Theory HOL-Algebra.Ring
theory Ring
imports FiniteProduct
begin
section ‹The Algebraic Hierarchy of Rings›
subsection ‹Abelian Groups›
record 'a ring = "'a monoid" +
zero :: 'a (‹𝟬ı›)
add :: "['a, 'a] ⇒ 'a" (infixl ‹⊕ı› 65)
abbreviation
add_monoid :: "('a, 'm) ring_scheme ⇒ ('a, 'm) monoid_scheme"
where "add_monoid R ≡ ⦇ carrier = carrier R, mult = add R, one = zero R, … = (undefined :: 'm) ⦈"
text ‹Derived operations.›
definition
a_inv :: "[('a, 'm) ring_scheme, 'a ] ⇒ 'a" (‹(‹open_block notation=‹prefix ⊖››⊖ı _)› [81] 80)
where "a_inv R = m_inv (add_monoid R)"
definition
a_minus :: "[('a, 'm) ring_scheme, 'a, 'a] => 'a" (‹(‹notation=‹infix ⊖››_ ⊖ı _)› [65,66] 65)
where "x ⊖⇘R⇙ y = x ⊕⇘R⇙ (⊖⇘R⇙ y)"
definition
add_pow :: "[_, ('b :: semiring_1), 'a] ⇒ 'a"
(‹(‹open_block notation=‹mixfix ⋅››[_] ⋅ı _)› [81, 81] 80)
where "[k] ⋅⇘R⇙ a = pow (add_monoid R) a k"
locale abelian_monoid =
fixes G (structure)
assumes a_comm_monoid:
"comm_monoid (add_monoid G)"
definition
finsum :: "[('b, 'm) ring_scheme, 'a ⇒ 'b, 'a set] ⇒ 'b" where
"finsum G = finprod (add_monoid G)"
syntax
"_finsum" :: "index ⇒ idt ⇒ 'a set ⇒ 'b ⇒ 'b"
(‹(‹indent=3 notation=‹binder ⨁››⨁__∈_. _)› [1000, 0, 51, 10] 10)
syntax_consts
"_finsum" ⇌ finsum
translations
"⨁⇘G⇙i∈A. b" ⇌ "CONST finsum G (λi. b) A"
locale abelian_group = abelian_monoid +
assumes a_comm_group:
"comm_group (add_monoid G)"
subsection ‹Basic Properties›
lemma abelian_monoidI:
fixes R (structure)
assumes "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ x ⊕ y ∈ carrier R"
and "𝟬 ∈ carrier R"
and "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ (x ⊕ y) ⊕ z = x ⊕ (y ⊕ z)"
and "⋀x. x ∈ carrier R ⟹ 𝟬 ⊕ x = x"
and "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ x ⊕ y = y ⊕ x"
shows "abelian_monoid R"
by (auto intro!: abelian_monoid.intro comm_monoidI intro: assms)
lemma abelian_monoidE:
fixes R (structure)
assumes "abelian_monoid R"
shows "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ x ⊕ y ∈ carrier R"
and "𝟬 ∈ carrier R"
and "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ (x ⊕ y) ⊕ z = x ⊕ (y ⊕ z)"
and "⋀x. x ∈ carrier R ⟹ 𝟬 ⊕ x = x"
and "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ x ⊕ y = y ⊕ x"
using assms unfolding abelian_monoid_def comm_monoid_def comm_monoid_axioms_def monoid_def by auto
lemma abelian_groupI:
fixes R (structure)
assumes "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ x ⊕ y ∈ carrier R"
and "𝟬 ∈ carrier R"
and "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ (x ⊕ y) ⊕ z = x ⊕ (y ⊕ z)"
and "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ x ⊕ y = y ⊕ x"
and "⋀x. x ∈ carrier R ⟹ 𝟬 ⊕ x = x"
and "⋀x. x ∈ carrier R ⟹ ∃y ∈ carrier R. y ⊕ x = 𝟬"
shows "abelian_group R"
by (auto intro!: abelian_group.intro abelian_monoidI
abelian_group_axioms.intro comm_monoidI comm_groupI
intro: assms)
lemma abelian_groupE:
fixes R (structure)
assumes "abelian_group R"
shows "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ x ⊕ y ∈ carrier R"
and "𝟬 ∈ carrier R"
and "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ (x ⊕ y) ⊕ z = x ⊕ (y ⊕ z)"
and "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ x ⊕ y = y ⊕ x"
and "⋀x. x ∈ carrier R ⟹ 𝟬 ⊕ x = x"
and "⋀x. x ∈ carrier R ⟹ ∃y ∈ carrier R. y ⊕ x = 𝟬"
using abelian_group.a_comm_group assms comm_groupE by fastforce+
lemma (in abelian_monoid) a_monoid:
"monoid (add_monoid G)"
by (rule comm_monoid.axioms, rule a_comm_monoid)
