(* Title: ZF/Ordinal.thy ID: $Id: Ordinal.thy,v 1.24 2005/06/17 14:15:09 haftmann Exp $ Author: Lawrence C Paulson, Cambridge University Computer Laboratory Copyright 1994 University of Cambridge *) header{*Transitive Sets and Ordinals*} theory Ordinal imports WF Bool equalities begin constdefs Memrel :: "i=>i" "Memrel(A) == {z: A*A . EX x y. z= & x:y }" Transset :: "i=>o" "Transset(i) == ALL x:i. x<=i" Ord :: "i=>o" "Ord(i) == Transset(i) & (ALL x:i. Transset(x))" lt :: "[i,i] => o" (infixl "<" 50) (*less-than on ordinals*) "io" "Limit(i) == Ord(i) & 0 succ(y) o" (infixl 50) (*less-than or equals*) translations "x le y" == "x < succ(y)" syntax (xsymbols) "op le" :: "[i,i] => o" (infixl "\" 50) (*less-than or equals*) syntax (HTML output) "op le" :: "[i,i] => o" (infixl "\" 50) (*less-than or equals*) subsection{*Rules for Transset*} subsubsection{*Three Neat Characterisations of Transset*} lemma Transset_iff_Pow: "Transset(A) <-> A<=Pow(A)" by (unfold Transset_def, blast) lemma Transset_iff_Union_succ: "Transset(A) <-> Union(succ(A)) = A" apply (unfold Transset_def) apply (blast elim!: equalityE) done lemma Transset_iff_Union_subset: "Transset(A) <-> Union(A) <= A" by (unfold Transset_def, blast) subsubsection{*Consequences of Downwards Closure*} lemma Transset_doubleton_D: "[| Transset(C); {a,b}: C |] ==> a:C & b: C" by (unfold Transset_def, blast) lemma Transset_Pair_D: "[| Transset(C); : C |] ==> a:C & b: C" apply (simp add: Pair_def) apply (blast dest: Transset_doubleton_D) done lemma Transset_includes_domain: "[| Transset(C); A*B <= C; b: B |] ==> A <= C" by (blast dest: Transset_Pair_D) lemma Transset_includes_range: "[| Transset(C); A*B <= C; a: A |] ==> B <= C" by (blast dest: Transset_Pair_D) subsubsection{*Closure Properties*} lemma Transset_0: "Transset(0)" by (unfold Transset_def, blast) lemma Transset_Un: "[| Transset(i); Transset(j) |] ==> Transset(i Un j)" by (unfold Transset_def, blast) lemma Transset_Int: "[| Transset(i); Transset(j) |] ==> Transset(i Int j)" by (unfold Transset_def, blast) lemma Transset_succ: "Transset(i) ==> Transset(succ(i))" by (unfold Transset_def, blast) lemma Transset_Pow: "Transset(i) ==> Transset(Pow(i))" by (unfold Transset_def, blast) lemma Transset_Union: "Transset(A) ==> Transset(Union(A))" by (unfold Transset_def, blast) lemma Transset_Union_family: "[| !!i. i:A ==> Transset(i) |] ==> Transset(Union(A))" by (unfold Transset_def, blast) lemma Transset_Inter_family: "[| !!i. i:A ==> Transset(i) |] ==> Transset(Inter(A))" by (unfold Inter_def Transset_def, blast) lemma Transset_UN: "(!!x. x \ A ==> Transset(B(x))) ==> Transset (\x\A. B(x))" by (rule Transset_Union_family, auto) lemma Transset_INT: "(!!x. x \ A ==> Transset(B(x))) ==> Transset (\x\A. B(x))" by (rule Transset_Inter_family, auto) subsection{*Lemmas for Ordinals*} lemma OrdI: "[| Transset(i); !!x. x:i ==> Transset(x) |] ==> Ord(i)" by (simp add: Ord_def) lemma Ord_is_Transset: "Ord(i) ==> Transset(i)" by (simp add: Ord_def) lemma Ord_contains_Transset: "[| Ord(i); j:i |] ==> Transset(j) " by (unfold Ord_def, blast) lemma Ord_in_Ord: "[| Ord(i); j:i |] ==> Ord(j)" by (unfold Ord_def Transset_def, blast) (*suitable for rewriting PROVIDED i has been fixed*) lemma Ord_in_Ord': "[| j:i; Ord(i) |] ==> Ord(j)" by (blast intro: Ord_in_Ord) (* Ord(succ(j)) ==> Ord(j) *) lemmas Ord_succD = Ord_in_Ord [OF _ succI1] lemma Ord_subset_Ord: "[| Ord(i); Transset(j); j<=i |] ==> Ord(j)" by (simp add: Ord_def Transset_def, blast) lemma OrdmemD: "[| j:i; Ord(i) |] ==> j<=i" by (unfold Ord_def Transset_def, blast) lemma Ord_trans: "[| i:j; j:k; Ord(k) |] ==> i:k" by (blast dest: OrdmemD) lemma Ord_succ_subsetI: "[| i:j; Ord(j) |] ==> succ(i) <= j" by (blast dest: OrdmemD) subsection{*The Construction of Ordinals: 0, succ, Union*} lemma Ord_0 [iff,TC]: "Ord(0)" by (blast intro: OrdI Transset_0) lemma Ord_succ [TC]: "Ord(i) ==> Ord(succ(i))" by (blast intro: OrdI Transset_succ Ord_is_Transset Ord_contains_Transset) lemmas Ord_1 = Ord_0 [THEN Ord_succ] lemma Ord_succ_iff [iff]: "Ord(succ(i)) <-> Ord(i)" by (blast intro: Ord_succ dest!: Ord_succD) lemma Ord_Un [intro,simp,TC]: "[| Ord(i); Ord(j) |] ==> Ord(i Un j)" apply (unfold Ord_def) apply (blast intro!: Transset_Un) done lemma Ord_Int [TC]: "[| Ord(i); Ord(j) |] ==> Ord(i Int j)" apply (unfold Ord_def) apply (blast intro!: Transset_Int) done (*There is no set of all ordinals, for then it would contain itself*) lemma ON_class: "~ (ALL i. i:X <-> Ord(i))" apply (rule notI) apply (frule_tac x = X in spec) apply (safe elim!: mem_irrefl) apply (erule swap, rule OrdI [OF _ Ord_is_Transset]) apply (simp add: Transset_def) apply (blast intro: Ord_in_Ord)+ done subsection{*< is 'less Than' for Ordinals*} lemma ltI: "[| i:j; Ord(j) |] ==> i P |] ==> P" apply (unfold lt_def) apply (blast intro: Ord_in_Ord) done lemma ltD: "i i:j" by (erule ltE, assumption) lemma not_lt0 [simp]: "~ i<0" by (unfold lt_def, blast) lemma lt_Ord: "j Ord(j)" by (erule ltE, assumption) lemma lt_Ord2: "j Ord(i)" by (erule ltE, assumption) (* "ja le j ==> Ord(j)" *) lemmas le_Ord2 = lt_Ord2 [THEN Ord_succD] (* i<0 ==> R *) lemmas lt0E = not_lt0 [THEN notE, elim!] lemma lt_trans: "[| i i ~ (j j P *) lemmas lt_asym = lt_not_sym [THEN swap] lemma lt_irrefl [elim!]: "i P" by (blast intro: lt_asym) lemma lt_not_refl: "~ i i i < succ(j)*) lemma leI: "i i le j" by (simp (no_asm_simp) add: le_iff) lemma le_eqI: "[| i=j; Ord(j) |] ==> i le j" by (simp (no_asm_simp) add: le_iff) lemmas le_refl = refl [THEN