--- a/src/HOL/Groups_Big.thy Tue Jan 11 06:47:47 2022 +0000
+++ b/src/HOL/Groups_Big.thy Tue Jan 11 06:48:02 2022 +0000
@@ -8,7 +8,7 @@
section \<open>Big sum and product over finite (non-empty) sets\<close>
theory Groups_Big
- imports Power
+ imports Power Equiv_Relations
begin
subsection \<open>Generic monoid operation over a set\<close>
@@ -1259,6 +1259,16 @@
using card_Un_le nat_add_left_cancel_le by (force intro: order_trans)
qed auto
+lemma card_quotient_disjoint:
+ assumes "finite A" "inj_on (\<lambda>x. {x} // r) A"
+ shows "card (A//r) = card A"
+proof -
+ have "\<forall>i\<in>A. \<forall>j\<in>A. i \<noteq> j \<longrightarrow> r `` {j} \<noteq> r `` {i}"
+ using assms by (fastforce simp add: quotient_def inj_on_def)
+ with assms show ?thesis
+ by (simp add: quotient_def card_UN_disjoint)
+qed
+
lemma sum_multicount_gen:
assumes "finite s" "finite t" "\<forall>j\<in>t. (card {i\<in>s. R i j} = k j)"
shows "sum (\<lambda>i. (card {j\<in>t. R i j})) s = sum k t"
@@ -1303,6 +1313,52 @@
qed
qed simp
+text \<open>By Jakub Kądziołka:\<close>
+
+lemma sum_fun_comp:
+ assumes "finite S" "finite R" "g ` S \<subseteq> R"
+ shows "(\<Sum>x \<in> S. f (g x)) = (\<Sum>y \<in> R. of_nat (card {x \<in> S. g x = y}) * f y)"
+proof -
+ let ?r = "relation_of (\<lambda>p q. g p = g q) S"
+ have eqv: "equiv S ?r"
+ unfolding relation_of_def by (auto intro: comp_equivI)
+ have finite: "C \<in> S//?r \<Longrightarrow> finite C" for C
+ by (fact finite_equiv_class[OF `finite S` equiv_type[OF `equiv S ?r`]])
+ have disjoint: "A \<in> S//?r \<Longrightarrow> B \<in> S//?r \<Longrightarrow> A \<noteq> B \<Longrightarrow> A \<inter> B = {}" for A B
+ using eqv quotient_disj by blast
+
+ let ?cls = "\<lambda>y. {x \<in> S. y = g x}"
+ have quot_as_img: "S//?r = ?cls ` g ` S"
+ by (auto simp add: relation_of_def quotient_def)
+ have cls_inj: "inj_on ?cls (g ` S)"
+ by (auto intro: inj_onI)
+
+ have rest_0: "(\<Sum>y \<in> R - g ` S. of_nat (card (?cls y)) * f y) = 0"
+ proof -
+ have "of_nat (card (?cls y)) * f y = 0" if asm: "y \<in> R - g ` S" for y
+ proof -
+ from asm have *: "?cls y = {}" by auto
+ show ?thesis unfolding * by simp
+ qed
+ thus ?thesis by simp
+ qed
+
+ have "(\<Sum>x \<in> S. f (g x)) = (\<Sum>C \<in> S//?r. \<Sum>x \<in> C. f (g x))"
+ using eqv finite disjoint
+ by (simp flip: sum.Union_disjoint[simplified] add: Union_quotient)
+ also have "... = (\<Sum>y \<in> g ` S. \<Sum>x \<in> ?cls y. f (g x))"
+ unfolding quot_as_img by (simp add: sum.reindex[OF cls_inj])
+ also have "... = (\<Sum>y \<in> g ` S. \<Sum>x \<in> ?cls y. f y)"
+ by auto
+ also have "... = (\<Sum>y \<in> g ` S. of_nat (card (?cls y)) * f y)"
+ by (simp flip: sum_constant)
+ also have "... = (\<Sum>y \<in> R. of_nat (card (?cls y)) * f y)"
+ using rest_0 by (simp add: sum.subset_diff[OF \<open>g ` S \<subseteq> R\<close> \<open>finite R\<close>])
+ finally show ?thesis
+ by (simp add: eq_commute)
+qed
+
+
subsubsection \<open>Cardinality of products\<close>