| author | kleing |
| Tue, 13 May 2003 08:59:21 +0200 | |
| changeset 14024 | 213dcc39358f |
| parent 13936 | d3671b878828 |
| child 14213 | 7bf882b0a51e |
| permissions | -rw-r--r-- |
|
13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
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(* |
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
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Title: The algebraic hierarchy of rings |
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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Id: $Id$ |
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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Author: Clemens Ballarin, started 9 December 1996 |
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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Copyright: Clemens Ballarin |
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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*) |
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
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theory CRing = FiniteProduct |
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91c9ab25fece
First distributed version of Group and Ring theory.
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files ("ringsimp.ML"):
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| 13936 | 11 |
section {* Abelian Groups *}
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record 'a ring = "'a monoid" + |
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zero :: 'a ("\<zero>\<index>")
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add :: "['a, 'a] => 'a" (infixl "\<oplus>\<index>" 65) |
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text {* Derived operations. *}
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constdefs |
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a_inv :: "[('a, 'm) ring_scheme, 'a ] => 'a" ("\<ominus>\<index> _" [81] 80)
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"a_inv R == m_inv (| carrier = carrier R, mult = add R, one = zero R |)" |
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minus :: "[('a, 'm) ring_scheme, 'a, 'a] => 'a" (infixl "\<ominus>\<index>" 65)
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"[| x \<in> carrier R; y \<in> carrier R |] ==> minus R x y == add R x (a_inv R y)" |
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locale abelian_monoid = struct G + |
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assumes a_comm_monoid: "comm_monoid (| carrier = carrier G, |
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mult = add G, one = zero G |)" |
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text {*
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The following definition is redundant but simple to use. |
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*} |
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locale abelian_group = abelian_monoid + |
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assumes a_comm_group: "comm_group (| carrier = carrier G, |
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mult = add G, one = zero G |)" |
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subsection {* Basic Properties *}
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lemma abelian_monoidI: |
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assumes a_closed: |
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"!!x y. [| x \<in> carrier R; y \<in> carrier R |] ==> add R x y \<in> carrier R" |
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and zero_closed: "zero R \<in> carrier R" |
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and a_assoc: |
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"!!x y z. [| x \<in> carrier R; y \<in> carrier R; z \<in> carrier R |] ==> |
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add R (add R x y) z = add R x (add R y z)" |
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and l_zero: "!!x. x \<in> carrier R ==> add R (zero R) x = x" |
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and a_comm: |
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"!!x y. [| x \<in> carrier R; y \<in> carrier R |] ==> add R x y = add R y x" |
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shows "abelian_monoid R" |
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by (auto intro!: abelian_monoid.intro comm_monoidI intro: prems) |
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lemma abelian_groupI: |
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assumes a_closed: |
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"!!x y. [| x \<in> carrier R; y \<in> carrier R |] ==> add R x y \<in> carrier R" |
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and zero_closed: "zero R \<in> carrier R" |
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and a_assoc: |
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"!!x y z. [| x \<in> carrier R; y \<in> carrier R; z \<in> carrier R |] ==> |
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add R (add R x y) z = add R x (add R y z)" |
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and a_comm: |
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"!!x y. [| x \<in> carrier R; y \<in> carrier R |] ==> add R x y = add R y x" |
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and l_zero: "!!x. x \<in> carrier R ==> add R (zero R) x = x" |
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and l_inv_ex: "!!x. x \<in> carrier R ==> EX y : carrier R. add R y x = zero R" |
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shows "abelian_group R" |
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by (auto intro!: abelian_group.intro abelian_monoidI |
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abelian_group_axioms.intro comm_monoidI comm_groupI |
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intro: prems) |
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(* TODO: The following thms are probably unnecessary. *) |
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lemma (in abelian_monoid) a_magma: |
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"magma (| carrier = carrier G, mult = add G, one = zero G |)" |
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by (rule comm_monoid.axioms) (rule a_comm_monoid) |
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lemma (in abelian_monoid) a_semigroup: |
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"semigroup (| carrier = carrier G, mult = add G, one = zero G |)" |
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by (unfold semigroup_def) (fast intro: comm_monoid.axioms a_comm_monoid) |
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lemma (in abelian_monoid) a_monoid: |
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"monoid (| carrier = carrier G, mult = add G, one = zero G |)" |
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by (unfold monoid_def) (fast intro: a_comm_monoid comm_monoid.axioms) |
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lemma (in abelian_group) a_group: |
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"group (| carrier = carrier G, mult = add G, one = zero G |)" |
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by (unfold group_def semigroup_def) |
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(fast intro: comm_group.axioms a_comm_group) |