lemma (in abelian_group) a_group:
"group (add_monoid G)"
by (simp add: group_def a_monoid)
(simp add: comm_group.axioms group.axioms a_comm_group)
lemmas monoid_record_simps = partial_object.simps monoid.simps
text ‹Transfer facts from multiplicative structures via interpretation.›
sublocale abelian_monoid <
add: monoid "(add_monoid G)"
rewrites "carrier (add_monoid G) = carrier G"
and "mult (add_monoid G) = add G"
and "one (add_monoid G) = zero G"
and "(λa k. pow (add_monoid G) a k) = (λa k. add_pow G k a)"
by (rule a_monoid) (auto simp add: add_pow_def)
context abelian_monoid
begin
lemmas a_closed = add.m_closed
lemmas zero_closed = add.one_closed
lemmas a_assoc = add.m_assoc
lemmas l_zero = add.l_one
lemmas r_zero = add.r_one
lemmas minus_unique = add.inv_unique
end
sublocale abelian_monoid <
add: comm_monoid "(add_monoid G)"
rewrites "carrier (add_monoid G) = carrier G"
and "mult (add_monoid G) = add G"
and "one (add_monoid G) = zero G"
and "finprod (add_monoid G) = finsum G"
and "pow (add_monoid G) = (λa k. add_pow G k a)"
by (rule a_comm_monoid) (auto simp: finsum_def add_pow_def)
context abelian_monoid begin
lemmas a_comm = add.m_comm
lemmas a_lcomm = add.m_lcomm
lemmas a_ac = a_assoc a_comm a_lcomm
lemmas finsum_empty = add.finprod_empty
lemmas finsum_insert = add.finprod_insert
lemmas finsum_zero = add.finprod_one
lemmas finsum_closed = add.finprod_closed
lemmas finsum_Un_Int = add.finprod_Un_Int
lemmas finsum_Un_disjoint = add.finprod_Un_disjoint
lemmas finsum_addf = add.finprod_multf
lemmas finsum_cong' = add.finprod_cong'
lemmas finsum_0 = add.finprod_0
lemmas finsum_Suc = add.finprod_Suc
lemmas finsum_Suc2 = add.finprod_Suc2
lemmas finsum_infinite = add.finprod_infinite
lemmas finsum_cong = add.finprod_cong
text ‹Usually, if this rule causes a failed congruence proof error,
the reason is that the premise ‹g ∈ B → carrier G› cannot be shown.
Adding @{thm [source] Pi_def} to the simpset is often useful.›
lemmas finsum_reindex = add.finprod_reindex
lemmas finsum_singleton = add.finprod_singleton
end
sublocale abelian_group <
add: group "(add_monoid G)"
rewrites "carrier (add_monoid G) = carrier G"
and "mult (add_monoid G) = add G"
and "one (add_monoid G) = zero G"
and "m_inv (add_monoid G) = a_inv G"
and "pow (add_monoid G) = (λa k. add_pow G k a)"
by (rule a_group) (auto simp: m_inv_def a_inv_def add_pow_def)
context abelian_group
begin
lemmas a_inv_closed = add.inv_closed
lemma minus_closed [intro, simp]:
"[| x ∈ carrier G; y ∈ carrier G |] ==> x ⊖ y ∈ carrier G"
by (simp add: a_minus_def)
lemmas l_neg = add.l_inv [simp del]
lemmas r_neg = add.r_inv [simp del]
lemmas minus_minus = add.inv_inv
lemmas a_inv_inj = add.inv_inj
lemmas minus_equality = add.inv_equality
end
sublocale abelian_group <
add: comm_group "(add_monoid G)"
rewrites "carrier (add_monoid G) = carrier G"
and "mult (add_monoid G) = add G"
and "one (add_monoid G) = zero G"
and "m_inv (add_monoid G) = a_inv G"
and "finprod (add_monoid G) = finsum G"
and "pow (add_monoid G) = (λa k. add_pow G k a)"
by (rule a_comm_group) (auto simp: m_inv_def a_inv_def finsum_def add_pow_def)
lemmas (in abelian_group) minus_add = add.inv_mult
text ‹Derive an ‹abelian_group› from a ‹comm_group››
lemma comm_group_abelian_groupI:
fixes G (structure)
assumes cg: "comm_group (add_monoid G)"
shows "abelian_group G"
proof -
interpret comm_group "(add_monoid G)"
by (rule cg)
show "abelian_group G" ..