le_eqI] lemma le_refl_iff [iff]: "i le i <-> Ord(i)" by (simp (no_asm_simp) add: lt_not_refl le_iff) lemma leCI: "(~ (i=j & Ord(j)) ==> i i le j" by (simp add: le_iff, blast) lemma leE: "[| i le j; i P; [| i=j; Ord(j) |] ==> P |] ==> P" by (simp add: le_iff, blast) lemma le_anti_sym: "[| i le j; j le i |] ==> i=j" apply (simp add: le_iff) apply (blast elim: lt_asym) done lemma le0_iff [simp]: "i le 0 <-> i=0" by (blast elim!: leE) lemmas le0D = le0_iff [THEN iffD1, dest!] subsection{*Natural Deduction Rules for Memrel*} (*The lemmas MemrelI/E give better speed than [iff] here*) lemma Memrel_iff [simp]: " : Memrel(A) <-> a:b & a:A & b:A" by (unfold Memrel_def, blast) lemma MemrelI [intro!]: "[| a: b; a: A; b: A |] ==> : Memrel(A)" by auto lemma MemrelE [elim!]: "[| : Memrel(A); [| a: A; b: A; a:b |] ==> P |] ==> P" by auto lemma Memrel_type: "Memrel(A) <= A*A" by (unfold Memrel_def, blast) lemma Memrel_mono: "A<=B ==> Memrel(A) <= Memrel(B)" by (unfold Memrel_def, blast) lemma Memrel_0 [simp]: "Memrel(0) = 0" by (unfold Memrel_def, blast) lemma Memrel_1 [simp]: "Memrel(1) = 0" by (unfold Memrel_def, blast) lemma relation_Memrel: "relation(Memrel(A))" by (simp add: relation_def Memrel_def) (*The membership relation (as a set) is well-founded. Proof idea: show A<=B by applying the foundation axiom to A-B *) lemma wf_Memrel: "wf(Memrel(A))" apply (unfold wf_def) apply (rule foundation [THEN disjE, THEN allI], erule disjI1, blast) done text{*The premise @{term "Ord(i)"} does not suffice.*} lemma trans_Memrel: "Ord(i) ==> trans(Memrel(i))" by (unfold Ord_def Transset_def trans_def, blast) text{*However, the following premise is strong enough.*} lemma Transset_trans_Memrel: "\j\i. Transset(j) ==> trans(Memrel(i))" by (unfold Transset_def trans_def, blast) (*If Transset(A) then Memrel(A) internalizes the membership relation below A*) lemma Transset_Memrel_iff: "Transset(A) ==> : Memrel(A) <-> a:b & b:A" by (unfold Transset_def, blast) subsection{*Transfinite Induction*} (*Epsilon induction over a transitive set*) lemma Transset_induct: "[| i: k; Transset(k); !!x.[| x: k; ALL y:x. P(y) |] ==> P(x) |] ==> P(i)" apply (simp add: Transset_def) apply (erule wf_Memrel [THEN wf_induct2], blast+) done (*Induction over an ordinal*) lemmas Ord_induct [consumes 2] = Transset_induct [OF _ Ord_is_Transset] lemmas Ord_induct_rule = Ord_induct [rule_format, consumes 2] (*Induction over the class of ordinals -- a useful corollary of Ord_induct*) lemma trans_induct [consumes 1]: "[| Ord(i); !!x.