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
586 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
587 |
|
| 25942 | 588 |
subsubsection{*Cancellation of Common Factors in Division*}
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
589 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
590 |
lemma div_mult_mult_lemma: |
| 22718 | 591 |
"[| (0::nat) < b; 0 < c |] ==> (c*a) div (c*b) = a div b" |
592 |
by (auto simp add: div_mult2_eq) |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
593 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
594 |
lemma div_mult_mult1 [simp]: "(0::nat) < c ==> (c*a) div (c*b) = a div b" |
| 22718 | 595 |
apply (cases "b = 0") |
596 |
apply (auto simp add: linorder_neq_iff [of b] div_mult_mult_lemma) |
|
597 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
598 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
599 |
lemma div_mult_mult2 [simp]: "(0::nat) < c ==> (a*c) div (b*c) = a div b" |
| 22718 | 600 |
apply (drule div_mult_mult1) |
601 |
apply (auto simp add: mult_commute) |
|
602 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
603 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
604 |
|
| 25942 | 605 |
subsubsection{*Further Facts about Quotient and Remainder*}
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
606 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
607 |
lemma div_1 [simp]: "m div Suc 0 = m" |
| 22718 | 608 |
by (induct m) (simp_all add: div_geq) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
609 |
|
| 25942 | 610 |
lemmas div_self [simp] = semiring_div_class.div_self [of "n\<Colon>nat", standard] |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
611 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
612 |
lemma div_add_self2: "0<n ==> (m+n) div n = Suc (m div n)" |
| 22718 | 613 |
apply (subgoal_tac "(n + m) div n = Suc ((n+m-n) div n) ") |
614 |
apply (simp add: add_commute) |
|
615 |
apply (subst div_geq [symmetric], simp_all) |
|
616 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
617 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
618 |
lemma div_add_self1: "0<n ==> (n+m) div n = Suc (m div n)" |
| 22718 | 619 |
by (simp add: add_commute div_add_self2) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
620 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
621 |
lemma div_mult_self1 [simp]: "!!n::nat. 0<n ==> (m + k*n) div n = k + m div n" |
| 22718 | 622 |
apply (subst div_add1_eq) |
623 |
apply (subst div_mult1_eq, simp) |
|
624 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
625 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
626 |
lemma div_mult_self2 [simp]: "0<n ==> (m + n*k) div n = k + m div (n::nat)" |
| 22718 | 627 |
by (simp add: mult_commute div_mult_self1) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
628 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
629 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
630 |
(* Monotonicity of div in first argument *) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
631 |
lemma div_le_mono [rule_format (no_asm)]: |
| 22718 | 632 |
"\<forall>m::nat. m \<le> n --> (m div k) \<le> (n div k)" |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
633 |
apply (case_tac "k=0", simp) |
| 15251 | 634 |
apply (induct "n" rule: nat_less_induct, clarify) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
635 |
apply (case_tac "n<k") |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
636 |
(* 1 case n<k *) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
637 |
apply simp |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
638 |
(* 2 case n >= k *) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
639 |
apply (case_tac "m<k") |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
640 |
(* 2.1 case m<k *) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
641 |
apply simp |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
642 |
(* 2.2 case m>=k *) |
| 15439 | 643 |
apply (simp add: div_geq diff_le_mono) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
644 |
done |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
