more fundamental pred-to-set conversions, particularly by means of inductive_set; associated consolidation of some theorem names (c.f. NEWS)

--- a/NEWS	Thu Mar 01 17:13:54 2012 +0000
+++ b/NEWS	Thu Mar 01 19:34:52 2012 +0100
@@ -90,6 +90,18 @@
 
 * New type synonym 'a rel = ('a * 'a) set
 
+* More default pred/set conversions on a couple of relation operations
+and predicates.  Consolidation of some relation theorems:
+
+  converse_def ~> converse_unfold
+  rel_comp_def ~> rel_comp_unfold
+  symp_def ~> (dropped, use symp_def and sym_def instead)
+  transp_def ~> transp_trans
+  Domain_def ~> Domain_unfold
+  Range_def ~> Domain_converse [symmetric]
+
+INCOMPATIBILITY.
+
 * Consolidated various theorem names relating to Finite_Set.fold
 combinator:
 
@@ -99,7 +111,7 @@
   SUPR_fold_sup ~> SUP_fold_sup
   union_set ~> union_set_fold
   minus_set ~> minus_set_fold
-  
+
 INCOMPATIBILITY.
 
 * Consolidated theorem names concerning fold combinators:

--- a/src/HOL/Equiv_Relations.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/Equiv_Relations.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -31,7 +31,7 @@
 
 lemma sym_trans_comp_subset:
     "sym r ==> trans r ==> r\<inverse> O r \<subseteq> r"
-  by (unfold trans_def sym_def converse_def) blast
+  by (unfold trans_def sym_def converse_unfold) blast
 
 lemma refl_on_comp_subset: "refl_on A r ==> r \<subseteq> r\<inverse> O r"
   by (unfold refl_on_def) blast
@@ -426,7 +426,7 @@
 
 lemma equivp_equiv:
   "equiv UNIV A \<longleftrightarrow> equivp (\<lambda>x y. (x, y) \<in> A)"
-  by (auto intro: equivpI elim: equivpE simp add: equiv_def reflp_def symp_def transp_def)
+  by (auto intro!: equivI equivpI [to_set] elim!: equivE equivpE [to_set])
 
 lemma equivp_reflp_symp_transp:
   shows "equivp R \<longleftrightarrow> reflp R \<and> symp R \<and> transp R"
@@ -449,3 +449,4 @@
   by (erule equivpE, erule transpE)
 
 end
+

--- a/src/HOL/Library/Zorn.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/Library/Zorn.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -453,7 +453,7 @@
     proof
       assume "m={}"
       moreover have "Well_order {(x,x)}"
-        by(simp add:order_on_defs refl_on_def trans_def antisym_def total_on_def Field_def Domain_def Range_def)
+        by(simp add:order_on_defs refl_on_def trans_def antisym_def total_on_def Field_def Domain_unfold Domain_converse [symmetric])
       ultimately show False using max
         by (auto simp:I_def init_seg_of_def simp del:Field_insert)
     qed
@@ -470,14 +470,14 @@
 --{*We show that the extension is a well-order*}
     have "Refl ?m" using `Refl m` Fm by(auto simp:refl_on_def)
     moreover have "trans ?m" using `trans m` `x \<notin> Field m`
-      unfolding trans_def Field_def Domain_def Range_def by blast
+      unfolding trans_def Field_def Domain_unfold Domain_converse [symmetric] by blast
     moreover have "antisym ?m" using `antisym m` `x \<notin> Field m`
-      unfolding antisym_def Field_def Domain_def Range_def by blast
+      unfolding antisym_def Field_def Domain_unfold Domain_converse [symmetric] by blast
     moreover have "Total ?m" using `Total m` Fm by(auto simp: total_on_def)
     moreover have "wf(?m-Id)"
     proof-
       have "wf ?s" using `x \<notin> Field m`
-        by(auto simp add:wf_eq_minimal Field_def Domain_def Range_def) metis
+        by(auto simp add:wf_eq_minimal Field_def Domain_unfold Domain_converse [symmetric]) metis
       thus ?thesis using `wf(m-Id)` `x \<notin> Field m`
         wf_subset[OF `wf ?s` Diff_subset]
         by (fastforce intro!: wf_Un simp add: Un_Diff Field_def)
@@ -485,7 +485,7 @@
     ultimately have "Well_order ?m" by(simp add:order_on_defs)
 --{*We show that the extension is above m*}
     moreover hence "(m,?m) : I" using `Well_order m` `x \<notin> Field m`
-      by(fastforce simp:I_def init_seg_of_def Field_def Domain_def Range_def)
+      by(fastforce simp:I_def init_seg_of_def Field_def Domain_unfold Domain_converse [symmetric])
     ultimately
 --{*This contradicts maximality of m:*}
     have False using max `x \<notin> Field m` unfolding Field_def by blast
@@ -501,7 +501,7 @@
     using well_ordering[where 'a = "'a"] by blast
   let ?r = "{(x,y). x:A & y:A & (x,y):r}"
   have 1: "Field ?r = A" using wo univ
-    by(fastforce simp: Field_def Domain_def Range_def order_on_defs refl_on_def)
+    by(fastforce simp: Field_def Domain_unfold Domain_converse [symmetric] order_on_defs refl_on_def)
   have "Refl r" "trans r" "antisym r" "Total r" "wf(r-Id)"
     using `Well_order r` by(simp_all add:order_on_defs)
   have "Refl ?r" using `Refl r` by(auto simp:refl_on_def 1 univ)

--- a/src/HOL/Metis_Examples/Tarski.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/Metis_Examples/Tarski.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -189,10 +189,10 @@
 by (simp add: glb_def greatest_def isGlb_def some_eq_ex [symmetric])
 
 lemma isGlb_dual_isLub: "isGlb S cl = isLub S (dual cl)"
-by (simp add: isLub_def isGlb_def dual_def converse_def)
+by (simp add: isLub_def isGlb_def dual_def converse_unfold)
 
 lemma isLub_dual_isGlb: "isLub S cl = isGlb S (dual cl)"
-by (simp add: isLub_def isGlb_def dual_def converse_def)
+by (simp add: isLub_def isGlb_def dual_def converse_unfold)
 
 lemma (in PO) dualPO: "dual cl \<in> PartialOrder"
 apply (insert cl_po)
@@ -212,10 +212,10 @@
 done
 
 lemma lub_dual_glb: "lub S cl = glb S (dual cl)"
-by (simp add: lub_def glb_def least_def greatest_def dual_def converse_def)
+by (simp add: lub_def glb_def least_def greatest_def dual_def converse_unfold)
 
 lemma glb_dual_lub: "glb S cl = lub S (dual cl)"
-by (simp add: lub_def glb_def least_def greatest_def dual_def converse_def)
+by (simp add: lub_def glb_def least_def greatest_def dual_def converse_unfold)
 
 lemma CL_subset_PO: "CompleteLattice \<subseteq> PartialOrder"
 by (simp add: PartialOrder_def CompleteLattice_def, fast)

--- a/src/HOL/Predicate_Compile_Examples/Predicate_Compile_Tests.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/Predicate_Compile_Examples/Predicate_Compile_Tests.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -1043,14 +1043,14 @@
   (i => bool) => o * i => bool,
   (i => bool) => i => bool) [inductify] Id_on .
 thm Id_on.equation
-thm Domain_def
+thm Domain_unfold
 code_pred (modes:
   (o * o => bool) => o => bool,
   (o * o => bool) => i => bool,
   (i * o => bool) => i => bool) [inductify] Domain .
 thm Domain.equation
 
-thm Range_def
+thm Domain_converse [symmetric]
 code_pred (modes:
   (o * o => bool) => o => bool,
   (o * o => bool) => i => bool,