qed
subsection ‹Rings: Basic Definitions›
locale semiring = abelian_monoid R + monoid R for R (structure) +
assumes l_distr: "⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ (x ⊕ y) ⊗ z = x ⊗ z ⊕ y ⊗ z"
and r_distr: "⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ z ⊗ (x ⊕ y) = z ⊗ x ⊕ z ⊗ y"
and l_null[simp]: "x ∈ carrier R ⟹ 𝟬 ⊗ x = 𝟬"
and r_null[simp]: "x ∈ carrier R ⟹ x ⊗ 𝟬 = 𝟬"
locale ring = abelian_group R + monoid R for R (structure) +
assumes "⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ (x ⊕ y) ⊗ z = x ⊗ z ⊕ y ⊗ z"
and "⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ z ⊗ (x ⊕ y) = z ⊗ x ⊕ z ⊗ y"
locale cring = ring + comm_monoid R
locale "domain" = cring +
assumes one_not_zero [simp]: "𝟭 ≠ 𝟬"
and integral: "⟦ a ⊗ b = 𝟬; a ∈ carrier R; b ∈ carrier R ⟧ ⟹ a = 𝟬 ∨ b = 𝟬"
locale field = "domain" +
assumes field_Units: "Units R = carrier R - {𝟬}"
subsection ‹Rings›
lemma ringI:
fixes R (structure)
assumes "abelian_group R"
and "monoid R"
and "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ (x ⊕ y) ⊗ z = x ⊗ z ⊕ y ⊗ z"
and "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ z ⊗ (x ⊕ y) = z ⊗ x ⊕ z ⊗ y"
shows "ring R"
by (auto intro: ring.intro
abelian_group.axioms ring_axioms.intro assms)
lemma ringE:
fixes R (structure)
assumes "ring R"
shows "abelian_group R"
and "monoid R"
and "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ (x ⊕ y) ⊗ z = x ⊗ z ⊕ y ⊗ z"
and "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ z ⊗ (x ⊕ y) = z ⊗ x ⊕ z ⊗ y"
using assms unfolding ring_def ring_axioms_def by auto
context ring begin
lemma is_abelian_group: "abelian_group R" ..
lemma is_monoid: "monoid R"
by (auto intro!: monoidI m_assoc)
end
thm monoid_record_simps
lemmas ring_record_simps = monoid_record_simps ring.simps
lemma cringI:
fixes R (structure)
assumes abelian_group: "abelian_group R"
and comm_monoid: "comm_monoid R"
and l_distr: "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹
(x ⊕ y) ⊗ z = x ⊗ z ⊕ y ⊗ z"
shows "cring R"
proof (intro cring.intro ring.intro)
show "ring_axioms R"
proof (rule ring_axioms.intro)
fix x y z
assume R: "x ∈ carrier R" "y ∈ carrier R" "z ∈ carrier R"
note [simp] = comm_monoid.axioms [OF comm_monoid]
abelian_group.axioms [OF abelian_group]
abelian_monoid.a_closed
from R have "z ⊗ (x ⊕ y) = (x ⊕ y) ⊗ z"
by (simp add: comm_monoid.m_comm [OF comm_monoid.intro])
also from R have "... = x ⊗ z ⊕ y ⊗ z" by (simp add: l_distr)
also from R have "... = z ⊗ x ⊕ z ⊗ y"
by (simp add: comm_monoid.m_comm [OF comm_monoid.intro])
finally show "z ⊗ (x ⊕ y) = z ⊗ x ⊕ z ⊗ y" .
qed (rule l_distr)
qed (auto intro: cring.intro
abelian_group.axioms comm_monoid.axioms ring_axioms.intro assms)
lemma cringE:
fixes R (structure)
assumes "cring R"
shows "comm_monoid R"
and "⋀x y z. ⟦ x ∈ carrier R; y ∈ carrier R; z ∈ carrier R ⟧ ⟹ (x ⊕ y) ⊗ z = x ⊗ z ⊕ y ⊗ z"
using assms cring_def by auto (simp add: assms cring.axioms(1) ringE(3))
lemma (in cring) is_cring:
"cring R" by (rule cring_axioms)
lemma (in ring) minus_zero [simp]: "⊖ 𝟬 = 𝟬"
by (simp add: a_inv_def)
subsubsection ‹Normaliser for Rings›
lemma (in abelian_group) r_neg1:
"⟦ x ∈ carrier G; y ∈ carrier G ⟧ ⟹ (⊖ x) ⊕ (x ⊕ y) = y"
proof -
assume G: "x ∈ carrier G" "y ∈ carrier G"
then have "(⊖ x ⊕ x) ⊕ y = y"
by (simp only: l_neg l_zero)
with G show ?thesis by (simp add: a_ac)
qed
lemma (in abelian_group) r_neg2:
"⟦ x ∈ carrier G; y ∈ carrier G ⟧ ⟹ x ⊕ ((⊖ x) ⊕ y) = y"
proof -
assume G: "x ∈ carrier G" "y ∈ carrier G"
then have "(x ⊕ ⊖ x) ⊕ y = y"
by (simp only: r_neg l_zero)
with G show ?thesis
by (simp add: a_ac)
qed
context ring begin
text ‹
The following proofs are from Jacobson, Basic Algebra I, pp.~88--89.
›
sublocale semiring
proof -
note [simp] = ring_axioms[unfolded ring_def ring_axioms_def]
show "semiring R"
proof (unfold_locales)
fix x
assume R: "x ∈ carrier R"
then have "𝟬 ⊗ x ⊕ 𝟬 ⊗ x = (𝟬 ⊕ 𝟬) ⊗ x"
by (simp del: l_zero r_zero)
also from R have "... = 𝟬 ⊗ x ⊕ 𝟬" by simp
finally have "𝟬 ⊗ x ⊕ 𝟬 ⊗ x = 𝟬 ⊗ x ⊕ 𝟬" .
