Theory HOL-Number_Theory.Residues
section ‹Residue rings›
theory Residues
imports
Cong
"HOL-Algebra.Multiplicative_Group"
Totient
begin
definition QuadRes :: "int ⇒ int ⇒ bool"
where "QuadRes p a = (∃y. ([y^2 = a] (mod p)))"
definition Legendre :: "int ⇒ int ⇒ int"
where "Legendre a p =
(if ([a = 0] (mod p)) then 0
else if QuadRes p a then 1
else -1)"
subsection ‹A locale for residue rings›
definition residue_ring :: "int ⇒ int ring"
where
"residue_ring m =
⦇carrier = {0..m - 1},
monoid.mult = λx y. (x * y) mod m,
one = 1,
zero = 0,
add = λx y. (x + y) mod m⦈"
locale residues =
fixes m :: int and R (structure)
assumes m_gt_one: "m > 1"
defines R_m_def: "R ≡ residue_ring m"
begin
lemma abelian_group: "abelian_group R"
proof -
have "∃y∈{0..m - 1}. (x + y) mod m = 0" if "0 ≤ x" "x < m" for x
proof (cases "x = 0")
case True
with m_gt_one show ?thesis by simp
next
case False
then have "(x + (m - x)) mod m = 0"
by simp
with m_gt_one that show ?thesis
by (metis False atLeastAtMost_iff diff_ge_0_iff_ge diff_left_mono int_one_le_iff_zero_less less_le)
qed
with m_gt_one show ?thesis
by (fastforce simp add: R_m_def residue_ring_def mod_add_right_eq ac_simps intro!: abelian_groupI)
qed
lemma comm_monoid: "comm_monoid R"
unfolding R_m_def residue_ring_def
apply (rule comm_monoidI)
using m_gt_one apply auto
apply (metis mod_mult_right_eq mult.assoc mult.commute)
apply (metis mult.commute)
done
lemma cring: "cring R"
apply (intro cringI abelian_group comm_monoid)
unfolding R_m_def residue_ring_def
apply (auto simp add: comm_semiring_class.distrib mod_add_eq mod_mult_left_eq)
done
end
sublocale residues < cring
by (rule cring)
context residues
begin
text ‹
These lemmas translate back and forth between internal and
external concepts.
›
lemma res_carrier_eq: "carrier R = {0..m - 1}"
by (auto simp: R_m_def residue_ring_def)
lemma res_add_eq: "x ⊕ y = (x + y) mod m"
by (auto simp: R_m_def residue_ring_def)
lemma res_mult_eq: "x ⊗ y = (x * y) mod m"
by (auto simp: R_m_def residue_ring_def)
lemma res_zero_eq: "𝟬 = 0"
by (auto simp: R_m_def residue_ring_def)
lemma res_one_eq: "𝟭 = 1"
by (auto simp: R_m_def residue_ring_def units_of_def)
lemma res_units_eq: "Units R = {x. 0 < x ∧ x < m ∧ coprime x m}"
using m_gt_one
apply (auto simp add: Units_def R_m_def residue_ring_def ac_simps invertible_coprime intro: ccontr)
apply (subst (asm) coprime_iff_invertible'_int)
apply (auto simp add: cong_def)
done
lemma res_neg_eq: "⊖ x = (- x) mod m"
using m_gt_one unfolding R_m_def a_inv_def m_inv_def residue_ring_def
apply simp
apply (rule the_equality)
apply (simp add: mod_add_right_eq)
apply (simp add: add.commute mod_add_right_eq)
apply (metis add.right_neutral minus_add_cancel mod_add_right_eq mod_pos_pos_trivial)
done
lemma finite [iff]: "finite (carrier R)"
by (simp add: res_carrier_eq)
lemma finite_Units [iff]: "finite (Units R)"
by (simp add: finite_ring_finite_units)
text ‹
The function ‹a ↦ a mod m› maps the integers to the
residue classes. The following lemmas show that this mapping
respects addition and multiplication on the integers.