645 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
646 |
(* Antimonotonicity of div in second argument *) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
647 |
lemma div_le_mono2: "!!m::nat. [| 0<m; m\<le>n |] ==> (k div n) \<le> (k div m)" |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
648 |
apply (subgoal_tac "0<n") |
| 22718 | 649 |
prefer 2 apply simp |
| 15251 | 650 |
apply (induct_tac k rule: nat_less_induct) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
651 |
apply (rename_tac "k") |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
652 |
apply (case_tac "k<n", simp) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
653 |
apply (subgoal_tac "~ (k<m) ") |
| 22718 | 654 |
prefer 2 apply simp |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
655 |
apply (simp add: div_geq) |
| 15251 | 656 |
apply (subgoal_tac "(k-n) div n \<le> (k-m) div n") |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
657 |
prefer 2 |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
658 |
apply (blast intro: div_le_mono diff_le_mono2) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
659 |
apply (rule le_trans, simp) |
| 15439 | 660 |
apply (simp) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
661 |
done |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
662 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
663 |
lemma div_le_dividend [simp]: "m div n \<le> (m::nat)" |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
664 |
apply (case_tac "n=0", simp) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
665 |
apply (subgoal_tac "m div n \<le> m div 1", simp) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
666 |
apply (rule div_le_mono2) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
667 |
apply (simp_all (no_asm_simp)) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
668 |
done |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
669 |
|
| 22718 | 670 |
(* Similar for "less than" *) |
| 17085 | 671 |
lemma div_less_dividend [rule_format]: |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
672 |
"!!n::nat. 1<n ==> 0 < m --> m div n < m" |
| 15251 | 673 |
apply (induct_tac m rule: nat_less_induct) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
674 |
apply (rename_tac "m") |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
675 |
apply (case_tac "m<n", simp) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
676 |
apply (subgoal_tac "0<n") |
| 22718 | 677 |
prefer 2 apply simp |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
678 |
apply (simp add: div_geq) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
679 |
apply (case_tac "n<m") |
| 15251 | 680 |
apply (subgoal_tac "(m-n) div n < (m-n) ") |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
681 |
apply (rule impI less_trans_Suc)+ |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
682 |
apply assumption |
| 15439 | 683 |
apply (simp_all) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
684 |
done |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
685 |
|
| 17085 | 686 |
declare div_less_dividend [simp] |
687 |
||
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
688 |
text{*A fact for the mutilated chess board*}
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
689 |
lemma mod_Suc: "Suc(m) mod n = (if Suc(m mod n) = n then 0 else Suc(m mod n))" |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
690 |
apply (case_tac "n=0", simp) |
| 15251 | 691 |
apply (induct "m" rule: nat_less_induct) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
692 |
apply (case_tac "Suc (na) <n") |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
693 |
(* case Suc(na) < n *) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
694 |
apply (frule lessI [THEN less_trans], simp add: less_not_refl3) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
695 |
(* case n \<le> Suc(na) *) |
| 16796 | 696 |
apply (simp add: linorder_not_less le_Suc_eq mod_geq) |
| 15439 | 697 |
apply (auto simp add: Suc_diff_le le_mod_geq) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
