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theory Ring(* Title: The algebraic hierarchy of rings
Author: Clemens Ballarin, started 9 December 1996
Copyright: Clemens Ballarin
*)
theory Ring
imports FiniteProduct
uses ("ringsimp.ML")
begin
section {* The Algebraic Hierarchy of Rings *}
subsection {* Abelian Groups *}
record 'a ring = "'a monoid" +
zero :: 'a ("\<zero>\<index>")
add :: "['a, 'a] => 'a" (infixl "⊕\<index>" 65)
text {* Derived operations. *}
definition
a_inv :: "[('a, 'm) ring_scheme, 'a ] => 'a" ("\<ominus>\<index> _" [81] 80)
where "a_inv R = m_inv (| carrier = carrier R, mult = add R, one = zero R |)"
definition
a_minus :: "[('a, 'm) ring_scheme, 'a, 'a] => 'a" (infixl "\<ominus>\<index>" 65)
where "[| x ∈ carrier R; y ∈ carrier R |] ==> x \<ominus>\<^bsub>R\<^esub> y = x ⊕\<^bsub>R\<^esub> (\<ominus>\<^bsub>R\<^esub> y)"
locale abelian_monoid =
fixes G (structure)
assumes a_comm_monoid:
"comm_monoid (| carrier = carrier G, mult = add G, one = zero G |)"
text {*
The following definition is redundant but simple to use.
*}
locale abelian_group = abelian_monoid +
assumes a_comm_group:
"comm_group (| carrier = carrier G, mult = add G, one = zero G |)"
subsection {* Basic Properties *}
lemma abelian_monoidI:
fixes R (structure)
assumes a_closed:
"!!x y. [| x ∈ carrier R; y ∈ carrier R |] ==> x ⊕ y ∈ carrier R"
and zero_closed: "\<zero> ∈ carrier R"
and a_assoc:
"!!x y z. [| x ∈ carrier R; y ∈ carrier R; z ∈ carrier R |] ==>
(x ⊕ y) ⊕ z = x ⊕ (y ⊕ z)"
and l_zero: "!!x. x ∈ carrier R ==> \<zero> ⊕ x = x"
and a_comm:
"!!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_groupI:
fixes R (structure)
assumes a_closed:
"!!x y. [| x ∈ carrier R; y ∈ carrier R |] ==> x ⊕ y ∈ carrier R"
and zero_closed: "zero R ∈ carrier R"
and a_assoc:
"!!x y z. [| x ∈ carrier R; y ∈ carrier R; z ∈ carrier R |] ==>
(x ⊕ y) ⊕ z = x ⊕ (y ⊕ z)"
and a_comm:
"!!x y. [| x ∈ carrier R; y ∈ carrier R |] ==> x ⊕ y = y ⊕ x"
and l_zero: "!!x. x ∈ carrier R ==> \<zero> ⊕ x = x"
and l_inv_ex: "!!x. x ∈ carrier R ==> EX y : carrier R. y ⊕ x = \<zero>"
shows "abelian_group R"
by (auto intro!: abelian_group.intro abelian_monoidI
abelian_group_axioms.intro comm_monoidI comm_groupI
intro: assms)
lemma (in abelian_monoid) a_monoid:
"monoid (| carrier = carrier G, mult = add G, one = zero G |)"
by (rule comm_monoid.axioms, rule a_comm_monoid)
lemma (in abelian_group) a_group:
"group (| carrier = carrier G, mult = add G, one = zero 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
lemma (in abelian_monoid) a_closed [intro, simp]:
"[| x ∈ carrier G; y ∈ carrier G |] ==> x ⊕ y ∈ carrier G"
by (rule monoid.m_closed [OF a_monoid, simplified monoid_record_simps])
lemma (in abelian_monoid) zero_closed [intro, simp]:
"\<zero> ∈ carrier G"
by (rule monoid.one_closed [OF a_monoid, simplified monoid_record_simps])
lemma (in abelian_group) a_inv_closed [intro, simp]:
"x ∈ carrier G ==> \<ominus> x ∈ carrier G"
by (simp add: a_inv_def
group.inv_closed [OF a_group, simplified monoid_record_simps])
lemma (in abelian_group) minus_closed [intro, simp]:
"[| x ∈ carrier G; y ∈ carrier G |] ==> x \<ominus> y ∈ carrier G"