--- a/src/HOL/Quotient_Examples/FSet.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/Quotient_Examples/FSet.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -534,7 +534,7 @@
   assumes "(R1 ===> R2 ===> R3) C C" and "(R4 ===> R5 ===> R6) C C"
   shows "(R1 OOO R4 ===> R2 OOO R5 ===> R3 OOO R6) C C"
   by (auto intro!: fun_relI)
-     (metis (full_types) assms fun_relE pred_comp.intros)
+     (metis (full_types) assms fun_relE pred_compI)
 
 lemma append_rsp2 [quot_respect]:
   "(list_all2 op \<approx> OOO op \<approx> ===> list_all2 op \<approx> OOO op \<approx> ===> list_all2 op \<approx> OOO op \<approx>) append append"
@@ -560,7 +560,7 @@
     by (induct y ya rule: list_induct2')
        (simp_all, metis apply_rsp' list_eq_def)
   show "(list_all2 op \<approx> OOO op \<approx>) (map f xa) (map f' ya)"
-    by (metis a b c list_eq_def pred_comp.intros)
+    by (metis a b c list_eq_def pred_compI)
 qed
 
 lemma map_prs2 [quot_preserve]:

--- a/src/HOL/Relation.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/Relation.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -113,28 +113,33 @@
 
 subsubsection {* Reflexivity *}
 
-definition
-  refl_on :: "'a set \<Rightarrow> ('a \<times> 'a) set \<Rightarrow> bool" where
-  "refl_on A r \<longleftrightarrow> r \<subseteq> A \<times> A & (ALL x: A. (x,x) : r)"
+definition refl_on :: "'a set \<Rightarrow> 'a rel \<Rightarrow> bool"
+where
+  "refl_on A r \<longleftrightarrow> r \<subseteq> A \<times> A \<and> (\<forall>x\<in>A. (x, x) \<in> r)"
 
-abbreviation
-  refl :: "('a * 'a) set => bool" where -- {* reflexivity over a type *}
+abbreviation refl :: "'a rel \<Rightarrow> bool"
+where -- {* reflexivity over a type *}
   "refl \<equiv> refl_on UNIV"
 
-definition reflp :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool" where
+definition reflp :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool"
+where
   "reflp r \<longleftrightarrow> refl {(x, y). r x y}"
 
+lemma reflp_refl_eq [pred_set_conv]:
+  "reflp (\<lambda>x y. (x, y) \<in> r) \<longleftrightarrow> refl r" 
+  by (simp add: refl_on_def reflp_def)
+
 lemma refl_onI: "r \<subseteq> A \<times> A ==> (!!x. x : A ==> (x, x) : r) ==> refl_on A r"
-by (unfold refl_on_def) (iprover intro!: ballI)
+  by (unfold refl_on_def) (iprover intro!: ballI)
 
 lemma refl_onD: "refl_on A r ==> a : A ==> (a, a) : r"
-by (unfold refl_on_def) blast
+  by (unfold refl_on_def) blast
 
 lemma refl_onD1: "refl_on A r ==> (x, y) : r ==> x : A"
-by (unfold refl_on_def) blast
+  by (unfold refl_on_def) blast
 
 lemma refl_onD2: "refl_on A r ==> (x, y) : r ==> y : A"
-by (unfold refl_on_def) blast
+  by (unfold refl_on_def) blast
 
 lemma reflpI:
   "(\<And>x. r x x) \<Longrightarrow> reflp r"
@@ -146,32 +151,40 @@
   using assms by (auto dest: refl_onD simp add: reflp_def)
 
 lemma refl_on_Int: "refl_on A r ==> refl_on B s ==> refl_on (A \<inter> B) (r \<inter> s)"
-by (unfold refl_on_def) blast
+  by (unfold refl_on_def) blast
+
+lemma reflp_inf:
+  "reflp r \<Longrightarrow> reflp s \<Longrightarrow> reflp (r \<sqinter> s)"
+  by (auto intro: reflpI elim: reflpE)
 
 lemma refl_on_Un: "refl_on A r ==> refl_on B s ==> refl_on (A \<union> B) (r \<union> s)"
-by (unfold refl_on_def) blast
+  by (unfold refl_on_def) blast
+
+lemma reflp_sup:
+  "reflp r \<Longrightarrow> reflp s \<Longrightarrow> reflp (r \<squnion> s)"
+  by (auto intro: reflpI elim: reflpE)
 
 lemma refl_on_INTER:
   "ALL x:S. refl_on (A x) (r x) ==> refl_on (INTER S A) (INTER S r)"
-by (unfold refl_on_def) fast
+  by (unfold refl_on_def) fast
 
 lemma refl_on_UNION:
   "ALL x:S. refl_on (A x) (r x) \<Longrightarrow> refl_on (UNION S A) (UNION S r)"
-by (unfold refl_on_def) blast
+  by (unfold refl_on_def) blast
 
-lemma refl_on_empty[simp]: "refl_on {} {}"
-by(simp add:refl_on_def)
+lemma refl_on_empty [simp]: "refl_on {} {}"
+  by (simp add:refl_on_def)
 
 lemma refl_on_def' [nitpick_unfold, code]:
-  "refl_on A r = ((\<forall>(x, y) \<in> r. x : A \<and> y : A) \<and> (\<forall>x \<in> A. (x, x) : r))"
-by (auto intro: refl_onI dest: refl_onD refl_onD1 refl_onD2)
+  "refl_on A r \<longleftrightarrow> (\<forall>(x, y) \<in> r. x \<in> A \<and> y \<in> A) \<and> (\<forall>x \<in> A. (x, x) \<in> r)"
+  by (auto intro: refl_onI dest: refl_onD refl_onD1 refl_onD2)
 
 
 subsubsection {* Irreflexivity *}
 
-definition
-  irrefl :: "('a * 'a) set => bool" where
-  "irrefl r \<longleftrightarrow> (\<forall>x. (x,x) \<notin> r)"
+definition irrefl :: "'a rel \<Rightarrow> bool"
+where
+  "irrefl r \<longleftrightarrow> (\<forall>x. (x, x) \<notin> r)"
 
 lemma irrefl_distinct [code]:
   "irrefl r \<longleftrightarrow> (\<forall>(x, y) \<in> r. x \<noteq> y)"
@@ -180,166 +193,231 @@
 
 subsubsection {* Symmetry *}
 
-definition
-  sym :: "('a * 'a) set => bool" where
-  "sym r \<longleftrightarrow> (ALL x y. (x,y): r --> (y,x): r)"
+definition sym :: "'a rel \<Rightarrow> bool"
+where
+  "sym r \<longleftrightarrow> (\<forall>x y. (x, y) \<in> r \<longrightarrow> (y, x) \<in> r)"
+
+definition symp :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool"
+where
+  "symp r \<longleftrightarrow> (\<forall>x y. r x y \<longrightarrow> r y x)"
 
-lemma symI: "(!!a b. (a, b) : r ==> (b, a) : r) ==> sym r"
-by (unfold sym_def) iprover
+lemma symp_sym_eq [pred_set_conv]:
+  "symp (\<lambda>x y. (x, y) \<in> r) \<longleftrightarrow> sym r" 
+  by (simp add: sym_def symp_def)
 
-lemma symD: "sym r ==> (a, b) : r ==> (b, a) : r"
-by (unfold sym_def, blast)
-
-definition symp :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool" where
-  "symp r \<longleftrightarrow> sym {(x, y). r x y}"
+lemma symI:
+  "(\<And>a b. (a, b) \<in> r \<Longrightarrow> (b, a) \<in> r) \<Longrightarrow> sym r"
+  by (unfold sym_def) iprover
 
 lemma sympI:
-  "(\<And>x y. r x y \<Longrightarrow> r y x) \<Longrightarrow> symp r"
-  by (auto intro: symI simp add: symp_def)
+  "(\<And>a b. r a b \<Longrightarrow> r b a) \<Longrightarrow> symp r"
+  by (fact symI [to_pred])
+
+lemma symE:
+  assumes "sym r" and "(b, a) \<in> r"
+  obtains "(a, b) \<in> r"
+  using assms by (simp add: sym_def)
 
 lemma sympE:
-  assumes "symp r" and "r x y"
-  obtains "r y x"
-  using assms by (auto dest: symD simp add: symp_def)
+  assumes "symp r" and "r b a"
+  obtains "r a b"
+  using assms by (rule symE [to_pred])
+
+lemma symD:
+  assumes "sym r" and "(b, a) \<in> r"
+  shows "(a, b) \<in> r"
+  using assms by (rule symE)
 