698 |
done |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
699 |
|
| 14437 | 700 |
lemma nat_mod_div_trivial [simp]: "m mod n div n = (0 :: nat)" |
| 22718 | 701 |
by (cases "n = 0") auto |
| 14437 | 702 |
|
703 |
lemma nat_mod_mod_trivial [simp]: "m mod n mod n = (m mod n :: nat)" |
|
| 22718 | 704 |
by (cases "n = 0") auto |
| 14437 | 705 |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
706 |
|
| 25942 | 707 |
subsubsection{*The Divides Relation*}
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
708 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
709 |
lemma dvdI [intro?]: "n = m * k ==> m dvd n" |
| 22718 | 710 |
unfolding dvd_def by blast |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
711 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
712 |
lemma dvdE [elim?]: "!!P. [|m dvd n; !!k. n = m*k ==> P|] ==> P" |
| 22718 | 713 |
unfolding dvd_def by blast |
| 13152 | 714 |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
715 |
lemma dvd_0_right [iff]: "m dvd (0::nat)" |
| 22718 | 716 |
unfolding dvd_def by (blast intro: mult_0_right [symmetric]) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
717 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
718 |
lemma dvd_0_left: "0 dvd m ==> m = (0::nat)" |
| 22718 | 719 |
by (force simp add: dvd_def) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
720 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
721 |
lemma dvd_0_left_iff [iff]: "(0 dvd (m::nat)) = (m = 0)" |
| 22718 | 722 |
by (blast intro: dvd_0_left) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
723 |
|
|
24286
7619080e49f0
ATP blacklisting is now in theory data, attribute noatp
paulson
parents:
24268
diff
changeset
|
724 |
declare dvd_0_left_iff [noatp] |
|
7619080e49f0
ATP blacklisting is now in theory data, attribute noatp
paulson
parents:
24268
diff
changeset
|
725 |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
726 |
lemma dvd_1_left [iff]: "Suc 0 dvd k" |
| 22718 | 727 |
unfolding dvd_def by simp |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
728 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
729 |
lemma dvd_1_iff_1 [simp]: "(m dvd Suc 0) = (m = Suc 0)" |
| 22718 | 730 |
by (simp add: dvd_def) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
731 |
|
| 25942 | 732 |
lemmas dvd_refl [simp] = semiring_div_class.dvd_refl [of "m\<Colon>nat", standard] |
733 |
lemmas dvd_trans [trans] = semiring_div_class.dvd_trans [of "m\<Colon>nat" n p, standard] |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
734 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
735 |
lemma dvd_anti_sym: "[| m dvd n; n dvd m |] ==> m = (n::nat)" |
| 22718 | 736 |
unfolding dvd_def |
737 |
by (force dest: mult_eq_self_implies_10 simp add: mult_assoc mult_eq_1_iff) |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
738 |
|
|
23684
8c508c4dc53b
introduced (auxiliary) class dvd_mod for more convenient code generation
haftmann
parents:
23162
diff
changeset
|
739 |
text {* @{term "op dvd"} is a partial order *}
|
|
8c508c4dc53b
introduced (auxiliary) class dvd_mod for more convenient code generation
haftmann
parents:
23162
diff
changeset
|
740 |
|
| 25942 | 741 |
interpretation dvd: order ["op dvd" "\<lambda>n m \<Colon> nat. n dvd m \<and> n \<noteq> m"] |
|
23684
8c508c4dc53b
introduced (auxiliary) class dvd_mod for more convenient code generation
haftmann
parents:
23162
diff
changeset
|
742 |
by unfold_locales (auto intro: dvd_trans dvd_anti_sym) |
|
8c508c4dc53b
introduced (auxiliary) class dvd_mod for more convenient code generation
haftmann
parents:
23162
diff
changeset
|
743 |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
744 |
lemma dvd_add: "[| k dvd m; k dvd n |] ==> k dvd (m+n :: nat)" |
| 22718 | 745 |
unfolding dvd_def |
746 |
by (blast intro: add_mult_distrib2 [symmetric]) |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
747 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
748 |
lemma dvd_diff: "[| k dvd m; k dvd n |] ==> k dvd (m-n :: nat)" |
| 22718 | 749 |
unfolding dvd_def |
750 |