by (simp add: a_minus_def)
lemma (in abelian_group) a_l_cancel [simp]:
"[| x ∈ carrier G; y ∈ carrier G; z ∈ carrier G |] ==>
(x ⊕ y = x ⊕ z) = (y = z)"
by (rule group.l_cancel [OF a_group, simplified monoid_record_simps])
lemma (in abelian_group) a_r_cancel [simp]:
"[| x ∈ carrier G; y ∈ carrier G; z ∈ carrier G |] ==>
(y ⊕ x = z ⊕ x) = (y = z)"
by (rule group.r_cancel [OF a_group, simplified monoid_record_simps])
lemma (in abelian_monoid) a_assoc:
"[|x ∈ carrier G; y ∈ carrier G; z ∈ carrier G|] ==>
(x ⊕ y) ⊕ z = x ⊕ (y ⊕ z)"
by (rule monoid.m_assoc [OF a_monoid, simplified monoid_record_simps])
lemma (in abelian_monoid) l_zero [simp]:
"x ∈ carrier G ==> \<zero> ⊕ x = x"
by (rule monoid.l_one [OF a_monoid, simplified monoid_record_simps])
lemma (in abelian_group) l_neg:
"x ∈ carrier G ==> \<ominus> x ⊕ x = \<zero>"
by (simp add: a_inv_def
group.l_inv [OF a_group, simplified monoid_record_simps])
lemma (in abelian_monoid) a_comm:
"[|x ∈ carrier G; y ∈ carrier G|] ==> x ⊕ y = y ⊕ x"
by (rule comm_monoid.m_comm [OF a_comm_monoid,
simplified monoid_record_simps])
lemma (in abelian_monoid) a_lcomm:
"[|x ∈ carrier G; y ∈ carrier G; z ∈ carrier G|] ==>
x ⊕ (y ⊕ z) = y ⊕ (x ⊕ z)"
by (rule comm_monoid.m_lcomm [OF a_comm_monoid,
simplified monoid_record_simps])
lemma (in abelian_monoid) r_zero [simp]:
"x ∈ carrier G ==> x ⊕ \<zero> = x"
using monoid.r_one [OF a_monoid]
by simp
lemma (in abelian_group) r_neg:
"x ∈ carrier G ==> x ⊕ (\<ominus> x) = \<zero>"
using group.r_inv [OF a_group]
by (simp add: a_inv_def)
lemma (in abelian_group) minus_zero [simp]:
"\<ominus> \<zero> = \<zero>"
by (simp add: a_inv_def
group.inv_one [OF a_group, simplified monoid_record_simps])
lemma (in abelian_group) minus_minus [simp]:
"x ∈ carrier G ==> \<ominus> (\<ominus> x) = x"
using group.inv_inv [OF a_group, simplified monoid_record_simps]
by (simp add: a_inv_def)
lemma (in abelian_group) a_inv_inj:
"inj_on (a_inv G) (carrier G)"
using group.inv_inj [OF a_group, simplified monoid_record_simps]
by (simp add: a_inv_def)
lemma (in abelian_group) minus_add:
"[| x ∈ carrier G; y ∈ carrier G |] ==> \<ominus> (x ⊕ y) = \<ominus> x ⊕ \<ominus> y"
using comm_group.inv_mult [OF a_comm_group]
by (simp add: a_inv_def)
lemma (in abelian_group) minus_equality:
"[| x ∈ carrier G; y ∈ carrier G; y ⊕ x = \<zero> |] ==> \<ominus> x = y"
using group.inv_equality [OF a_group]
by (auto simp add: a_inv_def)
lemma (in abelian_monoid) minus_unique:
"[| x ∈ carrier G; y ∈ carrier G; y' ∈ carrier G;
y ⊕ x = \<zero>; x ⊕ y' = \<zero> |] ==> y = y'"
using monoid.inv_unique [OF a_monoid]
by (simp add: a_inv_def)
lemmas (in abelian_monoid) a_ac = a_assoc a_comm a_lcomm
text {* Derive an @{text "abelian_group"} from a @{text "comm_group"} *}
lemma comm_group_abelian_groupI:
fixes G (structure)
assumes cg: "comm_group (|carrier = carrier G, mult = add G, one = zero G|)),"
shows "abelian_group G"
proof -
interpret comm_group "(|carrier = carrier G, mult = add G, one = zero G|)),"
by (rule cg)
show "abelian_group G" ..
qed
subsection {* Sums over Finite Sets *}
text {*
This definition makes it easy to lift lemmas from @{term finprod}.