-lemma sym_Int: "sym r ==> sym s ==> sym (r \<inter> s)"
-by (fast intro: symI dest: symD)
+lemma sympD:
+  assumes "symp r" and "r b a"
+  shows "r a b"
+  using assms by (rule symD [to_pred])
+
+lemma sym_Int:
+  "sym r \<Longrightarrow> sym s \<Longrightarrow> sym (r \<inter> s)"
+  by (fast intro: symI elim: symE)
 
-lemma sym_Un: "sym r ==> sym s ==> sym (r \<union> s)"
-by (fast intro: symI dest: symD)
+lemma symp_inf:
+  "symp r \<Longrightarrow> symp s \<Longrightarrow> symp (r \<sqinter> s)"
+  by (fact sym_Int [to_pred])
+
+lemma sym_Un:
+  "sym r \<Longrightarrow> sym s \<Longrightarrow> sym (r \<union> s)"
+  by (fast intro: symI elim: symE)
+
+lemma symp_sup:
+  "symp r \<Longrightarrow> symp s \<Longrightarrow> symp (r \<squnion> s)"
+  by (fact sym_Un [to_pred])
 
-lemma sym_INTER: "ALL x:S. sym (r x) ==> sym (INTER S r)"
-by (fast intro: symI dest: symD)
+lemma sym_INTER:
+  "\<forall>x\<in>S. sym (r x) \<Longrightarrow> sym (INTER S r)"
+  by (fast intro: symI elim: symE)
+
+(* FIXME thm sym_INTER [to_pred] *)
 
-lemma sym_UNION: "ALL x:S. sym (r x) ==> sym (UNION S r)"
-by (fast intro: symI dest: symD)
+lemma sym_UNION:
+  "\<forall>x\<in>S. sym (r x) \<Longrightarrow> sym (UNION S r)"
+  by (fast intro: symI elim: symE)
+
+(* FIXME thm sym_UNION [to_pred] *)
 
 
 subsubsection {* Antisymmetry *}
 
-definition
-  antisym :: "('a * 'a) set => bool" where
-  "antisym r \<longleftrightarrow> (ALL x y. (x,y):r --> (y,x):r --> x=y)"
+definition antisym :: "'a rel \<Rightarrow> bool"
+where
+  "antisym r \<longleftrightarrow> (\<forall>x y. (x, y) \<in> r \<longrightarrow> (y, x) \<in> r \<longrightarrow> x = y)"
+
+abbreviation antisymP :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool"
+where
+  "antisymP r \<equiv> antisym {(x, y). r x y}"
 
 lemma antisymI:
   "(!!x y. (x, y) : r ==> (y, x) : r ==> x=y) ==> antisym r"
-by (unfold antisym_def) iprover
+  by (unfold antisym_def) iprover
 
 lemma antisymD: "antisym r ==> (a, b) : r ==> (b, a) : r ==> a = b"
-by (unfold antisym_def) iprover
-
-abbreviation antisymP :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool" where
-  "antisymP r \<equiv> antisym {(x, y). r x y}"
+  by (unfold antisym_def) iprover
 
 lemma antisym_subset: "r \<subseteq> s ==> antisym s ==> antisym r"
-by (unfold antisym_def) blast
+  by (unfold antisym_def) blast
 
 lemma antisym_empty [simp]: "antisym {}"
-by (unfold antisym_def) blast
+  by (unfold antisym_def) blast
 
 
 subsubsection {* Transitivity *}
 
-definition
-  trans :: "('a * 'a) set => bool" where
-  "trans r \<longleftrightarrow> (ALL x y z. (x,y):r --> (y,z):r --> (x,z):r)"
+definition trans :: "'a rel \<Rightarrow> bool"
+where
+  "trans r \<longleftrightarrow> (\<forall>x y z. (x, y) \<in> r \<longrightarrow> (y, z) \<in> r \<longrightarrow> (x, z) \<in> r)"
+
+definition transp :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool"
+where
+  "transp r \<longleftrightarrow> (\<forall>x y z. r x y \<longrightarrow> r y z \<longrightarrow> r x z)"
+
+lemma transp_trans_eq [pred_set_conv]:
+  "transp (\<lambda>x y. (x, y) \<in> r) \<longleftrightarrow> trans r" 
+  by (simp add: trans_def transp_def)
+
+abbreviation transP :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool"
+where -- {* FIXME drop *}
+  "transP r \<equiv> trans {(x, y). r x y}"
 
 lemma transI:
-  "(!!x y z. (x, y) : r ==> (y, z) : r ==> (x, z) : r) ==> trans r"
-by (unfold trans_def) iprover
-
-lemma transD: "trans r ==> (a, b) : r ==> (b, c) : r ==> (a, c) : r"
-by (unfold trans_def) iprover
-
-abbreviation transP :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool" where
-  "transP r \<equiv> trans {(x, y). r x y}"
-
-definition transp :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> bool" where
-  "transp r \<longleftrightarrow> trans {(x, y). r x y}"
+  "(\<And>x y z. (x, y) \<in> r \<Longrightarrow> (y, z) \<in> r \<Longrightarrow> (x, z) \<in> r) \<Longrightarrow> trans r"
+  by (unfold trans_def) iprover
 
 lemma transpI:
   "(\<And>x y z. r x y \<Longrightarrow> r y z \<Longrightarrow> r x z) \<Longrightarrow> transp r"
-  by (auto intro: transI simp add: transp_def)
-  
+  by (fact transI [to_pred])
+
+lemma transE:
+  assumes "trans r" and "(x, y) \<in> r" and "(y, z) \<in> r"
+  obtains "(x, z) \<in> r"
+  using assms by (unfold trans_def) iprover
+
 lemma transpE:
   assumes "transp r" and "r x y" and "r y z"
   obtains "r x z"
-  using assms by (auto dest: transD simp add: transp_def)
+  using assms by (rule transE [to_pred])
+
+lemma transD:
+  assumes "trans r" and "(x, y) \<in> r" and "(y, z) \<in> r"
+  shows "(x, z) \<in> r"
+  using assms by (rule transE)
+
+lemma transpD:
+  assumes "transp r" and "r x y" and "r y z"
+  shows "r x z"
+  using assms by (rule transD [to_pred])
 
-lemma trans_Int: "trans r ==> trans s ==> trans (r \<inter> s)"
-by (fast intro: transI elim: transD)
+lemma trans_Int:
+  "trans r \<Longrightarrow> trans s \<Longrightarrow> trans (r \<inter> s)"
+  by (fast intro: transI elim: transE)
 
-lemma trans_INTER: "ALL x:S. trans (r x) ==> trans (INTER S r)"
-by (fast intro: transI elim: transD)
+lemma transp_inf:
+  "transp r \<Longrightarrow> transp s \<Longrightarrow> transp (r \<sqinter> s)"
+  by (fact trans_Int [to_pred])
+
+lemma trans_INTER:
+  "\<forall>x\<in>S. trans (r x) \<Longrightarrow> trans (INTER S r)"
+  by (fast intro: transI elim: transD)
+
+(* FIXME thm trans_INTER [to_pred] *)
 
 lemma trans_join [code]:
   "trans r \<longleftrightarrow> (\<forall>(x, y1) \<in> r. \<forall>(y2, z) \<in> r. y1 = y2 \<longrightarrow> (x, z) \<in> r)"
   by (auto simp add: trans_def)
 
+lemma transp_trans:
+  "transp r \<longleftrightarrow> trans {(x, y). r x y}"
+  by (simp add: trans_def transp_def)
+
 
 subsubsection {* Totality *}
 
-definition
-  total_on :: "'a set => ('a * 'a) set => bool" where
-  "total_on A r \<longleftrightarrow> (\<forall>x\<in>A.\<forall>y\<in>A. x\<noteq>y \<longrightarrow> (x,y)\<in>r \<or> (y,x)\<in>r)"
+definition total_on :: "'a set \<Rightarrow> 'a rel \<Rightarrow> bool"
+where
+  "total_on A r \<longleftrightarrow> (\<forall>x\<in>A. \<forall>y\<in>A. x \<noteq> y \<longrightarrow> (x, y) \<in> r \<or> (y, x) \<in> r)"
 
 abbreviation "total \<equiv> total_on UNIV"
 