by (blast intro: diff_mult_distrib2 [symmetric]) |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
751 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
752 |
lemma dvd_diffD: "[| k dvd m-n; k dvd n; n\<le>m |] ==> k dvd (m::nat)" |
| 22718 | 753 |
apply (erule linorder_not_less [THEN iffD2, THEN add_diff_inverse, THEN subst]) |
754 |
apply (blast intro: dvd_add) |
|
755 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
756 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
757 |
lemma dvd_diffD1: "[| k dvd m-n; k dvd m; n\<le>m |] ==> k dvd (n::nat)" |
| 22718 | 758 |
by (drule_tac m = m in dvd_diff, auto) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
759 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
760 |
lemma dvd_mult: "k dvd n ==> k dvd (m*n :: nat)" |
| 22718 | 761 |
unfolding dvd_def by (blast intro: mult_left_commute) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
762 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
763 |
lemma dvd_mult2: "k dvd m ==> k dvd (m*n :: nat)" |
| 22718 | 764 |
apply (subst mult_commute) |
765 |
apply (erule dvd_mult) |
|
766 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
767 |
|
|
17084
fb0a80aef0be
classical rules must have names for ATP integration
paulson
parents:
16796
diff
changeset
|
768 |
lemma dvd_triv_right [iff]: "k dvd (m*k :: nat)" |
| 22718 | 769 |
by (rule dvd_refl [THEN dvd_mult]) |
|
17084
fb0a80aef0be
classical rules must have names for ATP integration
paulson
parents:
16796
diff
changeset
|
770 |
|
|
fb0a80aef0be
classical rules must have names for ATP integration
paulson
parents:
16796
diff
changeset
|
771 |
lemma dvd_triv_left [iff]: "k dvd (k*m :: nat)" |
| 22718 | 772 |
by (rule dvd_refl [THEN dvd_mult2]) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
773 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
774 |
lemma dvd_reduce: "(k dvd n + k) = (k dvd (n::nat))" |
| 22718 | 775 |
apply (rule iffI) |
776 |
apply (erule_tac [2] dvd_add) |
|
777 |
apply (rule_tac [2] dvd_refl) |
|
778 |
apply (subgoal_tac "n = (n+k) -k") |
|
779 |
prefer 2 apply simp |
|
780 |
apply (erule ssubst) |
|
781 |
apply (erule dvd_diff) |
|
782 |
apply (rule dvd_refl) |
|
783 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
784 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
785 |
lemma dvd_mod: "!!n::nat. [| f dvd m; f dvd n |] ==> f dvd m mod n" |
| 22718 | 786 |
unfolding dvd_def |
787 |
apply (case_tac "n = 0", auto) |
|
788 |
apply (blast intro: mod_mult_distrib2 [symmetric]) |
|
789 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
790 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
791 |
lemma dvd_mod_imp_dvd: "[| (k::nat) dvd m mod n; k dvd n |] ==> k dvd m" |
| 22718 | 792 |
apply (subgoal_tac "k dvd (m div n) *n + m mod n") |
793 |
apply (simp add: mod_div_equality) |
|
794 |
apply (simp only: dvd_add dvd_mult) |
|
795 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
796 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
797 |
lemma dvd_mod_iff: "k dvd n ==> ((k::nat) dvd m mod n) = (k dvd m)" |
| 22718 | 798 |
by (blast intro: dvd_mod_imp_dvd dvd_mod) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
799 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
800 |
lemma dvd_mult_cancel: "!!k::nat. [| k*m dvd k*n; 0<k |] ==> m dvd n" |
| 22718 | 801 |
unfolding dvd_def |
802 |
apply (erule exE) |
|
803 |
apply (simp add: mult_ac) |
|
804 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
805 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
806 |
lemma dvd_mult_cancel1: "0<m ==> (m*n dvd m) = (n = (1::nat))" |
| 22718 | 807 |
apply auto |
808 |
apply (subgoal_tac "m*n dvd m*1") |
|
809 |
apply (drule dvd_mult_cancel, auto) |
|
810 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
811 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
812 |
lemma dvd_mult_cancel2: "0<m ==> (n*m dvd m) = (n = (1::nat))" |
| 22718 | 813 |
apply (subst mult_commute) |
814 |
apply (erule dvd_mult_cancel1) |
|
815 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
816 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
817 |