›
lemma mod_in_carrier [iff]: "a mod m ∈ carrier R"
unfolding res_carrier_eq
using insert m_gt_one by auto
lemma add_cong: "(x mod m) ⊕ (y mod m) = (x + y) mod m"
by (auto simp: R_m_def residue_ring_def mod_simps)
lemma mult_cong: "(x mod m) ⊗ (y mod m) = (x * y) mod m"
by (auto simp: R_m_def residue_ring_def mod_simps)
lemma zero_cong: "𝟬 = 0"
by (auto simp: R_m_def residue_ring_def)
lemma one_cong: "𝟭 = 1 mod m"
using m_gt_one by (auto simp: R_m_def residue_ring_def)
lemma pow_cong: "(x mod m) [^] n = x^n mod m"
using m_gt_one
apply (induct n)
apply (auto simp add: nat_pow_def one_cong)
apply (metis mult.commute mult_cong)
done
lemma neg_cong: "⊖ (x mod m) = (- x) mod m"
by (metis mod_minus_eq res_neg_eq)
lemma (in residues) prod_cong: "finite A ⟹ (⨂i∈A. (f i) mod m) = (∏i∈A. f i) mod m"
by (induct set: finite) (auto simp: one_cong mult_cong)
lemma (in residues) sum_cong: "finite A ⟹ (⨁i∈A. (f i) mod m) = (∑i∈A. f i) mod m"
by (induct set: finite) (auto simp: zero_cong add_cong)
lemma mod_in_res_units [simp]:
assumes "1 < m" and "coprime a m"
shows "a mod m ∈ Units R"
proof (cases "a mod m = 0")
case True
with assms show ?thesis
by (auto simp add: res_units_eq gcd_red_int [symmetric])
next
case False
from assms have "0 < m" by simp
then have "0 ≤ a mod m" by (rule pos_mod_sign [of m a])
with False have "0 < a mod m" by simp
with assms show ?thesis
by (auto simp add: res_units_eq gcd_red_int [symmetric] ac_simps)
qed
lemma res_eq_to_cong: "(a mod m) = (b mod m) ⟷ [a = b] (mod m)"
by (auto simp: cong_def)
text ‹Simplifying with these will translate a ring equation in R to a congruence.›
lemmas res_to_cong_simps =
add_cong mult_cong pow_cong one_cong
prod_cong sum_cong neg_cong res_eq_to_cong
text ‹Other useful facts about the residue ring.›
lemma one_eq_neg_one: "𝟭 = ⊖ 𝟭 ⟹ m = 2"
apply (simp add: res_one_eq res_neg_eq)
apply (metis add.commute add_diff_cancel mod_mod_trivial one_add_one uminus_add_conv_diff
zero_neq_one zmod_zminus1_eq_if)
done
end
subsection ‹Prime residues›
locale residues_prime =
fixes p :: nat and R (structure)
assumes p_prime [intro]: "prime p"
defines "R ≡ residue_ring (int p)"
sublocale residues_prime < residues p
unfolding R_def residues_def
using p_prime apply auto
apply (metis (full_types) of_nat_1 of_nat_less_iff prime_gt_1_nat)
done
context residues_prime
begin
lemma p_coprime_left:
"coprime p a ⟷ ¬ p dvd a"
using p_prime by (auto intro: prime_imp_coprime dest: coprime_common_divisor)
lemma p_coprime_right:
"coprime a p ⟷ ¬ p dvd a"
using p_coprime_left [of a] by (simp add: ac_simps)