[| Ord(x); ALL y:x. P(y) |] ==> P(x) |] ==> P(i)" apply (rule Ord_succ [THEN succI1 [THEN Ord_induct]], assumption) apply (blast intro: Ord_succ [THEN Ord_in_Ord]) done lemmas trans_induct_rule = trans_induct [rule_format, consumes 1] (*** Fundamental properties of the epsilon ordering (< on ordinals) ***) subsubsection{*Proving That < is a Linear Ordering on the Ordinals*} lemma Ord_linear [rule_format]: "Ord(i) ==> (ALL j. Ord(j) --> i:j | i=j | j:i)" apply (erule trans_induct) apply (rule impI [THEN allI]) apply (erule_tac i=j in trans_induct) apply (blast dest: Ord_trans) done (*The trichotomy law for ordinals!*) lemma Ord_linear_lt: "[| Ord(i); Ord(j); i P; i=j ==> P; j P |] ==> P" apply (simp add: lt_def) apply (rule_tac i1=i and j1=j in Ord_linear [THEN disjE], blast+) done lemma Ord_linear2: "[| Ord(i); Ord(j); i P; j le i ==> P |] ==> P" apply (rule_tac i = i and j = j in Ord_linear_lt) apply (blast intro: leI le_eqI sym ) + done lemma Ord_linear_le: "[| Ord(i); Ord(j); i le j ==> P; j le i ==> P |] ==> P" apply (rule_tac i = i and j = j in Ord_linear_lt) apply (blast intro: leI le_eqI ) + done lemma le_imp_not_lt: "j le i ==> ~ i j le i" by (rule_tac i = i and j = j in Ord_linear2, auto) subsubsection{*Some Rewrite Rules for <, le*} lemma Ord_mem_iff_lt: "Ord(j) ==> i:j <-> i ~ i j le i" by (blast dest: le_imp_not_lt not_lt_imp_le) lemma not_le_iff_lt: "[| Ord(i); Ord(j) |] ==> ~ i le j <-> j 0 le i" by (erule not_lt_iff_le [THEN iffD1], auto) lemma Ord_0_lt: "[| Ord(i); i~=0 |] ==> 0 i~=0 <-> 0 Ord(x)" by (blast intro: Ord_0_le elim: ltE) lemma subset_imp_le: "[| j<=i; Ord(i); Ord(j) |] ==> j le i" apply (rule not_lt_iff_le [THEN iffD1], assumption+) apply (blast elim: ltE mem_irrefl) done lemma le_imp_subset: "i le j ==> i<=j" by (blast dest: OrdmemD elim: ltE leE) lemma le_subset_iff: "j le i <-> j<=i & Ord(i) & Ord(j)" by (blast dest: subset_imp_le le_imp_subset elim: ltE) lemma le_succ_iff: "i le succ(j) <-> i le j | i=succ(j) & Ord(i)" apply (simp (no_asm) add: le_iff) apply blast done (*Just a variant of subset_imp_le*) lemma all_lt_imp_le: "[| Ord(i); Ord(j); !!x. x x j le i" by (blast intro: not_lt_imp_le dest: lt_irrefl) subsubsection{*Transitivity Laws*} lemma lt_trans1: "[| i le j; j i i i le k" by (blast intro: lt_trans1) lemma succ_leI: "i succ(i) le j" apply (rule not_lt_iff_le [THEN iffD1]) apply (blast elim: ltE leE lt_asym)+ done (*Identical to succ(i) < succ(j) ==> i i i i le j" by (blast dest!: succ_leE) lemma lt_subset_trans: "[| i <= j; j i 0 i j" apply auto apply (blast intro: lt_trans le_refl dest: lt_Ord) apply (frule lt_Ord) apply (rule not_le_iff_lt [THEN iffD1]) apply (blast intro: lt_Ord2) apply blast apply (simp add: lt_Ord lt_Ord2 le_iff) apply (blast dest: lt_asym) done lemma Ord_succ_mem_iff: "Ord(j) ==> succ(i) \ succ(j) <-> i\j" apply (insert succ_le_iff [of i j]) apply (simp add: lt_def) done subsubsection{*Union and Intersection*} lemma Un_upper1_le: "[| Ord(i); Ord(j) |] ==> i le i Un j" by (rule Un_upper1 [THEN subset_imp_le], auto) lemma Un_upper2_le: "[| Ord(i); Ord(j) |] ==> j le i Un j" by (rule Un_upper2 [THEN subset_imp_le], auto) (*Replacing k by succ(k') yields the similar rule for le!