lemma mult_dvd_mono: "[| i dvd m; j dvd n|] ==> i*j dvd (m*n :: nat)" |
| 22718 | 818 |
apply (unfold dvd_def, clarify) |
819 |
apply (rule_tac x = "k*ka" in exI) |
|
820 |
apply (simp add: mult_ac) |
|
821 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
822 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
823 |
lemma dvd_mult_left: "(i*j :: nat) dvd k ==> i dvd k" |
| 22718 | 824 |
by (simp add: dvd_def mult_assoc, blast) |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
825 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
826 |
lemma dvd_mult_right: "(i*j :: nat) dvd k ==> j dvd k" |
| 22718 | 827 |
apply (unfold dvd_def, clarify) |
828 |
apply (rule_tac x = "i*k" in exI) |
|
829 |
apply (simp add: mult_ac) |
|
830 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
831 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
832 |
lemma dvd_imp_le: "[| k dvd n; 0 < n |] ==> k \<le> (n::nat)" |
| 22718 | 833 |
apply (unfold dvd_def, clarify) |
834 |
apply (simp_all (no_asm_use) add: zero_less_mult_iff) |
|
835 |
apply (erule conjE) |
|
836 |
apply (rule le_trans) |
|
837 |
apply (rule_tac [2] le_refl [THEN mult_le_mono]) |
|
838 |
apply (erule_tac [2] Suc_leI, simp) |
|
839 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
840 |
|
| 25942 | 841 |
lemmas dvd_eq_mod_eq_0 = dvd_def_mod [of "k\<Colon>nat" n, standard] |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
842 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
843 |
lemma dvd_mult_div_cancel: "n dvd m ==> n * (m div n) = (m::nat)" |
| 22718 | 844 |
apply (subgoal_tac "m mod n = 0") |
845 |
apply (simp add: mult_div_cancel) |
|
846 |
apply (simp only: dvd_eq_mod_eq_0) |
|
847 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
848 |
|
| 21408 | 849 |
lemma le_imp_power_dvd: "!!i::nat. m \<le> n ==> i^m dvd i^n" |
| 22718 | 850 |
apply (unfold dvd_def) |
851 |
apply (erule linorder_not_less [THEN iffD2, THEN add_diff_inverse, THEN subst]) |
|
852 |
apply (simp add: power_add) |
|
853 |
done |
|
| 21408 | 854 |
|
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
855 |
lemma mod_add_left_eq: "((a::nat) + b) mod c = (a mod c + b) mod c" |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
856 |
apply (rule trans [symmetric]) |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
857 |
apply (rule mod_add1_eq, simp) |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
858 |
apply (rule mod_add1_eq [symmetric]) |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
859 |
done |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
860 |
|
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
861 |
lemma mod_add_right_eq: "(a+b) mod (c::nat) = (a + (b mod c)) mod c" |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
862 |
apply (rule trans [symmetric]) |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
863 |
apply (rule mod_add1_eq, simp) |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
864 |
apply (rule mod_add1_eq [symmetric]) |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
865 |
done |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
866 |
|
| 25162 | 867 |
lemma nat_zero_less_power_iff [simp]: "(x^n > 0) = (x > (0::nat) | n=0)" |
| 22718 | 868 |
by (induct n) auto |
| 21408 | 869 |
|
870 |
lemma power_le_dvd [rule_format]: "k^j dvd n --> i\<le>j --> k^i dvd (n::nat)" |
|
| 22718 | 871 |
apply (induct j) |
872 |
apply (simp_all add: le_Suc_eq) |
|
873 |
apply (blast dest!: dvd_mult_right) |
|
874 |
done |
|
| 21408 | 875 |
|
876 |
lemma power_dvd_imp_le: "[|i^m dvd i^n; (1::nat) < i|] ==> m \<le> n" |
|
| 22718 | 877 |
apply (rule power_le_imp_le_exp, assumption) |
878 |
apply (erule dvd_imp_le, simp) |
|
879 |
done |
|
| 21408 | 880 |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
881 |
lemma mod_eq_0_iff: "(m mod d = 0) = (\<exists>q::nat. m = d*q)" |
| 22718 | 882 |
by (auto simp add: dvd_eq_mod_eq_0 [symmetric] dvd_def) |
|
17084
fb0a80aef0be
classical rules must have names for ATP integration
paulson
parents:
16796
diff
changeset
|
883 |
|
| 22718 | 884 |
lemmas mod_eq_0D [dest!] = mod_eq_0_iff [THEN iffD1] |
