author | haftmann |
Tue, 19 Nov 2013 10:05:53 +0100 | |
changeset 54489 | 03ff4d1e6784 |
parent 54228 | 229282d53781 |
child 58645 | 94bef115c08f |
permissions | -rw-r--r-- |
41959 | 1 |
(* Title: HOL/Parity.thy |
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Author: Jeremy Avigad |
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Author: Jacques D. Fleuriot |
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*) |
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header {* Even and Odd for int and nat *} |
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theory Parity |
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imports Main |
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begin |
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class even_odd = semiring_div_parity |
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begin |
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definition even :: "'a \<Rightarrow> bool" |
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where |
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even_def [presburger]: "even a \<longleftrightarrow> a mod 2 = 0" |
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lemma even_iff_2_dvd [algebra]: |
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"even a \<longleftrightarrow> 2 dvd a" |
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by (simp add: even_def dvd_eq_mod_eq_0) |
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lemma even_zero [simp]: |
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"even 0" |
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by (simp add: even_def) |
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lemma even_times_anything: |
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"even a \<Longrightarrow> even (a * b)" |
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by (simp add: even_iff_2_dvd) |
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lemma anything_times_even: |
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"even a \<Longrightarrow> even (b * a)" |
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by (simp add: even_iff_2_dvd) |
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abbreviation odd :: "'a \<Rightarrow> bool" |
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where |
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"odd a \<equiv> \<not> even a" |
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lemma odd_times_odd: |
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"odd a \<Longrightarrow> odd b \<Longrightarrow> odd (a * b)" |
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by (auto simp add: even_def mod_mult_left_eq) |
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lemma even_product [simp, presburger]: |
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"even (a * b) \<longleftrightarrow> even a \<or> even b" |
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apply (auto simp add: even_times_anything anything_times_even) |
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apply (rule ccontr) |
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apply (auto simp add: odd_times_odd) |
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done |
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end |
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instance nat and int :: even_odd .. |
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lemma even_nat_def [presburger]: |
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"even x \<longleftrightarrow> even (int x)" |
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by (auto simp add: even_def int_eq_iff int_mult nat_mult_distrib) |
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lemma transfer_int_nat_relations: |
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"even (int x) \<longleftrightarrow> even x" |
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by (simp add: even_nat_def) |
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declare transfer_morphism_int_nat[transfer add return: |
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transfer_int_nat_relations |
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] |
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lemma odd_one_int [simp]: |
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"odd (1::int)" |
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by presburger |
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lemma odd_1_nat [simp]: |
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"odd (1::nat)" |
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by presburger |
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lemma even_numeral_int [simp]: "even (numeral (Num.Bit0 k) :: int)" |
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unfolding even_def by simp |
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lemma odd_numeral_int [simp]: "odd (numeral (Num.Bit1 k) :: int)" |
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unfolding even_def by simp |
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(* TODO: proper simp rules for Num.Bit0, Num.Bit1 *) |
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declare even_def [of "- numeral v", simp] for v |
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lemma even_numeral_nat [simp]: "even (numeral (Num.Bit0 k) :: nat)" |
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unfolding even_nat_def by simp |
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lemma odd_numeral_nat [simp]: "odd (numeral (Num.Bit1 k) :: nat)" |
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unfolding even_nat_def by simp |
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subsection {* Even and odd are mutually exclusive *} |
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subsection {* Behavior under integer arithmetic operations *} |
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lemma even_plus_even: "even (x::int) ==> even y ==> even (x + y)" |
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by presburger |
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lemma even_plus_odd: "even (x::int) ==> odd y ==> odd (x + y)" |
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by presburger |