*) lemma Un_least_lt: "[| i i Un j < k" apply (rule_tac i = i and j = j in Ord_linear_le) apply (auto simp add: Un_commute le_subset_iff subset_Un_iff lt_Ord) done lemma Un_least_lt_iff: "[| Ord(i); Ord(j) |] ==> i Un j < k <-> i i Un j : k <-> i:k & j:k" apply (insert Un_least_lt_iff [of i j k]) apply (simp add: lt_def) done (*Replacing k by succ(k') yields the similar rule for le!*) lemma Int_greatest_lt: "[| i i Int j < k" apply (rule_tac i = i and j = j in Ord_linear_le) apply (auto simp add: Int_commute le_subset_iff subset_Int_iff lt_Ord) done lemma Ord_Un_if: "[| Ord(i); Ord(j) |] ==> i \ j = (if j succ(i \ j) = succ(i) \ succ(j)" by (simp add: Ord_Un_if lt_Ord le_Ord2) lemma lt_Un_iff: "[| Ord(i); Ord(j) |] ==> k < i \ j <-> k < i | k < j"; apply (simp add: Ord_Un_if not_lt_iff_le) apply (blast intro: leI lt_trans2)+ done lemma le_Un_iff: "[| Ord(i); Ord(j) |] ==> k \ i \ j <-> k \ i | k \ j"; by (simp add: succ_Un_distrib lt_Un_iff [symmetric]) lemma Un_upper1_lt: "[|k < i; Ord(j)|] ==> k < i Un j" by (simp add: lt_Un_iff lt_Ord2) lemma Un_upper2_lt: "[|k < j; Ord(i)|] ==> k < i Un j" by (simp add: lt_Un_iff lt_Ord2) (*See also Transset_iff_Union_succ*) lemma Ord_Union_succ_eq: "Ord(i) ==> \(succ(i)) = i" by (blast intro: Ord_trans) subsection{*Results about Limits*} lemma Ord_Union [intro,simp,TC]: "[| !!i. i:A ==> Ord(i) |] ==> Ord(Union(A))" apply (rule Ord_is_Transset [THEN Transset_Union_family, THEN OrdI]) apply (blast intro: Ord_contains_Transset)+ done lemma Ord_UN [intro,simp,TC]: "[| !!x. x:A ==> Ord(B(x)) |] ==> Ord(\x\A. B(x))" by (rule Ord_Union, blast) lemma Ord_Inter [intro,simp,TC]: "[| !!i. i:A ==> Ord(i) |] ==> Ord(Inter(A))" apply (rule Transset_Inter_family [THEN OrdI]) apply (blast intro: Ord_is_Transset) apply (simp add: Inter_def) apply (blast intro: Ord_contains_Transset) done lemma Ord_INT [intro,simp,TC]: "[| !!x. x:A ==> Ord(B(x)) |] ==> Ord(\x\A. B(x))" by (rule Ord_Inter, blast) (* No < version; consider (\i\nat.i)=nat *) lemma UN_least_le: "[| Ord(i); !!x. x:A ==> b(x) le i |] ==> (\x\A. b(x)) le i" apply (rule le_imp_subset [THEN UN_least, THEN subset_imp_le]) apply (blast intro: Ord_UN elim: ltE)+ done lemma UN_succ_least_lt: "[| j b(x) (\x\A. succ(b(x))) < i" apply (rule ltE, assumption) apply (rule UN_least_le [THEN lt_trans2]) apply (blast intro: succ_leI)+ done lemma UN_upper_lt: "[| a\A; i < b(a); Ord(\x\A. b(x)) |] ==> i < (\x\A. b(x))" by (unfold lt_def, blast) lemma UN_upper_le: "[| a: A; i le b(a); Ord(\x\A. b(x)) |] ==> i le (\x\A. b(x))" apply (frule ltD) apply (rule le_imp_subset [THEN subset_trans, THEN subset_imp_le]) apply (blast intro: lt_Ord UN_upper)+ done lemma lt_Union_iff: "\i\A. Ord(i) ==> (j < \(A)) <-> (\i\A. jj; Ord(\(J)) |] ==> i \ \J" apply (subst Union_eq_UN) apply (rule UN_upper_le, auto) done lemma le_implies_UN_le_UN: "[| !!x. x:A ==> c(x) le d(x) |] ==> (\x\A. c(x)) le (\x\A. d(x))" apply (rule UN_least_le) apply (rule_tac [2] UN_upper_le) apply (blast intro: Ord_UN le_Ord2)+ done lemma Ord_equality: "Ord(i) ==> (\y\i. succ(y)) = i" by (blast intro: Ord_trans) (*Holds for all transitive sets, not just ordinals*) lemma Ord_Union_subset: "Ord(i) ==> Union(i) <= i" by (blast intro: Ord_trans) subsection{*Limit Ordinals -- General Properties*} lemma Limit_Union_eq: "Limit(i) ==> Union(i) = i" apply (unfold Limit_def) apply (fast intro!: ltI elim!: ltE elim: Ord_trans) done lemma Limit_is_Ord: "Limit(i) ==> Ord(i)" apply (unfold Limit_def) apply (erule conjunct1) done lemma Limit_has_0: "Limit(i) ==> 0 < i" apply (unfold Limit_def) apply (erule conjunct2 [THEN conjunct1]) done lemma Limit_nonzero: "Limit(i) ==> i ~= 0" by (drule Limit_has_0, blast) lemma Limit_has_succ: "[| Limit(i); j succ(j) < i" by (unfold Limit_def, blast) lemma Limit_succ_lt_iff [simp]: "Limit(i) ==> succ(j) < i <-> (j 1 < i" by (blast intro: Limit_has_0 Limit_has_succ) lemma increasing_LimitI: "[| 0x\l. \y\l. x Limit(l)" apply (unfold Limit_def, simp add: lt_Ord2, clarify) apply (drule_tac i=y in ltD) apply (blast intro: lt_trans1 [OF _ ltI] lt_Ord2) done lemma non_succ_LimitI: "[| 0 Limit(i)" apply (unfold Limit_def) apply (safe del: subsetI) apply (rule_tac [2] not_le_iff_lt [THEN iffD1]) apply (simp_all add: lt_Ord lt_Ord2) apply (blast elim: leE lt_asym) done lemma succ_LimitE [elim!]: "Limit(succ(i)) ==> P" apply (rule lt_irrefl) apply (rule Limit_has_succ, assumption) apply (erule Limit_is_Ord [THEN Ord_succD, THEN le_refl]) done lemma not_succ_Limit [simp]: "~ Limit(succ(i))" by blast lemma Limit_le_succD: "[| Limit(i); i le succ(j) |] ==> i le j" by (blast elim!: leE) subsubsection{*Traditional 3-Way Case Analysis on Ordinals*} lemma Ord_cases_disj: "Ord(i) ==> i=0 | (EX j. Ord(j) & i=succ(j)) | Limit(i)" by (blast intro!: non_succ_LimitI Ord_0_lt) lemma Ord_cases: "[| Ord(i); i=0 ==> P; !!j. [| Ord(j); i=succ(j) |] ==> P; Limit(i) ==> P |] ==> P" by (drule Ord_cases_disj, blast) lemma trans_induct3 [case_names 0 succ limit, consumes 1]: "[| Ord(i); P(0); !!x. [| Ord(x); P(x) |] ==> P(succ(x)); !!x. [| Limit(x); ALL y:x. P(y) |] ==> P(x) |] ==> P(i)" apply (erule trans_induct) apply (erule Ord_cases, blast+) done lemmas trans_induct3_rule = trans_induct3 [rule_format, case_names 0 succ limit, consumes 1] text{*A set of ordinals is either empty, contains its own union, or its union is a limit ordinal.