*}
definition
finsum :: "[('b, 'm) ring_scheme, 'a => 'b, 'a set] => 'b" where
"finsum G f A = finprod (| carrier = carrier G, mult = add G, one = zero G |) f A"
syntax
"_finsum" :: "index => idt => 'a set => 'b => 'b"
("(3\<Oplus>__:_. _)" [1000, 0, 51, 10] 10)
syntax (xsymbols)
"_finsum" :: "index => idt => 'a set => 'b => 'b"
("(3\<Oplus>__∈_. _)" [1000, 0, 51, 10] 10)
syntax (HTML output)
"_finsum" :: "index => idt => 'a set => 'b => 'b"
("(3\<Oplus>__∈_. _)" [1000, 0, 51, 10] 10)
translations
"\<Oplus>\<index>i:A. b" == "CONST finsum \<struct>\<index> (%i. b) A"
-- {* Beware of argument permutation! *}
context abelian_monoid begin
(*
lemmas finsum_empty [simp] =
comm_monoid.finprod_empty [OF a_comm_monoid, simplified]
is dangeous, because attributes (like simplified) are applied upon opening
the locale, simplified refers to the simpset at that time!!!
lemmas finsum_empty [simp] =
abelian_monoid.finprod_empty [OF a_abelian_monoid, folded finsum_def,
simplified monoid_record_simps]
makes the locale slow, because proofs are repeated for every
"lemma (in abelian_monoid)" command.
When lemma is used time in UnivPoly.thy from beginning to UP_cring goes down
from 110 secs to 60 secs.
*)
lemma finsum_empty [simp]:
"finsum G f {} = \<zero>"
by (rule comm_monoid.finprod_empty [OF a_comm_monoid,
folded finsum_def, simplified monoid_record_simps])
lemma finsum_insert [simp]:
"[| finite F; a ∉ F; f ∈ F -> carrier G; f a ∈ carrier G |]
==> finsum G f (insert a F) = f a ⊕ finsum G f F"
by (rule comm_monoid.finprod_insert [OF a_comm_monoid,
folded finsum_def, simplified monoid_record_simps])
lemma finsum_zero [simp]:
"finite A ==> (\<Oplus>i∈A. \<zero>) = \<zero>"
by (rule comm_monoid.finprod_one [OF a_comm_monoid, folded finsum_def,
simplified monoid_record_simps])
lemma finsum_closed [simp]:
fixes A
assumes fin: "finite A" and f: "f ∈ A -> carrier G"
shows "finsum G f A ∈ carrier G"
apply (rule comm_monoid.finprod_closed [OF a_comm_monoid,
folded finsum_def, simplified monoid_record_simps])
apply (rule fin)
apply (rule f)
done
lemma finsum_Un_Int:
"[| finite A; finite B; g ∈ A -> carrier G; g ∈ B -> carrier G |] ==>
finsum G g (A Un B) ⊕ finsum G g (A Int B) =
finsum G g A ⊕ finsum G g B"
by (rule comm_monoid.finprod_Un_Int [OF a_comm_monoid,
folded finsum_def, simplified monoid_record_simps])
lemma finsum_Un_disjoint:
"[| finite A; finite B; A Int B = {};
g ∈ A -> carrier G; g ∈ B -> carrier G |]
==> finsum G g (A Un B) = finsum G g A ⊕ finsum G g B"
by (rule comm_monoid.finprod_Un_disjoint [OF a_comm_monoid,
folded finsum_def, simplified monoid_record_simps])
lemma finsum_addf:
"[| finite A; f ∈ A -> carrier G; g ∈ A -> carrier G |] ==>
finsum G (%x. f x ⊕ g x) A = (finsum G f A ⊕ finsum G g A)"
by (rule comm_monoid.finprod_multf [OF a_comm_monoid,
folded finsum_def, simplified monoid_record_simps])
lemma finsum_cong':
"[| A = B; g : B -> carrier G;
!!i. i : B ==> f i = g i |] ==> finsum G f A = finsum G g B"
by (rule comm_monoid.finprod_cong' [OF a_comm_monoid,
folded finsum_def, simplified monoid_record_simps]) auto
lemma finsum_0 [simp]:
"f : {0::nat} -> carrier G ==> finsum G f {..0} = f 0"