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lemma (in abelian_monoid) a_comm_semigroup: |
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"comm_semigroup (| carrier = carrier G, mult = add G, one = zero G |)" |
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by (unfold comm_semigroup_def semigroup_def) |
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(fast intro: comm_monoid.axioms a_comm_monoid) |
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lemmas monoid_record_simps = semigroup.simps monoid.simps |
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lemma (in abelian_monoid) a_closed [intro, simp]: |
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"[| x \<in> carrier G; y \<in> carrier G |] ==> x \<oplus> y \<in> carrier G" |
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by (rule magma.m_closed [OF a_magma, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) zero_closed [intro, simp]: |
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"\<zero> \<in> carrier G" |
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by (rule monoid.one_closed [OF a_monoid, simplified monoid_record_simps]) |
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lemma (in abelian_group) a_inv_closed [intro, simp]: |
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"x \<in> carrier G ==> \<ominus> x \<in> carrier G" |
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by (simp add: a_inv_def |
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group.inv_closed [OF a_group, simplified monoid_record_simps]) |
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lemma (in abelian_group) minus_closed [intro, simp]: |
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"[| x \<in> carrier G; y \<in> carrier G |] ==> x \<ominus> y \<in> carrier G" |
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by (simp add: minus_def) |
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lemma (in abelian_group) a_l_cancel [simp]: |
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"[| x \<in> carrier G; y \<in> carrier G; z \<in> carrier G |] ==> |
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(x \<oplus> y = x \<oplus> z) = (y = z)" |
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by (rule group.l_cancel [OF a_group, simplified monoid_record_simps]) |
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lemma (in abelian_group) a_r_cancel [simp]: |
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"[| x \<in> carrier G; y \<in> carrier G; z \<in> carrier G |] ==> |
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(y \<oplus> x = z \<oplus> x) = (y = z)" |
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by (rule group.r_cancel [OF a_group, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) a_assoc: |
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"[| x \<in> carrier G; y \<in> carrier G; z \<in> carrier G |] ==> |
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(x \<oplus> y) \<oplus> z = x \<oplus> (y \<oplus> z)" |
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by (rule semigroup.m_assoc [OF a_semigroup, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) l_zero [simp]: |
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"x \<in> carrier G ==> \<zero> \<oplus> x = x" |
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by (rule monoid.l_one [OF a_monoid, simplified monoid_record_simps]) |
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lemma (in abelian_group) l_neg: |
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"x \<in> carrier G ==> \<ominus> x \<oplus> x = \<zero>" |
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by (simp add: a_inv_def |
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group.l_inv [OF a_group, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) a_comm: |
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"[| x \<in> carrier G; y \<in> carrier G |] ==> x \<oplus> y = y \<oplus> x" |
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by (rule comm_semigroup.m_comm [OF a_comm_semigroup, |
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simplified monoid_record_simps]) |
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lemma (in abelian_monoid) a_lcomm: |
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"[| x \<in> carrier G; y \<in> carrier G; z \<in> carrier G |] ==> |
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x \<oplus> (y \<oplus> z) = y \<oplus> (x \<oplus> z)" |
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by (rule comm_semigroup.m_lcomm [OF a_comm_semigroup, |
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simplified monoid_record_simps]) |
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lemma (in abelian_monoid) r_zero [simp]: |
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"x \<in> carrier G ==> x \<oplus> \<zero> = x" |
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using monoid.r_one [OF a_monoid] |
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by simp |
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lemma (in abelian_group) r_neg: |
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"x \<in> carrier G ==> x \<oplus> (\<ominus> x) = \<zero>" |
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using group.r_inv [OF a_group] |
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by (simp add: a_inv_def) |
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lemma (in abelian_group) minus_zero [simp]: |
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"\<ominus> \<zero> = \<zero>" |
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by (simp add: a_inv_def |
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group.inv_one [OF a_group, simplified monoid_record_simps]) |
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lemma (in abelian_group) minus_minus [simp]: |
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"x \<in> carrier G ==> \<ominus> (\<ominus> x) = x" |
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using group.inv_inv [OF a_group, simplified monoid_record_simps] |
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by (simp add: a_inv_def) |
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lemma (in abelian_group) a_inv_inj: |
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"inj_on (a_inv G) (carrier G)" |
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using group.inv_inj [OF a_group, simplified monoid_record_simps] |
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by (simp add: a_inv_def) |
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lemma (in abelian_group) minus_add: |
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"[| x \<in> carrier G; y \<in> carrier G |] ==> \<ominus> (x \<oplus> y) = \<ominus> x \<oplus> \<ominus> y" |
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using comm_group.inv_mult [OF a_comm_group] |
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by (simp add: a_inv_def) |
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lemmas (in abelian_monoid) a_ac = a_assoc a_comm a_lcomm |
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subsection {* Sums over Finite Sets *}
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text {*
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This definition makes it easy to lift lemmas from @{term finprod}.