with R show "𝟬 ⊗ x = 𝟬" by (simp del: r_zero)
from R have "x ⊗ 𝟬 ⊕ x ⊗ 𝟬 = x ⊗ (𝟬 ⊕ 𝟬)"
by (simp del: l_zero r_zero)
also from R have "... = x ⊗ 𝟬 ⊕ 𝟬" by simp
finally have "x ⊗ 𝟬 ⊕ x ⊗ 𝟬 = x ⊗ 𝟬 ⊕ 𝟬" .
with R show "x ⊗ 𝟬 = 𝟬" by (simp del: r_zero)
qed auto
qed
lemma l_minus:
"⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ (⊖ x) ⊗ y = ⊖ (x ⊗ y)"
proof -
assume R: "x ∈ carrier R" "y ∈ carrier R"
then have "(⊖ x) ⊗ y ⊕ x ⊗ y = (⊖ x ⊕ x) ⊗ y" by (simp add: l_distr)
also from R have "... = 𝟬" by (simp add: l_neg)
finally have "(⊖ x) ⊗ y ⊕ x ⊗ y = 𝟬" .
with R have "(⊖ x) ⊗ y ⊕ x ⊗ y ⊕ ⊖ (x ⊗ y) = 𝟬 ⊕ ⊖ (x ⊗ y)" by simp
with R show ?thesis by (simp add: a_assoc r_neg)
qed
lemma r_minus:
"⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ x ⊗ (⊖ y) = ⊖ (x ⊗ y)"
proof -
assume R: "x ∈ carrier R" "y ∈ carrier R"
then have "x ⊗ (⊖ y) ⊕ x ⊗ y = x ⊗ (⊖ y ⊕ y)" by (simp add: r_distr)
also from R have "... = 𝟬" by (simp add: l_neg)
finally have "x ⊗ (⊖ y) ⊕ x ⊗ y = 𝟬" .
with R have "x ⊗ (⊖ y) ⊕ x ⊗ y ⊕ ⊖ (x ⊗ y) = 𝟬 ⊕ ⊖ (x ⊗ y)" by simp
with R show ?thesis by (simp add: a_assoc r_neg )
qed
end
lemma (in abelian_group) minus_eq: "x ⊖ y = x ⊕ (⊖ y)"
by (rule a_minus_def)
text ‹Setup algebra method:
compute distributive normal form in locale contexts›
ML_file ‹ringsimp.ML›
attribute_setup algebra = ‹
Scan.lift ((Args.add >> K true || Args.del >> K false) --| Args.colon || Scan.succeed true)
-- Scan.lift Args.name -- Scan.repeat Args.term
>> (fn ((b, n), ts) => if b then Ringsimp.add_struct (n, ts) else Ringsimp.del_struct (n, ts))
› "theorems controlling algebra method"
method_setup algebra = ‹
Scan.succeed (SIMPLE_METHOD' o Ringsimp.algebra_tac)
› "normalisation of algebraic structure"
lemmas (in semiring) semiring_simprules
[algebra ring "zero R" "add R" "a_inv R" "a_minus R" "one R" "mult R"] =
a_closed zero_closed m_closed one_closed
a_assoc l_zero a_comm m_assoc l_one l_distr r_zero
a_lcomm r_distr l_null r_null
lemmas (in ring) ring_simprules
[algebra ring "zero R" "add R" "a_inv R" "a_minus R" "one R" "mult R"] =
a_closed zero_closed a_inv_closed minus_closed m_closed one_closed
a_assoc l_zero l_neg a_comm m_assoc l_one l_distr minus_eq
r_zero r_neg r_neg2 r_neg1 minus_add minus_minus minus_zero
a_lcomm r_distr l_null r_null l_minus r_minus
lemmas (in cring)
[algebra del: ring "zero R" "add R" "a_inv R" "a_minus R" "one R" "mult R"] =
_
lemmas (in cring) cring_simprules
[algebra add: cring "zero R" "add R" "a_inv R" "a_minus R" "one R" "mult R"] =
a_closed zero_closed a_inv_closed minus_closed m_closed one_closed
a_assoc l_zero l_neg a_comm m_assoc l_one l_distr m_comm minus_eq
r_zero r_neg r_neg2 r_neg1 minus_add minus_minus minus_zero
a_lcomm m_lcomm r_distr l_null r_null l_minus r_minus
lemma (in semiring) nat_pow_zero:
"(n::nat) ≠ 0 ⟹ 𝟬 [^] n = 𝟬"
by (induct n) simp_all
context semiring begin