by (rule comm_monoid.finprod_0 [OF a_comm_monoid, folded finsum_def,
simplified monoid_record_simps])
lemma finsum_Suc [simp]:
"f : {..Suc n} -> carrier G ==>
finsum G f {..Suc n} = (f (Suc n) ⊕ finsum G f {..n})"
by (rule comm_monoid.finprod_Suc [OF a_comm_monoid, folded finsum_def,
simplified monoid_record_simps])
lemma finsum_Suc2:
"f : {..Suc n} -> carrier G ==>
finsum G f {..Suc n} = (finsum G (%i. f (Suc i)) {..n} ⊕ f 0)"
by (rule comm_monoid.finprod_Suc2 [OF a_comm_monoid, folded finsum_def,
simplified monoid_record_simps])
lemma finsum_add [simp]:
"[| f : {..n} -> carrier G; g : {..n} -> carrier G |] ==>
finsum G (%i. f i ⊕ g i) {..n::nat} =
finsum G f {..n} ⊕ finsum G g {..n}"
by (rule comm_monoid.finprod_mult [OF a_comm_monoid, folded finsum_def,
simplified monoid_record_simps])
lemma finsum_cong:
"[| A = B; f : B -> carrier G;
!!i. i : B =simp=> f i = g i |] ==> finsum G f A = finsum G g B"
by (rule comm_monoid.finprod_cong [OF a_comm_monoid, folded finsum_def,
simplified monoid_record_simps]) (auto simp add: simp_implies_def)
text {*Usually, if this rule causes a failed congruence proof error,
the reason is that the premise @{text "g ∈ B -> carrier G"} cannot be shown.
Adding @{thm [source] Pi_def} to the simpset is often useful. *}
lemma finsum_reindex:
assumes fin: "finite A"
shows "f : (h ` A) -> carrier G ==>
inj_on h A ==> finsum G f (h ` A) = finsum G (%x. f (h x)) A"
using fin apply induct
apply (auto simp add: finsum_insert Pi_def)
done
(* The following is wrong. Needed is the equivalent of (^) for addition,
or indeed the canonical embedding from Nat into the monoid.
lemma finsum_const:
assumes fin [simp]: "finite A"
and a [simp]: "a : carrier G"
shows "finsum G (%x. a) A = a (^) card A"
using fin apply induct
apply force
apply (subst finsum_insert)
apply auto
apply (force simp add: Pi_def)
apply (subst m_comm)
apply auto
done
*)
(* By Jesus Aransay. *)
lemma finsum_singleton:
assumes i_in_A: "i ∈ A" and fin_A: "finite A" and f_Pi: "f ∈ A -> carrier G"
shows "(\<Oplus>j∈A. if i = j then f j else \<zero>) = f i"
using i_in_A finsum_insert [of "A - {i}" i "(λj. if i = j then f j else \<zero>)"]
fin_A f_Pi finsum_zero [of "A - {i}"]
finsum_cong [of "A - {i}" "A - {i}" "(λj. if i = j then f j else \<zero>)" "(λi. \<zero>)"]
unfolding Pi_def simp_implies_def by (force simp add: insert_absorb)
end
subsection {* Rings: Basic Definitions *}
locale ring = abelian_group 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"
locale cring = ring + comm_monoid R
locale "domain" = cring +
assumes one_not_zero [simp]: "\<one> ~= \<zero>"
and integral: "[| a ⊗ b = \<zero>; a ∈ carrier R; b ∈ carrier R |] ==>
a = \<zero> | b = \<zero>"
locale field = "domain" +
assumes field_Units: "Units R = carrier R - {\<zero>}"
subsection {* Rings *}
lemma ringI:
fixes R (structure)
assumes abelian_group: "abelian_group R"
and monoid: "monoid R"
and l_distr: "!!x y z. [| x ∈ carrier R; y ∈ carrier R; z ∈ carrier R |]
==> (x ⊕ y) ⊗ z = x ⊗ z ⊕ y ⊗ z"
and r_distr: "!!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 (in ring) is_abelian_group:
"abelian_group R"
..