-lemma total_on_empty[simp]: "total_on {} r"
-by(simp add:total_on_def)
+lemma total_on_empty [simp]: "total_on {} r"
+  by (simp add: total_on_def)
 
 
 subsubsection {* Single valued relations *}
 
-definition
-  single_valued :: "('a * 'b) set => bool" where
-  "single_valued r \<longleftrightarrow> (ALL x y. (x,y):r --> (ALL z. (x,z):r --> y=z))"
-
-lemma single_valuedI:
-  "ALL x y. (x,y):r --> (ALL z. (x,z):r --> y=z) ==> single_valued r"
-by (unfold single_valued_def)
-
-lemma single_valuedD:
-  "single_valued r ==> (x, y) : r ==> (x, z) : r ==> y = z"
-by (simp add: single_valued_def)
+definition single_valued :: "('a \<times> 'b) set \<Rightarrow> bool"
+where
+  "single_valued r \<longleftrightarrow> (\<forall>x y. (x, y) \<in> r \<longrightarrow> (\<forall>z. (x, z) \<in> r \<longrightarrow> y = z))"
 
 abbreviation single_valuedP :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> bool" where
   "single_valuedP r \<equiv> single_valued {(x, y). r x y}"
 
+lemma single_valuedI:
+  "ALL x y. (x,y):r --> (ALL z. (x,z):r --> y=z) ==> single_valued r"
+  by (unfold single_valued_def)
+
+lemma single_valuedD:
+  "single_valued r ==> (x, y) : r ==> (x, z) : r ==> y = z"
+  by (simp add: single_valued_def)
+
 lemma single_valued_subset:
   "r \<subseteq> s ==> single_valued s ==> single_valued r"
-by (unfold single_valued_def) blast
+  by (unfold single_valued_def) blast
 
 
 subsection {* Relation operations *}
 
 subsubsection {* The identity relation *}
 
-definition
-  Id :: "('a * 'a) set" where
-  "Id = {p. EX x. p = (x,x)}"
+definition Id :: "'a rel"
+where
+  "Id = {p. \<exists>x. p = (x, x)}"
 
 lemma IdI [intro]: "(a, a) : Id"
-by (simp add: Id_def)
+  by (simp add: Id_def)
 
 lemma IdE [elim!]: "p : Id ==> (!!x. p = (x, x) ==> P) ==> P"
-by (unfold Id_def) (iprover elim: CollectE)
+  by (unfold Id_def) (iprover elim: CollectE)
 
 lemma pair_in_Id_conv [iff]: "((a, b) : Id) = (a = b)"
-by (unfold Id_def) blast
+  by (unfold Id_def) blast
 
 lemma refl_Id: "refl Id"
-by (simp add: refl_on_def)
+  by (simp add: refl_on_def)
 
 lemma antisym_Id: "antisym Id"
   -- {* A strange result, since @{text Id} is also symmetric. *}
-by (simp add: antisym_def)
+  by (simp add: antisym_def)
 
 lemma sym_Id: "sym Id"
-by (simp add: sym_def)
+  by (simp add: sym_def)
 
 lemma trans_Id: "trans Id"
-by (simp add: trans_def)
+  by (simp add: trans_def)
 
 lemma single_valued_Id [simp]: "single_valued Id"
   by (unfold single_valued_def) blast
@@ -356,45 +434,45 @@
 
 subsubsection {* Diagonal: identity over a set *}
 
-definition
-  Id_on  :: "'a set => ('a * 'a) set" where
-  "Id_on A = (\<Union>x\<in>A. {(x,x)})"
+definition Id_on  :: "'a set \<Rightarrow> 'a rel"
+where
+  "Id_on A = (\<Union>x\<in>A. {(x, x)})"
 
 lemma Id_on_empty [simp]: "Id_on {} = {}"
-by (simp add: Id_on_def) 
+  by (simp add: Id_on_def) 
 
 lemma Id_on_eqI: "a = b ==> a : A ==> (a, b) : Id_on A"
-by (simp add: Id_on_def)
+  by (simp add: Id_on_def)
 
 lemma Id_onI [intro!,no_atp]: "a : A ==> (a, a) : Id_on A"
-by (rule Id_on_eqI) (rule refl)
+  by (rule Id_on_eqI) (rule refl)
 
 lemma Id_onE [elim!]:
   "c : Id_on A ==> (!!x. x : A ==> c = (x, x) ==> P) ==> P"
   -- {* The general elimination rule. *}
-by (unfold Id_on_def) (iprover elim!: UN_E singletonE)
+  by (unfold Id_on_def) (iprover elim!: UN_E singletonE)
 
 lemma Id_on_iff: "((x, y) : Id_on A) = (x = y & x : A)"
-by blast
+  by blast
 
 lemma Id_on_def' [nitpick_unfold]:
   "Id_on {x. A x} = Collect (\<lambda>(x, y). x = y \<and> A x)"
-by auto
+  by auto
 
 lemma Id_on_subset_Times: "Id_on A \<subseteq> A \<times> A"
-by blast
+  by blast
 
 lemma refl_on_Id_on: "refl_on A (Id_on A)"
-by (rule refl_onI [OF Id_on_subset_Times Id_onI])
+  by (rule refl_onI [OF Id_on_subset_Times Id_onI])
 
 lemma antisym_Id_on [simp]: "antisym (Id_on A)"
-by (unfold antisym_def) blast
+  by (unfold antisym_def) blast
 
 lemma sym_Id_on [simp]: "sym (Id_on A)"
-by (rule symI) clarify
+  by (rule symI) clarify
 
 lemma trans_Id_on [simp]: "trans (Id_on A)"
-by (fast intro: transI elim: transD)
+  by (fast intro: transI elim: transD)
 
 lemma single_valued_Id_on [simp]: "single_valued (Id_on A)"
   by (unfold single_valued_def) blast
@@ -402,184 +480,228 @@
 
 subsubsection {* Composition *}
 
-definition rel_comp  :: "('a \<times> 'b) set \<Rightarrow> ('b \<times> 'c) set \<Rightarrow> ('a * 'c) set" (infixr "O" 75)
+inductive_set rel_comp  :: "('a \<times> 'b) set \<Rightarrow> ('b \<times> 'c) set \<Rightarrow> ('a \<times> 'c) set" (infixr "O" 75)
+  for r :: "('a \<times> 'b) set" and s :: "('b \<times> 'c) set"
 where
-  "r O s = {(x, z). \<exists>y. (x, y) \<in> r \<and> (y, z) \<in> s}"
+  rel_compI [intro]: "(a, b) \<in> r \<Longrightarrow> (b, c) \<in> s \<Longrightarrow> (a, c) \<in> r O s"
 
-lemma rel_compI [intro]:
-  "(a, b) : r ==> (b, c) : s ==> (a, c) : r O s"
-by (unfold rel_comp_def) blast
+abbreviation pred_comp (infixr "OO" 75) where
+  "pred_comp \<equiv> rel_compp"
 
-lemma rel_compE [elim!]: "xz : r O s ==>
-  (!!x y z. xz = (x, z) ==> (x, y) : r ==> (y, z) : s  ==> P) ==> P"
-by (unfold rel_comp_def) (iprover elim!: CollectE splitE exE conjE)
+lemmas pred_compI = rel_compp.intros
 
-inductive pred_comp :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> ('b \<Rightarrow> 'c \<Rightarrow> bool) \<Rightarrow> 'a \<Rightarrow> 'c \<Rightarrow> bool" (infixr "OO" 75)
-for r :: "'a \<Rightarrow> 'b \<Rightarrow> bool" and s :: "'b \<Rightarrow> 'c \<Rightarrow> bool"
-where
-  pred_compI [intro]: "r a b \<Longrightarrow> s b c \<Longrightarrow> (r OO s) a c"
+text {*
+  For historic reasons, the elimination rules are not wholly corresponding.
+  Feel free to consolidate this.
+*}
 
+inductive_cases rel_compEpair: "(a, c) \<in> r O s"
 inductive_cases pred_compE [elim!]: "(r OO s) a c"
 