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*} |
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constdefs |
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finsum :: "[('b, 'm) ring_scheme, 'a => 'b, 'a set] => 'b"
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"finsum G f A == finprod (| carrier = carrier G, |
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mult = add G, one = zero G |) f A" |
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(* |
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lemmas (in abelian_monoid) finsum_empty [simp] = |
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comm_monoid.finprod_empty [OF a_comm_monoid, simplified] |
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is dangeous, because attributes (like simplified) are applied upon opening |
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the locale, simplified refers to the simpset at that time!!! |
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lemmas (in abelian_monoid) finsum_empty [simp] = |
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abelian_monoid.finprod_empty [OF a_abelian_monoid, folded finsum_def, |
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simplified monoid_record_simps] |
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makes the locale slow, because proofs are repeated for every |
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"lemma (in abelian_monoid)" command. |
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When lemma is used time in UnivPoly.thy from beginning to UP_cring goes down |
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from 110 secs to 60 secs. |
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*) |
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lemma (in abelian_monoid) finsum_empty [simp]: |
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"finsum G f {} = \<zero>"
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by (rule comm_monoid.finprod_empty [OF a_comm_monoid, |
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folded finsum_def, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_insert [simp]: |
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"[| finite F; a \<notin> F; f \<in> F -> carrier G; f a \<in> carrier G |] |
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==> finsum G f (insert a F) = f a \<oplus> finsum G f F" |
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by (rule comm_monoid.finprod_insert [OF a_comm_monoid, |
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folded finsum_def, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_zero [simp]: |
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"finite A ==> finsum G (%i. \<zero>) A = \<zero>" |
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by (rule comm_monoid.finprod_one [OF a_comm_monoid, folded finsum_def, |
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simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_closed [simp]: |
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fixes A |
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assumes fin: "finite A" and f: "f \<in> A -> carrier G" |
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shows "finsum G f A \<in> carrier G" |
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by (rule comm_monoid.finprod_closed [OF a_comm_monoid, |
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folded finsum_def, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_Un_Int: |
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"[| finite A; finite B; g \<in> A -> carrier G; g \<in> B -> carrier G |] ==> |
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finsum G g (A Un B) \<oplus> finsum G g (A Int B) = |
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finsum G g A \<oplus> finsum G g B" |
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by (rule comm_monoid.finprod_Un_Int [OF a_comm_monoid, |
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folded finsum_def, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_Un_disjoint: |
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"[| finite A; finite B; A Int B = {};
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g \<in> A -> carrier G; g \<in> B -> carrier G |] |
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==> finsum G g (A Un B) = finsum G g A \<oplus> finsum G g B" |
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by (rule comm_monoid.finprod_Un_disjoint [OF a_comm_monoid, |
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folded finsum_def, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_addf: |
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"[| finite A; f \<in> A -> carrier G; g \<in> A -> carrier G |] ==> |
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finsum G (%x. f x \<oplus> g x) A = (finsum G f A \<oplus> finsum G g A)" |
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by (rule comm_monoid.finprod_multf [OF a_comm_monoid, |
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folded finsum_def, simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_cong': |
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"[| A = B; g : B -> carrier G; |
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!!i. i : B ==> f i = g i |] ==> finsum G f A = finsum G g B" |
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by (rule comm_monoid.finprod_cong' [OF a_comm_monoid, |
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folded finsum_def, simplified monoid_record_simps]) auto |
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lemma (in abelian_monoid) finsum_0 [simp]: |
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"f : {0::nat} -> carrier G ==> finsum G f {..0} = f 0"
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by (rule comm_monoid.finprod_0 [OF a_comm_monoid, folded finsum_def, |
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simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_Suc [simp]: |
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"f : {..Suc n} -> carrier G ==>
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finsum G f {..Suc n} = (f (Suc n) \<oplus> finsum G f {..n})"