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lemma odd_plus_even: "odd (x::int) ==> even y ==> odd (x + y)" |
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by presburger |
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lemma odd_plus_odd: "odd (x::int) ==> odd y ==> even (x + y)" by presburger |
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lemma even_sum[simp,presburger]: |
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"even ((x::int) + y) = ((even x & even y) | (odd x & odd y))" |
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by presburger |
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lemma even_neg[simp,presburger,algebra]: "even (-(x::int)) = even x" |
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by presburger |
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lemma even_difference[simp]: |
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"even ((x::int) - y) = ((even x & even y) | (odd x & odd y))" by presburger |
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lemma even_power[simp,presburger]: "even ((x::int)^n) = (even x & n \<noteq> 0)" |
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by (induct n) auto |
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lemma odd_pow: "odd x ==> odd((x::int)^n)" by simp |
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subsection {* Equivalent definitions *} |
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lemma two_times_even_div_two: "even (x::int) ==> 2 * (x div 2) = x" |
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by presburger |
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lemma two_times_odd_div_two_plus_one: |
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"odd (x::int) ==> 2 * (x div 2) + 1 = x" |
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by presburger |
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lemma even_equiv_def: "even (x::int) = (EX y. x = 2 * y)" by presburger |
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lemma odd_equiv_def: "odd (x::int) = (EX y. x = 2 * y + 1)" by presburger |
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subsection {* even and odd for nats *} |
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lemma pos_int_even_equiv_nat_even: "0 \<le> x ==> even x = even (nat x)" |
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by (simp add: even_nat_def) |
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lemma even_product_nat[simp,presburger,algebra]: |
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"even((x::nat) * y) = (even x | even y)" |
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by (simp add: even_nat_def int_mult) |
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lemma even_sum_nat[simp,presburger,algebra]: |
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"even ((x::nat) + y) = ((even x & even y) | (odd x & odd y))" |
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by presburger |
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lemma even_difference_nat[simp,presburger,algebra]: |
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"even ((x::nat) - y) = (x < y | (even x & even y) | (odd x & odd y))" |
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by presburger |
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lemma even_Suc[simp,presburger,algebra]: "even (Suc x) = odd x" |
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by presburger |
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lemma even_power_nat[simp,presburger,algebra]: |
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"even ((x::nat)^y) = (even x & 0 < y)" |
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by (simp add: even_nat_def int_power) |
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subsection {* Equivalent definitions *} |
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lemma even_nat_mod_two_eq_zero: "even (x::nat) ==> x mod (Suc (Suc 0)) = 0" |
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by presburger |
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lemma odd_nat_mod_two_eq_one: "odd (x::nat) ==> x mod (Suc (Suc 0)) = Suc 0" |
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by presburger |
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lemma even_nat_equiv_def: "even (x::nat) = (x mod Suc (Suc 0) = 0)" |
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by presburger |
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lemma odd_nat_equiv_def: "odd (x::nat) = (x mod Suc (Suc 0) = Suc 0)" |
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by presburger |
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lemma even_nat_div_two_times_two: "even (x::nat) ==> |
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Suc (Suc 0) * (x div Suc (Suc 0)) = x" by presburger |
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lemma odd_nat_div_two_times_two_plus_one: "odd (x::nat) ==> |
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Suc( Suc (Suc 0) * (x div Suc (Suc 0))) = x" by presburger |
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lemma even_nat_equiv_def2: "even (x::nat) = (EX y. x = Suc (Suc 0) * y)" |
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by presburger |
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lemma odd_nat_equiv_def2: "odd (x::nat) = (EX y. x = Suc(Suc (Suc 0) * y))" |
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by presburger |
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subsection {* Parity and powers *} |
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lemma (in comm_ring_1) neg_power_if: |
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"(- a) ^ n = (if even n then (a ^ n) else - (a ^ n))" |
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by (induct n) simp_all |
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lemma (in comm_ring_1) |
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shows neg_one_even_power [simp]: "even n \<Longrightarrow> (- 1) ^ n = 1" |
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and neg_one_odd_power [simp]: "odd n \<Longrightarrow> (- 1) ^ n = - 1" |
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by (simp_all add: neg_power_if) |
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lemma zero_le_even_power: "even n ==> |
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0 <= (x::'a::{linordered_ring,monoid_mult}) ^ n" |