-lemma pred_comp_rel_comp_eq [pred_set_conv]:
-  "((\<lambda>x y. (x, y) \<in> r) OO (\<lambda>x y. (x, y) \<in> s)) = (\<lambda>x y. (x, y) \<in> r O s)"
-  by (auto simp add: fun_eq_iff)
+lemma rel_compE [elim!]: "xz \<in> r O s \<Longrightarrow>
+  (\<And>x y z. xz = (x, z) \<Longrightarrow> (x, y) \<in> r \<Longrightarrow> (y, z) \<in> s  \<Longrightarrow> P) \<Longrightarrow> P"
+  by (cases xz) (simp, erule rel_compEpair, iprover)
+
+lemmas pred_comp_rel_comp_eq = rel_compp_rel_comp_eq
+
+lemma R_O_Id [simp]:
+  "R O Id = R"
+  by fast
 
-lemma rel_compEpair:
-  "(a, c) : r O s ==> (!!y. (a, y) : r ==> (y, c) : s ==> P) ==> P"
-by (iprover elim: rel_compE Pair_inject ssubst)
+lemma Id_O_R [simp]:
+  "Id O R = R"
+  by fast
+
+lemma rel_comp_empty1 [simp]:
+  "{} O R = {}"
+  by blast
 
-lemma R_O_Id [simp]: "R O Id = R"
-by fast
+(* CANDIDATE lemma pred_comp_bot1 [simp]:
+  ""
+  by (fact rel_comp_empty1 [to_pred]) *)
 
-lemma Id_O_R [simp]: "Id O R = R"
-by fast
+lemma rel_comp_empty2 [simp]:
+  "R O {} = {}"
+  by blast
 
-lemma rel_comp_empty1[simp]: "{} O R = {}"
-by blast
+(* CANDIDATE lemma pred_comp_bot2 [simp]:
+  ""
+  by (fact rel_comp_empty2 [to_pred]) *)
 
-lemma rel_comp_empty2[simp]: "R O {} = {}"
-by blast
+lemma O_assoc:
+  "(R O S) O T = R O (S O T)"
+  by blast
+
+lemma pred_comp_assoc:
+  "(r OO s) OO t = r OO (s OO t)"
+  by (fact O_assoc [to_pred])
 
-lemma O_assoc: "(R O S) O T = R O (S O T)"
-by blast
+lemma trans_O_subset:
+  "trans r \<Longrightarrow> r O r \<subseteq> r"
+  by (unfold trans_def) blast
+
+lemma transp_pred_comp_less_eq:
+  "transp r \<Longrightarrow> r OO r \<le> r "
+  by (fact trans_O_subset [to_pred])
 
-lemma trans_O_subset: "trans r ==> r O r \<subseteq> r"
-by (unfold trans_def) blast
+lemma rel_comp_mono:
+  "r' \<subseteq> r \<Longrightarrow> s' \<subseteq> s \<Longrightarrow> r' O s' \<subseteq> r O s"
+  by blast
 
-lemma rel_comp_mono: "r' \<subseteq> r ==> s' \<subseteq> s ==> (r' O s') \<subseteq> (r O s)"
-by blast
+lemma pred_comp_mono:
+  "r' \<le> r \<Longrightarrow> s' \<le> s \<Longrightarrow> r' OO s' \<le> r OO s "
+  by (fact rel_comp_mono [to_pred])
 
 lemma rel_comp_subset_Sigma:
-    "r \<subseteq> A \<times> B ==> s \<subseteq> B \<times> C ==> (r O s) \<subseteq> A \<times> C"
-by blast
+  "r \<subseteq> A \<times> B \<Longrightarrow> s \<subseteq> B \<times> C \<Longrightarrow> r O s \<subseteq> A \<times> C"
+  by blast
+
+lemma rel_comp_distrib [simp]:
+  "R O (S \<union> T) = (R O S) \<union> (R O T)" 
+  by auto
 
-lemma rel_comp_distrib[simp]: "R O (S \<union> T) = (R O S) \<union> (R O T)" 
-by auto
+lemma pred_comp_distrib (* CANDIDATE [simp] *):
+  "R OO (S \<squnion> T) = R OO S \<squnion> R OO T"
+  by (fact rel_comp_distrib [to_pred])
+
+lemma rel_comp_distrib2 [simp]:
+  "(S \<union> T) O R = (S O R) \<union> (T O R)"
+  by auto
 
-lemma rel_comp_distrib2[simp]: "(S \<union> T) O R = (S O R) \<union> (T O R)"
-by auto
+lemma pred_comp_distrib2 (* CANDIDATE [simp] *):
+  "(S \<squnion> T) OO R = S OO R \<squnion> T OO R"
+  by (fact rel_comp_distrib2 [to_pred])
+
+lemma rel_comp_UNION_distrib:
+  "s O UNION I r = (\<Union>i\<in>I. s O r i) "
+  by auto
 
-lemma rel_comp_UNION_distrib: "s O UNION I r = UNION I (%i. s O r i)"
-by auto
+(* FIXME thm rel_comp_UNION_distrib [to_pred] *)
 
-lemma rel_comp_UNION_distrib2: "UNION I r O s = UNION I (%i. r i O s)"
-by auto
+lemma rel_comp_UNION_distrib2:
+  "UNION I r O s = (\<Union>i\<in>I. r i O s) "
+  by auto
+
+(* FIXME thm rel_comp_UNION_distrib2 [to_pred] *)
 
 lemma single_valued_rel_comp:
-  "single_valued r ==> single_valued s ==> single_valued (r O s)"
-by (unfold single_valued_def) blast
+  "single_valued r \<Longrightarrow> single_valued s \<Longrightarrow> single_valued (r O s)"
+  by (unfold single_valued_def) blast
+
+lemma rel_comp_unfold:
+  "r O s = {(x, z). \<exists>y. (x, y) \<in> r \<and> (y, z) \<in> s}"
+  by (auto simp add: set_eq_iff)
 
 
 subsubsection {* Converse *}
 
-definition
-  converse :: "('a * 'b) set => ('b * 'a) set"
-    ("(_^-1)" [1000] 999) where
-  "r^-1 = {(y, x). (x, y) : r}"
+inductive_set converse :: "('a \<times> 'b) set \<Rightarrow> ('b \<times> 'a) set" ("(_^-1)" [1000] 999)
+  for r :: "('a \<times> 'b) set"
+where
+  "(a, b) \<in> r \<Longrightarrow> (b, a) \<in> r^-1"
 
 notation (xsymbols)
   converse  ("(_\<inverse>)" [1000] 999)
 
-lemma converseI [sym]: "(a, b) : r ==> (b, a) : r^-1"
-  by (simp add: converse_def)
-
-lemma converseD [sym]: "(a,b) : r^-1 ==> (b, a) : r"
-  by (simp add: converse_def)
-
-lemma converseE [elim!]:
-  "yx : r^-1 ==> (!!x y. yx = (y, x) ==> (x, y) : r ==> P) ==> P"
-    -- {* More general than @{text converseD}, as it ``splits'' the member of the relation. *}
-  by (unfold converse_def) (iprover elim!: CollectE splitE bexE)
-
-lemma converse_iff [iff]: "((a,b): r^-1) = ((b,a) : r)"
-  by (simp add: converse_def)
-
-inductive conversep :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> 'b \<Rightarrow> 'a \<Rightarrow> bool" ("(_^--1)" [1000] 1000)
-  for r :: "'a \<Rightarrow> 'b \<Rightarrow> bool" where
-  conversepI: "r a b \<Longrightarrow> r^--1 b a"
+notation
+  conversep ("(_^--1)" [1000] 1000)
 
 notation (xsymbols)
   conversep  ("(_\<inverse>\<inverse>)" [1000] 1000)
 
-lemma conversepD:
-  assumes ab: "r^--1 a b"
-  shows "r b a" using ab
-  by cases simp
+lemma converseI [sym]:
+  "(a, b) \<in> r \<Longrightarrow> (b, a) \<in> r\<inverse>"
+  by (fact converse.intros)
+
+lemma conversepI (* CANDIDATE [sym] *):
+  "r a b \<Longrightarrow> r\<inverse>\<inverse> b a"
+  by (fact conversep.intros)
+
+lemma converseD [sym]:
+  "(a, b) \<in> r\<inverse> \<Longrightarrow> (b, a) \<in> r"
+  by (erule converse.cases) iprover
+
+lemma conversepD (* CANDIDATE [sym] *):
+  "r\<inverse>\<inverse> b a \<Longrightarrow> r a b"
+  by (fact converseD [to_pred])
+
+lemma converseE [elim!]:
+  -- {* More general than @{text converseD}, as it ``splits'' the member of the relation. *}
+  "yx \<in> r\<inverse> \<Longrightarrow> (\<And>x y. yx = (y, x) \<Longrightarrow> (x, y) \<in> r \<Longrightarrow> P) \<Longrightarrow> P"
+  by (cases yx) (simp, erule converse.cases, iprover)
 