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by (rule comm_monoid.finprod_Suc [OF a_comm_monoid, folded finsum_def, |
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simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_Suc2: |
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"f : {..Suc n} -> carrier G ==>
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finsum G f {..Suc n} = (finsum G (%i. f (Suc i)) {..n} \<oplus> f 0)"
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by (rule comm_monoid.finprod_Suc2 [OF a_comm_monoid, folded finsum_def, |
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simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_add [simp]: |
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"[| f : {..n} -> carrier G; g : {..n} -> carrier G |] ==>
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finsum G (%i. f i \<oplus> g i) {..n::nat} =
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finsum G f {..n} \<oplus> finsum G g {..n}"
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by (rule comm_monoid.finprod_mult [OF a_comm_monoid, folded finsum_def, |
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simplified monoid_record_simps]) |
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lemma (in abelian_monoid) finsum_cong: |
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"[| A = B; !!i. i : B ==> f i = g i; |
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g : B -> carrier G = True |] ==> finsum G f A = finsum G g B" |
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by (rule comm_monoid.finprod_cong [OF a_comm_monoid, folded finsum_def, |
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simplified monoid_record_simps]) auto |
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text {*Usually, if this rule causes a failed congruence proof error,
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the reason is that the premise @{text "g \<in> B -> carrier G"} cannot be shown.
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Adding @{thm [source] Pi_def} to the simpset is often useful. *}
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13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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288 |
section {* The Algebraic Hierarchy of Rings *}
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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289 |
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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290 |
subsection {* Basic Definitions *}
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Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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291 |
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| 13936 | 292 |
locale cring = abelian_group R + comm_monoid R + |
293 |
assumes l_distr: "[| x \<in> carrier R; y \<in> carrier R; z \<in> carrier R |] |
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13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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==> (x \<oplus> y) \<otimes> z = x \<otimes> z \<oplus> y \<otimes> z" |
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
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295 |
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| 13864 | 296 |
locale "domain" = cring + |
297 |
assumes one_not_zero [simp]: "\<one> ~= \<zero>" |
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298 |
and integral: "[| a \<otimes> b = \<zero>; a \<in> carrier R; b \<in> carrier R |] ==> |
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299 |
a = \<zero> | b = \<zero>" |
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301 |
subsection {* Basic Facts of Rings *}
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13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
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parents:
diff
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302 |
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| 13936 | 303 |
lemma cringI: |
304 |
assumes abelian_group: "abelian_group R" |
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305 |
and comm_monoid: "comm_monoid R" |
|
306 |
and l_distr: "!!x y z. [| x \<in> carrier R; y \<in> carrier R; z \<in> carrier R |] |
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307 |
==> mult R (add R x y) z = add R (mult R x z) (mult R y z)" |
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308 |
shows "cring R" |
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309 |
by (auto intro: cring.intro |
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310 |
abelian_group.axioms comm_monoid.axioms cring_axioms.intro prems) |
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13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
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|
311 |
|
| 13936 | 312 |
lemma (in cring) is_abelian_group: |
313 |
"abelian_group R" |
|
314 |
by (auto intro!: abelian_groupI a_assoc a_comm l_neg) |
|
|
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91c9ab25fece
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parents:
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changeset
|
315 |
|
| 13936 | 316 |
lemma (in cring) is_comm_monoid: |
317 |
"comm_monoid R" |
|
318 |
by (auto intro!: comm_monoidI m_assoc m_comm) |
|
|
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Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
319 |
|
|
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91c9ab25fece
First distributed version of Group and Ring theory.
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parents:
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changeset
|
320 |
subsection {* Normaliser for Commutative Rings *}
|
|
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12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
321 |
|
| 13936 | 322 |
lemma (in abelian_group) r_neg2: |
323 |
"[| x \<in> carrier G; y \<in> carrier G |] ==> x \<oplus> (\<ominus> x \<oplus> y) = y" |
|
|
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First distributed version of Group and Ring theory.