lemma one_zeroD:
assumes onezero: "𝟭 = 𝟬"
shows "carrier R = {𝟬}"
proof (rule, rule)
fix x
assume xcarr: "x ∈ carrier R"
from xcarr have "x = x ⊗ 𝟭" by simp
with onezero have "x = x ⊗ 𝟬" by simp
with xcarr have "x = 𝟬" by simp
then show "x ∈ {𝟬}" by fast
qed fast
lemma one_zeroI:
assumes carrzero: "carrier R = {𝟬}"
shows "𝟭 = 𝟬"
proof -
from one_closed and carrzero
show "𝟭 = 𝟬" by simp
qed
lemma carrier_one_zero: "(carrier R = {𝟬}) = (𝟭 = 𝟬)"
using one_zeroD by blast
lemma carrier_one_not_zero: "(carrier R ≠ {𝟬}) = (𝟭 ≠ 𝟬)"
by (simp add: carrier_one_zero)
end
text ‹Two examples for use of method algebra›
lemma
fixes R (structure) and S (structure)
assumes "ring R" "cring S"
assumes RS: "a ∈ carrier R" "b ∈ carrier R" "c ∈ carrier S" "d ∈ carrier S"
shows "a ⊕ (⊖ (a ⊕ (⊖ b))) = b ∧ c ⊗⇘S⇙ d = d ⊗⇘S⇙ c"
proof -
interpret ring R by fact
interpret cring S by fact
from RS show ?thesis by algebra
qed
lemma
fixes R (structure)
assumes "ring R"
assumes R: "a ∈ carrier R" "b ∈ carrier R"
shows "a ⊖ (a ⊖ b) = b"
proof -
interpret ring R by fact
from R show ?thesis by algebra
qed
subsubsection ‹Sums over Finite Sets›
lemma (in semiring) finsum_ldistr:
"⟦ finite A; a ∈ carrier R; f: A → carrier R ⟧ ⟹
(⨁ i ∈ A. (f i)) ⊗ a = (⨁ i ∈ A. ((f i) ⊗ a))"
proof (induct set: finite)
case empty then show ?case by simp
next
case (insert x F) then show ?case by (simp add: Pi_def l_distr)
qed
lemma (in semiring) finsum_rdistr:
"⟦ finite A; a ∈ carrier R; f: A → carrier R ⟧ ⟹
a ⊗ (⨁ i ∈ A. (f i)) = (⨁ i ∈ A. (a ⊗ (f i)))"
proof (induct set: finite)
case empty then show ?case by simp
next
case (insert x F) then show ?case by (simp add: Pi_def r_distr)
qed
text ‹A quick detour›
lemma add_pow_int_ge: "(k :: int) ≥ 0 ⟹ [ k ] ⋅⇘R⇙ a = [ nat k ] ⋅⇘R⇙ a"
by (simp add: add_pow_def int_pow_def nat_pow_def)
lemma add_pow_int_lt: "(k :: int) < 0 ⟹ [ k ] ⋅⇘R⇙ a = ⊖⇘R⇙ ([ nat (- k) ] ⋅⇘R⇙ a)"
by (simp add: int_pow_def nat_pow_def a_inv_def add_pow_def)
corollary (in semiring) add_pow_ldistr:
assumes "a ∈ carrier R" "b ∈ carrier R"
shows "([(k :: nat)] ⋅ a) ⊗ b = [k] ⋅ (a ⊗ b)"
proof -
have "([k] ⋅ a) ⊗ b = (⨁ i ∈ {..< k}. a) ⊗ b"
using add.finprod_const[OF assms(1), of "{..<k}"] by simp
also have " ... = (⨁ i ∈ {..< k}. (a ⊗ b))"
using finsum_ldistr[of "{..<k}" b "λx. a"] assms by simp
also have " ... = [k] ⋅ (a ⊗ b)"
using add.finprod_const[of "a ⊗ b" "{..<k}"] assms by simp
finally show ?thesis .
qed
corollary (in semiring) add_pow_rdistr:
assumes "a ∈ carrier R" "b ∈ carrier R"
shows "a ⊗ ([(k :: nat)] ⋅ b) = [k] ⋅ (a ⊗ b)"
proof -
have "a ⊗ ([k] ⋅ b) = a ⊗ (⨁ i ∈ {..< k}. b)"
using add.finprod_const[OF assms(2), of "{..<k}"] by simp
also have " ... = (⨁ i ∈ {..< k}. (a ⊗ b))"
using finsum_rdistr[of "{..<k}" a "λx. b"] assms by simp
also have " ... = [k] ⋅ (a ⊗ b)"
using add.finprod_const[of "a ⊗ b" "{..<k}"] assms by simp
finally show ?thesis .