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apply (simp add: even_nat_equiv_def2) |
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apply (erule exE) |
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apply (erule ssubst) |
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apply (subst power_add) |
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apply (rule zero_le_square) |
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done |
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lemma zero_le_odd_power: "odd n ==> |
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(0 <= (x::'a::{linordered_idom}) ^ n) = (0 <= x)" |
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apply (auto simp: odd_nat_equiv_def2 power_add zero_le_mult_iff) |
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apply (metis field_power_not_zero divisors_zero order_antisym_conv zero_le_square) |
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done |
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lemma zero_le_power_eq [presburger]: "(0 <= (x::'a::{linordered_idom}) ^ n) = |
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(even n | (odd n & 0 <= x))" |
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apply auto |
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apply (subst zero_le_odd_power [symmetric]) |
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apply assumption+ |
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apply (erule zero_le_even_power) |
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done |
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lemma zero_less_power_eq[presburger]: "(0 < (x::'a::{linordered_idom}) ^ n) = |
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(n = 0 | (even n & x ~= 0) | (odd n & 0 < x))" |
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|
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unfolding order_less_le zero_le_power_eq by auto |
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lemma power_less_zero_eq[presburger]: "((x::'a::{linordered_idom}) ^ n < 0) = |
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(odd n & x < 0)" |
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apply (subst linorder_not_le [symmetric])+ |
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apply (subst zero_le_power_eq) |
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apply auto |
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done |
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lemma power_le_zero_eq[presburger]: "((x::'a::{linordered_idom}) ^ n <= 0) = |
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(n ~= 0 & ((odd n & x <= 0) | (even n & x = 0)))" |
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apply (subst linorder_not_less [symmetric])+ |
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apply (subst zero_less_power_eq) |
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apply auto |
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done |
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lemma power_even_abs: "even n ==> |
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(abs (x::'a::{linordered_idom}))^n = x^n" |
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apply (subst power_abs [symmetric]) |
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apply (simp add: zero_le_even_power) |
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done |
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lemma power_minus_even [simp]: "even n ==> |
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(- x)^n = (x^n::'a::{comm_ring_1})" |
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apply (subst power_minus) |
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apply simp |
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done |
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lemma power_minus_odd [simp]: "odd n ==> |
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(- x)^n = - (x^n::'a::{comm_ring_1})" |
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apply (subst power_minus) |
254 |
apply simp |
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done |
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lemma power_mono_even: fixes x y :: "'a :: {linordered_idom}" |
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assumes "even n" and "\<bar>x\<bar> \<le> \<bar>y\<bar>" |
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shows "x^n \<le> y^n" |
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proof - |
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have "0 \<le> \<bar>x\<bar>" by auto |
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with `\<bar>x\<bar> \<le> \<bar>y\<bar>` |
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have "\<bar>x\<bar>^n \<le> \<bar>y\<bar>^n" by (rule power_mono) |
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thus ?thesis unfolding power_even_abs[OF `even n`] . |
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qed |
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266 |
|
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lemma odd_pos: "odd (n::nat) \<Longrightarrow> 0 < n" by presburger |
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268 |
|
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lemma power_mono_odd: fixes x y :: "'a :: {linordered_idom}" |
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assumes "odd n" and "x \<le> y" |
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shows "x^n \<le> y^n" |
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proof (cases "y < 0") |
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case True with `x \<le> y` have "-y \<le> -x" and "0 \<le> -y" by auto |
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hence "(-y)^n \<le> (-x)^n" by (rule power_mono) |
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thus ?thesis unfolding power_minus_odd[OF `odd n`] by auto |
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276 |
next |
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277 |
case False |
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show ?thesis |
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proof (cases "x < 0") |