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parents:
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|
324 |
proof - |
| 13936 | 325 |
assume G: "x \<in> carrier G" "y \<in> carrier G" |
326 |
then have "(x \<oplus> \<ominus> x) \<oplus> y = y" |
|
327 |
by (simp only: r_neg l_zero) |
|
328 |
with G show ?thesis |
|
329 |
by (simp add: a_ac) |
|
|
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Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
330 |
qed |
|
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
331 |
|
| 13936 | 332 |
lemma (in abelian_group) r_neg1: |
333 |
"[| x \<in> carrier G; y \<in> carrier G |] ==> \<ominus> x \<oplus> (x \<oplus> y) = y" |
|
|
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91c9ab25fece
First distributed version of Group and Ring theory.
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parents:
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diff
changeset
|
334 |
proof - |
| 13936 | 335 |
assume G: "x \<in> carrier G" "y \<in> carrier G" |
336 |
then have "(\<ominus> x \<oplus> x) \<oplus> y = y" |
|
337 |
by (simp only: l_neg l_zero) |
|
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
338 |
with G show ?thesis by (simp add: a_ac) |
|
13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
339 |
qed |
|
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
340 |
|
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
341 |
lemma (in cring) r_distr: |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
342 |
"[| x \<in> carrier R; y \<in> carrier R; z \<in> carrier R |] |
|
91c9ab25fece
First distributed version of Group and Ring theory.
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parents:
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changeset
|
343 |
==> z \<otimes> (x \<oplus> y) = z \<otimes> x \<oplus> z \<otimes> y" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
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parents:
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changeset
|
344 |
proof - |
| 13936 | 345 |
assume R: "x \<in> carrier R" "y \<in> carrier R" "z \<in> carrier R" |
|
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91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
346 |
then have "z \<otimes> (x \<oplus> y) = (x \<oplus> y) \<otimes> z" by (simp add: m_comm) |
| 13936 | 347 |
also from R have "... = x \<otimes> z \<oplus> y \<otimes> z" by (simp add: l_distr) |
348 |
also from R have "... = z \<otimes> x \<oplus> z \<otimes> y" by (simp add: m_comm) |
|
|
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91c9ab25fece
First distributed version of Group and Ring theory.
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parents:
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changeset
|
349 |
finally show ?thesis . |
|
13835
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Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
350 |
qed |
|
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
351 |
|
|
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91c9ab25fece
First distributed version of Group and Ring theory.
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parents:
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|
352 |
text {*
|
|
91c9ab25fece
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parents:
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|
353 |
The following proofs are from Jacobson, Basic Algebra I, pp.~88--89 |
|
13835
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parents:
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changeset
|
354 |
*} |
|
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
355 |
|
|
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First distributed version of Group and Ring theory.
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parents:
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changeset
|
356 |
lemma (in cring) l_null [simp]: |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
357 |
"x \<in> carrier R ==> \<zero> \<otimes> x = \<zero>" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
358 |
proof - |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
359 |
assume R: "x \<in> carrier R" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
360 |
then have "\<zero> \<otimes> x \<oplus> \<zero> \<otimes> x = (\<zero> \<oplus> \<zero>) \<otimes> x" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
361 |
by (simp add: l_distr del: l_zero r_zero) |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
362 |
also from R have "... = \<zero> \<otimes> x \<oplus> \<zero>" by simp |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
363 |
finally have "\<zero> \<otimes> x \<oplus> \<zero> \<otimes> x = \<zero> \<otimes> x \<oplus> \<zero>" . |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
364 |
with R show ?thesis by (simp del: r_zero) |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
365 |
qed |
|
13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
366 |
|
|
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91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
367 |
lemma (in cring) r_null [simp]: |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
368 |
"x \<in> carrier R ==> x \<otimes> \<zero> = \<zero>" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