lemma p_coprime_left_int:
"coprime (int p) a ⟷ ¬ int p dvd a"
using p_prime by (auto intro: prime_imp_coprime dest: coprime_common_divisor)
lemma p_coprime_right_int:
"coprime a (int p) ⟷ ¬ int p dvd a"
using p_coprime_left_int [of a] by (simp add: ac_simps)
lemma is_field: "field R"
proof -
have "0 < x ⟹ x < int p ⟹ coprime (int p) x" for x
by (rule prime_imp_coprime) (auto simp add: zdvd_not_zless)
then show ?thesis
by (intro cring.field_intro2 cring)
(auto simp add: res_carrier_eq res_one_eq res_zero_eq res_units_eq ac_simps)
qed
lemma res_prime_units_eq: "Units R = {1..p - 1}"
apply (subst res_units_eq)
apply (auto simp add: p_coprime_right_int zdvd_not_zless)
done
end
sublocale residues_prime < field
by (rule is_field)
section ‹Test cases: Euler's theorem and Wilson's theorem›
subsection ‹Euler's theorem›
lemma (in residues) totatives_eq:
"totatives (nat m) = nat ` Units R"
proof -
from m_gt_one have "¦m¦ > 1"
by simp
then have "totatives (nat ¦m¦) = nat ` abs ` Units R"
by (auto simp add: totatives_def res_units_eq image_iff le_less)
(use m_gt_one zless_nat_eq_int_zless in force)
moreover have "¦m¦ = m" "abs ` Units R = Units R"
using m_gt_one by (auto simp add: res_units_eq image_iff)
ultimately show ?thesis
by simp
qed
lemma (in residues) totient_eq:
"totient (nat m) = card (Units R)"
proof -
have *: "inj_on nat (Units R)"
by (rule inj_onI) (auto simp add: res_units_eq)
then show ?thesis
by (simp add: totient_def totatives_eq card_image)
qed
lemma (in residues_prime) prime_totient_eq: "totient p = p - 1"
using totient_eq by (simp add: res_prime_units_eq)
lemma (in residues) euler_theorem:
assumes "coprime a m"
shows "[a ^ totient (nat m) = 1] (mod m)"
proof -
have "a ^ totient (nat m) mod m = 1 mod m"
by (metis assms finite_Units m_gt_one mod_in_res_units one_cong totient_eq pow_cong units_power_order_eq_one)
then show ?thesis
using res_eq_to_cong by blast
qed
lemma euler_theorem:
fixes a m :: nat
assumes "coprime a m"
shows "[a ^ totient m = 1] (mod m)"
proof (cases "m = 0 ∨ m = 1")
case True
then show ?thesis by auto
next
case False
with assms show ?thesis
using residues.euler_theorem [of "int m" "int a"] cong_int_iff
by (auto simp add: residues_def gcd_int_def) fastforce
qed
lemma fermat_theorem:
fixes p a :: nat
assumes "prime p" and "¬ p dvd a"
shows "[a ^ (p - 1) = 1] (mod p)"
proof -
from assms prime_imp_coprime [of p a] have "coprime a p"
by (auto simp add: ac_simps)
then have "[a ^ totient p = 1] (mod p)"
by (rule euler_theorem)
also have "totient p = p - 1"
by (rule totient_prime) (rule assms)
finally show ?thesis .