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
885 |
|
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
886 |
(*Loses information, namely we also have r<d provided d is nonzero*) |
|
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
887 |
lemma mod_eqD: "(m mod d = r) ==> \<exists>q::nat. m = r + q*d" |
| 22718 | 888 |
apply (cut_tac m = m in mod_div_equality) |
889 |
apply (simp only: add_ac) |
|
890 |
apply (blast intro: sym) |
|
891 |
done |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
892 |
|
| 13152 | 893 |
lemma split_div: |
|
13189
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
894 |
"P(n div k :: nat) = |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
895 |
((k = 0 \<longrightarrow> P 0) \<and> (k \<noteq> 0 \<longrightarrow> (!i. !j<k. n = k*i + j \<longrightarrow> P i)))" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
896 |
(is "?P = ?Q" is "_ = (_ \<and> (_ \<longrightarrow> ?R))") |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
897 |
proof |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
898 |
assume P: ?P |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
899 |
show ?Q |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
900 |
proof (cases) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
901 |
assume "k = 0" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
902 |
with P show ?Q by(simp add:DIVISION_BY_ZERO_DIV) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
903 |
next |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
904 |
assume not0: "k \<noteq> 0" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
905 |
thus ?Q |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
906 |
proof (simp, intro allI impI) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
907 |
fix i j |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
908 |
assume n: "n = k*i + j" and j: "j < k" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
909 |
show "P i" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
910 |
proof (cases) |
| 22718 | 911 |
assume "i = 0" |
912 |
with n j P show "P i" by simp |
|
|
13189
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
913 |
next |
| 22718 | 914 |
assume "i \<noteq> 0" |
915 |
with not0 n j P show "P i" by(simp add:add_ac) |
|
|
13189
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
916 |
qed |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
917 |
qed |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
918 |
qed |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
919 |
next |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
920 |
assume Q: ?Q |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
921 |
show ?P |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
922 |
proof (cases) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
923 |
assume "k = 0" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
924 |
with Q show ?P by(simp add:DIVISION_BY_ZERO_DIV) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
925 |
next |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
926 |
assume not0: "k \<noteq> 0" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
927 |
with Q have R: ?R by simp |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
928 |
from not0 R[THEN spec,of "n div k",THEN spec, of "n mod k"] |
| 13517 | 929 |
show ?P by simp |
|
13189
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
930 |
qed |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
931 |
qed |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
932 |
|
| 13882 | 933 |
lemma split_div_lemma: |
|
26100
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
934 |
assumes "0 < n" |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
935 |
shows "n * q \<le> m \<and> m < n * Suc q \<longleftrightarrow> q = ((m\<Colon>nat) div n)" (is "?lhs \<longleftrightarrow> ?rhs") |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
936 |
proof |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
937 |
assume ?rhs |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
938 |