369 |
proof - |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
370 |
assume R: "x \<in> carrier R" |
| 13936 | 371 |
then have "x \<otimes> \<zero> = \<zero> \<otimes> x" by (simp add: m_ac) |
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
372 |
also from R have "... = \<zero>" by simp |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
373 |
finally show ?thesis . |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
374 |
qed |
|
13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
375 |
|
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
376 |
lemma (in cring) l_minus: |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
377 |
"[| x \<in> carrier R; y \<in> carrier R |] ==> \<ominus> x \<otimes> y = \<ominus> (x \<otimes> y)" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
378 |
proof - |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
379 |
assume R: "x \<in> carrier R" "y \<in> carrier R" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
380 |
then have "(\<ominus> x) \<otimes> y \<oplus> x \<otimes> y = (\<ominus> x \<oplus> x) \<otimes> y" by (simp add: l_distr) |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
381 |
also from R have "... = \<zero>" by (simp add: l_neg l_null) |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
382 |
finally have "(\<ominus> x) \<otimes> y \<oplus> x \<otimes> y = \<zero>" . |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
383 |
with R have "(\<ominus> x) \<otimes> y \<oplus> x \<otimes> y \<oplus> \<ominus> (x \<otimes> y) = \<zero> \<oplus> \<ominus> (x \<otimes> y)" by simp |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
384 |
with R show ?thesis by (simp add: a_assoc r_neg ) |
|
13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
385 |
qed |
|
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
386 |
|
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
387 |
lemma (in cring) r_minus: |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
388 |
"[| x \<in> carrier R; y \<in> carrier R |] ==> x \<otimes> \<ominus> y = \<ominus> (x \<otimes> y)" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
389 |
proof - |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
390 |
assume R: "x \<in> carrier R" "y \<in> carrier R" |
| 13936 | 391 |
then have "x \<otimes> \<ominus> y = \<ominus> y \<otimes> x" by (simp add: m_ac) |
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
392 |
also from R have "... = \<ominus> (y \<otimes> x)" by (simp add: l_minus) |
| 13936 | 393 |
also from R have "... = \<ominus> (x \<otimes> y)" by (simp add: m_ac) |
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
394 |
finally show ?thesis . |
|
13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
395 |
qed |
|
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
396 |
|
| 13936 | 397 |
lemma (in cring) minus_eq: |
398 |
"[| x \<in> carrier R; y \<in> carrier R |] ==> x \<ominus> y = x \<oplus> \<ominus> y" |
|
399 |
by (simp only: minus_def) |
|
400 |
||
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
401 |
lemmas (in cring) cring_simprules = |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
402 |
a_closed zero_closed a_inv_closed minus_closed m_closed one_closed |
| 13936 | 403 |
a_assoc l_zero l_neg a_comm m_assoc l_one l_distr m_comm minus_eq |
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
404 |
r_zero r_neg r_neg2 r_neg1 minus_add minus_minus minus_zero |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
405 |
a_lcomm m_lcomm r_distr l_null r_null l_minus r_minus |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
406 |
|
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
407 |
use "ringsimp.ML" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
408 |
|
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
409 |
method_setup algebra = |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
410 |
{* Method.ctxt_args cring_normalise *}
|
| 13936 | 411 |
{* computes distributive normal form in locale context cring *}
|
412 |
||
413 |
lemma (in cring) nat_pow_zero: |
|
414 |
"(n::nat) ~= 0 ==> \<zero> (^) n = \<zero>" |
|
415 |
by (induct n) simp_all |
|
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
416 |
|
| 13864 | 417 |
text {* Two examples for use of method algebra *}
|
418 |
||
|
13854
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
419 |
lemma |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
420 |
includes cring R + cring S |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
421 |
shows "[| a \<in> carrier R; b \<in> carrier R; c \<in> carrier S; d \<in> carrier S |] ==> |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
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diff
changeset
|
422 |
a \<oplus> \<ominus> (a \<oplus> \<ominus> b) = b & c \<otimes>\<^sub>2 d = d \<otimes>\<^sub>2 c" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
423 |
by algebra |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
424 |
|
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
425 |
lemma |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
426 |
includes cring |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
427 |
shows "[| a \<in> carrier R; b \<in> carrier R |] ==> a \<ominus> (a \<ominus> b) = b" |
|
91c9ab25fece
First distributed version of Group and Ring theory.