qed
subsection ‹Wilson's theorem›
lemma (in field) inv_pair_lemma: "x ∈ Units R ⟹ y ∈ Units R ⟹
{x, inv x} ≠ {y, inv y} ⟹ {x, inv x} ∩ {y, inv y} = {}"
apply auto
apply (metis Units_inv_inv)+
done
lemma (in residues_prime) wilson_theorem1:
assumes a: "p > 2"
shows "[fact (p - 1) = (-1::int)] (mod p)"
proof -
let ?Inverse_Pairs = "{{x, inv x}| x. x ∈ Units R - {𝟭, ⊖ 𝟭}}"
have UR: "Units R = {𝟭, ⊖ 𝟭} ∪ ⋃?Inverse_Pairs"
by auto
have "(⨂i∈Units R. i) = (⨂i∈{𝟭, ⊖ 𝟭}. i) ⊗ (⨂i∈⋃?Inverse_Pairs. i)"
apply (subst UR)
apply (subst finprod_Un_disjoint)
apply (auto intro: funcsetI)
using inv_one apply auto[1]
using inv_eq_neg_one_eq apply auto
done
also have "(⨂i∈{𝟭, ⊖ 𝟭}. i) = ⊖ 𝟭"
apply (subst finprod_insert)
apply auto
apply (frule one_eq_neg_one)
using a apply force
done
also have "(⨂i∈(⋃?Inverse_Pairs). i) = (⨂A∈?Inverse_Pairs. (⨂y∈A. y))"
apply (subst finprod_Union_disjoint)
apply (auto simp: pairwise_def disjnt_def)
apply (metis Units_inv_inv)+
done
also have "… = 𝟭"
apply (rule finprod_one_eqI)
apply auto
apply (subst finprod_insert)
apply auto
apply (metis inv_eq_self)
done
finally have "(⨂i∈Units R. i) = ⊖ 𝟭"
by simp
also have "(⨂i∈Units R. i) = (⨂i∈Units R. i mod p)"
by (rule finprod_cong') (auto simp: res_units_eq)
also have "… = (∏i∈Units R. i) mod p"
by (rule prod_cong) auto
also have "… = fact (p - 1) mod p"
apply (simp add: fact_prod)
using assms
apply (subst res_prime_units_eq)
apply (simp add: int_prod zmod_int prod_int_eq)
done
finally have "fact (p - 1) mod p = ⊖ 𝟭" .
then show ?thesis
by (simp add: cong_def res_neg_eq res_one_eq zmod_int)
qed
lemma wilson_theorem:
assumes "prime p"
shows "[fact (p - 1) = - 1] (mod p)"
proof (cases "p = 2")
case True
then show ?thesis
by (simp add: cong_def fact_prod)
next
case False
then show ?thesis
using assms prime_ge_2_nat
by (metis residues_prime.wilson_theorem1 residues_prime.intro le_eq_less_or_eq)
qed
text ‹
This result can be transferred to the multiplicative group of
‹ℤ/pℤ› for ‹p› prime.›
lemma mod_nat_int_pow_eq:
fixes n :: nat and p a :: int
shows "a ≥ 0 ⟹ p ≥ 0 ⟹ (nat a ^ n) mod (nat p) = nat ((a ^ n) mod p)"
by (simp add: int_one_le_iff_zero_less nat_mod_distrib order_less_imp_le nat_power_eq[symmetric])
theorem residue_prime_mult_group_has_gen:
fixes p :: nat
assumes prime_p : "prime p"
shows "∃a ∈ {1 .. p - 1}. {1 .. p - 1} = {a^i mod p|i . i ∈ UNIV}"
proof -
have "p ≥ 2"
using prime_gt_1_nat[OF prime_p] by simp
interpret R: residues_prime p "residue_ring p"
by (simp add: residues_prime_def prime_p)
have car: "carrier (residue_ring (int p)) - {𝟬⇘residue_ring (int p)⇙} = {1 .. int p - 1}"
by (auto simp add: R.zero_cong R.res_carrier_eq)
have "x [^]⇘residue_ring (int p)⇙ i = x ^ i mod (int p)"
if "x ∈ {1 .. int p - 1}" for x and i :: nat
using that R.pow_cong[of x i] by auto
moreover
obtain a where a: "a ∈ {1 .. int p - 1}"
and a_gen: "{1 .. int p - 1} = {a[^]⇘residue_ring (int p)⇙i|i::nat . i ∈ UNIV}"
using field.finite_field_mult_group_has_gen[OF R.is_field]
by (auto simp add: car[symmetric] carrier_mult_of)
moreover
have "nat ` {1 .. int p - 1} = {1 .. p - 1}" (is "?L = ?R")
proof
have "n ∈ ?R" if "n ∈ ?L" for n
using that ‹p≥2› by force
then show "?L ⊆ ?R" by blast
have "n ∈ ?L" if "n ∈ ?R" for n
using that ‹p≥2› by (auto intro: rev_image_eqI [of "int n"])
then show "?R ⊆ ?L" by blast
qed
moreover
have "nat ` {a^i mod (int p) | i::nat. i ∈ UNIV} = {nat a^i mod p | i . i ∈ UNIV}" (is "?L = ?R")
proof
have "x ∈ ?R" if "x ∈ ?L" for x
proof -
from that obtain i where i: "x = nat (a^i mod (int p))"
by blast
then have "x = nat a ^ i mod p"
using mod_nat_int_pow_eq[of a "int p" i] a ‹p≥2› by auto
with i show ?thesis by blast
qed
then show "?L ⊆ ?R" by blast
have "x ∈ ?L" if "x ∈ ?R" for x
proof -
from that obtain i where i: "x = nat a^i mod p"
by blast
with mod_nat_int_pow_eq[of a "int p" i] a ‹p≥2› show ?thesis
by auto
qed
then show "?R ⊆ ?L" by blast
qed
ultimately have "{1 .. p - 1} = {nat a^i mod p | i. i ∈ UNIV}"
by presburger
moreover from a have "nat a ∈ {1 .. p - 1}" by force
ultimately show ?thesis ..