with mult_div_cancel have nq: "n * q = m - (m mod n)" by simp |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
939 |
then have A: "n * q \<le> m" by simp |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
940 |
have "n - (m mod n) > 0" using mod_less_divisor assms by auto |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
941 |
then have "m < m + (n - (m mod n))" by simp |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
942 |
then have "m < n + (m - (m mod n))" by simp |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
943 |
with nq have "m < n + n * q" by simp |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
944 |
then have B: "m < n * Suc q" by simp |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
945 |
from A B show ?lhs .. |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
946 |
next |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
947 |
assume P: ?lhs |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
948 |
then have "divmod_rel m n q (m - n * q)" |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
949 |
unfolding divmod_rel_def by (auto simp add: mult_ac) |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
950 |
then show ?rhs using divmod_rel by (rule divmod_rel_unique_div) |
|
fbc60cd02ae2
using only an relation predicate to construct div and mod
haftmann
parents:
26072
diff
changeset
|
951 |
qed |
| 13882 | 952 |
|
953 |
theorem split_div': |
|
954 |
"P ((m::nat) div n) = ((n = 0 \<and> P 0) \<or> |
|
|
14267
b963e9cee2a0
More refinements to Ring_and_Field and numerics. Conversion of Divides_lemmas
paulson
parents:
14208
diff
changeset
|
955 |
(\<exists>q. (n * q \<le> m \<and> m < n * (Suc q)) \<and> P q))" |
| 13882 | 956 |
apply (case_tac "0 < n") |
957 |
apply (simp only: add: split_div_lemma) |
|
958 |
apply (simp_all add: DIVISION_BY_ZERO_DIV) |
|
959 |
done |
|
960 |
||
|
13189
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
961 |
lemma split_mod: |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
962 |
"P(n mod k :: nat) = |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
963 |
((k = 0 \<longrightarrow> P n) \<and> (k \<noteq> 0 \<longrightarrow> (!i. !j<k. n = k*i + j \<longrightarrow> P j)))" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
964 |
(is "?P = ?Q" is "_ = (_ \<and> (_ \<longrightarrow> ?R))") |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
965 |
proof |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
966 |
assume P: ?P |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
967 |
show ?Q |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
968 |
proof (cases) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
969 |
assume "k = 0" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
970 |
with P show ?Q by(simp add:DIVISION_BY_ZERO_MOD) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
971 |
next |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
972 |
assume not0: "k \<noteq> 0" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
973 |
thus ?Q |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
974 |
proof (simp, intro allI impI) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
975 |
fix i j |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
976 |
assume "n = k*i + j" "j < k" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
977 |
thus "P j" using not0 P by(simp add:add_ac mult_ac) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
978 |
qed |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
979 |
qed |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
980 |
next |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
981 |
assume Q: ?Q |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
982 |
show ?P |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
983 |
proof (cases) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
984 |
assume "k = 0" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
985 |
with Q show ?P by(simp add:DIVISION_BY_ZERO_MOD) |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
986 |
next |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
987 |