qed
lemma (in ring) add_pow_ldistr_int:
assumes "a ∈ carrier R" "b ∈ carrier R"
shows "([(k :: int)] ⋅ a) ⊗ b = [k] ⋅ (a ⊗ b)"
proof (cases "k ≥ 0")
case True thus ?thesis
using add_pow_int_ge[of k R] add_pow_ldistr[OF assms] by auto
next
case False thus ?thesis
using add_pow_int_lt[of k R a] add_pow_int_lt[of k R "a ⊗ b"]
add_pow_ldistr[OF assms, of "nat (- k)"] assms l_minus by auto
qed
lemma (in ring) add_pow_rdistr_int:
assumes "a ∈ carrier R" "b ∈ carrier R"
shows "a ⊗ ([(k :: int)] ⋅ b) = [k] ⋅ (a ⊗ b)"
proof (cases "k ≥ 0")
case True thus ?thesis
using add_pow_int_ge[of k R] add_pow_rdistr[OF assms] by auto
next
case False thus ?thesis
using add_pow_int_lt[of k R b] add_pow_int_lt[of k R "a ⊗ b"]
add_pow_rdistr[OF assms, of "nat (- k)"] assms r_minus by auto
qed
subsection ‹Integral Domains›
context "domain" begin
lemma zero_not_one [simp]: "𝟬 ≠ 𝟭"
by (rule not_sym) simp
lemma integral_iff:
"⟦ a ∈ carrier R; b ∈ carrier R ⟧ ⟹ (a ⊗ b = 𝟬) = (a = 𝟬 ∨ b = 𝟬)"
proof
assume "a ∈ carrier R" "b ∈ carrier R" "a ⊗ b = 𝟬"
then show "a = 𝟬 ∨ b = 𝟬" by (simp add: integral)
next
assume "a ∈ carrier R" "b ∈ carrier R" "a = 𝟬 ∨ b = 𝟬"
then show "a ⊗ b = 𝟬" by auto
qed
lemma m_lcancel:
assumes prem: "a ≠ 𝟬"
and R: "a ∈ carrier R" "b ∈ carrier R" "c ∈ carrier R"
shows "(a ⊗ b = a ⊗ c) = (b = c)"
proof
assume eq: "a ⊗ b = a ⊗ c"
with R have "a ⊗ (b ⊖ c) = 𝟬" by algebra
with R have "a = 𝟬 ∨ (b ⊖ c) = 𝟬" by (simp add: integral_iff)
with prem and R have "b ⊖ c = 𝟬" by auto
with R have "b = b ⊖ (b ⊖ c)" by algebra
also from R have "b ⊖ (b ⊖ c) = c" by algebra
finally show "b = c" .
next
assume "b = c" then show "a ⊗ b = a ⊗ c" by simp
qed
lemma m_rcancel:
assumes prem: "a ≠ 𝟬"
and R: "a ∈ carrier R" "b ∈ carrier R" "c ∈ carrier R"
shows conc: "(b ⊗ a = c ⊗ a) = (b = c)"
proof -
from prem and R have "(a ⊗ b = a ⊗ c) = (b = c)" by (rule m_lcancel)
with R show ?thesis by algebra
qed
end
subsection ‹Fields›
text ‹Field would not need to be derived from domain, the properties
for domain follow from the assumptions of field›
lemma (in field) is_ring: "ring R"
using ring_axioms .
lemma fieldE :
fixes R (structure)
assumes "field R"
shows "cring R"
and one_not_zero : "𝟭 ≠ 𝟬"
and integral: "⋀a b. ⟦ a ⊗ b = 𝟬; a ∈ carrier R; b ∈ carrier R ⟧ ⟹ a = 𝟬 ∨ b = 𝟬"
and field_Units: "Units R = carrier R - {𝟬}"
using assms unfolding field_def field_axioms_def domain_def domain_axioms_def by simp_all
lemma (in cring) cring_fieldI:
assumes field_Units: "Units R = carrier R - {𝟬}"
shows "field R"
proof
from field_Units have "𝟬 ∉ Units R" by fast
moreover have "𝟭 ∈ Units R" by fast
ultimately show "𝟭 ≠ 𝟬" by force
next
fix a b
assume acarr: "a ∈ carrier R"
and bcarr: "b ∈ carrier R"
and ab: "a ⊗ b = 𝟬"
show "a = 𝟬 ∨ b = 𝟬"
proof (cases "a = 𝟬", simp)
assume "a ≠ 𝟬"
with field_Units and acarr have aUnit: "a ∈ Units R" by fast
from bcarr have "b = 𝟭 ⊗ b" by algebra
also from aUnit acarr have "... = (inv a ⊗ a) ⊗ b" by simp
also from acarr bcarr aUnit[THEN Units_inv_closed]
have "... = (inv a) ⊗ (a ⊗ b)" by algebra
also from ab and acarr bcarr aUnit have "... = (inv a) ⊗ 𝟬" by simp
also from aUnit[THEN Units_inv_closed] have "... = 𝟬" by algebra
finally have "b = 𝟬" .