ballarin
parents:
13835
diff
changeset
|
428 |
by algebra |
|
13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
429 |
|
| 13864 | 430 |
subsection {* Sums over Finite Sets *}
|
431 |
||
432 |
lemma (in cring) finsum_ldistr: |
|
433 |
"[| finite A; a \<in> carrier R; f \<in> A -> carrier R |] ==> |
|
434 |
finsum R f A \<otimes> a = finsum R (%i. f i \<otimes> a) A" |
|
435 |
proof (induct set: Finites) |
|
436 |
case empty then show ?case by simp |
|
437 |
next |
|
438 |
case (insert F x) then show ?case by (simp add: Pi_def l_distr) |
|
439 |
qed |
|
440 |
||
441 |
lemma (in cring) finsum_rdistr: |
|
442 |
"[| finite A; a \<in> carrier R; f \<in> A -> carrier R |] ==> |
|
443 |
a \<otimes> finsum R f A = finsum R (%i. a \<otimes> f i) A" |
|
444 |
proof (induct set: Finites) |
|
445 |
case empty then show ?case by simp |
|
446 |
next |
|
447 |
case (insert F x) then show ?case by (simp add: Pi_def r_distr) |
|
448 |
qed |
|
449 |
||
450 |
subsection {* Facts of Integral Domains *}
|
|
451 |
||
452 |
lemma (in "domain") zero_not_one [simp]: |
|
453 |
"\<zero> ~= \<one>" |
|
454 |
by (rule not_sym) simp |
|
455 |
||
456 |
lemma (in "domain") integral_iff: (* not by default a simp rule! *) |
|
457 |
"[| a \<in> carrier R; b \<in> carrier R |] ==> (a \<otimes> b = \<zero>) = (a = \<zero> | b = \<zero>)" |
|
458 |
proof |
|
459 |
assume "a \<in> carrier R" "b \<in> carrier R" "a \<otimes> b = \<zero>" |
|
460 |
then show "a = \<zero> | b = \<zero>" by (simp add: integral) |
|
461 |
next |
|
462 |
assume "a \<in> carrier R" "b \<in> carrier R" "a = \<zero> | b = \<zero>" |
|
463 |
then show "a \<otimes> b = \<zero>" by auto |
|
464 |
qed |
|
465 |
||
466 |
lemma (in "domain") m_lcancel: |
|
467 |
assumes prem: "a ~= \<zero>" |
|
468 |
and R: "a \<in> carrier R" "b \<in> carrier R" "c \<in> carrier R" |
|
469 |
shows "(a \<otimes> b = a \<otimes> c) = (b = c)" |
|
470 |
proof |
|
471 |
assume eq: "a \<otimes> b = a \<otimes> c" |
|
472 |
with R have "a \<otimes> (b \<ominus> c) = \<zero>" by algebra |
|
473 |
with R have "a = \<zero> | (b \<ominus> c) = \<zero>" by (simp add: integral_iff) |
|
474 |
with prem and R have "b \<ominus> c = \<zero>" by auto |
|
475 |
with R have "b = b \<ominus> (b \<ominus> c)" by algebra |
|
476 |
also from R have "b \<ominus> (b \<ominus> c) = c" by algebra |
|
477 |
finally show "b = c" . |
|
478 |
next |
|
479 |
assume "b = c" then show "a \<otimes> b = a \<otimes> c" by simp |
|
480 |
qed |
|
481 |
||
482 |
lemma (in "domain") m_rcancel: |
|
483 |
assumes prem: "a ~= \<zero>" |
|
484 |
and R: "a \<in> carrier R" "b \<in> carrier R" "c \<in> carrier R" |
|
485 |
shows conc: "(b \<otimes> a = c \<otimes> a) = (b = c)" |
|
486 |
proof - |
|
487 |
from prem and R have "(a \<otimes> b = a \<otimes> c) = (b = c)" by (rule m_lcancel) |
|
488 |
with R show ?thesis by algebra |
|
489 |
qed |
|
490 |
||
| 13936 | 491 |
subsection {* Morphisms *}
|
492 |
||
493 |
constdefs |
|
494 |
ring_hom :: "[('a, 'm) ring_scheme, ('b, 'n) ring_scheme] => ('a => 'b) set"
|
|
495 |
"ring_hom R S == {h. h \<in> carrier R -> carrier S &
|
|
496 |
(ALL x y. x \<in> carrier R & y \<in> carrier R --> |
|
497 |
h (mult R x y) = mult S (h x) (h y) & |
|
498 |
h (add R x y) = add S (h x) (h y)) & |
|
499 |
h (one R) = one S}" |
|
500 |
||
501 |
lemma ring_hom_memI: |