-lemma conversep_iff [iff]: "r^--1 a b = r b a"
-  by (iprover intro: conversepI dest: conversepD)
+lemmas conversepE (* CANDIDATE [elim!] *) = conversep.cases
+
+lemma converse_iff [iff]:
+  "(a, b) \<in> r\<inverse> \<longleftrightarrow> (b, a) \<in> r"
+  by (auto intro: converseI)
+
+lemma conversep_iff [iff]:
+  "r\<inverse>\<inverse> a b = r b a"
+  by (fact converse_iff [to_pred])
 
-lemma conversep_converse_eq [pred_set_conv]:
-  "(\<lambda>x y. (x, y) \<in> r)^--1 = (\<lambda>x y. (x, y) \<in> r^-1)"
-  by (auto simp add: fun_eq_iff)
+lemma converse_converse [simp]:
+  "(r\<inverse>)\<inverse> = r"
+  by (simp add: set_eq_iff)
 
-lemma conversep_conversep [simp]: "(r^--1)^--1 = r"
-  by (iprover intro: order_antisym conversepI dest: conversepD)
+lemma conversep_conversep [simp]:
+  "(r\<inverse>\<inverse>)\<inverse>\<inverse> = r"
+  by (fact converse_converse [to_pred])
+
+lemma converse_rel_comp: "(r O s)^-1 = s^-1 O r^-1"
+  by blast
 
 lemma converse_pred_comp: "(r OO s)^--1 = s^--1 OO r^--1"
   by (iprover intro: order_antisym conversepI pred_compI
     elim: pred_compE dest: conversepD)
 
+lemma converse_Int: "(r \<inter> s)^-1 = r^-1 \<inter> s^-1"
+  by blast
+
 lemma converse_meet: "(r \<sqinter> s)^--1 = r^--1 \<sqinter> s^--1"
   by (simp add: inf_fun_def) (iprover intro: conversepI ext dest: conversepD)
 
+lemma converse_Un: "(r \<union> s)^-1 = r^-1 \<union> s^-1"
+  by blast
+
 lemma converse_join: "(r \<squnion> s)^--1 = r^--1 \<squnion> s^--1"
   by (simp add: sup_fun_def) (iprover intro: conversepI ext dest: conversepD)
 
-lemma conversep_noteq [simp]: "(op \<noteq>)^--1 = op \<noteq>"
-  by (auto simp add: fun_eq_iff)
-
-lemma conversep_eq [simp]: "(op =)^--1 = op ="
-  by (auto simp add: fun_eq_iff)
-
-lemma converse_converse [simp]: "(r^-1)^-1 = r"
-by (unfold converse_def) blast
-
-lemma converse_rel_comp: "(r O s)^-1 = s^-1 O r^-1"
-by blast
-
-lemma converse_Int: "(r \<inter> s)^-1 = r^-1 \<inter> s^-1"
-by blast
-
-lemma converse_Un: "(r \<union> s)^-1 = r^-1 \<union> s^-1"
-by blast
-
 lemma converse_INTER: "(INTER S r)^-1 = (INT x:S. (r x)^-1)"
-by fast
+  by fast
 
 lemma converse_UNION: "(UNION S r)^-1 = (UN x:S. (r x)^-1)"
-by blast
+  by blast
 
 lemma converse_Id [simp]: "Id^-1 = Id"
-by blast
+  by blast
 
 lemma converse_Id_on [simp]: "(Id_on A)^-1 = Id_on A"
-by blast
+  by blast
 
 lemma refl_on_converse [simp]: "refl_on A (converse r) = refl_on A r"
-by (unfold refl_on_def) auto
+  by (unfold refl_on_def) auto
 
 lemma sym_converse [simp]: "sym (converse r) = sym r"
-by (unfold sym_def) blast
+  by (unfold sym_def) blast
 
 lemma antisym_converse [simp]: "antisym (converse r) = antisym r"
-by (unfold antisym_def) blast
+  by (unfold antisym_def) blast
 
 lemma trans_converse [simp]: "trans (converse r) = trans r"
-by (unfold trans_def) blast
+  by (unfold trans_def) blast
 
 lemma sym_conv_converse_eq: "sym r = (r^-1 = r)"
-by (unfold sym_def) fast
+  by (unfold sym_def) fast
 
 lemma sym_Un_converse: "sym (r \<union> r^-1)"
-by (unfold sym_def) blast
+  by (unfold sym_def) blast
 
 lemma sym_Int_converse: "sym (r \<inter> r^-1)"
-by (unfold sym_def) blast
+  by (unfold sym_def) blast
 
-lemma total_on_converse[simp]: "total_on A (r^-1) = total_on A r"
-by (auto simp: total_on_def)
+lemma total_on_converse [simp]: "total_on A (r^-1) = total_on A r"
+  by (auto simp: total_on_def)
 
 lemma finite_converse [iff]: "finite (r^-1) = finite r"
   apply (subgoal_tac "r^-1 = (%(x,y). (y,x))`r")
@@ -588,50 +710,61 @@
     apply (erule finite_imageD [unfolded inj_on_def])
     apply (simp split add: split_split)
    apply (erule finite_imageI)
-  apply (simp add: converse_def image_def, auto)
+  apply (simp add: set_eq_iff image_def, auto)
   apply (rule bexI)
    prefer 2 apply assumption
   apply simp
   done
 
+lemma conversep_noteq [simp]: "(op \<noteq>)^--1 = op \<noteq>"
+  by (auto simp add: fun_eq_iff)
+
+lemma conversep_eq [simp]: "(op =)^--1 = op ="
+  by (auto simp add: fun_eq_iff)
+
+lemma converse_unfold:
+  "r\<inverse> = {(y, x). (x, y) \<in> r}"
+  by (simp add: set_eq_iff)
+
 
 subsubsection {* Domain, range and field *}
 
-definition
-  Domain :: "('a * 'b) set => 'a set" where
-  "Domain r = {x. EX y. (x,y):r}"
+definition Domain :: "('a \<times> 'b) set \<Rightarrow> 'a set"
+where
+  "Domain r = {x. \<exists>y. (x, y) \<in> r}"
 
-definition
-  Range  :: "('a * 'b) set => 'b set" where
-  "Range r = Domain(r^-1)"
+definition Range  :: "('a \<times> 'b) set \<Rightarrow> 'b set"
+where
+  "Range r = Domain (r\<inverse>)"
 
-definition
-  Field :: "('a * 'a) set => 'a set" where
+definition Field :: "'a rel \<Rightarrow> 'a set"
+where
   "Field r = Domain r \<union> Range r"
 
 declare Domain_def [no_atp]
 
 lemma Domain_iff: "(a : Domain r) = (EX y. (a, y) : r)"
-by (unfold Domain_def) blast
+  by (unfold Domain_def) blast
 
 lemma DomainI [intro]: "(a, b) : r ==> a : Domain r"
-by (iprover intro!: iffD2 [OF Domain_iff])
+  by (iprover intro!: iffD2 [OF Domain_iff])
 
 lemma DomainE [elim!]:
   "a : Domain r ==> (!!y. (a, y) : r ==> P) ==> P"
-by (iprover dest!: iffD1 [OF Domain_iff])
+  by (iprover dest!: iffD1 [OF Domain_iff])
 
 lemma Range_iff: "(a : Range r) = (EX y. (y, a) : r)"
-by (simp add: Domain_def Range_def)
+  by (simp add: Domain_def Range_def)
 
 lemma RangeI [intro]: "(a, b) : r ==> b : Range r"
-by (unfold Range_def) (iprover intro!: converseI DomainI)
+  by (unfold Range_def) (iprover intro!: converseI DomainI)
 