then show "a = 𝟬 ∨ b = 𝟬" by simp
qed
qed (rule field_Units)
text ‹Another variant to show that something is a field›
lemma (in cring) cring_fieldI2:
assumes notzero: "𝟬 ≠ 𝟭"
and invex: "⋀a. ⟦a ∈ carrier R; a ≠ 𝟬⟧ ⟹ ∃b∈carrier R. a ⊗ b = 𝟭"
shows "field R"
proof -
have *: "carrier R - {𝟬} ⊆ {y ∈ carrier R. ∃x∈carrier R. x ⊗ y = 𝟭 ∧ y ⊗ x = 𝟭}"
proof (clarsimp)
fix x
assume xcarr: "x ∈ carrier R" and "x ≠ 𝟬"
obtain y where ycarr: "y ∈ carrier R" and xy: "x ⊗ y = 𝟭"
using ‹x ≠ 𝟬› invex xcarr by blast
with ycarr and xy show "∃y∈carrier R. y ⊗ x = 𝟭 ∧ x ⊗ y = 𝟭"
using m_comm xcarr by fastforce
qed
show ?thesis
apply (rule cring_fieldI, simp add: Units_def)
using *
using group_l_invI notzero set_diff_eq by auto
qed
subsection ‹Morphisms›
definition
ring_hom :: "[('a, 'm) ring_scheme, ('b, 'n) ring_scheme] => ('a => 'b) set"
where "ring_hom R S =
{h. h ∈ carrier R → carrier S ∧
(∀x y. x ∈ carrier R ∧ y ∈ carrier R ⟶
h (x ⊗⇘R⇙ y) = h x ⊗⇘S⇙ h y ∧ h (x ⊕⇘R⇙ y) = h x ⊕⇘S⇙ h y) ∧
h 𝟭⇘R⇙ = 𝟭⇘S⇙}"
lemma ring_hom_memI:
fixes R (structure) and S (structure)
assumes "⋀x. x ∈ carrier R ⟹ h x ∈ carrier S"
and "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ h (x ⊗ y) = h x ⊗⇘S⇙ h y"
and "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ h (x ⊕ y) = h x ⊕⇘S⇙ h y"
and "h 𝟭 = 𝟭⇘S⇙"
shows "h ∈ ring_hom R S"
by (auto simp add: ring_hom_def assms Pi_def)
lemma ring_hom_memE:
fixes R (structure) and S (structure)
assumes "h ∈ ring_hom R S"
shows "⋀x. x ∈ carrier R ⟹ h x ∈ carrier S"
and "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ h (x ⊗ y) = h x ⊗⇘S⇙ h y"
and "⋀x y. ⟦ x ∈ carrier R; y ∈ carrier R ⟧ ⟹ h (x ⊕ y) = h x ⊕⇘S⇙ h y"
and "h 𝟭 = 𝟭⇘S⇙"
using assms unfolding ring_hom_def by auto
lemma ring_hom_closed:
"⟦ h ∈ ring_hom R S; x ∈ carrier R ⟧ ⟹ h x ∈ carrier S"
by (auto simp add: ring_hom_def funcset_mem)
lemma ring_hom_mult:
fixes R (structure) and S (structure)
shows "⟦ h ∈ ring_hom R S; x ∈ carrier R; y ∈ carrier R ⟧ ⟹ h (x ⊗ y) = h x ⊗⇘S⇙ h y"
by (simp add: ring_hom_def)
lemma ring_hom_add:
fixes R (structure) and S (structure)
shows "⟦ h ∈ ring_hom R S; x ∈ carrier R; y ∈ carrier R ⟧ ⟹ h (x ⊕ y) = h x ⊕⇘S⇙ h y"
by (simp add: ring_hom_def)
lemma ring_hom_one:
fixes R (structure) and S (structure)
shows "h ∈ ring_hom R S ⟹ h 𝟭 = 𝟭⇘S⇙"
by (simp add: ring_hom_def)
lemma ring_hom_zero:
fixes R (structure) and S (structure)
assumes "h ∈ ring_hom R S" "ring R" "ring S"
shows "h 𝟬 = 𝟬⇘S⇙"
proof -
have "h 𝟬 = h 𝟬 ⊕⇘S⇙ h 𝟬"
using ring_hom_add[OF assms(1), of 𝟬 𝟬] assms(2)
by (simp add: ring.ring_simprules(2) ring.ring_simprules(15))
thus ?thesis
by (metis abelian_group.l_neg assms ring.is_abelian_group ring.ring_simprules(18) ring.ring_simprules(2) ring_hom_closed)
qed
locale ring_hom_cring =
R?: cring R + S?: cring S for R (structure) and S (structure) + fixes h
assumes homh [simp, intro]: "h ∈ ring_hom R S"
notes hom_closed [simp, intro] = ring_hom_closed [OF homh]
and hom_mult [simp] = ring_hom_mult [OF homh]
and hom_add [simp] = ring_hom_add [OF homh]
and hom_one [simp] = ring_hom_one [OF homh]
lemma (in ring_hom_cring) hom_zero [simp]: "h 𝟬 = 𝟬⇘S⇙"
proof -
have "h 𝟬 ⊕⇘S⇙ h 𝟬 = h 𝟬 ⊕⇘S⇙ 𝟬⇘S⇙"
by (simp add: hom_add [symmetric] del: hom_add)
then show ?thesis by (simp del: S.r_zero)
qed
lemma (in ring_hom_cring) hom_a_inv [simp]:
"x ∈ carrier R ⟹ h (⊖ x) = ⊖⇘S⇙ h x"
proof -
assume R: "x ∈ carrier R"
then have "h x ⊕⇘S⇙ h (⊖ x) = h x ⊕⇘S⇙ (⊖⇘S⇙ h x)"
by (simp add: hom_add [symmetric] R.r_neg S.r_neg del: hom_add)
with R show ?thesis by simp
qed
lemma (in ring_hom_cring) hom_finsum [simp]:
assumes "f: A → carrier R"
shows "h (⨁ i ∈ A. f i) = (⨁⇘S⇙ i ∈ A. (h o f) i)"
using assms by (induct A rule: infinite_finite_induct, auto simp: Pi_def)
lemma (in ring_hom_cring) hom_finprod:
assumes "f: A → carrier R"
shows "h (⨂ i ∈ A. f i) = (⨂⇘S⇙ i ∈ A. (h o f) i)"
using assms by (induct A rule: infinite_finite_induct, auto simp: Pi_def)
declare ring_hom_cring.hom_finprod [simp]
lemma id_ring_hom [simp]: "id ∈ ring_hom R R"
by (auto intro!: ring_hom_memI)
lemma ring_hom_trans:
"⟦ f ∈ ring_hom R S; g ∈ ring_hom S T ⟧ ⟹ g ∘ f ∈ ring_hom R T"
by (rule ring_hom_memI) (auto simp add: ring_hom_closed ring_hom_mult ring_hom_add ring_hom_one)
subsection‹Jeremy Avigad's ‹More_Finite_Product› material›
lemma (in cring) sum_zero_eq_neg: "x ∈ carrier R ⟹ y ∈ carrier R ⟹ x ⊕ y = 𝟬 ⟹ x = ⊖ y"
by (metis minus_equality)
lemma (in domain) square_eq_one:
fixes x
assumes [simp]: "x ∈ carrier R"
and "x ⊗ x = 𝟭"
shows "x = 𝟭 ∨ x = ⊖𝟭"
proof -
have "(x ⊕ 𝟭) ⊗ (x ⊕ ⊖ 𝟭) = x ⊗ x ⊕ ⊖ 𝟭"
by (simp add: ring_simprules)
also from ‹x ⊗ x = 𝟭› have "… = 𝟬"
by (simp add: ring_simprules)
finally have "(x ⊕ 𝟭) ⊗ (x ⊕ ⊖ 𝟭) = 𝟬" .