*} lemma Ord_set_cases: "\i\I. Ord(i) ==> I=0 \ \(I) \ I \ (\(I) \ I \ Limit(\(I)))" apply (clarify elim!: not_emptyE) apply (cases "\(I)" rule: Ord_cases) apply (blast intro: Ord_Union) apply (blast intro: subst_elem) apply auto apply (clarify elim!: equalityE succ_subsetE) apply (simp add: Union_subset_iff) apply (subgoal_tac "B = succ(j)", blast) apply (rule le_anti_sym) apply (simp add: le_subset_iff) apply (simp add: ltI) done text{*If the union of a set of ordinals is a successor, then it is an element of that set.*} lemma Ord_Union_eq_succD: "[|\x\X. Ord(x); \X = succ(j)|] ==> succ(j) \ X" by (drule Ord_set_cases, auto) lemma Limit_Union [rule_format]: "[| I \ 0; \i\I. Limit(i) |] ==> Limit(\I)" apply (simp add: Limit_def lt_def) apply (blast intro!: equalityI) done ML {* val Memrel_def = thm "Memrel_def"; val Transset_def = thm "Transset_def"; val Ord_def = thm "Ord_def"; val lt_def = thm "lt_def"; val Limit_def = thm "Limit_def"; val Transset_iff_Pow = thm "Transset_iff_Pow"; val Transset_iff_Union_succ = thm "Transset_iff_Union_succ"; val Transset_iff_Union_subset = thm "Transset_iff_Union_subset"; val Transset_doubleton_D = thm "Transset_doubleton_D"; val Transset_Pair_D = thm "Transset_Pair_D"; val Transset_includes_domain = thm "Transset_includes_domain"; val Transset_includes_range = thm "Transset_includes_range"; val Transset_0 = thm "Transset_0"; val Transset_Un = thm "Transset_Un"; val Transset_Int = thm "Transset_Int"; val Transset_succ = thm "Transset_succ"; val Transset_Pow = thm "Transset_Pow"; val Transset_Union = thm "Transset_Union"; val Transset_Union_family = thm "Transset_Union_family"; val Transset_Inter_family = thm "Transset_Inter_family"; val OrdI = thm "OrdI"; val Ord_is_Transset = thm "Ord_is_Transset"; val Ord_contains_Transset = thm "Ord_contains_Transset"; val Ord_in_Ord = thm "Ord_in_Ord"; val Ord_succD = thm "Ord_succD"; val Ord_subset_Ord = thm "Ord_subset_Ord"; val OrdmemD = thm "OrdmemD"; val Ord_trans = thm "Ord_trans"; val Ord_succ_subsetI = thm "Ord_succ_subsetI"; val Ord_0 = thm "Ord_0"; val Ord_succ = thm "Ord_succ"; val Ord_1 = thm "Ord_1"; val Ord_succ_iff = thm "Ord_succ_iff"; val Ord_Un = thm "Ord_Un"; val Ord_Int = thm "Ord_Int"; val Ord_Inter = thm "Ord_Inter"; val Ord_INT = thm "Ord_INT"; val ON_class = thm "ON_class"; val ltI = thm "ltI"; val ltE = thm "ltE"; val ltD = thm "ltD"; val not_lt0 = thm "not_lt0"; val lt_Ord = thm "lt_Ord"; val lt_Ord2 = thm "lt_Ord2"; val le_Ord2 = thm "le_Ord2"; val lt0E = thm "lt0E"; val lt_trans = thm "lt_trans"; val lt_not_sym = thm "lt_not_sym"; val lt_asym = thm "lt_asym"; val lt_irrefl = thm "lt_irrefl"; val lt_not_refl = thm "lt_not_refl"; val le_iff = thm "le_iff"; val leI = thm "leI"; val le_eqI = thm "le_eqI"; val le_refl = thm "le_refl"; val le_refl_iff = thm "le_refl_iff"; val leCI = thm "leCI"; val leE = thm "leE"; val le_anti_sym = thm "le_anti_sym"; val le0_iff = thm "le0_iff"; val le0D = thm "le0D"; val Memrel_iff = thm "Memrel_iff"; val MemrelI = thm "MemrelI"; val MemrelE = thm "MemrelE"; val Memrel_type = thm "Memrel_type"; val Memrel_mono = thm "Memrel_mono"; val Memrel_0 = thm "Memrel_0"; val Memrel_1 = thm "Memrel_1"; val wf_Memrel = thm "wf_Memrel"; val trans_Memrel = thm "trans_Memrel"; val Transset_Memrel_iff = thm "Transset_Memrel_iff"; val Transset_induct = thm "Transset_induct"; val Ord_induct = thm "Ord_induct"; val trans_induct = thm "trans_induct"; val Ord_linear = thm "Ord_linear"; val Ord_linear_lt = thm "Ord_linear_lt"; val Ord_linear2 = thm "Ord_linear2"; val Ord_linear_le = thm "Ord_linear_le"; val le_imp_not_lt = thm "le_imp_not_lt"; val not_lt_imp_le = thm "not_lt_imp_le"; val Ord_mem_iff_lt = thm "Ord_mem_iff_lt"; val not_lt_iff_le = thm "not_lt_iff_le"; val not_le_iff_lt = thm "not_le_iff_lt"; val Ord_0_le = thm "Ord_0_le"; val Ord_0_lt = thm "Ord_0_lt"; val Ord_0_lt_iff = thm "Ord_0_lt_iff"; val zero_le_succ_iff = thm "zero_le_succ_iff"; val subset_imp_le = thm "subset_imp_le"; val le_imp_subset = thm "le_imp_subset"; val le_subset_iff = thm "le_subset_iff"; val le_succ_iff = thm "le_succ_iff"; val all_lt_imp_le = thm "all_lt_imp_le"; val lt_trans1 = thm "lt_trans1"; val lt_trans2 = thm "lt_trans2"; val le_trans = thm "le_trans"; val succ_leI = thm "succ_leI"; val succ_leE = thm "succ_leE"; val succ_le_iff = thm "succ_le_iff"; val succ_le_imp_le = thm "succ_le_imp_le"; val lt_subset_trans = thm "lt_subset_trans"; val Un_upper1_le = thm "Un_upper1_le"; val Un_upper2_le = thm "Un_upper2_le"; val Un_least_lt = thm "Un_least_lt"; val Un_least_lt_iff = thm "Un_least_lt_iff"; val Un_least_mem_iff = thm "Un_least_mem_iff"; val Int_greatest_lt = thm "Int_greatest_lt"; val Ord_Union = thm "Ord_Union"; val Ord_UN = thm "Ord_UN"; val UN_least_le = thm "UN_least_le"; val UN_succ_least_lt = thm "UN_succ_least_lt"; val UN_upper_le = thm "UN_upper_le"; val le_implies_UN_le_UN = thm "le_implies_UN_le_UN"; val Ord_equality = thm "Ord_equality"; val Ord_Union_subset = thm "Ord_Union_subset"; val Limit_Union_eq = thm "Limit_Union_eq"; val Limit_is_Ord = thm "Limit_is_Ord"; val Limit_has_0 = thm "Limit_has_0"; val Limit_has_succ = thm "Limit_has_succ"; val non_succ_LimitI = thm "non_succ_LimitI"; val succ_LimitE = thm "succ_LimitE"; val not_succ_Limit = thm "not_succ_Limit"; val Limit_le_succD = thm "Limit_le_succD"; val Ord_cases_disj = thm "Ord_cases_disj"; val Ord_cases = thm "Ord_cases"; val trans_induct3 = thm "trans_induct3"; *} end