lemma (in ring) is_monoid:
"monoid R"
by (auto intro!: monoidI m_assoc)
lemma (in ring) is_ring:
"ring R"
by (rule ring_axioms)
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"
-- {* Right-distributivity follows from left-distributivity and
commutativity. *}
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 (in cring) is_comm_monoid:
"comm_monoid R"
by (auto intro!: comm_monoidI m_assoc m_comm)
*)
lemma (in cring) is_cring:
"cring R" by (rule cring_axioms)
subsubsection {* Normaliser for Rings *}
lemma (in abelian_group) r_neg2:
"[| x ∈ carrier G; y ∈ carrier G |] ==> x ⊕ (\<ominus> x ⊕ y) = y"
proof -
assume G: "x ∈ carrier G" "y ∈ carrier G"
then have "(x ⊕ \<ominus> x) ⊕ y = y"
by (simp only: r_neg l_zero)
with G show ?thesis
by (simp add: a_ac)
qed
lemma (in abelian_group) r_neg1:
"[| x ∈ carrier G; y ∈ carrier G |] ==> \<ominus> x ⊕ (x ⊕ y) = y"
proof -
assume G: "x ∈ carrier G" "y ∈ carrier G"
then have "(\<ominus> x ⊕ x) ⊕ y = y"
by (simp only: l_neg l_zero)
with G show ?thesis by (simp add: a_ac)
qed
text {*
The following proofs are from Jacobson, Basic Algebra I, pp.~88--89
*}
lemma (in ring) l_null [simp]:
"x ∈ carrier R ==> \<zero> ⊗ x = \<zero>"
proof -
assume R: "x ∈ carrier R"
then have "\<zero> ⊗ x ⊕ \<zero> ⊗ x = (\<zero> ⊕ \<zero>) ⊗ x"
by (simp add: l_distr del: l_zero r_zero)
also from R have "... = \<zero> ⊗ x ⊕ \<zero>" by simp
finally have "\<zero> ⊗ x ⊕ \<zero> ⊗ x = \<zero> ⊗ x ⊕ \<zero>" .
with R show ?thesis by (simp del: r_zero)
qed
lemma (in ring) r_null [simp]:
"x ∈ carrier R ==> x ⊗ \<zero> = \<zero>"
proof -
assume R: "x ∈ carrier R"
then have "x ⊗ \<zero> ⊕ x ⊗ \<zero> = x ⊗ (\<zero> ⊕ \<zero>)"
by (simp add: r_distr del: l_zero r_zero)
also from R have "... = x ⊗ \<zero> ⊕ \<zero>" by simp
finally have "x ⊗ \<zero> ⊕ x ⊗ \<zero> = x ⊗ \<zero> ⊕ \<zero>" .
with R show ?thesis by (simp del: r_zero)
qed
lemma (in ring) l_minus:
"[| x ∈ carrier R; y ∈ carrier R |] ==> \<ominus> x ⊗ y = \<ominus> (x ⊗ y)"
proof -
assume R: "x ∈ carrier R" "y ∈ carrier R"
then have "(\<ominus> x) ⊗ y ⊕ x ⊗ y = (\<ominus> x ⊕ x) ⊗ y" by (simp add: l_distr)
also from R have "... = \<zero>" by (simp add: l_neg l_null)
finally have "(\<ominus> x) ⊗ y ⊕ x ⊗ y = \<zero>" .
with R have "(\<ominus> x) ⊗ y ⊕ x ⊗ y ⊕ \<ominus> (x ⊗ y) = \<zero> ⊕ \<ominus> (x ⊗ y)" by simp
with R show ?thesis by (simp add: a_assoc r_neg)
qed
lemma (in ring) r_minus:
"[| x ∈ carrier R; y ∈ carrier R |] ==> x ⊗ \<ominus> y = \<ominus> (x ⊗ y)"
proof -
assume R: "x ∈ carrier R" "y ∈ carrier R"
then have "x ⊗ (\<ominus> y) ⊕ x ⊗ y = x ⊗ (\<ominus> y ⊕ y)" by (simp add: r_distr)
also from R have "... = \<zero>" by (simp add: l_neg r_null)
finally have "x ⊗ (\<ominus> y) ⊕ x ⊗ y = \<zero>" .