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case True hence "n \<noteq> 0" and "x \<le> 0" using `odd n`[THEN odd_pos] by auto |
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hence "x^n \<le> 0" unfolding power_le_zero_eq using `odd n` by auto |
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moreover |
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from `\<not> y < 0` have "0 \<le> y" by auto |
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hence "0 \<le> y^n" by auto |
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ultimately show ?thesis by auto |
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next |
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case False hence "0 \<le> x" by auto |
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with `x \<le> y` show ?thesis using power_mono by auto |
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qed |
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qed |
21263 | 291 |
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subsection {* More Even/Odd Results *} |
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294 |
||
27668 | 295 |
lemma even_mult_two_ex: "even(n) = (\<exists>m::nat. n = 2*m)" by presburger |
296 |
lemma odd_Suc_mult_two_ex: "odd(n) = (\<exists>m. n = Suc (2*m))" by presburger |
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lemma even_add [simp]: "even(m + n::nat) = (even m = even n)" by presburger |
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25600 | 298 |
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27668 | 299 |
lemma odd_add [simp]: "odd(m + n::nat) = (odd m \<noteq> odd n)" by presburger |
25600 | 300 |
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27668 | 301 |
lemma lemma_even_div2 [simp]: "even (n::nat) ==> (n + 1) div 2 = n div 2" by presburger |
25600 | 302 |
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303 |
lemma lemma_not_even_div2 [simp]: "~even n ==> (n + 1) div 2 = Suc (n div 2)" |
|
27668 | 304 |
by presburger |
25600 | 305 |
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27668 | 306 |
lemma even_num_iff: "0 < n ==> even n = (~ even(n - 1 :: nat))" by presburger |
307 |
lemma even_even_mod_4_iff: "even (n::nat) = even (n mod 4)" by presburger |
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25600 | 308 |
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27668 | 309 |
lemma lemma_odd_mod_4_div_2: "n mod 4 = (3::nat) ==> odd((n - 1) div 2)" by presburger |
25600 | 310 |
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311 |
lemma lemma_even_mod_4_div_2: "n mod 4 = (1::nat) ==> even ((n - 1) div 2)" |
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27668 | 312 |
by presburger |
25600 | 313 |
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21263 | 314 |
text {* Simplify, when the exponent is a numeral *} |
21256 | 315 |
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lemmas zero_le_power_eq_numeral [simp] = |
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zero_le_power_eq [of _ "numeral w"] for w |
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lemmas zero_less_power_eq_numeral [simp] = |
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zero_less_power_eq [of _ "numeral w"] for w |
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lemmas power_le_zero_eq_numeral [simp] = |
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power_le_zero_eq [of _ "numeral w"] for w |
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lemmas power_less_zero_eq_numeral [simp] = |
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power_less_zero_eq [of _ "numeral w"] for w |
21256 | 327 |
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lemmas zero_less_power_nat_eq_numeral [simp] = |
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nat_zero_less_power_iff [of _ "numeral w"] for w |
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lemmas power_eq_0_iff_numeral [simp] = |
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power_eq_0_iff [of _ "numeral w"] for w |
21256 | 333 |
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lemmas power_even_abs_numeral [simp] = |
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power_even_abs [of "numeral w" _] for w |
21256 | 336 |
|
337 |
||
338 |
subsection {* An Equivalence for @{term [source] "0 \<le> a^n"} *} |
|
339 |
||
23522 | 340 |
lemma zero_le_power_iff[presburger]: |
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341 |
"(0 \<le> a^n) = (0 \<le> (a::'a::{linordered_idom}) | even n)" |
21256 | 342 |
proof cases |
343 |
assume even: "even n" |
|
344 |
then obtain k where "n = 2*k" |
|
345 |
by (auto simp add: even_nat_equiv_def2 numeral_2_eq_2) |
|
21263 | 346 |
thus ?thesis by (simp add: zero_le_even_power even) |
21256 | 347 |
next |
348 |
assume odd: "odd n" |
|
349 |
then obtain k where "n = Suc(2*k)" |
|
350 |
by (auto simp add: odd_nat_equiv_def2 numeral_2_eq_2) |
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moreover have "a ^ (2 * k) \<le> 0 \<Longrightarrow> a = 0" |
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by (induct k) (auto simp add: zero_le_mult_iff mult_le_0_iff) |
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353 |
ultimately show ?thesis |
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354 |
by (auto simp add: zero_le_mult_iff zero_le_even_power) |
21263 | 355 |
qed |
356 |
||
21256 | 357 |
|
358 |
subsection {* Miscellaneous *} |
|
359 |
||
23522 | 360 |
lemma [presburger]:"(x + 1) div 2 = x div 2 \<longleftrightarrow> even (x::int)" by presburger |
361 |
lemma [presburger]: "(x + 1) div 2 = x div 2 + 1 \<longleftrightarrow> odd (x::int)" by presburger |
|
362 |
lemma even_plus_one_div_two: "even (x::int) ==> (x + 1) div 2 = x div 2" by presburger |
|
363 |
lemma odd_plus_one_div_two: "odd (x::int) ==> (x + 1) div 2 = x div 2 + 1" by presburger |
|
21256 | 364 |
|
23522 | 365 |
lemma [presburger]: "(Suc x) div Suc (Suc 0) = x div Suc (Suc 0) \<longleftrightarrow> even x" by presburger |
21263 | 366 |
lemma even_nat_plus_one_div_two: "even (x::nat) ==> |
23522 | 367 |
(Suc x) div Suc (Suc 0) = x div Suc (Suc 0)" by presburger |
21256 | 368 |
|
21263 | 369 |
lemma odd_nat_plus_one_div_two: "odd (x::nat) ==> |
23522 | 370 |
(Suc x) div Suc (Suc 0) = Suc (x div Suc (Suc 0))" by presburger |
21256 | 371 |
|
372 |
end |
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373 |