assume not0: "k \<noteq> 0" |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
988 |
with Q have R: ?R by simp |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
989 |
from not0 R[THEN spec,of "n div k",THEN spec, of "n mod k"] |
| 13517 | 990 |
show ?P by simp |
|
13189
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
991 |
qed |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
992 |
qed |
|
81ed5c6de890
Now arith can deal with div/mod arbitrary nat numerals.
nipkow
parents:
13152
diff
changeset
|
993 |
|
| 13882 | 994 |
theorem mod_div_equality': "(m::nat) mod n = m - (m div n) * n" |
995 |
apply (rule_tac P="%x. m mod n = x - (m div n) * n" in |
|
996 |
subst [OF mod_div_equality [of _ n]]) |
|
997 |
apply arith |
|
998 |
done |
|
999 |
||
| 22800 | 1000 |
lemma div_mod_equality': |
1001 |
fixes m n :: nat |
|
1002 |
shows "m div n * n = m - m mod n" |
|
1003 |
proof - |
|
1004 |
have "m mod n \<le> m mod n" .. |
|
1005 |
from div_mod_equality have |
|
1006 |
"m div n * n + m mod n - m mod n = m - m mod n" by simp |
|
1007 |
with diff_add_assoc [OF `m mod n \<le> m mod n`, of "m div n * n"] have |
|
1008 |
"m div n * n + (m mod n - m mod n) = m - m mod n" |
|
1009 |
by simp |
|
1010 |
then show ?thesis by simp |
|
1011 |
qed |
|
1012 |
||
1013 |
||
| 25942 | 1014 |
subsubsection {*An ``induction'' law for modulus arithmetic.*}
|
| 14640 | 1015 |
|
1016 |
lemma mod_induct_0: |
|
1017 |
assumes step: "\<forall>i<p. P i \<longrightarrow> P ((Suc i) mod p)" |
|
1018 |
and base: "P i" and i: "i<p" |
|
1019 |
shows "P 0" |
|
1020 |
proof (rule ccontr) |
|
1021 |
assume contra: "\<not>(P 0)" |
|
1022 |
from i have p: "0<p" by simp |
|
1023 |
have "\<forall>k. 0<k \<longrightarrow> \<not> P (p-k)" (is "\<forall>k. ?A k") |
|
1024 |
proof |
|
1025 |
fix k |
|
1026 |
show "?A k" |
|
1027 |
proof (induct k) |
|
1028 |
show "?A 0" by simp -- "by contradiction" |
|
1029 |
next |
|
1030 |
fix n |
|
1031 |
assume ih: "?A n" |
|
1032 |
show "?A (Suc n)" |
|
1033 |
proof (clarsimp) |
|
| 22718 | 1034 |
assume y: "P (p - Suc n)" |
1035 |
have n: "Suc n < p" |
|
1036 |
proof (rule ccontr) |
|
1037 |
assume "\<not>(Suc n < p)" |
|
1038 |
hence "p - Suc n = 0" |
|
1039 |
by simp |
|
1040 |
with y contra show "False" |
|
1041 |
by simp |
|
1042 |
qed |
|
1043 |
hence n2: "Suc (p - Suc n) = p-n" by arith |
|
1044 |
from p have "p - Suc n < p" by arith |
|
1045 |
with y step have z: "P ((Suc (p - Suc n)) mod p)" |
|
1046 |
by blast |
|
1047 |
show "False" |
|
1048 |
proof (cases "n=0") |
|
1049 |
case True |
|
1050 |
with z n2 contra show ?thesis by simp |
|
1051 |
next |
|
1052 |
case False |
|
1053 |
with p have "p-n < p" by arith |
|
1054 |
with z n2 False ih show ?thesis by simp |
|
1055 |
qed |
|
| 14640 | 1056 |
qed |
1057 |
qed |
|
1058 |
qed |
|
1059 |
moreover |
|
1060 |
from i obtain k where "0<k \<and> i+k=p" |
|
1061 |
by (blast dest: less_imp_add_positive) |
|
1062 |
hence "0<k \<and> i=p-k" by auto |
|
1063 |
moreover |
|
1064 |
note base |
|
1065 |
ultimately |
|
1066 |
show "False" by blast |
|
1067 |
qed |
|
1068 |
||
1069 |
lemma mod_induct: |
|
1070 |
assumes step: "\<forall>i<p. P i \<longrightarrow> P ((Suc i) mod p)" |
|
1071 |
and base: "P i" and i: "i<p" and j: "j<p" |
|
1072 |
shows "P j" |
|
1073 |
proof - |
|
1074 |
have "\<forall>j<p. P j" |
|
1075 |
proof |
|
1076 |
fix j |
|
1077 |
show "j<p \<longrightarrow> P j" (is "?A j") |
|
1078 |
proof (induct j) |
|
1079 |
from step base i show "?A 0" |
|
| 22718 | 1080 |
by (auto elim: mod_induct_0) |
| 14640 | 1081 |
next |
1082 |
fix k |
|
1083 |
assume ih: "?A k" |
|
1084 |
show "?A (Suc k)" |
|
1085 |
proof |
|
| 22718 | 1086 |
assume suc: "Suc k < p" |
1087 |
hence k: "k<p" by simp |
|
1088 |
with ih have "P k" .. |
|
1089 |
with step k have "P (Suc k mod p)" |
|
1090 |
by blast |
|
1091 |
moreover |
|
1092 |
from suc have "Suc k mod p = Suc k" |
|
1093 |
by simp |
|
1094 |
ultimately |
|
1095 |
show "P (Suc k)" by simp |
|
| 14640 | 1096 |
qed |
1097 |
qed |
|
1098 |
qed |
|
1099 |
with j show ?thesis by blast |
|
1100 |
qed |
|
1101 |
||
| 3366 | 1102 |
end |