|
502 |
assumes hom_closed: "!!x. x \<in> carrier R ==> h x \<in> carrier S" |
|
503 |
and hom_mult: "!!x y. [| x \<in> carrier R; y \<in> carrier R |] ==> |
|
504 |
h (mult R x y) = mult S (h x) (h y)" |
|
505 |
and hom_add: "!!x y. [| x \<in> carrier R; y \<in> carrier R |] ==> |
|
506 |
h (add R x y) = add S (h x) (h y)" |
|
507 |
and hom_one: "h (one R) = one S" |
|
508 |
shows "h \<in> ring_hom R S" |
|
509 |
by (auto simp add: ring_hom_def prems Pi_def) |
|
510 |
||
511 |
lemma ring_hom_closed: |
|
512 |
"[| h \<in> ring_hom R S; x \<in> carrier R |] ==> h x \<in> carrier S" |
|
513 |
by (auto simp add: ring_hom_def funcset_mem) |
|
514 |
||
515 |
lemma ring_hom_mult: |
|
516 |
"[| h \<in> ring_hom R S; x \<in> carrier R; y \<in> carrier R |] ==> |
|
517 |
h (mult R x y) = mult S (h x) (h y)" |
|
518 |
by (simp add: ring_hom_def) |
|
519 |
||
520 |
lemma ring_hom_add: |
|
521 |
"[| h \<in> ring_hom R S; x \<in> carrier R; y \<in> carrier R |] ==> |
|
522 |
h (add R x y) = add S (h x) (h y)" |
|
523 |
by (simp add: ring_hom_def) |
|
524 |
||
525 |
lemma ring_hom_one: |
|
526 |
"h \<in> ring_hom R S ==> h (one R) = one S" |
|
527 |
by (simp add: ring_hom_def) |
|
528 |
||
529 |
locale ring_hom_cring = cring R + cring S + var h + |
|
530 |
assumes homh [simp, intro]: "h \<in> ring_hom R S" |
|
531 |
notes hom_closed [simp, intro] = ring_hom_closed [OF homh] |
|
532 |
and hom_mult [simp] = ring_hom_mult [OF homh] |
|
533 |
and hom_add [simp] = ring_hom_add [OF homh] |
|
534 |
and hom_one [simp] = ring_hom_one [OF homh] |
|
535 |
||
536 |
lemma (in ring_hom_cring) hom_zero [simp]: |
|
537 |
"h \<zero> = \<zero>\<^sub>2" |
|
538 |
proof - |
|
539 |
have "h \<zero> \<oplus>\<^sub>2 h \<zero> = h \<zero> \<oplus>\<^sub>2 \<zero>\<^sub>2" |
|
540 |
by (simp add: hom_add [symmetric] del: hom_add) |
|
541 |
then show ?thesis by (simp del: S.r_zero) |
|
542 |
qed |
|
543 |
||
544 |
lemma (in ring_hom_cring) hom_a_inv [simp]: |
|
545 |
"x \<in> carrier R ==> h (\<ominus> x) = \<ominus>\<^sub>2 h x" |
|
546 |
proof - |
|
547 |
assume R: "x \<in> carrier R" |
|
548 |
then have "h x \<oplus>\<^sub>2 h (\<ominus> x) = h x \<oplus>\<^sub>2 (\<ominus>\<^sub>2 h x)" |
|
549 |
by (simp add: hom_add [symmetric] R.r_neg S.r_neg del: hom_add) |
|
550 |
with R show ?thesis by simp |
|
551 |
qed |
|
552 |
||
553 |
lemma (in ring_hom_cring) hom_finsum [simp]: |
|
554 |
"[| finite A; f \<in> A -> carrier R |] ==> |
|
555 |
h (finsum R f A) = finsum S (h o f) A" |
|
556 |
proof (induct set: Finites) |
|
557 |
case empty then show ?case by simp |
|
558 |
next |
|
559 |
case insert then show ?case by (simp add: Pi_def) |
|
560 |
qed |
|
561 |
||
562 |
lemma (in ring_hom_cring) hom_finprod: |
|
563 |
"[| finite A; f \<in> A -> carrier R |] ==> |
|
564 |
h (finprod R f A) = finprod S (h o f) A" |
|
565 |
proof (induct set: Finites) |
|
566 |
case empty then show ?case by simp |
|
567 |
next |
|
568 |
case insert then show ?case by (simp add: Pi_def) |
|
569 |
qed |
|
570 |
||
571 |
declare ring_hom_cring.hom_finprod [simp] |
|
572 |
||
573 |
lemma id_ring_hom [simp]: |
|
574 |
"id \<in> ring_hom R R" |
|
575 |
by (auto intro!: ring_hom_memI) |
|
576 |
||
|
13835
12b2ffbe543a
Change to meta simplifier: congruence rules may now have frees as head of term.
ballarin
parents:
diff
changeset
|
577 |
end |