 lemma RangeE [elim!]: "b : Range r ==> (!!x. (x, b) : r ==> P) ==> P"
-by (unfold Range_def) (iprover elim!: DomainE dest!: converseD)
+  by (unfold Range_def) (iprover elim!: DomainE dest!: converseD)
 
 inductive DomainP :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> 'a \<Rightarrow> bool"
-  for r :: "'a \<Rightarrow> 'b \<Rightarrow> bool" where
+  for r :: "'a \<Rightarrow> 'b \<Rightarrow> bool"
+where
   DomainPI [intro]: "r a b \<Longrightarrow> DomainP r a"
 
 inductive_cases DomainPE [elim!]: "DomainP r a"
@@ -640,7 +773,8 @@
   by (blast intro!: Orderings.order_antisym predicate1I)
 
 inductive RangeP :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> 'b \<Rightarrow> bool"
-  for r :: "'a \<Rightarrow> 'b \<Rightarrow> bool" where
+  for r :: "'a \<Rightarrow> 'b \<Rightarrow> bool"
+where
   RangePI [intro]: "r a b \<Longrightarrow> RangeP r b"
 
 inductive_cases RangePE [elim!]: "RangeP r b"
@@ -679,8 +813,8 @@
 lemma Domain_Union: "Domain (Union S) = (\<Union>A\<in>S. Domain A)"
   by blast
 
-lemma Domain_converse[simp]: "Domain(r^-1) = Range r"
-  by(auto simp: Range_def)
+lemma Domain_converse [simp]: "Domain (r\<inverse>) = Range r"
+  by auto
 
 lemma Domain_mono: "r \<subseteq> s ==> Domain r \<subseteq> Domain s"
   by blast
@@ -731,7 +865,7 @@
 lemma Range_Union: "Range (Union S) = (\<Union>A\<in>S. Range A)"
   by blast
 
-lemma Range_converse [simp]: "Range(r^-1) = Domain r"
+lemma Range_converse [simp]: "Range (r\<inverse>) = Domain r"
   by blast
 
 lemma snd_eq_Range: "snd ` R = Range R"
@@ -767,73 +901,76 @@
    apply (auto simp add: Field_def Domain_insert Range_insert)
   done
 
+lemma Domain_unfold:
+  "Domain r = {x. \<exists>y. (x, y) \<in> r}"
+  by (fact Domain_def)
+
 
 subsubsection {* Image of a set under a relation *}
 
-definition
-  Image :: "[('a * 'b) set, 'a set] => 'b set"
-    (infixl "``" 90) where
-  "r `` s = {y. EX x:s. (x,y):r}"
+definition Image :: "('a \<times> 'b) set \<Rightarrow> 'a set \<Rightarrow> 'b set" (infixl "``" 90)
+where
+  "r `` s = {y. \<exists>x\<in>s. (x, y) \<in> r}"
 
 declare Image_def [no_atp]
 
 lemma Image_iff: "(b : r``A) = (EX x:A. (x, b) : r)"
-by (simp add: Image_def)
+  by (simp add: Image_def)
 
 lemma Image_singleton: "r``{a} = {b. (a, b) : r}"
-by (simp add: Image_def)
+  by (simp add: Image_def)
 
 lemma Image_singleton_iff [iff]: "(b : r``{a}) = ((a, b) : r)"
-by (rule Image_iff [THEN trans]) simp
+  by (rule Image_iff [THEN trans]) simp
 
 lemma ImageI [intro,no_atp]: "(a, b) : r ==> a : A ==> b : r``A"
-by (unfold Image_def) blast
+  by (unfold Image_def) blast
 
 lemma ImageE [elim!]:
-    "b : r `` A ==> (!!x. (x, b) : r ==> x : A ==> P) ==> P"
-by (unfold Image_def) (iprover elim!: CollectE bexE)
+  "b : r `` A ==> (!!x. (x, b) : r ==> x : A ==> P) ==> P"
+  by (unfold Image_def) (iprover elim!: CollectE bexE)
 
 lemma rev_ImageI: "a : A ==> (a, b) : r ==> b : r `` A"
   -- {* This version's more effective when we already have the required @{text a} *}
-by blast
+  by blast
 
 lemma Image_empty [simp]: "R``{} = {}"
-by blast
+  by blast
 
 lemma Image_Id [simp]: "Id `` A = A"
-by blast
+  by blast
 
 lemma Image_Id_on [simp]: "Id_on A `` B = A \<inter> B"
-by blast
+  by blast
 
 lemma Image_Int_subset: "R `` (A \<inter> B) \<subseteq> R `` A \<inter> R `` B"
-by blast
+  by blast
 
 lemma Image_Int_eq:
      "single_valued (converse R) ==> R `` (A \<inter> B) = R `` A \<inter> R `` B"
-by (simp add: single_valued_def, blast) 
+     by (simp add: single_valued_def, blast) 
 
 lemma Image_Un: "R `` (A \<union> B) = R `` A \<union> R `` B"
-by blast
+  by blast
 
 lemma Un_Image: "(R \<union> S) `` A = R `` A \<union> S `` A"
-by blast
+  by blast
 
 lemma Image_subset: "r \<subseteq> A \<times> B ==> r``C \<subseteq> B"
-by (iprover intro!: subsetI elim!: ImageE dest!: subsetD SigmaD2)
+  by (iprover intro!: subsetI elim!: ImageE dest!: subsetD SigmaD2)
 
 lemma Image_eq_UN: "r``B = (\<Union>y\<in> B. r``{y})"
   -- {* NOT suitable for rewriting *}
-by blast
+  by blast
 
 lemma Image_mono: "r' \<subseteq> r ==> A' \<subseteq> A ==> (r' `` A') \<subseteq> (r `` A)"
-by blast
+  by blast
 
 lemma Image_UN: "(r `` (UNION A B)) = (\<Union>x\<in>A. r `` (B x))"
-by blast
+  by blast
 
 lemma Image_INT_subset: "(r `` INTER A B) \<subseteq> (\<Inter>x\<in>A. r `` (B x))"
-by blast
+  by blast
 
 text{*Converse inclusion requires some assumptions*}
 lemma Image_INT_eq:
@@ -844,26 +981,27 @@
 done
 
 lemma Image_subset_eq: "(r``A \<subseteq> B) = (A \<subseteq> - ((r^-1) `` (-B)))"
-by blast
+  by blast
 
 lemma Image_Collect_split [simp]: "{(x, y). P x y} `` A = {y. EX x:A. P x y}"
-by auto
+  by auto
 
 
 subsubsection {* Inverse image *}
 
-definition
-  inv_image :: "('b * 'b) set => ('a => 'b) => ('a * 'a) set" where
-  "inv_image r f = {(x, y). (f x, f y) : r}"
+definition inv_image :: "'b rel \<Rightarrow> ('a \<Rightarrow> 'b) \<Rightarrow> 'a rel"
+where
+  "inv_image r f = {(x, y). (f x, f y) \<in> r}"
 
-definition inv_imagep :: "('b \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> ('a \<Rightarrow> 'b) \<Rightarrow> 'a \<Rightarrow> 'a \<Rightarrow> bool" where
+definition inv_imagep :: "('b \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> ('a \<Rightarrow> 'b) \<Rightarrow> 'a \<Rightarrow> 'a \<Rightarrow> bool"
+where
   "inv_imagep r f = (\<lambda>x y. r (f x) (f y))"
 
 lemma [pred_set_conv]: "inv_imagep (\<lambda>x y. (x, y) \<in> r) f = (\<lambda>x y. (x, y) \<in> inv_image r f)"
   by (simp add: inv_image_def inv_imagep_def)
 
 lemma sym_inv_image: "sym r ==> sym (inv_image r f)"
-by (unfold sym_def inv_image_def) blast
+  by (unfold sym_def inv_image_def) blast
 
 lemma trans_inv_image: "trans r ==> trans (inv_image r f)"
   apply (unfold trans_def inv_image_def)
@@ -875,7 +1013,7 @@
   by (auto simp:inv_image_def)
 
 lemma converse_inv_image[simp]: "(inv_image R f)^-1 = inv_image (R^-1) f"
-unfolding inv_image_def converse_def by auto
+  unfolding inv_image_def converse_unfold by auto
 
 lemma in_inv_imagep [simp]: "inv_imagep r f x y = r (f x) (f y)"
   by (simp add: inv_imagep_def)
@@ -883,7 +1021,8 @@
 
 subsubsection {* Powerset *}
 
-definition Powp :: "('a \<Rightarrow> bool) \<Rightarrow> 'a set \<Rightarrow> bool" where
+definition Powp :: "('a \<Rightarrow> bool) \<Rightarrow> 'a set \<Rightarrow> bool"
+where
   "Powp A = (\<lambda>B. \<forall>x \<in> B. A x)"
 
 lemma Powp_Pow_eq [pred_set_conv]: "Powp (\<lambda>x. x \<in> A) = (\<lambda>x. x \<in> Pow A)"