then have "(x ⊕ 𝟭) = 𝟬 ∨ (x ⊕ ⊖ 𝟭) = 𝟬"
by (intro integral) auto
then show ?thesis
by (metis add.inv_closed add.inv_solve_right assms(1) l_zero one_closed zero_closed)
qed
lemma (in domain) inv_eq_self: "x ∈ Units R ⟹ x = inv x ⟹ x = 𝟭 ∨ x = ⊖𝟭"
by (metis Units_closed Units_l_inv square_eq_one)
text ‹
The following translates theorems about groups to the facts about
the units of a ring. (The list should be expanded as more things are
needed.)
›
lemma (in ring) finite_ring_finite_units [intro]: "finite (carrier R) ⟹ finite (Units R)"
by (rule finite_subset) auto
lemma (in monoid) units_of_pow:
fixes n :: nat
shows "x ∈ Units G ⟹ x [^]⇘units_of G⇙ n = x [^]⇘G⇙ n"
apply (induct n)
apply (auto simp add: units_group group.is_monoid
monoid.nat_pow_0 monoid.nat_pow_Suc units_of_one units_of_mult)
done
lemma (in cring) units_power_order_eq_one:
"finite (Units R) ⟹ a ∈ Units R ⟹ a [^] card(Units R) = 𝟭"
by (metis comm_group.power_order_eq_one units_comm_group units_of_carrier units_of_one units_of_pow)
subsection‹Jeremy Avigad's ‹More_Ring› material›
lemma (in cring) field_intro2:
assumes "𝟬⇘R⇙ ≠ 𝟭⇘R⇙" and un: "⋀x. x ∈ carrier R - {𝟬⇘R⇙} ⟹ x ∈ Units R"
shows "field R"
proof unfold_locales
show "𝟭 ≠ 𝟬" using assms by auto
show "⟦a ⊗ b = 𝟬; a ∈ carrier R;
b ∈ carrier R⟧
⟹ a = 𝟬 ∨ b = 𝟬" for a b
by (metis un Units_l_cancel insert_Diff_single insert_iff r_null zero_closed)
qed (use assms in ‹auto simp: Units_def›)
lemma (in monoid) inv_char:
assumes "x ∈ carrier G" "y ∈ carrier G" "x ⊗ y = 𝟭" "y ⊗ x = 𝟭"
shows "inv x = y"
using assms inv_unique' by auto
lemma (in comm_monoid) comm_inv_char: "x ∈ carrier G ⟹ y ∈ carrier G ⟹ x ⊗ y = 𝟭 ⟹ inv x = y"
by (simp add: inv_char m_comm)
lemma (in ring) inv_neg_one [simp]: "inv (⊖ 𝟭) = ⊖ 𝟭"
by (simp add: inv_char local.ring_axioms ring.r_minus)
lemma (in monoid) inv_eq_imp_eq [dest!]: "inv x = inv y ⟹ x ∈ Units G ⟹ y ∈ Units G ⟹ x = y"
by (metis Units_inv_inv)
lemma (in ring) Units_minus_one_closed [intro]: "⊖ 𝟭 ∈ Units R"
by (simp add: Units_def) (metis add.l_inv_ex local.minus_minus minus_equality one_closed r_minus r_one)
lemma (in ring) inv_eq_neg_one_eq: "x ∈ Units R ⟹ inv x = ⊖ 𝟭 ⟷ x = ⊖ 𝟭"
by (metis Units_inv_inv inv_neg_one)
lemma (in monoid) inv_eq_one_eq: "x ∈ Units G ⟹ inv x = 𝟭 ⟷ x = 𝟭"
by (metis Units_inv_inv inv_one)
end