qed
subsection ‹Upper bound for the number of $n$-th roots›
lemma roots_mod_prime_bound:
fixes n c p :: nat
assumes "prime p" "n > 0"
defines "A ≡ {x∈{..<p}. [x ^ n = c] (mod p)}"
shows "card A ≤ n"
proof -
define R where "R = residue_ring (int p)"
from assms(1) interpret residues_prime p R
by unfold_locales (simp_all add: R_def)
interpret R: UP_domain R "UP R" by (unfold_locales)
let ?f = "UnivPoly.monom (UP R) 𝟭⇘R⇙ n ⊖⇘(UP R)⇙ UnivPoly.monom (UP R) (int (c mod p)) 0"
have in_carrier: "int (c mod p) ∈ carrier R"
using prime_gt_1_nat[OF assms(1)] by (simp add: R_def residue_ring_def)
have "deg R ?f = n"
using assms in_carrier by (simp add: R.deg_minus_eq)
hence f_not_zero: "?f ≠ 𝟬⇘UP R⇙" using assms by (auto simp add : R.deg_nzero_nzero)
have roots_bound: "finite {a ∈ carrier R. UnivPoly.eval R R id a ?f = 𝟬⇘R⇙} ∧
card {a ∈ carrier R. UnivPoly.eval R R id a ?f = 𝟬⇘R⇙} ≤ deg R ?f"
using finite in_carrier by (intro R.roots_bound[OF _ f_not_zero]) simp
have subs: "{x ∈ carrier R. x [^]⇘R⇙ n = int (c mod p)} ⊆
{a ∈ carrier R. UnivPoly.eval R R id a ?f = 𝟬⇘R⇙}"
using in_carrier by (auto simp: R.evalRR_simps)
then have "card {x ∈ carrier R. x [^]⇘R⇙ n = int (c mod p)} ≤
card {a ∈ carrier R. UnivPoly.eval R R id a ?f = 𝟬⇘R⇙}"
using finite by (intro card_mono) auto
also have "… ≤ n"
using ‹deg R ?f = n› roots_bound by linarith
also {
fix x assume "x ∈ carrier R"
hence "x [^]⇘R⇙ n = (x ^ n) mod (int p)"
by (subst pow_cong [symmetric]) (auto simp: R_def residue_ring_def)
}
hence "{x ∈ carrier R. x [^]⇘R⇙ n = int (c mod p)} = {x ∈ carrier R. [x ^ n = int c] (mod p)}"
by (fastforce simp: cong_def zmod_int)
also have "bij_betw int A {x ∈ carrier R. [x ^ n = int c] (mod p)}"
by (rule bij_betwI[of int _ _ nat])
(use cong_int_iff in ‹force simp: R_def residue_ring_def A_def›)+
from bij_betw_same_card[OF this] have "card {x ∈ carrier R. [x ^ n = int c] (mod p)} = card A" ..
finally show ?thesis .
qed
end