with R have "x ⊗ (\<ominus> y) ⊕ x ⊗ y ⊕ \<ominus> (x ⊗ y) = \<zero> ⊕ \<ominus> (x ⊗ y)" by simp
with R show ?thesis by (simp add: a_assoc r_neg )
qed
lemma (in abelian_group) minus_eq:
"[| x ∈ carrier G; y ∈ carrier G |] ==> x \<ominus> y = x ⊕ \<ominus> y"
by (simp only: a_minus_def)
text {* Setup algebra method:
compute distributive normal form in locale contexts *}
use "ringsimp.ML"
setup Algebra.setup
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 cring) nat_pow_zero:
"(n::nat) ~= 0 ==> \<zero> (^) n = \<zero>"
by (induct n) simp_all
lemma (in ring) one_zeroD:
assumes onezero: "\<one> = \<zero>"
shows "carrier R = {\<zero>}"
proof (rule, rule)
fix x
assume xcarr: "x ∈ carrier R"
from xcarr
have "x = x ⊗ \<one>" by simp
from this and onezero
have "x = x ⊗ \<zero>" by simp
from this and xcarr
have "x = \<zero>" by simp
thus "x ∈ {\<zero>}" by fast
qed fast
lemma (in ring) one_zeroI:
assumes carrzero: "carrier R = {\<zero>}"
shows "\<one> = \<zero>"
proof -
from one_closed and carrzero
show "\<one> = \<zero>" by simp
qed
lemma (in ring) carrier_one_zero:
shows "(carrier R = {\<zero>}) = (\<one> = \<zero>)"
by (rule, erule one_zeroI, erule one_zeroD)
lemma (in ring) carrier_one_not_zero:
shows "(carrier R ≠ {\<zero>}) = (\<one> ≠ \<zero>)"
by (simp add: carrier_one_zero)
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 ⊕ \<ominus> (a ⊕ \<ominus> b) = b & c ⊗\<^bsub>S\<^esub> d = d ⊗\<^bsub>S\<^esub> c"
proof -
interpret ring R by fact
interpret cring S by fact
ML_val {* Algebra.print_structures @{context} *}
from RS show ?thesis by algebra
qed
lemma
fixes R (structure)
assumes "ring R"
assumes R: "a ∈ carrier R" "b ∈ carrier R"
shows "a \<ominus> (a \<ominus> b) = b"
proof -
interpret ring R by fact
from R show ?thesis by algebra
qed
subsubsection {* Sums over Finite Sets *}
lemma (in ring) finsum_ldistr:
"[| finite A; a ∈ carrier R; f ∈ A -> carrier R |] ==>
finsum R f A ⊗ a = finsum R (%i. f i ⊗ a) 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 ring) finsum_rdistr:
"[| finite A; a ∈ carrier R; f ∈ A -> carrier R |] ==>
a ⊗ finsum R f A = finsum R (%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 r_distr)
qed
subsection {* Integral Domains *}
lemma (in "domain") zero_not_one [simp]:
"\<zero> ~= \<one>"
by (rule not_sym) simp
lemma (in "domain") integral_iff: (* not by default a simp rule! *)
"[| a ∈ carrier R; b ∈ carrier R |] ==> (a ⊗ b = \<zero>) = (a = \<zero> | b = \<zero>)"
proof
assume "a ∈ carrier R" "b ∈ carrier R" "a ⊗ b = \<zero>"
then show "a = \<zero> | b = \<zero>" by (simp add: integral)
next
assume "a ∈ carrier R" "b ∈ carrier R" "a = \<zero> | b = \<zero>"
then show "a ⊗ b = \<zero>" by auto
qed
lemma (in "domain") m_lcancel:
assumes prem: "a ~= \<zero>"
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 \<ominus> c) = \<zero>" by algebra
with R have "a = \<zero> | (b \<ominus> c) = \<zero>" by (simp add: integral_iff)
with prem and R have "b \<ominus> c = \<zero>" by auto
with R have "b = b \<ominus> (b \<ominus> c)" by algebra
also from R have "b \<ominus> (b \<ominus> c) = c" by algebra
finally show "b = c" .
next
assume "b = c" then show "a ⊗ b = a ⊗ c" by simp
qed
lemma (in "domain") m_rcancel:
assumes prem: "a ~= \<zero>"
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
subsection {* Fields *}
text {* Field would not need to be derived from domain, the properties
for domain follow from the assumptions of field *}
lemma (in cring) cring_fieldI:
assumes field_Units: "Units R = carrier R - {\<zero>}"
shows "field R"
proof
from field_Units
have a: "\<zero> ∉ Units R" by fast
have "\<one> ∈ Units R" by fast
from this and a
show "\<one> ≠ \<zero>" by force
next
fix a b
assume acarr: "a ∈ carrier R"
and bcarr: "b ∈ carrier R"
and ab: "a ⊗ b = \<zero>"
show "a = \<zero> ∨ b = \<zero>"
proof (cases "a = \<zero>", simp)
assume "a ≠ \<zero>"
from this and field_Units and acarr
have aUnit: "a ∈ Units R" by fast
from bcarr
have "b = \<one> ⊗ b" by algebra
also from aUnit acarr
have "... = (inv a ⊗ a) ⊗ b" by (simp add: Units_l_inv)
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) ⊗ \<zero>" by simp
also from aUnit[THEN Units_inv_closed]
have "... = \<zero>" by algebra
finally
have "b = \<zero>" .