--- a/src/HOL/Transitive_Closure.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/Transitive_Closure.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -628,10 +628,10 @@
   by (blast intro: subsetD [OF rtrancl_Un_subset])
 
 lemma trancl_domain [simp]: "Domain (r^+) = Domain r"
-  by (unfold Domain_def) (blast dest: tranclD)
+  by (unfold Domain_unfold) (blast dest: tranclD)
 
 lemma trancl_range [simp]: "Range (r^+) = Range r"
-unfolding Range_def by(simp add: trancl_converse [symmetric])
+  unfolding Domain_converse [symmetric] by (simp add: trancl_converse [symmetric])
 
 lemma Not_Domain_rtrancl:
     "x ~: Domain R ==> ((x, y) : R^*) = (x = y)"
@@ -839,7 +839,7 @@
    apply (drule tranclD2)
    apply (clarsimp simp: rtrancl_is_UN_relpow)
    apply (rule_tac x="Suc n" in exI)
-   apply (clarsimp simp: rel_comp_def)
+   apply (clarsimp simp: rel_comp_unfold)
    apply fastforce
   apply clarsimp
   apply (case_tac n, simp)
@@ -860,7 +860,7 @@
 next
   case (Suc n)
   show ?case
-  proof (simp add: rel_comp_def Suc)
+  proof (simp add: rel_comp_unfold Suc)
     show "(\<exists>y. (\<exists>f. f 0 = a \<and> f n = y \<and> (\<forall>i<n. (f i,f(Suc i)) \<in> R)) \<and> (y,b) \<in> R)
      = (\<exists>f. f 0 = a \<and> f(Suc n) = b \<and> (\<forall>i<Suc n. (f i, f (Suc i)) \<in> R))"
     (is "?l = ?r")
@@ -1175,3 +1175,4 @@
   {* simple transitivity reasoner (predicate version) *}
 
 end
+

--- a/src/HOL/UNITY/Comp/Client.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/UNITY/Comp/Client.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -138,7 +138,7 @@
      "Client \<in> transient {s. rel s = k & k<h & h \<le> giv s & h pfixGe ask s}"
 apply (simp add: Client_def mk_total_program_def)
 apply (rule_tac act = rel_act in totalize_transientI)
-  apply (auto simp add: Domain_def Client_def)
+  apply (auto simp add: Domain_unfold Client_def)
  apply (blast intro: less_le_trans prefix_length_le strict_prefix_length_less)
 apply (auto simp add: prefix_def genPrefix_iff_nth Ge_def)
 apply (blast intro: strict_prefix_length_less)

--- a/src/HOL/UNITY/UNITY_tactics.ML	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/UNITY/UNITY_tactics.ML	Thu Mar 01 19:34:52 2012 +0100
@@ -46,7 +46,7 @@
       ORELSE res_inst_tac ctxt
         [(("act", 0), sact)] @{thm transientI} 2,
          (*simplify the command's domain*)
-      simp_tac (simpset_of ctxt addsimps @{thms Domain_def}) 3,
+      simp_tac (simpset_of ctxt addsimps @{thms Domain_unfold}) 3,
       constrains_tac ctxt 1,
       ALLGOALS (clarify_tac ctxt),
       ALLGOALS (asm_lr_simp_tac (simpset_of ctxt))]);

--- a/src/HOL/ZF/Games.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/ZF/Games.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -330,7 +330,7 @@
     by (simp add: option_to_is_option_of) 
   show ?thesis
     apply (simp add: option_of)
-    apply (auto intro: wf_inv_image wf_is_option_of)
+    apply (auto intro: wf_is_option_of)
     done
 qed
   
@@ -359,7 +359,7 @@
 lemma "neg_game (neg_game g) = g"
   apply (induct g rule: neg_game.induct)
   apply (subst neg_game.simps)+
-  apply (simp add: right_options left_options comp_zimage_eq)
+  apply (simp add: comp_zimage_eq)
   apply (subgoal_tac "zimage (neg_game o neg_game) (left_options g) = left_options g")
   apply (subgoal_tac "zimage (neg_game o neg_game) (right_options g) = right_options g")
   apply (auto simp add: game_split[symmetric])
@@ -552,7 +552,7 @@
         apply (simp only: plus_game.simps[where G=G and H=H])
         apply (simp add: game_ext_eq goal1)
         apply (auto simp add: 
-          zimage_cong[where f = "\<lambda> g. plus_game g zero_game" and g = "id"] 
+          zimage_cong [where f = "\<lambda> g. plus_game g zero_game" and g = "id"] 
           induct_hyp)
         done
     qed
@@ -974,3 +974,4 @@
 qed
 
 end
+

--- a/src/HOL/ZF/HOLZF.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/ZF/HOLZF.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -660,7 +660,7 @@
   "Ext R y \<equiv> { x . (x, y) \<in> R }" 
 
 lemma Ext_Elem: "Ext is_Elem_of = explode"
-  by (auto intro: ext simp add: Ext_def is_Elem_of_def explode_def)
+  by (auto simp add: Ext_def is_Elem_of_def explode_def)
 
 lemma "Ext SpecialR Empty \<noteq> explode z"
 proof 
@@ -892,3 +892,4 @@
   by (auto intro: set_like_subset wf_subset simp add: wf_eq_wfzf[symmetric])  
 
 end
+

--- a/src/HOL/ex/Set_Theory.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/ex/Set_Theory.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -128,7 +128,7 @@
   let ?n = "card A"
   have "finite A" using `card A \<ge> 2` by(auto intro:ccontr)
   have 0: "R `` A <= A" using `sym R` `Domain R <= A`
-    unfolding Domain_def sym_def by blast
+    unfolding Domain_unfold sym_def by blast
   have h: "ALL a:A. R `` {a} <= A" using 0 by blast
   hence 1: "ALL a:A. finite(R `` {a})" using `finite A`
     by(blast intro: finite_subset)

--- a/src/HOL/ex/Tarski.thy	Thu Mar 01 17:13:54 2012 +0000
+++ b/src/HOL/ex/Tarski.thy	Thu Mar 01 19:34:52 2012 +0100
@@ -227,10 +227,10 @@
 by (simp add: glb_def greatest_def isGlb_def some_eq_ex [symmetric])
 
 lemma isGlb_dual_isLub: "isGlb S cl = isLub S (dual cl)"
-by (simp add: isLub_def isGlb_def dual_def converse_def)
+by (simp add: isLub_def isGlb_def dual_def converse_unfold)
 
 lemma isLub_dual_isGlb: "isLub S cl = isGlb S (dual cl)"
-by (simp add: isLub_def isGlb_def dual_def converse_def)
+by (simp add: isLub_def isGlb_def dual_def converse_unfold)
 
 lemma (in PO) dualPO: "dual cl \<in> PartialOrder"
 apply (insert cl_po)
@@ -251,10 +251,10 @@
 done
 
 lemma lub_dual_glb: "lub S cl = glb S (dual cl)"
-by (simp add: lub_def glb_def least_def greatest_def dual_def converse_def)
+by (simp add: lub_def glb_def least_def greatest_def dual_def converse_unfold)
 
 lemma glb_dual_lub: "glb S cl = lub S (dual cl)"
-by (simp add: lub_def glb_def least_def greatest_def dual_def converse_def)
+by (simp add: lub_def glb_def least_def greatest_def dual_def converse_unfold)
 
 lemma CL_subset_PO: "CompleteLattice \<subseteq> PartialOrder"
 by (simp add: PartialOrder_def CompleteLattice_def, fast)