thus "a = \<zero> ∨ b = \<zero>" by simp
qed
qed (rule field_Units)
text {* Another variant to show that something is a field *}
lemma (in cring) cring_fieldI2:
assumes notzero: "\<zero> ≠ \<one>"
and invex: "!!a. [|a ∈ carrier R; a ≠ \<zero>|] ==> ∃b∈carrier R. a ⊗ b = \<one>"
shows "field R"
apply (rule cring_fieldI, simp add: Units_def)
apply (rule, clarsimp)
apply (simp add: notzero)
proof (clarsimp)
fix x
assume xcarr: "x ∈ carrier R"
and "x ≠ \<zero>"
from this
have "∃y∈carrier R. x ⊗ y = \<one>" by (rule invex)
from this
obtain y
where ycarr: "y ∈ carrier R"
and xy: "x ⊗ y = \<one>"
by fast
from xy xcarr ycarr have "y ⊗ x = \<one>" by (simp add: m_comm)
from ycarr and this and xy
show "∃y∈carrier R. y ⊗ x = \<one> ∧ x ⊗ y = \<one>" by fast
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 &
(ALL x y. x ∈ carrier R & y ∈ carrier R -->
h (x ⊗\<^bsub>R\<^esub> y) = h x ⊗\<^bsub>S\<^esub> h y & h (x ⊕\<^bsub>R\<^esub> y) = h x ⊕\<^bsub>S\<^esub> h y) &
h \<one>\<^bsub>R\<^esub> = \<one>\<^bsub>S\<^esub>}"
lemma ring_hom_memI:
fixes R (structure) and S (structure)
assumes hom_closed: "!!x. x ∈ carrier R ==> h x ∈ carrier S"
and hom_mult: "!!x y. [| x ∈ carrier R; y ∈ carrier R |] ==>
h (x ⊗ y) = h x ⊗\<^bsub>S\<^esub> h y"
and hom_add: "!!x y. [| x ∈ carrier R; y ∈ carrier R |] ==>
h (x ⊕ y) = h x ⊕\<^bsub>S\<^esub> h y"
and hom_one: "h \<one> = \<one>\<^bsub>S\<^esub>"
shows "h ∈ ring_hom R S"
by (auto simp add: ring_hom_def assms Pi_def)
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 ⊗\<^bsub>S\<^esub> 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 ⊕\<^bsub>S\<^esub> 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 \<one> = \<one>\<^bsub>S\<^esub>"
by (simp add: ring_hom_def)
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 \<zero> = \<zero>\<^bsub>S\<^esub>"
proof -
have "h \<zero> ⊕\<^bsub>S\<^esub> h \<zero> = h \<zero> ⊕\<^bsub>S\<^esub> \<zero>\<^bsub>S\<^esub>"
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 (\<ominus> x) = \<ominus>\<^bsub>S\<^esub> h x"
proof -
assume R: "x ∈ carrier R"
then have "h x ⊕\<^bsub>S\<^esub> h (\<ominus> x) = h x ⊕\<^bsub>S\<^esub> (\<ominus>\<^bsub>S\<^esub> 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]:
"[| finite A; f ∈ A -> carrier R |] ==>
h (finsum R f A) = finsum S (h o f) A"
proof (induct set: finite)
case empty then show ?case by simp
next
case insert then show ?case by (simp add: Pi_def)
qed
lemma (in ring_hom_cring) hom_finprod:
"[| finite A; f ∈ A -> carrier R |] ==>
h (finprod R f A) = finprod S (h o f) A"
proof (induct set: finite)
case empty then show ?case by simp
next
case insert then show ?case by (simp add: Pi_def)
qed
declare ring_hom_cring.hom_finprod [simp]
lemma id_ring_hom [simp]:
"id ∈ ring_hom R R"
by (auto intro!: ring_hom_memI)
end